necp.c   [plain text]

/*
 * Copyright (c) 2013-2019 Apple Inc. All rights reserved.
 *
 * @APPLE_OSREFERENCE_LICENSE_HEADER_START@
 *
 * This file contains Original Code and/or Modifications of Original Code
 * as defined in and that are subject to the Apple Public Source License
 * Version 2.0 (the 'License'). You may not use this file except in
 * compliance with the License. The rights granted to you under the License
 * may not be used to create, or enable the creation or redistribution of,
 * unlawful or unlicensed copies of an Apple operating system, or to
 * circumvent, violate, or enable the circumvention or violation of, any
 * terms of an Apple operating system software license agreement.
 *
 * Please obtain a copy of the License at
 * http://www.opensource.apple.com/apsl/ and read it before using this file.
 *
 * The Original Code and all software distributed under the License are
 * distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER
 * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
 * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY,
 * FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT.
 * Please see the License for the specific language governing rights and
 * limitations under the License.
 *
 * @APPLE_OSREFERENCE_LICENSE_HEADER_END@
 */

#include <string.h>
#include <sys/systm.h>
#include <sys/types.h>
#include <sys/queue.h>
#include <sys/malloc.h>
#include <libkern/OSMalloc.h>
#include <sys/kernel.h>
#include <sys/kern_control.h>
#include <sys/mbuf.h>
#include <sys/kpi_mbuf.h>
#include <sys/proc_uuid_policy.h>
#include <net/if.h>
#include <sys/domain.h>
#include <sys/protosw.h>
#include <sys/socket.h>
#include <sys/socketvar.h>
#include <sys/coalition.h>
#include <sys/ubc.h>
#include <sys/codesign.h>
#include <kern/cs_blobs.h>
#include <netinet/ip.h>
#include <netinet/ip6.h>
#include <netinet/tcp.h>
#include <netinet/tcp_var.h>
#include <netinet/tcp_cache.h>
#include <netinet/udp.h>
#include <netinet/in_pcb.h>
#include <netinet/in_tclass.h>
#include <netinet6/esp.h>
#include <net/flowhash.h>
#include <net/if_var.h>
#include <sys/kauth.h>
#include <sys/sysctl.h>
#include <sys/sysproto.h>
#include <sys/priv.h>
#include <sys/kern_event.h>
#include <sys/file_internal.h>
#include <IOKit/IOBSD.h>
#include <libkern/crypto/rand.h>
#include <corecrypto/cchmac.h>
#include <corecrypto/ccsha2.h>
#include <os/refcnt.h>
#include <net/network_agent.h>
#include <net/necp.h>

/*
 * NECP - Network Extension Control Policy database
 * ------------------------------------------------
 * The goal of this module is to allow clients connecting via a
 * policy file descriptor to create high-level policy sessions, which
 * are ingested into low-level kernel policies that control and tag
 * traffic at the application, socket, and IP layers.
 *
 * ------------------------------------------------
 * Sessions
 * ------------------------------------------------
 * Each session owns a list of session policies, each of which can
 * specify any combination of conditions and a single result. Each
 * session also has a priority level (such as High, Default, or Low)
 * which is requested by the client. Based on the requested level,
 * a session order value is assigned to the session, which will be used
 * to sort kernel policies generated by the session. The session client
 * can specify the sub-order for each policy it creates which will be
 * used to further sort the kernel policies.
 *
 *  Policy fd --> 1 necp_session --> list of necp_session_policy structs
 *
 * ------------------------------------------------
 * Kernel Policies
 * ------------------------------------------------
 * Whenever a session send the Apply command, its policies are ingested
 * and generate kernel policies. There are two phases of kernel policy
 * ingestion.
 *
 * 1. The session policy is parsed to create kernel policies at the socket
 *	  and IP layers, when applicable. For example, a policy that requires
 *    all traffic from App1 to Pass will generate a socket kernel policy to
 *    match App1 and mark packets with ID1, and also an IP policy to match
 *    ID1 and let the packet pass. This is handled in necp_apply_policy. The
 *    resulting kernel policies are added to the global socket and IP layer
 *    policy lists.
 *  necp_session_policy --> necp_kernel_socket_policy and necp_kernel_ip_output_policy
 *                                      ||                             ||
 *                                      \/                             \/
 *                          necp_kernel_socket_policies   necp_kernel_ip_output_policies
 *
 * 2. Once the global lists of kernel policies have been filled out, each
 *    list is traversed to create optimized sub-lists ("Maps") which are used during
 *    data-path evaluation. IP policies are sent into necp_kernel_ip_output_policies_map,
 *    which hashes incoming packets based on marked socket-layer policies, and removes
 *    duplicate or overlapping policies. Socket policies are sent into two maps,
 *    necp_kernel_socket_policies_map and necp_kernel_socket_policies_app_layer_map.
 *    The app layer map is used for policy checks coming in from user space, and is one
 *    list with duplicate and overlapping policies removed. The socket map hashes based
 *    on app UUID, and removes duplicate and overlapping policies.
 *  necp_kernel_socket_policy --> necp_kernel_socket_policies_app_layer_map
 *                            |-> necp_kernel_socket_policies_map
 *
 *  necp_kernel_ip_output_policies --> necp_kernel_ip_output_policies_map
 *
 * ------------------------------------------------
 * Drop All Level
 * ------------------------------------------------
 * The Drop All Level is a sysctl that controls the level at which policies are allowed
 * to override a global drop rule. If the value is 0, no drop rule is applied. If the value
 * is 1, all traffic is dropped. If the value is greater than 1, all kernel policies created
 * by a session with a priority level better than (numerically less than) the
 * Drop All Level will allow matching traffic to not be dropped. The Drop All Level is
 * dynamically interpreted into necp_drop_all_order, which specifies the equivalent assigned
 * session orders to be dropped.
 */

u_int32_t necp_drop_all_order = 0;
u_int32_t necp_drop_all_level = 0;

u_int32_t necp_pass_loopback = 1; // 0=Off, 1=On
u_int32_t necp_pass_keepalives = 1; // 0=Off, 1=On
u_int32_t necp_pass_interpose = 1; // 0=Off, 1=On

u_int32_t necp_drop_unentitled_order = 0;
#ifdef XNU_TARGET_OS_WATCH
u_int32_t necp_drop_unentitled_level = NECP_SESSION_PRIORITY_CONTROL + 1; // Block all unentitled traffic from policies below control level
#else // XNU_TARGET_OS_WATCH
u_int32_t necp_drop_unentitled_level = 0;
#endif // XNU_TARGET_OS_WATCH

u_int32_t necp_debug = 0; // 0=None, 1=Basic, 2=EveryMatch

u_int32_t necp_session_count = 0;

#define LIST_INSERT_SORTED_ASCENDING(head, elm, field, sortfield, tmpelm) do {          \
	if (LIST_EMPTY((head)) || (LIST_FIRST(head)->sortfield >= (elm)->sortfield)) {  \
	        LIST_INSERT_HEAD((head), elm, field);                                                                           \
	} else {                                                                                                                                                \
	        LIST_FOREACH(tmpelm, head, field) {                                                                                     \
	                if (LIST_NEXT(tmpelm, field) == NULL || LIST_NEXT(tmpelm, field)->sortfield >= (elm)->sortfield) {      \
	                        LIST_INSERT_AFTER(tmpelm, elm, field);                                                          \
	                        break;                                                                                                                          \
	                }                                                                                                                                               \
	        }                                                                                                                                                       \
	}                                                                                                                                                               \
} while (0)

#define LIST_INSERT_SORTED_TWICE_ASCENDING(head, elm, field, firstsortfield, secondsortfield, tmpelm) do {      \
	if (LIST_EMPTY((head)) || (LIST_FIRST(head)->firstsortfield > (elm)->firstsortfield) || ((LIST_FIRST(head)->firstsortfield == (elm)->firstsortfield) && (LIST_FIRST(head)->secondsortfield >= (elm)->secondsortfield))) {                                                                                                               \
	        LIST_INSERT_HEAD((head), elm, field);                                                                           \
	} else {                                                                                                                                                \
	        LIST_FOREACH(tmpelm, head, field) {                                                                                     \
	                if (LIST_NEXT(tmpelm, field) == NULL || (LIST_NEXT(tmpelm, field)->firstsortfield > (elm)->firstsortfield) || ((LIST_NEXT(tmpelm, field)->firstsortfield == (elm)->firstsortfield) && (LIST_NEXT(tmpelm, field)->secondsortfield >= (elm)->secondsortfield))) {         \
	                        LIST_INSERT_AFTER(tmpelm, elm, field);                                                          \
	                        break;                                                                                                                          \
	                }                                                                                                                                               \
	        }                                                                                                                                                       \
	}                                                                                                                                                               \
} while (0)

#define LIST_INSERT_SORTED_THRICE_ASCENDING(head, elm, field, firstsortfield, secondsortfield, thirdsortfield, tmpelm) do { \
	if (LIST_EMPTY((head)) || (LIST_FIRST(head)->firstsortfield > (elm)->firstsortfield) || ((LIST_FIRST(head)->firstsortfield == (elm)->firstsortfield) && (LIST_FIRST(head)->secondsortfield >= (elm)->secondsortfield)) || ((LIST_FIRST(head)->firstsortfield == (elm)->firstsortfield) && (LIST_FIRST(head)->secondsortfield == (elm)->secondsortfield) && (LIST_FIRST(head)->thirdsortfield >= (elm)->thirdsortfield))) {                                                                                                                      \
	        LIST_INSERT_HEAD((head), elm, field);                                                                           \
	} else {                                                                                                                                                \
	        LIST_FOREACH(tmpelm, head, field) {                                                                                     \
	                if (LIST_NEXT(tmpelm, field) == NULL || (LIST_NEXT(tmpelm, field)->firstsortfield > (elm)->firstsortfield) || ((LIST_NEXT(tmpelm, field)->firstsortfield == (elm)->firstsortfield) && (LIST_NEXT(tmpelm, field)->secondsortfield >= (elm)->secondsortfield)) || ((LIST_NEXT(tmpelm, field)->firstsortfield == (elm)->firstsortfield) && (LIST_NEXT(tmpelm, field)->secondsortfield == (elm)->secondsortfield) && (LIST_NEXT(tmpelm, field)->thirdsortfield >= (elm)->thirdsortfield)))	{ \
	                        LIST_INSERT_AFTER(tmpelm, elm, field);                                                          \
	                        break;                                                                                                                          \
	                }                                                                                                                                               \
	        }                                                                                                                                                       \
	}                                                                                                                                                               \
} while (0)

#define IS_NECP_ROUTE_RULE_ALLOW_OR_DENY(x)     ((x) == NECP_ROUTE_RULE_DENY_INTERFACE || (x) == NECP_ROUTE_RULE_ALLOW_INTERFACE)

#define IS_NECP_DEST_IN_LOCAL_NETWORKS(rt) \
    ((rt) != NULL && !((rt)->rt_flags & RTF_GATEWAY) && ((rt)->rt_ifa && (rt)->rt_ifa->ifa_ifp && !((rt)->rt_ifa->ifa_ifp->if_flags & IFF_POINTOPOINT)))

#define NECP_KERNEL_CONDITION_ALL_INTERFACES            0x000001
#define NECP_KERNEL_CONDITION_BOUND_INTERFACE           0x000002
#define NECP_KERNEL_CONDITION_PROTOCOL                          0x000004
#define NECP_KERNEL_CONDITION_LOCAL_START                       0x000008
#define NECP_KERNEL_CONDITION_LOCAL_END                         0x000010
#define NECP_KERNEL_CONDITION_LOCAL_PREFIX                      0x000020
#define NECP_KERNEL_CONDITION_REMOTE_START                      0x000040
#define NECP_KERNEL_CONDITION_REMOTE_END                        0x000080
#define NECP_KERNEL_CONDITION_REMOTE_PREFIX                     0x000100
#define NECP_KERNEL_CONDITION_APP_ID                            0x000200
#define NECP_KERNEL_CONDITION_REAL_APP_ID                       0x000400
#define NECP_KERNEL_CONDITION_DOMAIN                            0x000800
#define NECP_KERNEL_CONDITION_ACCOUNT_ID                        0x001000
#define NECP_KERNEL_CONDITION_POLICY_ID                         0x002000
#define NECP_KERNEL_CONDITION_PID                                       0x004000
#define NECP_KERNEL_CONDITION_UID                                       0x008000
#define NECP_KERNEL_CONDITION_LAST_INTERFACE            0x010000                        // Only set from packets looping between interfaces
#define NECP_KERNEL_CONDITION_TRAFFIC_CLASS                     0x020000
#define NECP_KERNEL_CONDITION_ENTITLEMENT                       0x040000
#define NECP_KERNEL_CONDITION_CUSTOM_ENTITLEMENT        0x080000
#define NECP_KERNEL_CONDITION_AGENT_TYPE                        0x100000
#define NECP_KERNEL_CONDITION_HAS_CLIENT                        0x200000
#define NECP_KERNEL_CONDITION_LOCAL_NETWORKS                    0x400000
#define NECP_KERNEL_CONDITION_CLIENT_FLAGS                      0x800000
#define NECP_KERNEL_CONDITION_LOCAL_EMPTY                       0x1000000
#define NECP_KERNEL_CONDITION_REMOTE_EMPTY                      0x2000000
#define NECP_KERNEL_CONDITION_PLATFORM_BINARY                   0x4000000

#define NECP_MAX_POLICY_RESULT_SIZE                                     512
#define NECP_MAX_ROUTE_RULES_ARRAY_SIZE                         1024
#define NECP_MAX_CONDITIONS_ARRAY_SIZE                          4096
#define NECP_MAX_POLICY_LIST_COUNT                                      1024

// Cap the policy size at the max result + conditions size, with room for extra TLVs
#define NECP_MAX_POLICY_SIZE                                            (1024 + NECP_MAX_POLICY_RESULT_SIZE + NECP_MAX_CONDITIONS_ARRAY_SIZE)

struct necp_service_registration {
	LIST_ENTRY(necp_service_registration)   session_chain;
	LIST_ENTRY(necp_service_registration)   kernel_chain;
	u_int32_t                                                               service_id;
};

struct necp_session {
	u_int8_t                                        necp_fd_type;
	u_int32_t                                       control_unit;
	u_int32_t                                       session_priority; // Descriptive priority rating
	u_int32_t                                       session_order;

	necp_policy_id                          last_policy_id;

	decl_lck_mtx_data(, lock);

	bool                                            proc_locked; // Messages must come from proc_uuid
	uuid_t                                          proc_uuid;
	int                                                     proc_pid;

	bool                                            dirty;
	LIST_HEAD(_policies, necp_session_policy) policies;

	LIST_HEAD(_services, necp_service_registration) services;

	TAILQ_ENTRY(necp_session) chain;
};

#define NECP_SESSION_LOCK(_s) lck_mtx_lock(&_s->lock)
#define NECP_SESSION_UNLOCK(_s) lck_mtx_unlock(&_s->lock)

static TAILQ_HEAD(_necp_session_list, necp_session) necp_session_list;

struct necp_socket_info {
	pid_t pid;
	uid_t uid;
	union necp_sockaddr_union local_addr;
	union necp_sockaddr_union remote_addr;
	u_int32_t bound_interface_index;
	u_int32_t traffic_class;
	u_int16_t protocol;
	u_int32_t application_id;
	u_int32_t real_application_id;
	u_int32_t account_id;
	u_int32_t drop_order;
	u_int32_t client_flags;
	char *domain;
	errno_t cred_result;
	unsigned has_client : 1;
	unsigned is_platform_binary : 1;
	unsigned __pad_bits : 6;
};

static  lck_grp_attr_t  *necp_kernel_policy_grp_attr    = NULL;
static  lck_attr_t              *necp_kernel_policy_mtx_attr    = NULL;
static  lck_grp_t               *necp_kernel_policy_mtx_grp             = NULL;
decl_lck_rw_data(static, necp_kernel_policy_lock);

static  lck_grp_attr_t  *necp_route_rule_grp_attr       = NULL;
static  lck_attr_t              *necp_route_rule_mtx_attr       = NULL;
static  lck_grp_t               *necp_route_rule_mtx_grp        = NULL;
decl_lck_rw_data(static, necp_route_rule_lock);

os_refgrp_decl(static, necp_refgrp, "NECPRefGroup", NULL);

/*
 * On modification, invalidate cached lookups by bumping the generation count.
 * Other calls will need to take the slowpath of taking
 * the subsystem lock.
 */
static volatile int32_t necp_kernel_socket_policies_gencount;
#define BUMP_KERNEL_SOCKET_POLICIES_GENERATION_COUNT() do {                                                     \
	if (OSIncrementAtomic(&necp_kernel_socket_policies_gencount) == (INT32_MAX - 1)) {      \
	        necp_kernel_socket_policies_gencount = 1;                                                                               \
	}                                                                                                                                                               \
} while (0)

/*
 * Drop-all Bypass:
 * Allow priviledged processes to bypass the default drop-all
 * via entitlement check.  For OSX, since entitlement check is
 * not supported for configd, configd signing identity is checked
 * instead.
 */
#define SIGNING_ID_CONFIGD "com.apple.configd"
#define SIGNING_ID_CONFIGD_LEN (sizeof(SIGNING_ID_CONFIGD) - 1)

typedef enum {
	NECP_DROP_ALL_BYPASS_CHECK_RESULT_NONE = 0,
	NECP_DROP_ALL_BYPASS_CHECK_RESULT_TRUE = 1,
	NECP_DROP_ALL_BYPASS_CHECK_RESULT_FALSE = 2,
} necp_drop_all_bypass_check_result_t;

static u_int32_t necp_kernel_application_policies_condition_mask;
static size_t necp_kernel_application_policies_count;
static u_int32_t necp_kernel_socket_policies_condition_mask;
static size_t necp_kernel_socket_policies_count;
static size_t necp_kernel_socket_policies_non_app_count;
static LIST_HEAD(_necpkernelsocketconnectpolicies, necp_kernel_socket_policy) necp_kernel_socket_policies;
#define NECP_KERNEL_SOCKET_POLICIES_MAP_NUM_APP_ID_BUCKETS 5
#define NECP_SOCKET_MAP_APP_ID_TO_BUCKET(appid) (appid ? (appid%(NECP_KERNEL_SOCKET_POLICIES_MAP_NUM_APP_ID_BUCKETS - 1) + 1) : 0)
static struct necp_kernel_socket_policy **necp_kernel_socket_policies_map[NECP_KERNEL_SOCKET_POLICIES_MAP_NUM_APP_ID_BUCKETS];
static struct necp_kernel_socket_policy **necp_kernel_socket_policies_app_layer_map;
/*
 * A note on policy 'maps': these are used for boosting efficiency when matching policies. For each dimension of the map,
 * such as an ID, the 0 bucket is reserved for sockets/packets that do not have this parameter, while the other
 * buckets lead to an array of policy pointers that form the list applicable when the (parameter%(NUM_BUCKETS - 1) + 1) == bucket_index.
 *
 * For example, a packet with policy ID of 7, when there are 4 ID buckets, will map to bucket (7%3 + 1) = 2.
 */

static u_int32_t necp_kernel_ip_output_policies_condition_mask;
static size_t necp_kernel_ip_output_policies_count;
static size_t necp_kernel_ip_output_policies_non_id_count;
static LIST_HEAD(_necpkernelipoutputpolicies, necp_kernel_ip_output_policy) necp_kernel_ip_output_policies;
#define NECP_KERNEL_IP_OUTPUT_POLICIES_MAP_NUM_ID_BUCKETS 5
#define NECP_IP_OUTPUT_MAP_ID_TO_BUCKET(id) (id ? (id%(NECP_KERNEL_IP_OUTPUT_POLICIES_MAP_NUM_ID_BUCKETS - 1) + 1) : 0)
static struct necp_kernel_ip_output_policy **necp_kernel_ip_output_policies_map[NECP_KERNEL_IP_OUTPUT_POLICIES_MAP_NUM_ID_BUCKETS];
static struct necp_kernel_socket_policy pass_policy =
{
	.id = NECP_KERNEL_POLICY_ID_NO_MATCH,
	.result = NECP_KERNEL_POLICY_RESULT_PASS,
};

static struct necp_session *necp_create_session(void);
static void necp_delete_session(struct necp_session *session);

static necp_policy_id necp_handle_policy_add(struct necp_session *session,
    u_int8_t *tlv_buffer, size_t tlv_buffer_length, int offset, int *error);
static int necp_handle_policy_dump_all(user_addr_t out_buffer, size_t out_buffer_length);

#define MAX_RESULT_STRING_LEN 64
static inline const char * necp_get_result_description(char *result_string, necp_kernel_policy_result result, necp_kernel_policy_result_parameter result_parameter);

static struct necp_session_policy *necp_policy_create(struct necp_session *session, necp_policy_order order, u_int8_t *conditions_array, u_int32_t conditions_array_size, u_int8_t *route_rules_array, u_int32_t route_rules_array_size, u_int8_t *result, u_int32_t result_size);
static struct necp_session_policy *necp_policy_find(struct necp_session *session, necp_policy_id policy_id);
static bool necp_policy_mark_for_deletion(struct necp_session *session, struct necp_session_policy *policy);
static bool necp_policy_mark_all_for_deletion(struct necp_session *session);
static bool necp_policy_delete(struct necp_session *session, struct necp_session_policy *policy);
static void necp_policy_apply_all(struct necp_session *session);

static necp_kernel_policy_id necp_kernel_socket_policy_add(necp_policy_order order, u_int32_t session_order, int session_pid, u_int32_t condition_mask, u_int32_t condition_negated_mask, necp_app_id cond_app_id, necp_app_id cond_real_app_id, char *cond_custom_entitlement, u_int32_t cond_account_id, char *domain, pid_t cond_pid, uid_t cond_uid, ifnet_t cond_bound_interface, struct necp_policy_condition_tc_range cond_traffic_class, u_int16_t cond_protocol, union necp_sockaddr_union *cond_local_start, union necp_sockaddr_union *cond_local_end, u_int8_t cond_local_prefix, union necp_sockaddr_union *cond_remote_start, union necp_sockaddr_union *cond_remote_end, u_int8_t cond_remote_prefix, struct necp_policy_condition_agent_type *cond_agent_type, u_int32_t cond_client_flags, necp_kernel_policy_result result, necp_kernel_policy_result_parameter result_parameter);
static bool necp_kernel_socket_policy_delete(necp_kernel_policy_id policy_id);
static bool necp_kernel_socket_policies_reprocess(void);
static bool necp_kernel_socket_policies_update_uuid_table(void);
static inline struct necp_kernel_socket_policy *necp_socket_find_policy_match_with_info_locked(struct necp_kernel_socket_policy **policy_search_array, struct necp_socket_info *info, necp_kernel_policy_filter *return_filter, u_int32_t *return_route_rule_id_array, size_t *return_route_rule_id_array_count, size_t route_rule_id_array_count, necp_kernel_policy_result *return_service_action, necp_kernel_policy_service *return_service, u_int32_t *return_netagent_array, u_int32_t *return_netagent_use_flags_array, size_t netagent_array_count, struct necp_client_parameter_netagent_type *required_agent_types, u_int32_t num_required_agent_types, proc_t proc, necp_kernel_policy_id *skip_policy_id, struct rtentry *rt, necp_kernel_policy_result *return_drop_dest_policy_result, necp_drop_all_bypass_check_result_t *return_drop_all_bypass);

static necp_kernel_policy_id necp_kernel_ip_output_policy_add(necp_policy_order order, necp_policy_order suborder, u_int32_t session_order, int session_pid, u_int32_t condition_mask, u_int32_t condition_negated_mask, necp_kernel_policy_id cond_policy_id, ifnet_t cond_bound_interface, u_int32_t cond_last_interface_index, u_int16_t cond_protocol, union necp_sockaddr_union *cond_local_start, union necp_sockaddr_union *cond_local_end, u_int8_t cond_local_prefix, union necp_sockaddr_union *cond_remote_start, union necp_sockaddr_union *cond_remote_end, u_int8_t cond_remote_prefix, necp_kernel_policy_result result, necp_kernel_policy_result_parameter result_parameter);
static bool necp_kernel_ip_output_policy_delete(necp_kernel_policy_id policy_id);
static bool necp_kernel_ip_output_policies_reprocess(void);

static bool necp_is_addr_in_range(struct sockaddr *addr, struct sockaddr *range_start, struct sockaddr *range_end);
static bool necp_is_range_in_range(struct sockaddr *inner_range_start, struct sockaddr *inner_range_end, struct sockaddr *range_start, struct sockaddr *range_end);
static bool necp_is_addr_in_subnet(struct sockaddr *addr, struct sockaddr *subnet_addr, u_int8_t subnet_prefix);
static int necp_addr_compare(struct sockaddr *sa1, struct sockaddr *sa2, int check_port);
static bool necp_buffer_compare_with_bit_prefix(u_int8_t *p1, u_int8_t *p2, u_int32_t bits);
static bool necp_addr_is_empty(struct sockaddr *addr);
static bool necp_is_loopback(struct sockaddr *local_addr, struct sockaddr *remote_addr, struct inpcb *inp, struct mbuf *packet, u_int32_t bound_interface_index);
static bool necp_is_intcoproc(struct inpcb *inp, struct mbuf *packet);

struct necp_uuid_id_mapping {
	LIST_ENTRY(necp_uuid_id_mapping) chain;
	uuid_t          uuid;
	u_int32_t       id;
	os_refcnt_t     refcount;
	u_int32_t       table_usecount; // Add to UUID policy table count
};
static size_t necp_num_uuid_app_id_mappings;
static bool necp_uuid_app_id_mappings_dirty;
#define NECP_UUID_APP_ID_HASH_SIZE 64
static u_long necp_uuid_app_id_hash_mask;
static u_long necp_uuid_app_id_hash_num_buckets;
static LIST_HEAD(necp_uuid_id_mapping_head, necp_uuid_id_mapping) * necp_uuid_app_id_hashtbl, necp_uuid_service_id_list; // App map is real hash table, service map is just mapping
#define APPUUIDHASH(uuid) (&necp_uuid_app_id_hashtbl[uuid[0] & necp_uuid_app_id_hash_mask]) // Assume first byte of UUIDs are evenly distributed
static u_int32_t necp_create_uuid_app_id_mapping(uuid_t uuid, bool *allocated_mapping, bool uuid_policy_table);
static bool necp_remove_uuid_app_id_mapping(uuid_t uuid, bool *removed_mapping, bool uuid_policy_table);
static struct necp_uuid_id_mapping *necp_uuid_lookup_uuid_with_app_id_locked(u_int32_t local_id);

static struct necp_uuid_id_mapping *necp_uuid_lookup_service_id_locked(uuid_t uuid);
static struct necp_uuid_id_mapping *necp_uuid_lookup_uuid_with_service_id_locked(u_int32_t local_id);
static u_int32_t necp_create_uuid_service_id_mapping(uuid_t uuid);
static bool necp_remove_uuid_service_id_mapping(uuid_t uuid);

struct necp_string_id_mapping {
	LIST_ENTRY(necp_string_id_mapping) chain;
	char            *string;
	necp_app_id     id;
	os_refcnt_t     refcount;
};
static LIST_HEAD(necp_string_id_mapping_list, necp_string_id_mapping) necp_account_id_list;
static u_int32_t necp_create_string_to_id_mapping(struct necp_string_id_mapping_list *list, char *domain);
static bool necp_remove_string_to_id_mapping(struct necp_string_id_mapping_list *list, char *domain);
static struct necp_string_id_mapping *necp_lookup_string_with_id_locked(struct necp_string_id_mapping_list *list, u_int32_t local_id);

static struct necp_kernel_socket_policy *necp_kernel_socket_policy_find(necp_kernel_policy_id policy_id);
static struct necp_kernel_ip_output_policy *necp_kernel_ip_output_policy_find(necp_kernel_policy_id policy_id);

static LIST_HEAD(_necp_kernel_service_list, necp_service_registration) necp_registered_service_list;

static char *necp_create_trimmed_domain(char *string, size_t length);
static inline int necp_count_dots(char *string, size_t length);

static char *necp_copy_string(char *string, size_t length);
static bool necp_update_qos_marking(struct ifnet *ifp, u_int32_t route_rule_id);

#define ROUTE_RULE_IS_AGGREGATE(ruleid) (ruleid > UINT16_MAX)

#define MAX_ROUTE_RULE_INTERFACES 10
struct necp_route_rule {
	LIST_ENTRY(necp_route_rule) chain;
	u_int32_t       id;
	u_int32_t       default_action;
	u_int8_t        cellular_action;
	u_int8_t        wifi_action;
	u_int8_t        wired_action;
	u_int8_t        expensive_action;
	u_int8_t        constrained_action;
	u_int           exception_if_indices[MAX_ROUTE_RULE_INTERFACES];
	u_int8_t        exception_if_actions[MAX_ROUTE_RULE_INTERFACES];
	os_refcnt_t     refcount;
};
static LIST_HEAD(necp_route_rule_list, necp_route_rule) necp_route_rules;
static u_int32_t necp_create_route_rule(struct necp_route_rule_list *list, u_int8_t *route_rules_array, u_int32_t route_rules_array_size);
static bool necp_remove_route_rule(struct necp_route_rule_list *list, u_int32_t route_rule_id);
static bool necp_route_is_allowed(struct rtentry *route, ifnet_t interface, u_int32_t route_rule_id, u_int32_t *interface_type_denied);
static struct necp_route_rule *necp_lookup_route_rule_locked(struct necp_route_rule_list *list, u_int32_t route_rule_id);
static inline void necp_get_parent_cred_result(proc_t proc, struct necp_socket_info *info);

#define MAX_AGGREGATE_ROUTE_RULES 16
struct necp_aggregate_route_rule {
	LIST_ENTRY(necp_aggregate_route_rule) chain;
	u_int32_t       id;
	u_int32_t       rule_ids[MAX_AGGREGATE_ROUTE_RULES];
};
static LIST_HEAD(necp_aggregate_route_rule_list, necp_aggregate_route_rule) necp_aggregate_route_rules;
static u_int32_t necp_create_aggregate_route_rule(u_int32_t *rule_ids);

// Sysctl definitions
static int sysctl_handle_necp_level SYSCTL_HANDLER_ARGS;
static int sysctl_handle_necp_unentitled_level SYSCTL_HANDLER_ARGS;

SYSCTL_NODE(_net, OID_AUTO, necp, CTLFLAG_RW | CTLFLAG_LOCKED, 0, "NECP");
SYSCTL_INT(_net_necp, NECPCTL_PASS_LOOPBACK, pass_loopback, CTLFLAG_LOCKED | CTLFLAG_RW, &necp_pass_loopback, 0, "");
SYSCTL_INT(_net_necp, NECPCTL_PASS_KEEPALIVES, pass_keepalives, CTLFLAG_LOCKED | CTLFLAG_RW, &necp_pass_keepalives, 0, "");
SYSCTL_INT(_net_necp, NECPCTL_PASS_INTERPOSE, pass_interpose, CTLFLAG_LOCKED | CTLFLAG_RW, &necp_pass_interpose, 0, "");
SYSCTL_INT(_net_necp, NECPCTL_DEBUG, debug, CTLFLAG_LOCKED | CTLFLAG_RW, &necp_debug, 0, "");
SYSCTL_PROC(_net_necp, NECPCTL_DROP_UNENTITLED_LEVEL, drop_unentitled_level, CTLTYPE_INT | CTLFLAG_LOCKED | CTLFLAG_RW, &necp_drop_unentitled_level, 0, &sysctl_handle_necp_unentitled_level, "IU", "");
SYSCTL_PROC(_net_necp, NECPCTL_DROP_ALL_LEVEL, drop_all_level, CTLTYPE_INT | CTLFLAG_LOCKED | CTLFLAG_RW, &necp_drop_all_level, 0, &sysctl_handle_necp_level, "IU", "");
SYSCTL_LONG(_net_necp, NECPCTL_SOCKET_POLICY_COUNT, socket_policy_count, CTLFLAG_LOCKED | CTLFLAG_RD, &necp_kernel_socket_policies_count, "");
SYSCTL_LONG(_net_necp, NECPCTL_SOCKET_NON_APP_POLICY_COUNT, socket_non_app_policy_count, CTLFLAG_LOCKED | CTLFLAG_RD, &necp_kernel_socket_policies_non_app_count, "");
SYSCTL_LONG(_net_necp, NECPCTL_IP_POLICY_COUNT, ip_policy_count, CTLFLAG_LOCKED | CTLFLAG_RD, &necp_kernel_ip_output_policies_count, "");
SYSCTL_INT(_net_necp, NECPCTL_SESSION_COUNT, session_count, CTLFLAG_LOCKED | CTLFLAG_RD, &necp_session_count, 0, "");

static struct necp_drop_dest_policy necp_drop_dest_policy;
static int necp_drop_dest_debug = 0;    // 0: off, 1: match, >1: every evaluation
SYSCTL_INT(_net_necp, OID_AUTO, drop_dest_debug, CTLFLAG_LOCKED | CTLFLAG_RW, &necp_drop_dest_debug, 0, "");

static int sysctl_handle_necp_drop_dest_level SYSCTL_HANDLER_ARGS;
SYSCTL_PROC(_net_necp, OID_AUTO, drop_dest_level, CTLTYPE_STRUCT | CTLFLAG_LOCKED | CTLFLAG_ANYBODY | CTLFLAG_RW,
    0, 0, &sysctl_handle_necp_drop_dest_level, "S,necp_drop_dest_level", "");

static bool necp_address_matches_drop_dest_policy(union necp_sockaddr_union *, u_int32_t);

// Session order allocation
static u_int32_t
necp_allocate_new_session_order(u_int32_t priority, u_int32_t control_unit)
{
	u_int32_t new_order = 0;

	// For now, just allocate 1000 orders for each priority
	if (priority == NECP_SESSION_PRIORITY_UNKNOWN || priority > NECP_SESSION_NUM_PRIORITIES) {
		priority = NECP_SESSION_PRIORITY_DEFAULT;
	}

	// Use the control unit to decide the offset into the priority list
	new_order = (control_unit) + ((priority - 1) * 1000);

	return new_order;
}

static inline u_int32_t
necp_get_first_order_for_priority(u_int32_t priority)
{
	if (priority == 0) {
		return 0;
	}
	return ((priority - 1) * 1000) + 1;
}

// Sysctl handler
static int
sysctl_handle_necp_level SYSCTL_HANDLER_ARGS
{
#pragma unused(arg1, arg2)
	int error = sysctl_handle_int(oidp, oidp->oid_arg1, oidp->oid_arg2, req);
	necp_drop_all_order = necp_get_first_order_for_priority(necp_drop_all_level);
	return error;
}

static int
sysctl_handle_necp_unentitled_level SYSCTL_HANDLER_ARGS
{
#pragma unused(arg1, arg2)
	int error = sysctl_handle_int(oidp, oidp->oid_arg1, oidp->oid_arg2, req);
	necp_drop_unentitled_order = necp_get_first_order_for_priority(necp_drop_unentitled_level);
	return error;
}

// Use a macro here to avoid computing the kauth_cred_t when necp_drop_unentitled_level is 0
static inline u_int32_t
_necp_process_drop_order_inner(kauth_cred_t cred)
{
	if (priv_check_cred(cred, PRIV_NET_PRIVILEGED_CLIENT_ACCESS, 0) != 0 &&
	    priv_check_cred(cred, PRIV_NET_PRIVILEGED_SERVER_ACCESS, 0) != 0) {
		return necp_drop_unentitled_order;
	} else {
		return 0;
	}
}

#define necp_process_drop_order(_cred) (necp_drop_unentitled_order != 0 ? _necp_process_drop_order_inner(_cred) : necp_drop_unentitled_order)
#pragma GCC poison _necp_process_drop_order_inner

// Session fd

static int necp_session_op_close(struct fileglob *, vfs_context_t);

static const struct fileops necp_session_fd_ops = {
	.fo_type     = DTYPE_NETPOLICY,
	.fo_read     = fo_no_read,
	.fo_write    = fo_no_write,
	.fo_ioctl    = fo_no_ioctl,
	.fo_select   = fo_no_select,
	.fo_close    = necp_session_op_close,
	.fo_drain    = fo_no_drain,
	.fo_kqfilter = fo_no_kqfilter,
};

static inline necp_drop_all_bypass_check_result_t
necp_check_drop_all_bypass_result(proc_t proc)
{
	if (proc == NULL) {
		proc = current_proc();
		if (proc == NULL) {
			return NECP_DROP_ALL_BYPASS_CHECK_RESULT_FALSE;
		}
	}

#if defined(XNU_TARGET_OS_OSX)
	const char *signing_id = NULL;
	const bool isConfigd = (csproc_get_platform_binary(proc) &&
	    (signing_id = cs_identity_get(proc)) &&
	    (strlen(signing_id) == SIGNING_ID_CONFIGD_LEN) &&
	    (memcmp(signing_id, SIGNING_ID_CONFIGD, SIGNING_ID_CONFIGD_LEN) == 0));
	if (isConfigd) {
		return NECP_DROP_ALL_BYPASS_CHECK_RESULT_TRUE;
	}
#endif

	const task_t task = proc_task(proc);
	if (task == NULL || !IOTaskHasEntitlement(task, "com.apple.private.necp.drop_all_bypass")) {
		return NECP_DROP_ALL_BYPASS_CHECK_RESULT_FALSE;
	} else {
		return NECP_DROP_ALL_BYPASS_CHECK_RESULT_TRUE;
	}
}

int
necp_session_open(struct proc *p, struct necp_session_open_args *uap, int *retval)
{
#pragma unused(uap)
	int error = 0;
	struct necp_session *session = NULL;
	struct fileproc *fp = NULL;
	int fd = -1;

	uid_t uid = kauth_cred_getuid(proc_ucred(p));
	if (uid != 0 && priv_check_cred(kauth_cred_get(), PRIV_NET_PRIVILEGED_NECP_POLICIES, 0) != 0) {
		NECPLOG0(LOG_ERR, "Process does not hold necessary entitlement to open NECP session");
		error = EACCES;
		goto done;
	}

	error = falloc(p, &fp, &fd, vfs_context_current());
	if (error != 0) {
		goto done;
	}

	session = necp_create_session();
	if (session == NULL) {
		error = ENOMEM;
		goto done;
	}

	fp->f_fglob->fg_flag = 0;
	fp->f_fglob->fg_ops = &necp_session_fd_ops;
	fp->f_fglob->fg_data = session;

	proc_fdlock(p);
	FDFLAGS_SET(p, fd, (UF_EXCLOSE | UF_FORKCLOSE));
	procfdtbl_releasefd(p, fd, NULL);
	fp_drop(p, fd, fp, 1);
	proc_fdunlock(p);

	*retval = fd;
done:
	if (error != 0) {
		if (fp != NULL) {
			fp_free(p, fd, fp);
			fp = NULL;
		}
	}

	return error;
}

static int
necp_session_op_close(struct fileglob *fg, vfs_context_t ctx)
{
#pragma unused(ctx)
	struct necp_session *session = (struct necp_session *)fg->fg_data;
	fg->fg_data = NULL;

	if (session != NULL) {
		necp_policy_mark_all_for_deletion(session);
		necp_policy_apply_all(session);
		necp_delete_session(session);
		return 0;
	} else {
		return ENOENT;
	}
}

static int
necp_session_find_from_fd(int fd, struct necp_session **session)
{
	proc_t p = current_proc();
	struct fileproc *fp = NULL;
	int error = 0;

	proc_fdlock_spin(p);
	if ((error = fp_lookup(p, fd, &fp, 1)) != 0) {
		goto done;
	}
	if (fp->f_fglob->fg_ops->fo_type != DTYPE_NETPOLICY) {
		fp_drop(p, fd, fp, 1);
		error = ENODEV;
		goto done;
	}
	*session = (struct necp_session *)fp->f_fglob->fg_data;

	if ((*session)->necp_fd_type != necp_fd_type_session) {
		// Not a client fd, ignore
		fp_drop(p, fd, fp, 1);
		error = EINVAL;
		goto done;
	}

done:
	proc_fdunlock(p);
	return error;
}

static int
necp_session_add_policy(struct necp_session *session, struct necp_session_action_args *uap, int *retval)
{
	int error = 0;
	u_int8_t *tlv_buffer = NULL;

	if (uap->in_buffer_length == 0 || uap->in_buffer_length > NECP_MAX_POLICY_SIZE || uap->in_buffer == 0) {
		NECPLOG(LOG_ERR, "necp_session_add_policy invalid input (%zu)", uap->in_buffer_length);
		error = EINVAL;
		goto done;
	}

	if (uap->out_buffer_length < sizeof(necp_policy_id) || uap->out_buffer == 0) {
		NECPLOG(LOG_ERR, "necp_session_add_policy invalid output buffer (%zu)", uap->out_buffer_length);
		error = EINVAL;
		goto done;
	}

	if ((tlv_buffer = _MALLOC(uap->in_buffer_length, M_NECP, M_WAITOK | M_ZERO)) == NULL) {
		error = ENOMEM;
		goto done;
	}

	error = copyin(uap->in_buffer, tlv_buffer, uap->in_buffer_length);
	if (error != 0) {
		NECPLOG(LOG_ERR, "necp_session_add_policy tlv copyin error (%d)", error);
		goto done;
	}

	necp_policy_id new_policy_id = necp_handle_policy_add(session, tlv_buffer, uap->in_buffer_length, 0, &error);
	if (error != 0) {
		NECPLOG(LOG_ERR, "necp_session_add_policy failed to add policy (%d)", error);
		goto done;
	}

	error = copyout(&new_policy_id, uap->out_buffer, sizeof(new_policy_id));
	if (error != 0) {
		NECPLOG(LOG_ERR, "necp_session_add_policy policy_id copyout error (%d)", error);
		goto done;
	}

done:
	if (tlv_buffer != NULL) {
		FREE(tlv_buffer, M_NECP);
		tlv_buffer = NULL;
	}
	*retval = error;

	return error;
}

static int
necp_session_get_policy(struct necp_session *session, struct necp_session_action_args *uap, int *retval)
{
	int error = 0;
	u_int8_t *response = NULL;

	if (uap->in_buffer_length < sizeof(necp_policy_id) || uap->in_buffer == 0) {
		NECPLOG(LOG_ERR, "necp_session_get_policy invalid input (%zu)", uap->in_buffer_length);
		error = EINVAL;
		goto done;
	}

	necp_policy_id policy_id = 0;
	error = copyin(uap->in_buffer, &policy_id, sizeof(policy_id));
	if (error != 0) {
		NECPLOG(LOG_ERR, "necp_session_get_policy policy_id copyin error (%d)", error);
		goto done;
	}

	struct necp_session_policy *policy = necp_policy_find(session, policy_id);
	if (policy == NULL || policy->pending_deletion) {
		NECPLOG(LOG_ERR, "Failed to find policy with id %d", policy_id);
		error = ENOENT;
		goto done;
	}

	u_int32_t order_tlv_size = sizeof(u_int8_t) + sizeof(u_int32_t) + sizeof(necp_policy_order);
	u_int32_t result_tlv_size = (policy->result_size ? (sizeof(u_int8_t) + sizeof(u_int32_t) + policy->result_size) : 0);
	u_int32_t response_size = order_tlv_size + result_tlv_size + policy->conditions_size;

	if (uap->out_buffer_length < response_size || uap->out_buffer == 0) {
		NECPLOG(LOG_ERR, "necp_session_get_policy buffer not large enough (%u < %u)", uap->out_buffer_length, response_size);
		error = EINVAL;
		goto done;
	}

	if (response_size > NECP_MAX_POLICY_SIZE) {
		NECPLOG(LOG_ERR, "necp_session_get_policy size too large to copy (%u)", response_size);
		error = EINVAL;
		goto done;
	}

	MALLOC(response, u_int8_t *, response_size, M_NECP, M_WAITOK | M_ZERO);
	if (response == NULL) {
		error = ENOMEM;
		goto done;
	}

	u_int8_t *cursor = response;
	cursor = necp_buffer_write_tlv(cursor, NECP_TLV_POLICY_ORDER, sizeof(necp_policy_order), &policy->order, response, response_size);
	if (result_tlv_size) {
		cursor = necp_buffer_write_tlv(cursor, NECP_TLV_POLICY_RESULT, policy->result_size, &policy->result, response, response_size);
	}
	if (policy->conditions_size) {
		memcpy(((u_int8_t *)(void *)(cursor)), policy->conditions, policy->conditions_size);
	}

	error = copyout(response, uap->out_buffer, response_size);
	if (error != 0) {
		NECPLOG(LOG_ERR, "necp_session_get_policy TLV copyout error (%d)", error);
		goto done;
	}

done:
	if (response != NULL) {
		FREE(response, M_NECP);
		response = NULL;
	}
	*retval = error;

	return error;
}

static int
necp_session_delete_policy(struct necp_session *session, struct necp_session_action_args *uap, int *retval)
{
	int error = 0;

	if (uap->in_buffer_length < sizeof(necp_policy_id) || uap->in_buffer == 0) {
		NECPLOG(LOG_ERR, "necp_session_delete_policy invalid input (%zu)", uap->in_buffer_length);
		error = EINVAL;
		goto done;
	}

	necp_policy_id delete_policy_id = 0;
	error = copyin(uap->in_buffer, &delete_policy_id, sizeof(delete_policy_id));
	if (error != 0) {
		NECPLOG(LOG_ERR, "necp_session_delete_policy policy_id copyin error (%d)", error);
		goto done;
	}

	struct necp_session_policy *policy = necp_policy_find(session, delete_policy_id);
	if (policy == NULL || policy->pending_deletion) {
		NECPLOG(LOG_ERR, "necp_session_delete_policy failed to find policy with id %u", delete_policy_id);
		error = ENOENT;
		goto done;
	}

	necp_policy_mark_for_deletion(session, policy);
done:
	*retval = error;
	return error;
}

static int
necp_session_apply_all(struct necp_session *session, struct necp_session_action_args *uap, int *retval)
{
#pragma unused(uap)
	necp_policy_apply_all(session);
	*retval = 0;
	return 0;
}

static int
necp_session_list_all(struct necp_session *session, struct necp_session_action_args *uap, int *retval)
{
	u_int32_t tlv_size = (sizeof(u_int8_t) + sizeof(u_int32_t) + sizeof(necp_policy_id));
	u_int32_t response_size = 0;
	u_int8_t *response = NULL;
	int num_policies = 0;
	int cur_policy_index = 0;
	int error = 0;
	struct necp_session_policy *policy;

	LIST_FOREACH(policy, &session->policies, chain) {
		if (!policy->pending_deletion) {
			num_policies++;
		}
	}

	if (num_policies > NECP_MAX_POLICY_LIST_COUNT) {
		NECPLOG(LOG_ERR, "necp_session_list_all size too large to copy (%u policies)", num_policies);
		error = EINVAL;
		goto done;
	}

	response_size = num_policies * tlv_size;
	if (uap->out_buffer_length < response_size || uap->out_buffer == 0) {
		NECPLOG(LOG_ERR, "necp_session_list_all buffer not large enough (%u < %u)", uap->out_buffer_length, response_size);
		error = EINVAL;
		goto done;
	}

	// Create a response with one Policy ID TLV for each policy
	MALLOC(response, u_int8_t *, response_size, M_NECP, M_WAITOK | M_ZERO);
	if (response == NULL) {
		error = ENOMEM;
		goto done;
	}

	u_int8_t *cursor = response;
	LIST_FOREACH(policy, &session->policies, chain) {
		if (!policy->pending_deletion && cur_policy_index < num_policies) {
			cursor = necp_buffer_write_tlv(cursor, NECP_TLV_POLICY_ID, sizeof(u_int32_t), &policy->local_id, response, response_size);
			cur_policy_index++;
		}
	}

	error = copyout(response, uap->out_buffer, response_size);
	if (error != 0) {
		NECPLOG(LOG_ERR, "necp_session_list_all TLV copyout error (%d)", error);
		goto done;
	}

done:
	if (response != NULL) {
		FREE(response, M_NECP);
		response = NULL;
	}
	*retval = error;

	return error;
}


static int
necp_session_delete_all(struct necp_session *session, struct necp_session_action_args *uap, int *retval)
{
#pragma unused(uap)
	necp_policy_mark_all_for_deletion(session);
	*retval = 0;
	return 0;
}

static int
necp_session_set_session_priority(struct necp_session *session, struct necp_session_action_args *uap, int *retval)
{
	int error = 0;
	struct necp_session_policy *policy = NULL;
	struct necp_session_policy *temp_policy = NULL;

	if (uap->in_buffer_length < sizeof(necp_session_priority) || uap->in_buffer == 0) {
		NECPLOG(LOG_ERR, "necp_session_set_session_priority invalid input (%zu)", uap->in_buffer_length);
		error = EINVAL;
		goto done;
	}

	necp_session_priority requested_session_priority = 0;
	error = copyin(uap->in_buffer, &requested_session_priority, sizeof(requested_session_priority));
	if (error != 0) {
		NECPLOG(LOG_ERR, "necp_session_set_session_priority priority copyin error (%d)", error);
		goto done;
	}

	// Enforce special session priorities with entitlements
	if (requested_session_priority == NECP_SESSION_PRIORITY_CONTROL ||
	    requested_session_priority == NECP_SESSION_PRIORITY_PRIVILEGED_TUNNEL) {
		errno_t cred_result = priv_check_cred(kauth_cred_get(), PRIV_NET_PRIVILEGED_NECP_POLICIES, 0);
		if (cred_result != 0) {
			NECPLOG(LOG_ERR, "Session does not hold necessary entitlement to claim priority level %d", requested_session_priority);
			error = EPERM;
			goto done;
		}
	}

	if (session->session_priority != requested_session_priority) {
		session->session_priority = requested_session_priority;
		session->session_order = necp_allocate_new_session_order(session->session_priority, session->control_unit);
		session->dirty = TRUE;

		// Mark all policies as needing updates
		LIST_FOREACH_SAFE(policy, &session->policies, chain, temp_policy) {
			policy->pending_update = TRUE;
		}
	}

done:
	*retval = error;
	return error;
}

static int
necp_session_lock_to_process(struct necp_session *session, struct necp_session_action_args *uap, int *retval)
{
#pragma unused(uap)
	session->proc_locked = TRUE;
	*retval = 0;
	return 0;
}

static int
necp_session_register_service(struct necp_session *session, struct necp_session_action_args *uap, int *retval)
{
	int error = 0;
	struct necp_service_registration *new_service = NULL;

	if (uap->in_buffer_length < sizeof(uuid_t) || uap->in_buffer == 0) {
		NECPLOG(LOG_ERR, "necp_session_register_service invalid input (%zu)", uap->in_buffer_length);
		error = EINVAL;
		goto done;
	}

	uuid_t service_uuid;
	error = copyin(uap->in_buffer, service_uuid, sizeof(service_uuid));
	if (error != 0) {
		NECPLOG(LOG_ERR, "necp_session_register_service uuid copyin error (%d)", error);
		goto done;
	}

	MALLOC(new_service, struct necp_service_registration *, sizeof(*new_service), M_NECP, M_WAITOK | M_ZERO);
	if (new_service == NULL) {
		NECPLOG0(LOG_ERR, "Failed to allocate service registration");
		error = ENOMEM;
		goto done;
	}

	lck_rw_lock_exclusive(&necp_kernel_policy_lock);
	new_service->service_id = necp_create_uuid_service_id_mapping(service_uuid);
	LIST_INSERT_HEAD(&session->services, new_service, session_chain);
	LIST_INSERT_HEAD(&necp_registered_service_list, new_service, kernel_chain);
	lck_rw_done(&necp_kernel_policy_lock);

done:
	*retval = error;
	return error;
}

static int
necp_session_unregister_service(struct necp_session *session, struct necp_session_action_args *uap, int *retval)
{
	int error = 0;
	struct necp_service_registration *service = NULL;
	struct necp_service_registration *temp_service = NULL;
	struct necp_uuid_id_mapping *mapping = NULL;

	if (uap->in_buffer_length < sizeof(uuid_t) || uap->in_buffer == 0) {
		NECPLOG(LOG_ERR, "necp_session_unregister_service invalid input (%zu)", uap->in_buffer_length);
		error = EINVAL;
		goto done;
	}

	uuid_t service_uuid;
	error = copyin(uap->in_buffer, service_uuid, sizeof(service_uuid));
	if (error != 0) {
		NECPLOG(LOG_ERR, "necp_session_unregister_service uuid copyin error (%d)", error);
		goto done;
	}

	// Remove all matching services for this session
	lck_rw_lock_exclusive(&necp_kernel_policy_lock);
	mapping = necp_uuid_lookup_service_id_locked(service_uuid);
	if (mapping != NULL) {
		LIST_FOREACH_SAFE(service, &session->services, session_chain, temp_service) {
			if (service->service_id == mapping->id) {
				LIST_REMOVE(service, session_chain);
				LIST_REMOVE(service, kernel_chain);
				FREE(service, M_NECP);
			}
		}
		necp_remove_uuid_service_id_mapping(service_uuid);
	}
	lck_rw_done(&necp_kernel_policy_lock);

done:
	*retval = error;
	return error;
}

static int
necp_session_dump_all(struct necp_session *session, struct necp_session_action_args *uap, int *retval)
{
#pragma unused(session)
	int error = 0;

	if (uap->out_buffer_length == 0 || uap->out_buffer == 0) {
		NECPLOG(LOG_ERR, "necp_session_dump_all invalid output buffer (%zu)", uap->out_buffer_length);
		error = EINVAL;
		goto done;
	}

	error = necp_handle_policy_dump_all(uap->out_buffer, uap->out_buffer_length);
done:
	*retval = error;
	return error;
}

int
necp_session_action(struct proc *p, struct necp_session_action_args *uap, int *retval)
{
#pragma unused(p)
	int error = 0;
	int return_value = 0;
	struct necp_session *session = NULL;
	error = necp_session_find_from_fd(uap->necp_fd, &session);
	if (error != 0) {
		NECPLOG(LOG_ERR, "necp_session_action find fd error (%d)", error);
		return error;
	}

	NECP_SESSION_LOCK(session);

	if (session->proc_locked) {
		// Verify that the calling process is allowed to do actions
		uuid_t proc_uuid;
		proc_getexecutableuuid(current_proc(), proc_uuid, sizeof(proc_uuid));
		if (uuid_compare(proc_uuid, session->proc_uuid) != 0) {
			error = EPERM;
			goto done;
		}
	} else {
		// If not locked, update the proc_uuid and proc_pid of the session
		proc_getexecutableuuid(current_proc(), session->proc_uuid, sizeof(session->proc_uuid));
		session->proc_pid = proc_pid(current_proc());
	}

	u_int32_t action = uap->action;
	switch (action) {
	case NECP_SESSION_ACTION_POLICY_ADD: {
		return_value = necp_session_add_policy(session, uap, retval);
		break;
	}
	case NECP_SESSION_ACTION_POLICY_GET: {
		return_value = necp_session_get_policy(session, uap, retval);
		break;
	}
	case NECP_SESSION_ACTION_POLICY_DELETE:  {
		return_value = necp_session_delete_policy(session, uap, retval);
		break;
	}
	case NECP_SESSION_ACTION_POLICY_APPLY_ALL: {
		return_value = necp_session_apply_all(session, uap, retval);
		break;
	}
	case NECP_SESSION_ACTION_POLICY_LIST_ALL: {
		return_value = necp_session_list_all(session, uap, retval);
		break;
	}
	case NECP_SESSION_ACTION_POLICY_DELETE_ALL: {
		return_value = necp_session_delete_all(session, uap, retval);
		break;
	}
	case NECP_SESSION_ACTION_SET_SESSION_PRIORITY: {
		return_value = necp_session_set_session_priority(session, uap, retval);
		break;
	}
	case NECP_SESSION_ACTION_LOCK_SESSION_TO_PROC: {
		return_value = necp_session_lock_to_process(session, uap, retval);
		break;
	}
	case NECP_SESSION_ACTION_REGISTER_SERVICE: {
		return_value = necp_session_register_service(session, uap, retval);
		break;
	}
	case NECP_SESSION_ACTION_UNREGISTER_SERVICE: {
		return_value = necp_session_unregister_service(session, uap, retval);
		break;
	}
	case NECP_SESSION_ACTION_POLICY_DUMP_ALL: {
		return_value = necp_session_dump_all(session, uap, retval);
		break;
	}
	default: {
		NECPLOG(LOG_ERR, "necp_session_action unknown action (%u)", action);
		return_value = EINVAL;
		break;
	}
	}

done:
	NECP_SESSION_UNLOCK(session);
	file_drop(uap->necp_fd);

	return return_value;
}

struct necp_resolver_key_state {
	const struct ccdigest_info *digest_info;
	uint8_t key[CCSHA256_OUTPUT_SIZE];
};
static struct necp_resolver_key_state s_necp_resolver_key_state;

static void
necp_generate_resolver_key(void)
{
	s_necp_resolver_key_state.digest_info = ccsha256_di();
	cc_rand_generate(s_necp_resolver_key_state.key, sizeof(s_necp_resolver_key_state.key));
}

static void
necp_sign_update_context(const struct ccdigest_info *di,
    cchmac_ctx_t ctx,
    uuid_t client_id,
    u_int8_t *query,
    u_int32_t query_length,
    u_int8_t *answer,
    u_int32_t answer_length)
{
	const uint8_t context[32] = {[0 ... 31] = 0x20}; // 0x20 repeated 32 times
	const char *context_string = "NECP Resolver Binder";
	uint8_t separator = 0;
	cchmac_update(di, ctx, sizeof(context), context);
	cchmac_update(di, ctx, strlen(context_string), context_string);
	cchmac_update(di, ctx, sizeof(separator), &separator);
	cchmac_update(di, ctx, sizeof(uuid_t), client_id);
	cchmac_update(di, ctx, sizeof(query_length), &query_length);
	cchmac_update(di, ctx, query_length, query);
	cchmac_update(di, ctx, sizeof(answer_length), &answer_length);
	cchmac_update(di, ctx, answer_length, answer);
}

int
necp_sign_resolver_answer(uuid_t client_id, u_int8_t *query, u_int32_t query_length,
    u_int8_t *answer, u_int32_t answer_length,
    u_int8_t *tag, u_int32_t *out_tag_length)
{
	if (s_necp_resolver_key_state.digest_info == NULL) {
		return EINVAL;
	}

	if (query == NULL ||
	    query_length == 0 ||
	    answer == NULL ||
	    answer_length == 0 ||
	    tag == NULL ||
	    out_tag_length == NULL) {
		return EINVAL;
	}

	size_t required_tag_length = s_necp_resolver_key_state.digest_info->output_size;
	if (*out_tag_length < required_tag_length) {
		return ERANGE;
	}

	*out_tag_length = required_tag_length;

	cchmac_ctx_decl(s_necp_resolver_key_state.digest_info->state_size,
	    s_necp_resolver_key_state.digest_info->block_size, ctx);
	cchmac_init(s_necp_resolver_key_state.digest_info, ctx,
	    sizeof(s_necp_resolver_key_state.key),
	    s_necp_resolver_key_state.key);
	necp_sign_update_context(s_necp_resolver_key_state.digest_info,
	    ctx, client_id, query, query_length,
	    answer, answer_length);
	cchmac_final(s_necp_resolver_key_state.digest_info, ctx, tag);

	return 0;
}

bool
necp_validate_resolver_answer(uuid_t client_id, u_int8_t *query, u_int32_t query_length,
    u_int8_t *answer, u_int32_t answer_length,
    u_int8_t *tag, u_int32_t tag_length)
{
	if (s_necp_resolver_key_state.digest_info == NULL) {
		return false;
	}

	if (query == NULL ||
	    query_length == 0 ||
	    answer == NULL ||
	    answer_length == 0 ||
	    tag == NULL ||
	    tag_length == 0) {
		return false;
	}

	size_t required_tag_length = s_necp_resolver_key_state.digest_info->output_size;
	if (tag_length != required_tag_length) {
		return false;
	}

	uint8_t actual_tag[required_tag_length];

	cchmac_ctx_decl(s_necp_resolver_key_state.digest_info->state_size,
	    s_necp_resolver_key_state.digest_info->block_size, ctx);
	cchmac_init(s_necp_resolver_key_state.digest_info, ctx,
	    sizeof(s_necp_resolver_key_state.key),
	    s_necp_resolver_key_state.key);
	necp_sign_update_context(s_necp_resolver_key_state.digest_info,
	    ctx, client_id, query, query_length,
	    answer, answer_length);
	cchmac_final(s_necp_resolver_key_state.digest_info, ctx, actual_tag);

	return cc_cmp_safe(s_necp_resolver_key_state.digest_info->output_size, tag, actual_tag) == 0;
}

errno_t
necp_init(void)
{
	errno_t result = 0;

	necp_kernel_policy_grp_attr = lck_grp_attr_alloc_init();
	if (necp_kernel_policy_grp_attr == NULL) {
		NECPLOG0(LOG_ERR, "lck_grp_attr_alloc_init failed");
		result = ENOMEM;
		goto done;
	}

	necp_kernel_policy_mtx_grp = lck_grp_alloc_init(NECP_CONTROL_NAME, necp_kernel_policy_grp_attr);
	if (necp_kernel_policy_mtx_grp == NULL) {
		NECPLOG0(LOG_ERR, "lck_grp_alloc_init failed");
		result = ENOMEM;
		goto done;
	}

	necp_kernel_policy_mtx_attr = lck_attr_alloc_init();
	if (necp_kernel_policy_mtx_attr == NULL) {
		NECPLOG0(LOG_ERR, "lck_attr_alloc_init failed");
		result = ENOMEM;
		goto done;
	}

	lck_rw_init(&necp_kernel_policy_lock, necp_kernel_policy_mtx_grp, necp_kernel_policy_mtx_attr);

	necp_route_rule_grp_attr = lck_grp_attr_alloc_init();
	if (necp_route_rule_grp_attr == NULL) {
		NECPLOG0(LOG_ERR, "lck_grp_attr_alloc_init failed");
		result = ENOMEM;
		goto done;
	}

	necp_route_rule_mtx_grp = lck_grp_alloc_init("necp_route_rule", necp_route_rule_grp_attr);
	if (necp_route_rule_mtx_grp == NULL) {
		NECPLOG0(LOG_ERR, "lck_grp_alloc_init failed");
		result = ENOMEM;
		goto done;
	}

	necp_route_rule_mtx_attr = lck_attr_alloc_init();
	if (necp_route_rule_mtx_attr == NULL) {
		NECPLOG0(LOG_ERR, "lck_attr_alloc_init failed");
		result = ENOMEM;
		goto done;
	}

	lck_rw_init(&necp_route_rule_lock, necp_route_rule_mtx_grp, necp_route_rule_mtx_attr);

	necp_client_init();

	TAILQ_INIT(&necp_session_list);

	LIST_INIT(&necp_kernel_socket_policies);
	LIST_INIT(&necp_kernel_ip_output_policies);

	LIST_INIT(&necp_account_id_list);

	LIST_INIT(&necp_uuid_service_id_list);

	LIST_INIT(&necp_registered_service_list);

	LIST_INIT(&necp_route_rules);
	LIST_INIT(&necp_aggregate_route_rules);

	necp_generate_resolver_key();

	necp_uuid_app_id_hashtbl = hashinit(NECP_UUID_APP_ID_HASH_SIZE, M_NECP, &necp_uuid_app_id_hash_mask);
	necp_uuid_app_id_hash_num_buckets = necp_uuid_app_id_hash_mask + 1;
	necp_num_uuid_app_id_mappings = 0;
	necp_uuid_app_id_mappings_dirty = FALSE;

	necp_kernel_application_policies_condition_mask = 0;
	necp_kernel_socket_policies_condition_mask = 0;
	necp_kernel_ip_output_policies_condition_mask = 0;

	necp_kernel_application_policies_count = 0;
	necp_kernel_socket_policies_count = 0;
	necp_kernel_socket_policies_non_app_count = 0;
	necp_kernel_ip_output_policies_count = 0;
	necp_kernel_ip_output_policies_non_id_count = 0;

	necp_kernel_socket_policies_gencount = 1;

	memset(&necp_kernel_socket_policies_map, 0, sizeof(necp_kernel_socket_policies_map));
	memset(&necp_kernel_ip_output_policies_map, 0, sizeof(necp_kernel_ip_output_policies_map));
	necp_kernel_socket_policies_app_layer_map = NULL;

	necp_drop_unentitled_order = necp_get_first_order_for_priority(necp_drop_unentitled_level);

done:
	if (result != 0) {
		if (necp_kernel_policy_mtx_attr != NULL) {
			lck_attr_free(necp_kernel_policy_mtx_attr);
			necp_kernel_policy_mtx_attr = NULL;
		}
		if (necp_kernel_policy_mtx_grp != NULL) {
			lck_grp_free(necp_kernel_policy_mtx_grp);
			necp_kernel_policy_mtx_grp = NULL;
		}
		if (necp_kernel_policy_grp_attr != NULL) {
			lck_grp_attr_free(necp_kernel_policy_grp_attr);
			necp_kernel_policy_grp_attr = NULL;
		}
		if (necp_route_rule_mtx_attr != NULL) {
			lck_attr_free(necp_route_rule_mtx_attr);
			necp_route_rule_mtx_attr = NULL;
		}
		if (necp_route_rule_mtx_grp != NULL) {
			lck_grp_free(necp_route_rule_mtx_grp);
			necp_route_rule_mtx_grp = NULL;
		}
		if (necp_route_rule_grp_attr != NULL) {
			lck_grp_attr_free(necp_route_rule_grp_attr);
			necp_route_rule_grp_attr = NULL;
		}
	}
	return result;
}

static void
necp_post_change_event(struct kev_necp_policies_changed_data *necp_event_data)
{
	struct kev_msg ev_msg;
	memset(&ev_msg, 0, sizeof(ev_msg));

	ev_msg.vendor_code      = KEV_VENDOR_APPLE;
	ev_msg.kev_class        = KEV_NETWORK_CLASS;
	ev_msg.kev_subclass     = KEV_NECP_SUBCLASS;
	ev_msg.event_code       = KEV_NECP_POLICIES_CHANGED;

	ev_msg.dv[0].data_ptr    = necp_event_data;
	ev_msg.dv[0].data_length = sizeof(necp_event_data->changed_count);
	ev_msg.dv[1].data_length = 0;

	kev_post_msg(&ev_msg);
}

static inline bool
necp_buffer_write_tlv_validate(u_int8_t *cursor, u_int8_t type, u_int32_t length,
    u_int8_t *buffer, u_int32_t buffer_length)
{
	if (cursor < buffer || (uintptr_t)(cursor - buffer) > buffer_length) {
		NECPLOG0(LOG_ERR, "Cannot write TLV in buffer (invalid cursor)");
		return false;
	}
	u_int8_t *next_tlv = (u_int8_t *)(cursor + sizeof(type) + sizeof(length) + length);
	if (next_tlv <= buffer || // make sure the next TLV start doesn't overflow
	    (uintptr_t)(next_tlv - buffer) > buffer_length) {     // make sure the next TLV has enough room in buffer
		NECPLOG(LOG_ERR, "Cannot write TLV in buffer (TLV length %u, buffer length %u)",
		    length, buffer_length);
		return false;
	}
	return true;
}

u_int8_t *
necp_buffer_write_tlv_if_different(u_int8_t *cursor, u_int8_t type,
    u_int32_t length, const void *value, bool *updated,
    u_int8_t *buffer, u_int32_t buffer_length)
{
	if (!necp_buffer_write_tlv_validate(cursor, type, length, buffer, buffer_length)) {
		// If we can't fit this TLV, return the current cursor
		return cursor;
	}
	u_int8_t *next_tlv = (u_int8_t *)(cursor + sizeof(type) + sizeof(length) + length);
	if (*updated || *(u_int8_t *)(cursor) != type) {
		*(u_int8_t *)(cursor) = type;
		*updated = TRUE;
	}
	if (*updated || *(u_int32_t *)(void *)(cursor + sizeof(type)) != length) {
		*(u_int32_t *)(void *)(cursor + sizeof(type)) = length;
		*updated = TRUE;
	}
	if (length > 0) {
		if (*updated || memcmp((u_int8_t *)(cursor + sizeof(type) + sizeof(length)), value, length) != 0) {
			memcpy((u_int8_t *)(cursor + sizeof(type) + sizeof(length)), value, length);
			*updated = TRUE;
		}
	}
	return next_tlv;
}

u_int8_t *
necp_buffer_write_tlv(u_int8_t *cursor, u_int8_t type,
    u_int32_t length, const void *value,
    u_int8_t *buffer, u_int32_t buffer_length)
{
	if (!necp_buffer_write_tlv_validate(cursor, type, length, buffer, buffer_length)) {
		return NULL;
	}
	u_int8_t *next_tlv = (u_int8_t *)(cursor + sizeof(type) + sizeof(length) + length);
	*(u_int8_t *)(cursor) = type;
	*(u_int32_t *)(void *)(cursor + sizeof(type)) = length;
	if (length > 0) {
		memcpy((u_int8_t *)(cursor + sizeof(type) + sizeof(length)), value, length);
	}

	return next_tlv;
}

u_int8_t
necp_buffer_get_tlv_type(u_int8_t *buffer, int tlv_offset)
{
	u_int8_t *type = NULL;

	if (buffer == NULL) {
		return 0;
	}

	type = (u_int8_t *)((u_int8_t *)buffer + tlv_offset);
	return type ? *type : 0;
}

u_int32_t
necp_buffer_get_tlv_length(u_int8_t *buffer, int tlv_offset)
{
	u_int32_t *length = NULL;

	if (buffer == NULL) {
		return 0;
	}

	length = (u_int32_t *)(void *)((u_int8_t *)buffer + tlv_offset + sizeof(u_int8_t));
	return length ? *length : 0;
}

u_int8_t *
necp_buffer_get_tlv_value(u_int8_t *buffer, int tlv_offset, u_int32_t *value_size)
{
	u_int8_t *value = NULL;
	u_int32_t length = necp_buffer_get_tlv_length(buffer, tlv_offset);
	if (length == 0) {
		return value;
	}

	if (value_size) {
		*value_size = length;
	}

	value = (u_int8_t *)((u_int8_t *)buffer + tlv_offset + sizeof(u_int8_t) + sizeof(u_int32_t));
	return value;
}

int
necp_buffer_find_tlv(u_int8_t *buffer, u_int32_t buffer_length, int offset, u_int8_t type, int *err, int next)
{
	if (err != NULL) {
		*err = ENOENT;
	}
	if (offset < 0) {
		if (err != NULL) {
			*err = EINVAL;
		}
		return -1;
	}
	int cursor = offset;
	int next_cursor;
	u_int32_t curr_length;
	u_int8_t curr_type;

	while (TRUE) {
		if ((((u_int32_t)cursor) + sizeof(curr_type) + sizeof(curr_length)) > buffer_length) {
			return -1;
		}
		if (!next) {
			curr_type = necp_buffer_get_tlv_type(buffer, cursor);
		} else {
			next = 0;
			curr_type = NECP_TLV_NIL;
		}
		curr_length = necp_buffer_get_tlv_length(buffer, cursor);
		if (curr_length > buffer_length - ((u_int32_t)cursor + sizeof(curr_type) + sizeof(curr_length))) {
			return -1;
		}

		next_cursor = (cursor + sizeof(curr_type) + sizeof(curr_length) + curr_length);
		if (curr_type == type) {
			// check if entire TLV fits inside buffer
			if (((u_int32_t)next_cursor) <= buffer_length) {
				if (err != NULL) {
					*err = 0;
				}
				return cursor;
			} else {
				return -1;
			}
		}
		cursor = next_cursor;
	}
}

static int
necp_find_tlv(u_int8_t *buffer, u_int32_t buffer_length, int offset, u_int8_t type, int *err, int next)
{
	int cursor = -1;
	if (buffer != NULL) {
		cursor = necp_buffer_find_tlv(buffer, buffer_length, offset, type, err, next);
	}
	return cursor;
}

static int
necp_get_tlv_at_offset(u_int8_t *buffer, u_int32_t buffer_length,
    int tlv_offset, u_int32_t out_buffer_length, void *out_buffer, u_int32_t *value_size)
{
	if (buffer == NULL) {
		NECPLOG0(LOG_ERR, "necp_get_tlv_at_offset buffer is NULL");
		return EINVAL;
	}

	// Handle buffer parsing

	// Validate that buffer has enough room for any TLV
	if (tlv_offset + sizeof(u_int8_t) + sizeof(u_int32_t) > buffer_length) {
		NECPLOG(LOG_ERR, "necp_get_tlv_at_offset buffer_length is too small for TLV (%u < %u)",
		    buffer_length, tlv_offset + sizeof(u_int8_t) + sizeof(u_int32_t));
		return EINVAL;
	}

	// Validate that buffer has enough room for this TLV
	u_int32_t tlv_length = necp_buffer_get_tlv_length(buffer, tlv_offset);
	if (tlv_length > buffer_length - (tlv_offset + sizeof(u_int8_t) + sizeof(u_int32_t))) {
		NECPLOG(LOG_ERR, "necp_get_tlv_at_offset buffer_length is too small for TLV of length %u (%u < %u)",
		    tlv_length, buffer_length, tlv_offset + sizeof(u_int8_t) + sizeof(u_int32_t) + tlv_length);
		return EINVAL;
	}

	if (out_buffer != NULL && out_buffer_length > 0) {
		// Validate that out buffer is large enough for  value
		if (out_buffer_length < tlv_length) {
			NECPLOG(LOG_ERR, "necp_get_tlv_at_offset out_buffer_length is too small for TLV value (%u < %u)",
			    out_buffer_length, tlv_length);
			return EINVAL;
		}

		// Get value pointer
		u_int8_t *tlv_value = necp_buffer_get_tlv_value(buffer, tlv_offset, NULL);
		if (tlv_value == NULL) {
			NECPLOG0(LOG_ERR, "necp_get_tlv_at_offset tlv_value is NULL");
			return ENOENT;
		}

		// Copy value
		memcpy(out_buffer, tlv_value, tlv_length);
	}

	// Copy out length
	if (value_size != NULL) {
		*value_size = tlv_length;
	}

	return 0;
}

static int
necp_get_tlv(u_int8_t *buffer, u_int32_t buffer_length,
    int offset, u_int8_t type, u_int32_t buff_len, void *buff, u_int32_t *value_size)
{
	int error = 0;

	int tlv_offset = necp_find_tlv(buffer, buffer_length, offset, type, &error, 0);
	if (tlv_offset < 0) {
		return error;
	}

	return necp_get_tlv_at_offset(buffer, buffer_length, tlv_offset, buff_len, buff, value_size);
}

// Session Management

static struct necp_session *
necp_create_session(void)
{
	struct necp_session *new_session = NULL;

	MALLOC(new_session, struct necp_session *, sizeof(*new_session), M_NECP, M_WAITOK | M_ZERO);
	if (new_session == NULL) {
		goto done;
	}

	new_session->necp_fd_type = necp_fd_type_session;
	new_session->session_priority = NECP_SESSION_PRIORITY_UNKNOWN;
	new_session->dirty = FALSE;
	LIST_INIT(&new_session->policies);
	lck_mtx_init(&new_session->lock, necp_kernel_policy_mtx_grp, necp_kernel_policy_mtx_attr);

	// Take the lock
	lck_rw_lock_exclusive(&necp_kernel_policy_lock);

	// Find the next available control unit
	u_int32_t control_unit = 1;
	struct necp_session *next_session = NULL;
	TAILQ_FOREACH(next_session, &necp_session_list, chain) {
		if (next_session->control_unit > control_unit) {
			// Found a gap, grab this control unit
			break;
		}

		// Try the next control unit, loop around
		control_unit = next_session->control_unit + 1;
	}

	new_session->control_unit = control_unit;
	new_session->session_order = necp_allocate_new_session_order(new_session->session_priority, control_unit);

	if (next_session != NULL) {
		TAILQ_INSERT_BEFORE(next_session, new_session, chain);
	} else {
		TAILQ_INSERT_TAIL(&necp_session_list, new_session, chain);
	}

	necp_session_count++;
	lck_rw_done(&necp_kernel_policy_lock);

	if (necp_debug) {
		NECPLOG(LOG_DEBUG, "Created NECP session, control unit %d", control_unit);
	}

done:
	return new_session;
}

static void
necp_delete_session(struct necp_session *session)
{
	if (session != NULL) {
		struct necp_service_registration *service = NULL;
		struct necp_service_registration *temp_service = NULL;
		LIST_FOREACH_SAFE(service, &session->services, session_chain, temp_service) {
			LIST_REMOVE(service, session_chain);
			lck_rw_lock_exclusive(&necp_kernel_policy_lock);
			LIST_REMOVE(service, kernel_chain);
			lck_rw_done(&necp_kernel_policy_lock);
			FREE(service, M_NECP);
		}
		if (necp_debug) {
			NECPLOG0(LOG_DEBUG, "Deleted NECP session");
		}

		lck_rw_lock_exclusive(&necp_kernel_policy_lock);
		TAILQ_REMOVE(&necp_session_list, session, chain);
		necp_session_count--;
		lck_rw_done(&necp_kernel_policy_lock);

		lck_mtx_destroy(&session->lock, necp_kernel_policy_mtx_grp);
		FREE(session, M_NECP);
	}
}

// Session Policy Management

static inline u_int8_t
necp_policy_result_get_type_from_buffer(u_int8_t *buffer, u_int32_t length)
{
	return (buffer && length >= sizeof(u_int8_t)) ? buffer[0] : 0;
}

static inline u_int32_t
necp_policy_result_get_parameter_length_from_buffer(u_int8_t *buffer, u_int32_t length)
{
	return (buffer && length > sizeof(u_int8_t)) ? (length - sizeof(u_int8_t)) : 0;
}

static inline u_int8_t *
necp_policy_result_get_parameter_pointer_from_buffer(u_int8_t *buffer, u_int32_t length)
{
	return (buffer && length > sizeof(u_int8_t)) ? (buffer + sizeof(u_int8_t)) : NULL;
}

static bool
necp_policy_result_requires_route_rules(u_int8_t *buffer, u_int32_t length)
{
	u_int8_t type = necp_policy_result_get_type_from_buffer(buffer, length);
	if (type == NECP_POLICY_RESULT_ROUTE_RULES) {
		return TRUE;
	}
	return FALSE;
}

static inline bool
necp_address_is_valid(struct sockaddr *address)
{
	if (address->sa_family == AF_INET) {
		return address->sa_len == sizeof(struct sockaddr_in);
	} else if (address->sa_family == AF_INET6) {
		return address->sa_len == sizeof(struct sockaddr_in6);
	} else {
		return FALSE;
	}
}

static bool
necp_policy_result_is_valid(u_int8_t *buffer, u_int32_t length)
{
	bool validated = FALSE;
	u_int8_t type = necp_policy_result_get_type_from_buffer(buffer, length);
	u_int32_t parameter_length = necp_policy_result_get_parameter_length_from_buffer(buffer, length);
	switch (type) {
	case NECP_POLICY_RESULT_PASS:
	case NECP_POLICY_RESULT_DROP:
	case NECP_POLICY_RESULT_ROUTE_RULES:
	case NECP_POLICY_RESULT_SCOPED_DIRECT:
	case NECP_POLICY_RESULT_ALLOW_UNENTITLED: {
		validated = TRUE;
		break;
	}
	case NECP_POLICY_RESULT_SKIP:
	case NECP_POLICY_RESULT_SOCKET_DIVERT:
	case NECP_POLICY_RESULT_SOCKET_FILTER: {
		if (parameter_length >= sizeof(u_int32_t)) {
			validated = TRUE;
		}
		break;
	}
	case NECP_POLICY_RESULT_IP_TUNNEL: {
		if (parameter_length > sizeof(u_int32_t)) {
			validated = TRUE;
		}
		break;
	}
	case NECP_POLICY_RESULT_SOCKET_SCOPED: {
		if (parameter_length > 0) {
			validated = TRUE;
		}
		break;
	}
	case NECP_POLICY_RESULT_TRIGGER:
	case NECP_POLICY_RESULT_TRIGGER_IF_NEEDED:
	case NECP_POLICY_RESULT_TRIGGER_SCOPED:
	case NECP_POLICY_RESULT_NO_TRIGGER_SCOPED:
	case NECP_POLICY_RESULT_USE_NETAGENT:
	case NECP_POLICY_RESULT_NETAGENT_SCOPED:{
		if (parameter_length >= sizeof(uuid_t)) {
			validated = TRUE;
		}
		break;
	}
	default: {
		validated = FALSE;
		break;
	}
	}

	if (necp_debug) {
		NECPLOG(LOG_DEBUG, "Policy result type %d, valid %d", type, validated);
	}

	return validated;
}

static inline u_int8_t
necp_policy_condition_get_type_from_buffer(u_int8_t *buffer, u_int32_t length)
{
	return (buffer && length >= sizeof(u_int8_t)) ? buffer[0] : 0;
}

static inline u_int8_t
necp_policy_condition_get_flags_from_buffer(u_int8_t *buffer, u_int32_t length)
{
	return (buffer && length >= (2 * sizeof(u_int8_t))) ? buffer[1] : 0;
}

static inline u_int32_t
necp_policy_condition_get_value_length_from_buffer(u_int8_t *buffer, u_int32_t length)
{
	return (buffer && length >= (2 * sizeof(u_int8_t))) ? (length - (2 * sizeof(u_int8_t))) : 0;
}

static inline u_int8_t *
necp_policy_condition_get_value_pointer_from_buffer(u_int8_t *buffer, u_int32_t length)
{
	return (buffer && length > (2 * sizeof(u_int8_t))) ? (buffer + (2 * sizeof(u_int8_t))) : NULL;
}

static inline bool
necp_policy_condition_is_default(u_int8_t *buffer, u_int32_t length)
{
	return necp_policy_condition_get_type_from_buffer(buffer, length) == NECP_POLICY_CONDITION_DEFAULT;
}

static inline bool
necp_policy_condition_is_application(u_int8_t *buffer, u_int32_t length)
{
	return necp_policy_condition_get_type_from_buffer(buffer, length) == NECP_POLICY_CONDITION_APPLICATION;
}

static inline bool
necp_policy_condition_is_real_application(u_int8_t *buffer, u_int32_t length)
{
	return necp_policy_condition_get_type_from_buffer(buffer, length) == NECP_POLICY_CONDITION_REAL_APPLICATION;
}

static inline bool
necp_policy_condition_requires_application(u_int8_t *buffer, u_int32_t length)
{
	u_int8_t type = necp_policy_condition_get_type_from_buffer(buffer, length);
	return type == NECP_POLICY_CONDITION_REAL_APPLICATION;
}

static inline bool
necp_policy_condition_requires_real_application(u_int8_t *buffer, u_int32_t length)
{
	u_int8_t type = necp_policy_condition_get_type_from_buffer(buffer, length);
	return type == NECP_POLICY_CONDITION_ENTITLEMENT;
}

static bool
necp_policy_condition_is_valid(u_int8_t *buffer, u_int32_t length, u_int8_t policy_result_type)
{
	bool validated = FALSE;
	bool result_cannot_have_ip_layer = (policy_result_type == NECP_POLICY_RESULT_SOCKET_DIVERT ||
	    policy_result_type == NECP_POLICY_RESULT_SOCKET_FILTER ||
	    policy_result_type == NECP_POLICY_RESULT_TRIGGER ||
	    policy_result_type == NECP_POLICY_RESULT_TRIGGER_IF_NEEDED ||
	    policy_result_type == NECP_POLICY_RESULT_TRIGGER_SCOPED ||
	    policy_result_type == NECP_POLICY_RESULT_NO_TRIGGER_SCOPED ||
	    policy_result_type == NECP_POLICY_RESULT_SOCKET_SCOPED ||
	    policy_result_type == NECP_POLICY_RESULT_ROUTE_RULES ||
	    policy_result_type == NECP_POLICY_RESULT_USE_NETAGENT ||
	    policy_result_type == NECP_POLICY_RESULT_NETAGENT_SCOPED ||
	    policy_result_type == NECP_POLICY_RESULT_SCOPED_DIRECT ||
	    policy_result_type == NECP_POLICY_RESULT_ALLOW_UNENTITLED) ? TRUE : FALSE;
	u_int32_t condition_length = necp_policy_condition_get_value_length_from_buffer(buffer, length);
	u_int8_t *condition_value = necp_policy_condition_get_value_pointer_from_buffer(buffer, length);
	u_int8_t type = necp_policy_condition_get_type_from_buffer(buffer, length);
	u_int8_t flags = necp_policy_condition_get_flags_from_buffer(buffer, length);
	switch (type) {
	case NECP_POLICY_CONDITION_APPLICATION:
	case NECP_POLICY_CONDITION_REAL_APPLICATION: {
		if (!(flags & NECP_POLICY_CONDITION_FLAGS_NEGATIVE) &&
		    condition_length >= sizeof(uuid_t) &&
		    condition_value != NULL &&
		    !uuid_is_null(condition_value)) {
			validated = TRUE;
		}
		break;
	}
	case NECP_POLICY_CONDITION_DOMAIN:
	case NECP_POLICY_CONDITION_ACCOUNT:
	case NECP_POLICY_CONDITION_BOUND_INTERFACE: {
		if (condition_length > 0) {
			validated = TRUE;
		}
		break;
	}
	case NECP_POLICY_CONDITION_TRAFFIC_CLASS: {
		if (condition_length >= sizeof(struct necp_policy_condition_tc_range)) {
			validated = TRUE;
		}
		break;
	}
	case NECP_POLICY_CONDITION_DEFAULT:
	case NECP_POLICY_CONDITION_ALL_INTERFACES:
	case NECP_POLICY_CONDITION_ENTITLEMENT:
	case NECP_POLICY_CONDITION_PLATFORM_BINARY:
	case NECP_POLICY_CONDITION_HAS_CLIENT:
	case NECP_POLICY_CONDITION_LOCAL_NETWORKS: {
		if (!(flags & NECP_POLICY_CONDITION_FLAGS_NEGATIVE)) {
			validated = TRUE;
		}
		break;
	}
	case NECP_POLICY_CONDITION_IP_PROTOCOL: {
		if (condition_length >= sizeof(u_int16_t)) {
			validated = TRUE;
		}
		break;
	}
	case NECP_POLICY_CONDITION_PID: {
		if (condition_length >= sizeof(pid_t) &&
		    condition_value != NULL &&
		    *((pid_t *)(void *)condition_value) != 0) {
			validated = TRUE;
		}
		break;
	}
	case NECP_POLICY_CONDITION_UID: {
		if (condition_length >= sizeof(uid_t)) {
			validated = TRUE;
		}
		break;
	}
	case NECP_POLICY_CONDITION_LOCAL_ADDR:
	case NECP_POLICY_CONDITION_REMOTE_ADDR: {
		if (!result_cannot_have_ip_layer && condition_length >= sizeof(struct necp_policy_condition_addr) &&
		    necp_address_is_valid(&((struct necp_policy_condition_addr *)(void *)condition_value)->address.sa)) {
			validated = TRUE;
		}
		break;
	}
	case NECP_POLICY_CONDITION_LOCAL_ADDR_RANGE:
	case NECP_POLICY_CONDITION_REMOTE_ADDR_RANGE: {
		if (!result_cannot_have_ip_layer && condition_length >= sizeof(struct necp_policy_condition_addr_range) &&
		    necp_address_is_valid(&((struct necp_policy_condition_addr_range *)(void *)condition_value)->start_address.sa) &&
		    necp_address_is_valid(&((struct necp_policy_condition_addr_range *)(void *)condition_value)->end_address.sa)) {
			validated = TRUE;
		}
		break;
	}
	case NECP_POLICY_CONDITION_AGENT_TYPE: {
		if (!(flags & NECP_POLICY_CONDITION_FLAGS_NEGATIVE) &&
		    condition_length >= sizeof(struct necp_policy_condition_agent_type)) {
			validated = TRUE;
		}
		break;
	}
	case NECP_POLICY_CONDITION_FLOW_IP_PROTOCOL: {
		if (condition_length >= sizeof(u_int16_t)) {
			validated = TRUE;
		}
		break;
	}
	case NECP_POLICY_CONDITION_FLOW_LOCAL_ADDR:
	case NECP_POLICY_CONDITION_FLOW_REMOTE_ADDR: {
		if (condition_length >= sizeof(struct necp_policy_condition_addr) &&
		    necp_address_is_valid(&((struct necp_policy_condition_addr *)(void *)condition_value)->address.sa)) {
			validated = TRUE;
		}
		break;
	}
	case NECP_POLICY_CONDITION_FLOW_LOCAL_ADDR_RANGE:
	case NECP_POLICY_CONDITION_FLOW_REMOTE_ADDR_RANGE: {
		if (condition_length >= sizeof(struct necp_policy_condition_addr_range) &&
		    necp_address_is_valid(&((struct necp_policy_condition_addr_range *)(void *)condition_value)->start_address.sa) &&
		    necp_address_is_valid(&((struct necp_policy_condition_addr_range *)(void *)condition_value)->end_address.sa)) {
			validated = TRUE;
		}
		break;
	}
	case NECP_POLICY_CONDITION_CLIENT_FLAGS: {
		if (condition_length == 0 || condition_length >= sizeof(u_int32_t)) {
			validated = TRUE;
		}
		break;
	}
	case NECP_POLICY_CONDITION_FLOW_LOCAL_ADDR_EMPTY: {
		validated = TRUE;
		break;
	}
	case NECP_POLICY_CONDITION_FLOW_REMOTE_ADDR_EMPTY: {
		validated = TRUE;
		break;
	}
	default: {
		validated = FALSE;
		break;
	}
	}

	if (necp_debug) {
		NECPLOG(LOG_DEBUG, "Policy condition type %d, valid %d", type, validated);
	}

	return validated;
}

static bool
necp_policy_route_rule_is_default(u_int8_t *buffer, u_int32_t length)
{
	return necp_policy_condition_get_value_length_from_buffer(buffer, length) == 0 &&
	       necp_policy_condition_get_flags_from_buffer(buffer, length) == 0;
}

static bool
necp_policy_route_rule_is_valid(u_int8_t *buffer, u_int32_t length)
{
	bool validated = FALSE;
	u_int8_t type = necp_policy_condition_get_type_from_buffer(buffer, length);
	switch (type) {
	case NECP_ROUTE_RULE_ALLOW_INTERFACE: {
		validated = TRUE;
		break;
	}
	case NECP_ROUTE_RULE_DENY_INTERFACE: {
		validated = TRUE;
		break;
	}
	case NECP_ROUTE_RULE_QOS_MARKING: {
		validated = TRUE;
		break;
	}
	case NECP_ROUTE_RULE_DENY_LQM_ABORT: {
		validated = TRUE;
		break;
	}
	default: {
		validated = FALSE;
		break;
	}
	}

	if (necp_debug) {
		NECPLOG(LOG_DEBUG, "Policy route rule type %d, valid %d", type, validated);
	}

	return validated;
}

static int
necp_get_posix_error_for_necp_error(int response_error)
{
	switch (response_error) {
	case NECP_ERROR_UNKNOWN_PACKET_TYPE:
	case NECP_ERROR_INVALID_TLV:
	case NECP_ERROR_POLICY_RESULT_INVALID:
	case NECP_ERROR_POLICY_CONDITIONS_INVALID:
	case NECP_ERROR_ROUTE_RULES_INVALID: {
		return EINVAL;
	}
	case NECP_ERROR_POLICY_ID_NOT_FOUND: {
		return ENOENT;
	}
	case NECP_ERROR_INVALID_PROCESS: {
		return EPERM;
	}
	case NECP_ERROR_INTERNAL:
	default: {
		return ENOMEM;
	}
	}
}

static necp_policy_id
necp_handle_policy_add(struct necp_session *session,
    u_int8_t *tlv_buffer, size_t tlv_buffer_length, int offset, int *return_error)
{
	bool has_default_condition = FALSE;
	bool has_non_default_condition = FALSE;
	bool has_application_condition = FALSE;
	bool has_real_application_condition = FALSE;
	bool requires_application_condition = FALSE;
	bool requires_real_application_condition = FALSE;
	u_int8_t *conditions_array = NULL;
	u_int32_t conditions_array_size = 0;
	int conditions_array_cursor;

	bool has_default_route_rule = FALSE;
	u_int8_t *route_rules_array = NULL;
	u_int32_t route_rules_array_size = 0;
	int route_rules_array_cursor;

	int cursor;
	int error = 0;
	u_int32_t response_error = NECP_ERROR_INTERNAL;

	necp_policy_order order = 0;
	struct necp_session_policy *policy = NULL;
	u_int8_t *policy_result = NULL;
	u_int32_t policy_result_size = 0;

	// Read policy order
	error = necp_get_tlv(tlv_buffer, tlv_buffer_length, offset, NECP_TLV_POLICY_ORDER, sizeof(order), &order, NULL);
	if (error) {
		NECPLOG(LOG_ERR, "Failed to get policy order: %d", error);
		response_error = NECP_ERROR_INVALID_TLV;
		goto fail;
	}

	// Read policy result
	cursor = necp_find_tlv(tlv_buffer, tlv_buffer_length, offset, NECP_TLV_POLICY_RESULT, &error, 0);
	if (error || cursor < 0) {
		NECPLOG(LOG_ERR, "Failed to find policy result TLV: %d", error);
		response_error = NECP_ERROR_INVALID_TLV;
		goto fail;
	}
	error = necp_get_tlv_at_offset(tlv_buffer, tlv_buffer_length, cursor, 0, NULL, &policy_result_size);
	if (error || policy_result_size == 0) {
		NECPLOG(LOG_ERR, "Failed to get policy result length: %d", error);
		response_error = NECP_ERROR_INVALID_TLV;
		goto fail;
	}
	if (policy_result_size > NECP_MAX_POLICY_RESULT_SIZE) {
		NECPLOG(LOG_ERR, "Policy result length too large: %u", policy_result_size);
		response_error = NECP_ERROR_INVALID_TLV;
		goto fail;
	}
	MALLOC(policy_result, u_int8_t *, policy_result_size, M_NECP, M_WAITOK);
	if (policy_result == NULL) {
		NECPLOG(LOG_ERR, "Failed to allocate a policy result buffer (size %d)", policy_result_size);
		response_error = NECP_ERROR_INTERNAL;
		goto fail;
	}
	error = necp_get_tlv_at_offset(tlv_buffer, tlv_buffer_length, cursor, policy_result_size, policy_result, NULL);
	if (error) {
		NECPLOG(LOG_ERR, "Failed to get policy result: %d", error);
		response_error = NECP_ERROR_POLICY_RESULT_INVALID;
		goto fail;
	}
	if (!necp_policy_result_is_valid(policy_result, policy_result_size)) {
		NECPLOG0(LOG_ERR, "Failed to validate policy result");
		response_error = NECP_ERROR_POLICY_RESULT_INVALID;
		goto fail;
	}

	if (necp_policy_result_requires_route_rules(policy_result, policy_result_size)) {
		// Read route rules conditions
		for (cursor = necp_find_tlv(tlv_buffer, tlv_buffer_length, offset, NECP_TLV_ROUTE_RULE, &error, 0);
		    cursor >= 0;
		    cursor = necp_find_tlv(tlv_buffer, tlv_buffer_length, cursor, NECP_TLV_ROUTE_RULE, &error, 1)) {
			u_int32_t route_rule_size = 0;
			necp_get_tlv_at_offset(tlv_buffer, tlv_buffer_length, cursor, 0, NULL, &route_rule_size);
			if (os_add_overflow(route_rules_array_size,
			    (sizeof(u_int8_t) + sizeof(u_int32_t) + route_rule_size),
			    &route_rules_array_size)) {
				NECPLOG0(LOG_ERR, "Route rules size overflowed, too large");
				response_error = NECP_ERROR_INVALID_TLV;
				goto fail;
			}
		}

		if (route_rules_array_size == 0) {
			NECPLOG0(LOG_ERR, "Failed to get policy route rules");
			response_error = NECP_ERROR_INVALID_TLV;
			goto fail;
		}
		if (route_rules_array_size > NECP_MAX_ROUTE_RULES_ARRAY_SIZE) {
			NECPLOG(LOG_ERR, "Route rules length too large: %u", route_rules_array_size);
			response_error = NECP_ERROR_INVALID_TLV;
			goto fail;
		}
		MALLOC(route_rules_array, u_int8_t *, route_rules_array_size, M_NECP, M_WAITOK);
		if (route_rules_array == NULL) {
			NECPLOG(LOG_ERR, "Failed to allocate a policy route rules array (size %d)", route_rules_array_size);
			response_error = NECP_ERROR_INTERNAL;
			goto fail;
		}

		route_rules_array_cursor = 0;
		for (cursor = necp_find_tlv(tlv_buffer, tlv_buffer_length, offset, NECP_TLV_ROUTE_RULE, &error, 0);
		    cursor >= 0;
		    cursor = necp_find_tlv(tlv_buffer, tlv_buffer_length, cursor, NECP_TLV_ROUTE_RULE, &error, 1)) {
			u_int8_t route_rule_type = NECP_TLV_ROUTE_RULE;
			u_int32_t route_rule_size = 0;
			necp_get_tlv_at_offset(tlv_buffer, tlv_buffer_length, cursor, 0, NULL, &route_rule_size);
			if (route_rule_size > 0 &&
			    (sizeof(route_rule_type) + sizeof(route_rule_size) + route_rule_size) <= (route_rules_array_size - route_rules_array_cursor)) {
				// Add type
				memcpy((route_rules_array + route_rules_array_cursor), &route_rule_type, sizeof(route_rule_type));
				route_rules_array_cursor += sizeof(route_rule_type);

				// Add length
				memcpy((route_rules_array + route_rules_array_cursor), &route_rule_size, sizeof(route_rule_size));
				route_rules_array_cursor += sizeof(route_rule_size);

				// Add value
				necp_get_tlv_at_offset(tlv_buffer, tlv_buffer_length, cursor, route_rule_size, (route_rules_array + route_rules_array_cursor), NULL);

				if (!necp_policy_route_rule_is_valid((route_rules_array + route_rules_array_cursor), route_rule_size)) {
					NECPLOG0(LOG_ERR, "Failed to validate policy route rule");
					response_error = NECP_ERROR_ROUTE_RULES_INVALID;
					goto fail;
				}

				if (necp_policy_route_rule_is_default((route_rules_array + route_rules_array_cursor), route_rule_size)) {
					if (has_default_route_rule) {
						NECPLOG0(LOG_ERR, "Failed to validate route rule; contained multiple default route rules");
						response_error = NECP_ERROR_ROUTE_RULES_INVALID;
						goto fail;
					}
					has_default_route_rule = TRUE;
				}

				route_rules_array_cursor += route_rule_size;
			}
		}
	}

	// Read policy conditions
	for (cursor = necp_find_tlv(tlv_buffer, tlv_buffer_length, offset, NECP_TLV_POLICY_CONDITION, &error, 0);
	    cursor >= 0;
	    cursor = necp_find_tlv(tlv_buffer, tlv_buffer_length, cursor, NECP_TLV_POLICY_CONDITION, &error, 1)) {
		u_int32_t condition_size = 0;
		necp_get_tlv_at_offset(tlv_buffer, tlv_buffer_length, cursor, 0, NULL, &condition_size);

		if (condition_size > 0) {
			if (os_add_overflow(conditions_array_size,
			    (sizeof(u_int8_t) + sizeof(u_int32_t) + condition_size),
			    &conditions_array_size)) {
				NECPLOG0(LOG_ERR, "Conditions size overflowed, too large");
				response_error = NECP_ERROR_INVALID_TLV;
				goto fail;
			}
		}
	}

	if (conditions_array_size == 0) {
		NECPLOG0(LOG_ERR, "Failed to get policy conditions");
		response_error = NECP_ERROR_INVALID_TLV;
		goto fail;
	}
	if (conditions_array_size > NECP_MAX_CONDITIONS_ARRAY_SIZE) {
		NECPLOG(LOG_ERR, "Conditions length too large: %u", conditions_array_size);
		response_error = NECP_ERROR_INVALID_TLV;
		goto fail;
	}
	MALLOC(conditions_array, u_int8_t *, conditions_array_size, M_NECP, M_WAITOK);
	if (conditions_array == NULL) {
		NECPLOG(LOG_ERR, "Failed to allocate a policy conditions array (size %d)", conditions_array_size);
		response_error = NECP_ERROR_INTERNAL;
		goto fail;
	}

	conditions_array_cursor = 0;
	for (cursor = necp_find_tlv(tlv_buffer, tlv_buffer_length, offset, NECP_TLV_POLICY_CONDITION, &error, 0);
	    cursor >= 0;
	    cursor = necp_find_tlv(tlv_buffer, tlv_buffer_length, cursor, NECP_TLV_POLICY_CONDITION, &error, 1)) {
		u_int8_t condition_type = NECP_TLV_POLICY_CONDITION;
		u_int32_t condition_size = 0;
		necp_get_tlv_at_offset(tlv_buffer, tlv_buffer_length, cursor, 0, NULL, &condition_size);
		if (condition_size > 0 &&
		    (sizeof(condition_type) + sizeof(condition_size) + condition_size) <= (conditions_array_size - conditions_array_cursor)) {
			// Add type
			memcpy((conditions_array + conditions_array_cursor), &condition_type, sizeof(condition_type));
			conditions_array_cursor += sizeof(condition_type);

			// Add length
			memcpy((conditions_array + conditions_array_cursor), &condition_size, sizeof(condition_size));
			conditions_array_cursor += sizeof(condition_size);

			// Add value
			necp_get_tlv_at_offset(tlv_buffer, tlv_buffer_length, cursor, condition_size, (conditions_array + conditions_array_cursor), NULL);
			if (!necp_policy_condition_is_valid((conditions_array + conditions_array_cursor), condition_size, necp_policy_result_get_type_from_buffer(policy_result, policy_result_size))) {
				NECPLOG0(LOG_ERR, "Failed to validate policy condition");
				response_error = NECP_ERROR_POLICY_CONDITIONS_INVALID;
				goto fail;
			}

			if (necp_policy_condition_is_default((conditions_array + conditions_array_cursor), condition_size)) {
				has_default_condition = TRUE;
			} else {
				has_non_default_condition = TRUE;
			}
			if (has_default_condition && has_non_default_condition) {
				NECPLOG0(LOG_ERR, "Failed to validate conditions; contained default and non-default conditions");
				response_error = NECP_ERROR_POLICY_CONDITIONS_INVALID;
				goto fail;
			}

			if (necp_policy_condition_is_application((conditions_array + conditions_array_cursor), condition_size)) {
				has_application_condition = TRUE;
			}

			if (necp_policy_condition_is_real_application((conditions_array + conditions_array_cursor), condition_size)) {
				has_real_application_condition = TRUE;
			}

			if (necp_policy_condition_requires_application((conditions_array + conditions_array_cursor), condition_size)) {
				requires_application_condition = TRUE;
			}

			if (necp_policy_condition_requires_real_application((conditions_array + conditions_array_cursor), condition_size)) {
				requires_real_application_condition = TRUE;
			}

			conditions_array_cursor += condition_size;
		}
	}

	if (requires_application_condition && !has_application_condition) {
		NECPLOG0(LOG_ERR, "Failed to validate conditions; did not contain application condition");
		response_error = NECP_ERROR_POLICY_CONDITIONS_INVALID;
		goto fail;
	}

	if (requires_real_application_condition && !has_real_application_condition) {
		NECPLOG0(LOG_ERR, "Failed to validate conditions; did not contain real application condition");
		response_error = NECP_ERROR_POLICY_CONDITIONS_INVALID;
		goto fail;
	}

	if ((policy = necp_policy_create(session, order, conditions_array, conditions_array_size, route_rules_array, route_rules_array_size, policy_result, policy_result_size)) == NULL) {
		response_error = NECP_ERROR_INTERNAL;
		goto fail;
	}

	return policy->local_id;

fail:
	if (policy_result != NULL) {
		FREE(policy_result, M_NECP);
	}
	if (conditions_array != NULL) {
		FREE(conditions_array, M_NECP);
	}
	if (route_rules_array != NULL) {
		FREE(route_rules_array, M_NECP);
	}

	if (return_error != NULL) {
		*return_error = necp_get_posix_error_for_necp_error(response_error);
	}
	return 0;
}

static necp_policy_id
necp_policy_get_new_id(struct necp_session *session)
{
	session->last_policy_id++;
	if (session->last_policy_id < 1) {
		session->last_policy_id = 1;
	}

	necp_policy_id newid = session->last_policy_id;

	if (newid == 0) {
		NECPLOG0(LOG_ERR, "Allocate policy id failed.\n");
		return 0;
	}

	return newid;
}

/*
 *	For the policy dump response this is the structure:
 *
 *	<NECP_PACKET_HEADER>
 *	{
 *		type	:	NECP_TLV_POLICY_DUMP
 *		length	:	...
 *		value	:
 *		{
 *			{
 *				type	:	NECP_TLV_POLICY_ID
 *				len		:	...
 *				value	:	...
 *			}
 *			{
 *				type	:	NECP_TLV_POLICY_ORDER
 *				len		:	...
 *				value	:	...
 *			}
 *			{
 *				type	:	NECP_TLV_POLICY_RESULT_STRING
 *				len		:	...
 *				value	:	...
 *			}
 *			{
 *				type	:	NECP_TLV_POLICY_OWNER
 *				len		:	...
 *				value	:	...
 *			}
 *			{
 *				type	:	NECP_TLV_POLICY_CONDITION
 *				len		:	...
 *				value	:
 *				{
 *					{
 *						type	:	NECP_POLICY_CONDITION_ALL_INTERFACES
 *						len		:	...
 *						value	:	...
 *					}
 *					{
 *						type	:	NECP_POLICY_CONDITION_BOUND_INTERFACES
 *						len		:	...
 *						value	:	...
 *					}
 *					...
 *				}
 *			}
 *		}
 *	}
 *	{
 *		type	:	NECP_TLV_POLICY_DUMP
 *		length	:	...
 *		value	:
 *		{
 *			{
 *				type	:	NECP_TLV_POLICY_ID
 *				len		:	...
 *				value	:	...
 *			}
 *			{
 *				type	:	NECP_TLV_POLICY_ORDER
 *				len		:	...
 *				value	:	...
 *			}
 *			{
 *				type	:	NECP_TLV_POLICY_RESULT_STRING
 *				len		:	...
 *				value	:	...
 *			}
 *			{
 *				type	:	NECP_TLV_POLICY_OWNER
 *				len		:	...
 *				value	:	...
 *			}
 *			{
 *				type	:	NECP_TLV_POLICY_CONDITION
 *				len		:	...
 *				value	:
 *				{
 *					{
 *						type	:	NECP_POLICY_CONDITION_ALL_INTERFACES
 *						len		:	...
 *						value	:	...
 *					}
 *					{
 *						type	:	NECP_POLICY_CONDITION_BOUND_INTERFACES
 *						len		:	...
 *						value	:	...
 *					}
 *					...
 *				}
 *			}
 *		}
 *	}
 *	...
 */
static int
necp_handle_policy_dump_all(user_addr_t out_buffer, size_t out_buffer_length)
{
	struct necp_kernel_socket_policy *policy = NULL;
	int policy_i;
	int policy_count = 0;
	u_int8_t **tlv_buffer_pointers = NULL;
	u_int32_t *tlv_buffer_lengths = NULL;
	u_int32_t total_tlv_len = 0;
	u_int8_t *result_buf = NULL;
	u_int8_t *result_buf_cursor = result_buf;
	char result_string[MAX_RESULT_STRING_LEN];
	char proc_name_string[MAXCOMLEN + 1];

	int error_code = 0;
	bool error_occured = false;
	u_int32_t response_error = NECP_ERROR_INTERNAL;

#define REPORT_ERROR(error) error_occured = true;               \
	                                                response_error = error;         \
	                                                goto done

#define UNLOCK_AND_REPORT_ERROR(lock, error)    lck_rw_done(lock);      \
	                                                                                        REPORT_ERROR(error)

	errno_t cred_result = priv_check_cred(kauth_cred_get(), PRIV_NET_PRIVILEGED_NECP_POLICIES, 0);
	if (cred_result != 0) {
		NECPLOG0(LOG_ERR, "Session does not hold the necessary entitlement to get Network Extension Policy information");
		REPORT_ERROR(NECP_ERROR_INTERNAL);
	}

	// LOCK
	lck_rw_lock_shared(&necp_kernel_policy_lock);

	if (necp_debug) {
		NECPLOG0(LOG_DEBUG, "Gathering policies");
	}

	policy_count = necp_kernel_application_policies_count;

	MALLOC(tlv_buffer_pointers, u_int8_t * *, sizeof(u_int8_t *) * policy_count, M_NECP, M_NOWAIT | M_ZERO);
	if (tlv_buffer_pointers == NULL) {
		NECPLOG(LOG_DEBUG, "Failed to allocate tlv_buffer_pointers (%u bytes)", sizeof(u_int8_t *) * policy_count);
		UNLOCK_AND_REPORT_ERROR(&necp_kernel_policy_lock, NECP_ERROR_INTERNAL);
	}

	MALLOC(tlv_buffer_lengths, u_int32_t *, sizeof(u_int32_t) * policy_count, M_NECP, M_NOWAIT | M_ZERO);
	if (tlv_buffer_lengths == NULL) {
		NECPLOG(LOG_DEBUG, "Failed to allocate tlv_buffer_lengths (%u bytes)", sizeof(u_int32_t) * policy_count);
		UNLOCK_AND_REPORT_ERROR(&necp_kernel_policy_lock, NECP_ERROR_INTERNAL);
	}

	for (policy_i = 0; necp_kernel_socket_policies_app_layer_map != NULL && necp_kernel_socket_policies_app_layer_map[policy_i] != NULL; policy_i++) {
		policy = necp_kernel_socket_policies_app_layer_map[policy_i];

		memset(result_string, 0, MAX_RESULT_STRING_LEN);
		memset(proc_name_string, 0, MAXCOMLEN + 1);

		necp_get_result_description(result_string, policy->result, policy->result_parameter);
		proc_name(policy->session_pid, proc_name_string, MAXCOMLEN);

		u_int16_t proc_name_len = strlen(proc_name_string) + 1;
		u_int16_t result_string_len = strlen(result_string) + 1;

		if (necp_debug) {
			NECPLOG(LOG_DEBUG, "Policy: process: %s, result: %s", proc_name_string, result_string);
		}

		u_int32_t total_allocated_bytes =       sizeof(u_int8_t) + sizeof(u_int32_t) + sizeof(policy->id) +                                     // NECP_TLV_POLICY_ID
		    sizeof(u_int8_t) + sizeof(u_int32_t) + sizeof(policy->order) +                                                                                              // NECP_TLV_POLICY_ORDER
		    sizeof(u_int8_t) + sizeof(u_int32_t) + sizeof(policy->session_order) +                                                                              // NECP_TLV_POLICY_SESSION_ORDER
		    sizeof(u_int8_t) + sizeof(u_int32_t) + result_string_len +                                                                                                          // NECP_TLV_POLICY_RESULT_STRING
		    sizeof(u_int8_t) + sizeof(u_int32_t) + proc_name_len +                                                                                                              // NECP_TLV_POLICY_OWNER
		    sizeof(u_int8_t) + sizeof(u_int32_t);                                                                                                                                               // NECP_TLV_POLICY_CONDITION

		// We now traverse the condition_mask to see how much space we need to allocate
		u_int32_t condition_mask = policy->condition_mask;
		u_int8_t num_conditions = 0;
		struct necp_string_id_mapping *account_id_entry = NULL;
		char if_name[IFXNAMSIZ];
		u_int32_t condition_tlv_length = 0;
		memset(if_name, 0, sizeof(if_name));

		if (condition_mask == NECP_POLICY_CONDITION_DEFAULT) {
			num_conditions++;
		} else {
			if (condition_mask & NECP_KERNEL_CONDITION_ALL_INTERFACES) {
				num_conditions++;
			}
			if (condition_mask & NECP_KERNEL_CONDITION_HAS_CLIENT) {
				num_conditions++;
			}
			if (condition_mask & NECP_KERNEL_CONDITION_BOUND_INTERFACE) {
				snprintf(if_name, IFXNAMSIZ, "%s%d", ifnet_name(policy->cond_bound_interface), ifnet_unit(policy->cond_bound_interface));
				condition_tlv_length += strlen(if_name) + 1;
				num_conditions++;
			}
			if (condition_mask & NECP_KERNEL_CONDITION_PROTOCOL) {
				condition_tlv_length += sizeof(policy->cond_protocol);
				num_conditions++;
			}
			if (condition_mask & NECP_KERNEL_CONDITION_APP_ID) {
				condition_tlv_length += sizeof(uuid_t);
				num_conditions++;
			}
			if (condition_mask & NECP_KERNEL_CONDITION_REAL_APP_ID) {
				condition_tlv_length += sizeof(uuid_t);
				num_conditions++;
			}
			if (condition_mask & NECP_KERNEL_CONDITION_DOMAIN) {
				u_int32_t domain_len = strlen(policy->cond_domain) + 1;
				condition_tlv_length += domain_len;
				num_conditions++;
			}
			if (condition_mask & NECP_KERNEL_CONDITION_ACCOUNT_ID) {
				account_id_entry = necp_lookup_string_with_id_locked(&necp_account_id_list, policy->cond_account_id);
				u_int32_t account_id_len = 0;
				if (account_id_entry) {
					account_id_len = account_id_entry->string ? strlen(account_id_entry->string) + 1 : 0;
				}
				condition_tlv_length += account_id_len;
				num_conditions++;
			}
			if (condition_mask & NECP_KERNEL_CONDITION_PID) {
				condition_tlv_length += sizeof(pid_t);
				num_conditions++;
			}
			if (condition_mask & NECP_KERNEL_CONDITION_UID) {
				condition_tlv_length += sizeof(uid_t);
				num_conditions++;
			}
			if (condition_mask & NECP_KERNEL_CONDITION_TRAFFIC_CLASS) {
				condition_tlv_length += sizeof(struct necp_policy_condition_tc_range);
				num_conditions++;
			}
			if (condition_mask & NECP_KERNEL_CONDITION_ENTITLEMENT) {
				num_conditions++;
			}
			if (condition_mask & NECP_KERNEL_CONDITION_CUSTOM_ENTITLEMENT) {
				u_int32_t entitlement_len = strlen(policy->cond_custom_entitlement) + 1;
				condition_tlv_length += entitlement_len;
				num_conditions++;
			}
			if (condition_mask & NECP_KERNEL_CONDITION_PLATFORM_BINARY) {
				num_conditions++;
			}
			if (condition_mask & NECP_KERNEL_CONDITION_LOCAL_NETWORKS) {
				num_conditions++;
			}
			if (condition_mask & NECP_KERNEL_CONDITION_LOCAL_START) {
				if (condition_mask & NECP_KERNEL_CONDITION_LOCAL_END) {
					condition_tlv_length += sizeof(struct necp_policy_condition_addr_range);
				} else {
					condition_tlv_length += sizeof(struct necp_policy_condition_addr);
				}
				num_conditions++;
			}
			if (condition_mask & NECP_KERNEL_CONDITION_REMOTE_START) {
				if (condition_mask & NECP_KERNEL_CONDITION_REMOTE_END) {
					condition_tlv_length += sizeof(struct necp_policy_condition_addr_range);
				} else {
					condition_tlv_length += sizeof(struct necp_policy_condition_addr);
				}
				num_conditions++;
			}
			if (condition_mask & NECP_KERNEL_CONDITION_AGENT_TYPE) {
				condition_tlv_length += sizeof(struct necp_policy_condition_agent_type);
				num_conditions++;
			}
			if (condition_mask & NECP_KERNEL_CONDITION_CLIENT_FLAGS) {
				condition_tlv_length += sizeof(u_int32_t);
				num_conditions++;
			}
			if (condition_mask & NECP_KERNEL_CONDITION_LOCAL_EMPTY) {
				num_conditions++;
			}
			if (condition_mask & NECP_KERNEL_CONDITION_REMOTE_EMPTY) {
				num_conditions++;
			}
		}

		condition_tlv_length += num_conditions * (sizeof(u_int8_t) + sizeof(u_int32_t)); // These are for the condition TLVs. The space for "value" is already accounted for above.
		total_allocated_bytes += condition_tlv_length;

		u_int8_t *tlv_buffer;
		MALLOC(tlv_buffer, u_int8_t *, total_allocated_bytes, M_NECP, M_NOWAIT | M_ZERO);
		if (tlv_buffer == NULL) {
			NECPLOG(LOG_DEBUG, "Failed to allocate tlv_buffer (%u bytes)", total_allocated_bytes);
			continue;
		}

		u_int8_t *cursor = tlv_buffer;
		cursor = necp_buffer_write_tlv(cursor, NECP_TLV_POLICY_ID, sizeof(policy->id), &policy->id, tlv_buffer, total_allocated_bytes);
		cursor = necp_buffer_write_tlv(cursor, NECP_TLV_POLICY_ORDER, sizeof(necp_policy_order), &policy->order, tlv_buffer, total_allocated_bytes);
		cursor = necp_buffer_write_tlv(cursor, NECP_TLV_POLICY_SESSION_ORDER, sizeof(policy->session_order), &policy->session_order, tlv_buffer, total_allocated_bytes);
		cursor = necp_buffer_write_tlv(cursor, NECP_TLV_POLICY_RESULT_STRING, result_string_len, result_string, tlv_buffer, total_allocated_bytes);
		cursor = necp_buffer_write_tlv(cursor, NECP_TLV_POLICY_OWNER, proc_name_len, proc_name_string, tlv_buffer, total_allocated_bytes);

#define N_QUICK 256
		u_int8_t q_cond_buf[N_QUICK]; // Minor optimization

		u_int8_t *cond_buf; // To be used for condition TLVs
		if (condition_tlv_length <= N_QUICK) {
			cond_buf = q_cond_buf;
		} else {
			MALLOC(cond_buf, u_int8_t *, condition_tlv_length, M_NECP, M_NOWAIT);
			if (cond_buf == NULL) {
				NECPLOG(LOG_DEBUG, "Failed to allocate cond_buffer (%u bytes)", condition_tlv_length);
				FREE(tlv_buffer, M_NECP);
				continue;
			}
		}

		memset(cond_buf, 0, condition_tlv_length);
		u_int8_t *cond_buf_cursor = cond_buf;
		if (condition_mask == NECP_POLICY_CONDITION_DEFAULT) {
			cond_buf_cursor = necp_buffer_write_tlv(cond_buf_cursor, NECP_POLICY_CONDITION_DEFAULT, 0, "", cond_buf, condition_tlv_length);
		} else {
			if (condition_mask & NECP_KERNEL_CONDITION_ALL_INTERFACES) {
				cond_buf_cursor = necp_buffer_write_tlv(cond_buf_cursor, NECP_POLICY_CONDITION_ALL_INTERFACES, 0, "", cond_buf, condition_tlv_length);
			}
			if (condition_mask & NECP_KERNEL_CONDITION_HAS_CLIENT) {
				cond_buf_cursor = necp_buffer_write_tlv(cond_buf_cursor, NECP_POLICY_CONDITION_HAS_CLIENT, 0, "", cond_buf, condition_tlv_length);
			}
			if (condition_mask & NECP_KERNEL_CONDITION_LOCAL_NETWORKS) {
				cond_buf_cursor = necp_buffer_write_tlv(cond_buf_cursor, NECP_POLICY_CONDITION_LOCAL_NETWORKS, 0, "", cond_buf, condition_tlv_length);
			}
			if (condition_mask & NECP_KERNEL_CONDITION_BOUND_INTERFACE) {
				cond_buf_cursor = necp_buffer_write_tlv(cond_buf_cursor, NECP_POLICY_CONDITION_BOUND_INTERFACE, strlen(if_name) + 1,
				    if_name, cond_buf, condition_tlv_length);
			}
			if (condition_mask & NECP_KERNEL_CONDITION_PROTOCOL) {
				cond_buf_cursor = necp_buffer_write_tlv(cond_buf_cursor, NECP_POLICY_CONDITION_IP_PROTOCOL, sizeof(policy->cond_protocol), &policy->cond_protocol,
				    cond_buf, condition_tlv_length);
			}
			if (condition_mask & NECP_KERNEL_CONDITION_APP_ID) {
				struct necp_uuid_id_mapping *entry = necp_uuid_lookup_uuid_with_app_id_locked(policy->cond_app_id);
				if (entry != NULL) {
					cond_buf_cursor = necp_buffer_write_tlv(cond_buf_cursor, NECP_POLICY_CONDITION_APPLICATION, sizeof(entry->uuid), entry->uuid,
					    cond_buf, condition_tlv_length);
				}
			}
			if (condition_mask & NECP_KERNEL_CONDITION_REAL_APP_ID) {
				struct necp_uuid_id_mapping *entry = necp_uuid_lookup_uuid_with_app_id_locked(policy->cond_real_app_id);
				if (entry != NULL) {
					cond_buf_cursor = necp_buffer_write_tlv(cond_buf_cursor, NECP_POLICY_CONDITION_REAL_APPLICATION, sizeof(entry->uuid), entry->uuid,
					    cond_buf, condition_tlv_length);
				}
			}
			if (condition_mask & NECP_KERNEL_CONDITION_DOMAIN) {
				cond_buf_cursor = necp_buffer_write_tlv(cond_buf_cursor, NECP_POLICY_CONDITION_DOMAIN, strlen(policy->cond_domain) + 1, policy->cond_domain,
				    cond_buf, condition_tlv_length);
			}
			if (condition_mask & NECP_KERNEL_CONDITION_ACCOUNT_ID) {
				if (account_id_entry != NULL) {
					cond_buf_cursor = necp_buffer_write_tlv(cond_buf_cursor, NECP_POLICY_CONDITION_ACCOUNT, strlen(account_id_entry->string) + 1, account_id_entry->string,
					    cond_buf, condition_tlv_length);
				}
			}
			if (condition_mask & NECP_KERNEL_CONDITION_PID) {
				cond_buf_cursor = necp_buffer_write_tlv(cond_buf_cursor, NECP_POLICY_CONDITION_PID, sizeof(policy->cond_pid), &policy->cond_pid,
				    cond_buf, condition_tlv_length);
			}
			if (condition_mask & NECP_KERNEL_CONDITION_UID) {
				cond_buf_cursor = necp_buffer_write_tlv(cond_buf_cursor, NECP_POLICY_CONDITION_UID, sizeof(policy->cond_uid), &policy->cond_uid,
				    cond_buf, condition_tlv_length);
			}
			if (condition_mask & NECP_KERNEL_CONDITION_TRAFFIC_CLASS) {
				cond_buf_cursor = necp_buffer_write_tlv(cond_buf_cursor, NECP_POLICY_CONDITION_TRAFFIC_CLASS, sizeof(policy->cond_traffic_class), &policy->cond_traffic_class,
				    cond_buf, condition_tlv_length);
			}
			if (condition_mask & NECP_KERNEL_CONDITION_ENTITLEMENT) {
				cond_buf_cursor = necp_buffer_write_tlv(cond_buf_cursor, NECP_POLICY_CONDITION_ENTITLEMENT, 0, "",
				    cond_buf, condition_tlv_length);
			}
			if (condition_mask & NECP_KERNEL_CONDITION_CUSTOM_ENTITLEMENT) {
				cond_buf_cursor = necp_buffer_write_tlv(cond_buf_cursor, NECP_POLICY_CONDITION_ENTITLEMENT, strlen(policy->cond_custom_entitlement) + 1, policy->cond_custom_entitlement,
				    cond_buf, condition_tlv_length);
			}
			if (condition_mask & NECP_KERNEL_CONDITION_PLATFORM_BINARY) {
				cond_buf_cursor = necp_buffer_write_tlv(cond_buf_cursor, NECP_POLICY_CONDITION_PLATFORM_BINARY, 0, "", cond_buf, condition_tlv_length);
			}
			if (condition_mask & NECP_KERNEL_CONDITION_LOCAL_START) {
				if (condition_mask & NECP_KERNEL_CONDITION_LOCAL_END) {
					struct necp_policy_condition_addr_range range;
					memcpy(&range.start_address, &policy->cond_local_start, sizeof(policy->cond_local_start));
					memcpy(&range.end_address, &policy->cond_local_end, sizeof(policy->cond_local_end));
					cond_buf_cursor = necp_buffer_write_tlv(cond_buf_cursor, NECP_POLICY_CONDITION_LOCAL_ADDR_RANGE, sizeof(range), &range,
					    cond_buf, condition_tlv_length);
				} else {
					struct necp_policy_condition_addr addr;
					addr.prefix = policy->cond_local_prefix;
					memcpy(&addr.address, &policy->cond_local_start, sizeof(policy->cond_local_start));
					cond_buf_cursor = necp_buffer_write_tlv(cond_buf_cursor, NECP_POLICY_CONDITION_LOCAL_ADDR, sizeof(addr), &addr,
					    cond_buf, condition_tlv_length);
				}
			}
			if (condition_mask & NECP_KERNEL_CONDITION_REMOTE_START) {
				if (condition_mask & NECP_KERNEL_CONDITION_REMOTE_END) {
					struct necp_policy_condition_addr_range range;
					memcpy(&range.start_address, &policy->cond_remote_start, sizeof(policy->cond_remote_start));
					memcpy(&range.end_address, &policy->cond_remote_end, sizeof(policy->cond_remote_end));
					cond_buf_cursor = necp_buffer_write_tlv(cond_buf_cursor, NECP_POLICY_CONDITION_REMOTE_ADDR_RANGE, sizeof(range), &range,
					    cond_buf, condition_tlv_length);
				} else {
					struct necp_policy_condition_addr addr;
					addr.prefix = policy->cond_remote_prefix;
					memcpy(&addr.address, &policy->cond_remote_start, sizeof(policy->cond_remote_start));
					cond_buf_cursor = necp_buffer_write_tlv(cond_buf_cursor, NECP_POLICY_CONDITION_REMOTE_ADDR, sizeof(addr), &addr,
					    cond_buf, condition_tlv_length);
				}
			}
			if (condition_mask & NECP_KERNEL_CONDITION_AGENT_TYPE) {
				cond_buf_cursor = necp_buffer_write_tlv(cond_buf_cursor, NECP_POLICY_CONDITION_AGENT_TYPE,
				    sizeof(policy->cond_agent_type), &policy->cond_agent_type,
				    cond_buf, condition_tlv_length);
			}
			if (condition_mask & NECP_KERNEL_CONDITION_CLIENT_FLAGS) {
				cond_buf_cursor = necp_buffer_write_tlv(cond_buf_cursor, NECP_POLICY_CONDITION_CLIENT_FLAGS, sizeof(policy->cond_client_flags), &policy->cond_client_flags, cond_buf, condition_tlv_length);
			}
			if (condition_mask & NECP_KERNEL_CONDITION_LOCAL_EMPTY) {
				cond_buf_cursor = necp_buffer_write_tlv(cond_buf_cursor, NECP_POLICY_CONDITION_FLOW_LOCAL_ADDR_EMPTY, 0, "", cond_buf, condition_tlv_length);
			}
			if (condition_mask & NECP_KERNEL_CONDITION_REMOTE_EMPTY) {
				cond_buf_cursor = necp_buffer_write_tlv(cond_buf_cursor, NECP_POLICY_CONDITION_FLOW_REMOTE_ADDR_EMPTY, 0, "", cond_buf, condition_tlv_length);
			}
		}

		cursor = necp_buffer_write_tlv(cursor, NECP_TLV_POLICY_CONDITION, cond_buf_cursor - cond_buf, cond_buf, tlv_buffer, total_allocated_bytes);
		if (cond_buf != q_cond_buf) {
			FREE(cond_buf, M_NECP);
		}

		tlv_buffer_pointers[policy_i] = tlv_buffer;
		tlv_buffer_lengths[policy_i] = (cursor - tlv_buffer);

		// This is the length of the TLV for NECP_TLV_POLICY_DUMP
		total_tlv_len += sizeof(u_int8_t) + sizeof(u_int32_t) + (cursor - tlv_buffer);
	}

	// UNLOCK
	lck_rw_done(&necp_kernel_policy_lock);

	// Copy out
	if (out_buffer != 0) {
		if (out_buffer_length < total_tlv_len + sizeof(u_int32_t)) {
			NECPLOG(LOG_DEBUG, "out_buffer_length too small (%u < %u)", out_buffer_length, total_tlv_len + sizeof(u_int32_t));
			REPORT_ERROR(NECP_ERROR_INVALID_TLV);
		}

		// Allow malloc to wait, since the total buffer may be large and we are not holding any locks
		MALLOC(result_buf, u_int8_t *, total_tlv_len + sizeof(u_int32_t), M_NECP, M_WAITOK | M_ZERO);
		if (result_buf == NULL) {
			NECPLOG(LOG_DEBUG, "Failed to allocate result_buffer (%u bytes)", total_tlv_len + sizeof(u_int32_t));
			REPORT_ERROR(NECP_ERROR_INTERNAL);
		}

		// Add four bytes for total length at the start
		memcpy(result_buf, &total_tlv_len, sizeof(u_int32_t));

		// Copy the TLVs
		result_buf_cursor = result_buf + sizeof(u_int32_t);
		for (int i = 0; i < policy_count; i++) {
			if (tlv_buffer_pointers[i] != NULL) {
				result_buf_cursor = necp_buffer_write_tlv(result_buf_cursor, NECP_TLV_POLICY_DUMP, tlv_buffer_lengths[i], tlv_buffer_pointers[i],
				    result_buf, total_tlv_len + sizeof(u_int32_t));
			}
		}

		int copy_error = copyout(result_buf, out_buffer, total_tlv_len + sizeof(u_int32_t));
		if (copy_error) {
			NECPLOG(LOG_DEBUG, "Failed to copy out result_buffer (%u bytes)", total_tlv_len + sizeof(u_int32_t));
			REPORT_ERROR(NECP_ERROR_INTERNAL);
		}
	}

done:

	if (error_occured) {
		error_code = necp_get_posix_error_for_necp_error(response_error);
	}

	if (result_buf != NULL) {
		FREE(result_buf, M_NECP);
	}

	if (tlv_buffer_pointers != NULL) {
		for (int i = 0; i < policy_count; i++) {
			if (tlv_buffer_pointers[i] != NULL) {
				FREE(tlv_buffer_pointers[i], M_NECP);
				tlv_buffer_pointers[i] = NULL;
			}
		}
		FREE(tlv_buffer_pointers, M_NECP);
	}

	if (tlv_buffer_lengths != NULL) {
		FREE(tlv_buffer_lengths, M_NECP);
	}
#undef N_QUICK
#undef RESET_COND_BUF
#undef REPORT_ERROR
#undef UNLOCK_AND_REPORT_ERROR

	return error_code;
}

static struct necp_session_policy *
necp_policy_create(struct necp_session *session, necp_policy_order order, u_int8_t *conditions_array, u_int32_t conditions_array_size, u_int8_t *route_rules_array, u_int32_t route_rules_array_size, u_int8_t *result, u_int32_t result_size)
{
	struct necp_session_policy *new_policy = NULL;
	struct necp_session_policy *tmp_policy = NULL;

	if (session == NULL || conditions_array == NULL || result == NULL || result_size == 0) {
		goto done;
	}

	MALLOC_ZONE(new_policy, struct necp_session_policy *, sizeof(*new_policy), M_NECP_SESSION_POLICY, M_WAITOK);
	if (new_policy == NULL) {
		goto done;
	}

	memset(new_policy, 0, sizeof(*new_policy)); // M_ZERO is not supported for MALLOC_ZONE
	new_policy->applied = FALSE;
	new_policy->pending_deletion = FALSE;
	new_policy->pending_update = FALSE;
	new_policy->order = order;
	new_policy->conditions = conditions_array;
	new_policy->conditions_size = conditions_array_size;
	new_policy->route_rules = route_rules_array;
	new_policy->route_rules_size = route_rules_array_size;
	new_policy->result = result;
	new_policy->result_size = result_size;
	new_policy->local_id = necp_policy_get_new_id(session);

	LIST_INSERT_SORTED_ASCENDING(&session->policies, new_policy, chain, order, tmp_policy);

	session->dirty = TRUE;

	if (necp_debug) {
		NECPLOG(LOG_DEBUG, "Created NECP policy, order %d", order);
	}
done:
	return new_policy;
}

static struct necp_session_policy *
necp_policy_find(struct necp_session *session, necp_policy_id policy_id)
{
	struct necp_session_policy *policy = NULL;
	if (policy_id == 0) {
		return NULL;
	}

	LIST_FOREACH(policy, &session->policies, chain) {
		if (policy->local_id == policy_id) {
			return policy;
		}
	}

	return NULL;
}

static inline u_int8_t
necp_policy_get_result_type(struct necp_session_policy *policy)
{
	return policy ? necp_policy_result_get_type_from_buffer(policy->result, policy->result_size) : 0;
}

static inline u_int32_t
necp_policy_get_result_parameter_length(struct necp_session_policy *policy)
{
	return policy ? necp_policy_result_get_parameter_length_from_buffer(policy->result, policy->result_size) : 0;
}

static bool
necp_policy_get_result_parameter(struct necp_session_policy *policy, u_int8_t *parameter_buffer, u_int32_t parameter_buffer_length)
{
	if (policy) {
		u_int32_t parameter_length = necp_policy_result_get_parameter_length_from_buffer(policy->result, policy->result_size);
		if (parameter_buffer_length >= parameter_length) {
			u_int8_t *parameter = necp_policy_result_get_parameter_pointer_from_buffer(policy->result, policy->result_size);
			if (parameter && parameter_buffer) {
				memcpy(parameter_buffer, parameter, parameter_length);
				return TRUE;
			}
		}
	}

	return FALSE;
}

static bool
necp_policy_mark_for_deletion(struct necp_session *session, struct necp_session_policy *policy)
{
	if (session == NULL || policy == NULL) {
		return FALSE;
	}

	policy->pending_deletion = TRUE;
	session->dirty = TRUE;

	if (necp_debug) {
		NECPLOG0(LOG_DEBUG, "Marked NECP policy for removal");
	}
	return TRUE;
}

static bool
necp_policy_mark_all_for_deletion(struct necp_session *session)
{
	struct necp_session_policy *policy = NULL;
	struct necp_session_policy *temp_policy = NULL;

	LIST_FOREACH_SAFE(policy, &session->policies, chain, temp_policy) {
		necp_policy_mark_for_deletion(session, policy);
	}

	return TRUE;
}

static bool
necp_policy_delete(struct necp_session *session, struct necp_session_policy *policy)
{
	if (session == NULL || policy == NULL) {
		return FALSE;
	}

	LIST_REMOVE(policy, chain);

	if (policy->result) {
		FREE(policy->result, M_NECP);
		policy->result = NULL;
	}

	if (policy->conditions) {
		FREE(policy->conditions, M_NECP);
		policy->conditions = NULL;
	}

	if (policy->route_rules) {
		FREE(policy->route_rules, M_NECP);
		policy->route_rules = NULL;
	}

	FREE_ZONE(policy, sizeof(*policy), M_NECP_SESSION_POLICY);

	if (necp_debug) {
		NECPLOG0(LOG_DEBUG, "Removed NECP policy");
	}
	return TRUE;
}

static bool
necp_policy_unapply(struct necp_session_policy *policy)
{
	int i = 0;
	if (policy == NULL) {
		return FALSE;
	}

	LCK_RW_ASSERT(&necp_kernel_policy_lock, LCK_RW_ASSERT_EXCLUSIVE);

	// Release local uuid mappings
	if (!uuid_is_null(policy->applied_app_uuid)) {
		bool removed_mapping = FALSE;
		if (necp_remove_uuid_app_id_mapping(policy->applied_app_uuid, &removed_mapping, TRUE) && removed_mapping) {
			necp_uuid_app_id_mappings_dirty = TRUE;
			necp_num_uuid_app_id_mappings--;
		}
		uuid_clear(policy->applied_app_uuid);
	}
	if (!uuid_is_null(policy->applied_real_app_uuid)) {
		necp_remove_uuid_app_id_mapping(policy->applied_real_app_uuid, NULL, FALSE);
		uuid_clear(policy->applied_real_app_uuid);
	}
	if (!uuid_is_null(policy->applied_result_uuid)) {
		necp_remove_uuid_service_id_mapping(policy->applied_result_uuid);
		uuid_clear(policy->applied_result_uuid);
	}

	// Release string mappings
	if (policy->applied_account != NULL) {
		necp_remove_string_to_id_mapping(&necp_account_id_list, policy->applied_account);
		FREE(policy->applied_account, M_NECP);
		policy->applied_account = NULL;
	}

	// Release route rule
	if (policy->applied_route_rules_id != 0) {
		necp_remove_route_rule(&necp_route_rules, policy->applied_route_rules_id);
		policy->applied_route_rules_id = 0;
	}

	// Remove socket policies
	for (i = 0; i < MAX_KERNEL_SOCKET_POLICIES; i++) {
		if (policy->kernel_socket_policies[i] != 0) {
			necp_kernel_socket_policy_delete(policy->kernel_socket_policies[i]);
			policy->kernel_socket_policies[i] = 0;
		}
	}

	// Remove IP output policies
	for (i = 0; i < MAX_KERNEL_IP_OUTPUT_POLICIES; i++) {
		if (policy->kernel_ip_output_policies[i] != 0) {
			necp_kernel_ip_output_policy_delete(policy->kernel_ip_output_policies[i]);
			policy->kernel_ip_output_policies[i] = 0;
		}
	}

	policy->applied = FALSE;

	return TRUE;
}

#define NECP_KERNEL_POLICY_SUBORDER_ID_TUNNEL_CONDITION                 0
#define NECP_KERNEL_POLICY_SUBORDER_NON_ID_TUNNEL_CONDITION             1
#define NECP_KERNEL_POLICY_SUBORDER_ID_CONDITION                                2
#define NECP_KERNEL_POLICY_SUBORDER_NON_ID_CONDITIONS                   3
struct necp_policy_result_ip_tunnel {
	u_int32_t secondary_result;
	char interface_name[IFXNAMSIZ];
} __attribute__((__packed__));

struct necp_policy_result_service {
	uuid_t identifier;
	u_int32_t data;
} __attribute__((__packed__));

static bool
necp_policy_apply(struct necp_session *session, struct necp_session_policy *policy)
{
	bool socket_only_conditions = FALSE;
	bool socket_ip_conditions = FALSE;

	bool socket_layer_non_id_conditions = FALSE;
	bool ip_output_layer_non_id_conditions = FALSE;
	bool ip_output_layer_non_id_only = FALSE;
	bool ip_output_layer_id_condition = FALSE;
	bool ip_output_layer_tunnel_condition_from_id = FALSE;
	bool ip_output_layer_tunnel_condition_from_non_id = FALSE;
	necp_kernel_policy_id cond_ip_output_layer_id = NECP_KERNEL_POLICY_ID_NONE;

	u_int32_t master_condition_mask = 0;
	u_int32_t master_condition_negated_mask = 0;
	ifnet_t cond_bound_interface = NULL;
	u_int32_t cond_account_id = 0;
	char *cond_domain = NULL;
	char *cond_custom_entitlement = NULL;
	pid_t cond_pid = 0;
	uid_t cond_uid = 0;
	necp_app_id cond_app_id = 0;
	necp_app_id cond_real_app_id = 0;
	struct necp_policy_condition_tc_range cond_traffic_class;
	cond_traffic_class.start_tc = 0;
	cond_traffic_class.end_tc = 0;
	u_int16_t cond_protocol = 0;
	union necp_sockaddr_union cond_local_start;
	union necp_sockaddr_union cond_local_end;
	u_int8_t cond_local_prefix = 0;
	union necp_sockaddr_union cond_remote_start;
	union necp_sockaddr_union cond_remote_end;
	u_int8_t cond_remote_prefix = 0;
	u_int32_t cond_client_flags = 0;
	u_int32_t offset = 0;
	u_int8_t ultimate_result = 0;
	u_int32_t secondary_result = 0;
	struct necp_policy_condition_agent_type cond_agent_type = {};
	necp_kernel_policy_result_parameter secondary_result_parameter;
	memset(&secondary_result_parameter, 0, sizeof(secondary_result_parameter));
	u_int32_t cond_last_interface_index = 0;
	necp_kernel_policy_result_parameter ultimate_result_parameter;
	memset(&ultimate_result_parameter, 0, sizeof(ultimate_result_parameter));

	if (policy == NULL) {
		return FALSE;
	}

	LCK_RW_ASSERT(&necp_kernel_policy_lock, LCK_RW_ASSERT_EXCLUSIVE);

	// Process conditions
	while (offset < policy->conditions_size) {
		u_int32_t length = 0;
		u_int8_t *value = necp_buffer_get_tlv_value(policy->conditions, offset, &length);

		u_int8_t condition_type = necp_policy_condition_get_type_from_buffer(value, length);
		u_int8_t condition_flags = necp_policy_condition_get_flags_from_buffer(value, length);
		bool condition_is_negative = condition_flags & NECP_POLICY_CONDITION_FLAGS_NEGATIVE;
		u_int32_t condition_length = necp_policy_condition_get_value_length_from_buffer(value, length);
		u_int8_t *condition_value = necp_policy_condition_get_value_pointer_from_buffer(value, length);
		switch (condition_type) {
		case NECP_POLICY_CONDITION_DEFAULT: {
			socket_ip_conditions = TRUE;
			break;
		}
		case NECP_POLICY_CONDITION_ALL_INTERFACES: {
			master_condition_mask |= NECP_KERNEL_CONDITION_ALL_INTERFACES;
			socket_ip_conditions = TRUE;
			break;
		}
		case NECP_POLICY_CONDITION_HAS_CLIENT: {
			master_condition_mask |= NECP_KERNEL_CONDITION_HAS_CLIENT;
			socket_only_conditions = TRUE;
			break;
		}
		case NECP_POLICY_CONDITION_ENTITLEMENT: {
			if (condition_length > 0) {
				if (cond_custom_entitlement == NULL) {
					cond_custom_entitlement = necp_copy_string((char *)condition_value, condition_length);
					if (cond_custom_entitlement != NULL) {
						master_condition_mask |= NECP_KERNEL_CONDITION_CUSTOM_ENTITLEMENT;
						socket_only_conditions = TRUE;
					}
				}
			} else {
				master_condition_mask |= NECP_KERNEL_CONDITION_ENTITLEMENT;
				socket_only_conditions = TRUE;
			}
			break;
		}
		case NECP_POLICY_CONDITION_PLATFORM_BINARY: {
			master_condition_mask |= NECP_KERNEL_CONDITION_PLATFORM_BINARY;
			socket_only_conditions = TRUE;
			break;
		}
		case NECP_POLICY_CONDITION_DOMAIN: {
			// Make sure there is only one such rule
			if (condition_length > 0 && cond_domain == NULL) {
				cond_domain = necp_create_trimmed_domain((char *)condition_value, condition_length);
				if (cond_domain != NULL) {
					master_condition_mask |= NECP_KERNEL_CONDITION_DOMAIN;
					if (condition_is_negative) {
						master_condition_negated_mask |= NECP_KERNEL_CONDITION_DOMAIN;
					}
					socket_only_conditions = TRUE;
				}
			}
			break;
		}
		case NECP_POLICY_CONDITION_ACCOUNT: {
			// Make sure there is only one such rule
			if (condition_length > 0 && cond_account_id == 0 && policy->applied_account == NULL) {
				char *string = NULL;
				MALLOC(string, char *, condition_length + 1, M_NECP, M_WAITOK);
				if (string != NULL) {
					memcpy(string, condition_value, condition_length);
					string[condition_length] = 0;
					cond_account_id = necp_create_string_to_id_mapping(&necp_account_id_list, string);
					if (cond_account_id != 0) {
						policy->applied_account = string;         // Save the string in parent policy
						master_condition_mask |= NECP_KERNEL_CONDITION_ACCOUNT_ID;
						if (condition_is_negative) {
							master_condition_negated_mask |= NECP_KERNEL_CONDITION_ACCOUNT_ID;
						}
						socket_only_conditions = TRUE;
					} else {
						FREE(string, M_NECP);
					}
				}
			}
			break;
		}
		case NECP_POLICY_CONDITION_APPLICATION: {
			// Make sure there is only one such rule, because we save the uuid in the policy
			if (condition_length >= sizeof(uuid_t) && cond_app_id == 0) {
				bool allocated_mapping = FALSE;
				uuid_t application_uuid;
				memcpy(application_uuid, condition_value, sizeof(uuid_t));
				cond_app_id = necp_create_uuid_app_id_mapping(application_uuid, &allocated_mapping, TRUE);
				if (cond_app_id != 0) {
					if (allocated_mapping) {
						necp_uuid_app_id_mappings_dirty = TRUE;
						necp_num_uuid_app_id_mappings++;
					}
					uuid_copy(policy->applied_app_uuid, application_uuid);
					master_condition_mask |= NECP_KERNEL_CONDITION_APP_ID;
					if (condition_is_negative) {
						master_condition_negated_mask |= NECP_KERNEL_CONDITION_APP_ID;
					}
					socket_only_conditions = TRUE;
				}
			}
			break;
		}
		case NECP_POLICY_CONDITION_REAL_APPLICATION: {
			// Make sure there is only one such rule, because we save the uuid in the policy
			if (condition_length >= sizeof(uuid_t) && cond_real_app_id == 0) {
				uuid_t real_application_uuid;
				memcpy(real_application_uuid, condition_value, sizeof(uuid_t));
				cond_real_app_id = necp_create_uuid_app_id_mapping(real_application_uuid, NULL, FALSE);
				if (cond_real_app_id != 0) {
					uuid_copy(policy->applied_real_app_uuid, real_application_uuid);
					master_condition_mask |= NECP_KERNEL_CONDITION_REAL_APP_ID;
					if (condition_is_negative) {
						master_condition_negated_mask |= NECP_KERNEL_CONDITION_REAL_APP_ID;
					}
					socket_only_conditions = TRUE;
				}
			}
			break;
		}
		case NECP_POLICY_CONDITION_PID: {
			if (condition_length >= sizeof(pid_t)) {
				master_condition_mask |= NECP_KERNEL_CONDITION_PID;
				if (condition_is_negative) {
					master_condition_negated_mask |= NECP_KERNEL_CONDITION_PID;
				}
				memcpy(&cond_pid, condition_value, sizeof(cond_pid));
				socket_only_conditions = TRUE;
			}
			break;
		}
		case NECP_POLICY_CONDITION_UID: {
			if (condition_length >= sizeof(uid_t)) {
				master_condition_mask |= NECP_KERNEL_CONDITION_UID;
				if (condition_is_negative) {
					master_condition_negated_mask |= NECP_KERNEL_CONDITION_UID;
				}
				memcpy(&cond_uid, condition_value, sizeof(cond_uid));
				socket_only_conditions = TRUE;
			}
			break;
		}
		case NECP_POLICY_CONDITION_TRAFFIC_CLASS: {
			if (condition_length >= sizeof(struct necp_policy_condition_tc_range)) {
				master_condition_mask |= NECP_KERNEL_CONDITION_TRAFFIC_CLASS;
				if (condition_is_negative) {
					master_condition_negated_mask |= NECP_KERNEL_CONDITION_TRAFFIC_CLASS;
				}
				memcpy(&cond_traffic_class, condition_value, sizeof(cond_traffic_class));
				socket_only_conditions = TRUE;
			}
			break;
		}
		case NECP_POLICY_CONDITION_BOUND_INTERFACE: {
			if (condition_length <= IFXNAMSIZ && condition_length > 0) {
				char interface_name[IFXNAMSIZ];
				memcpy(interface_name, condition_value, condition_length);
				interface_name[condition_length - 1] = 0;         // Make sure the string is NULL terminated
				if (ifnet_find_by_name(interface_name, &cond_bound_interface) == 0) {
					master_condition_mask |= NECP_KERNEL_CONDITION_BOUND_INTERFACE;
					if (condition_is_negative) {
						master_condition_negated_mask |= NECP_KERNEL_CONDITION_BOUND_INTERFACE;
					}
				}
				socket_ip_conditions = TRUE;
			}
			break;
		}
		case NECP_POLICY_CONDITION_IP_PROTOCOL:
		case NECP_POLICY_CONDITION_FLOW_IP_PROTOCOL: {
			if (condition_length >= sizeof(u_int16_t)) {
				master_condition_mask |= NECP_KERNEL_CONDITION_PROTOCOL;
				if (condition_is_negative) {
					master_condition_negated_mask |= NECP_KERNEL_CONDITION_PROTOCOL;
				}
				memcpy(&cond_protocol, condition_value, sizeof(cond_protocol));
				if (condition_type == NECP_POLICY_CONDITION_FLOW_IP_PROTOCOL) {
					socket_only_conditions = TRUE;
				} else {
					socket_ip_conditions = TRUE;
				}
			}
			break;
		}
		case NECP_POLICY_CONDITION_LOCAL_NETWORKS: {
			master_condition_mask |= NECP_KERNEL_CONDITION_LOCAL_NETWORKS;
			socket_ip_conditions = TRUE;
			break;
		}
		case NECP_POLICY_CONDITION_LOCAL_ADDR:
		case NECP_POLICY_CONDITION_FLOW_LOCAL_ADDR: {
			struct necp_policy_condition_addr *address_struct = (struct necp_policy_condition_addr *)(void *)condition_value;
			if (!necp_address_is_valid(&address_struct->address.sa)) {
				break;
			}

			cond_local_prefix = address_struct->prefix;
			memcpy(&cond_local_start, &address_struct->address, sizeof(address_struct->address));
			master_condition_mask |= NECP_KERNEL_CONDITION_LOCAL_START;
			master_condition_mask |= NECP_KERNEL_CONDITION_LOCAL_PREFIX;
			if (condition_is_negative) {
				master_condition_negated_mask |= NECP_KERNEL_CONDITION_LOCAL_START;
				master_condition_negated_mask |= NECP_KERNEL_CONDITION_LOCAL_PREFIX;
			}
			if (condition_type == NECP_POLICY_CONDITION_FLOW_LOCAL_ADDR) {
				socket_only_conditions = TRUE;
			} else {
				socket_ip_conditions = TRUE;
			}
			break;
		}
		case NECP_POLICY_CONDITION_REMOTE_ADDR:
		case NECP_POLICY_CONDITION_FLOW_REMOTE_ADDR: {
			struct necp_policy_condition_addr *address_struct = (struct necp_policy_condition_addr *)(void *)condition_value;
			if (!necp_address_is_valid(&address_struct->address.sa)) {
				break;
			}

			cond_remote_prefix = address_struct->prefix;
			memcpy(&cond_remote_start, &address_struct->address, sizeof(address_struct->address));
			master_condition_mask |= NECP_KERNEL_CONDITION_REMOTE_START;
			master_condition_mask |= NECP_KERNEL_CONDITION_REMOTE_PREFIX;
			if (condition_is_negative) {
				master_condition_negated_mask |= NECP_KERNEL_CONDITION_REMOTE_START;
				master_condition_negated_mask |= NECP_KERNEL_CONDITION_REMOTE_PREFIX;
			}
			if (condition_type == NECP_POLICY_CONDITION_FLOW_REMOTE_ADDR) {
				socket_only_conditions = TRUE;
			} else {
				socket_ip_conditions = TRUE;
			}
			break;
		}
		case NECP_POLICY_CONDITION_LOCAL_ADDR_RANGE:
		case NECP_POLICY_CONDITION_FLOW_LOCAL_ADDR_RANGE: {
			struct necp_policy_condition_addr_range *address_struct = (struct necp_policy_condition_addr_range *)(void *)condition_value;
			if (!necp_address_is_valid(&address_struct->start_address.sa) ||
			    !necp_address_is_valid(&address_struct->end_address.sa)) {
				break;
			}

			memcpy(&cond_local_start, &address_struct->start_address, sizeof(address_struct->start_address));
			memcpy(&cond_local_end, &address_struct->end_address, sizeof(address_struct->end_address));
			master_condition_mask |= NECP_KERNEL_CONDITION_LOCAL_START;
			master_condition_mask |= NECP_KERNEL_CONDITION_LOCAL_END;
			if (condition_is_negative) {
				master_condition_negated_mask |= NECP_KERNEL_CONDITION_LOCAL_START;
				master_condition_negated_mask |= NECP_KERNEL_CONDITION_LOCAL_END;
			}
			if (condition_type == NECP_POLICY_CONDITION_FLOW_LOCAL_ADDR_RANGE) {
				socket_only_conditions = TRUE;
			} else {
				socket_ip_conditions = TRUE;
			}
			break;
		}
		case NECP_POLICY_CONDITION_REMOTE_ADDR_RANGE:
		case NECP_POLICY_CONDITION_FLOW_REMOTE_ADDR_RANGE: {
			struct necp_policy_condition_addr_range *address_struct = (struct necp_policy_condition_addr_range *)(void *)condition_value;
			if (!necp_address_is_valid(&address_struct->start_address.sa) ||
			    !necp_address_is_valid(&address_struct->end_address.sa)) {
				break;
			}

			memcpy(&cond_remote_start, &address_struct->start_address, sizeof(address_struct->start_address));
			memcpy(&cond_remote_end, &address_struct->end_address, sizeof(address_struct->end_address));
			master_condition_mask |= NECP_KERNEL_CONDITION_REMOTE_START;
			master_condition_mask |= NECP_KERNEL_CONDITION_REMOTE_END;
			if (condition_is_negative) {
				master_condition_negated_mask |= NECP_KERNEL_CONDITION_REMOTE_START;
				master_condition_negated_mask |= NECP_KERNEL_CONDITION_REMOTE_END;
			}
			if (condition_type == NECP_POLICY_CONDITION_FLOW_REMOTE_ADDR_RANGE) {
				socket_only_conditions = TRUE;
			} else {
				socket_ip_conditions = TRUE;
			}
			break;
		}
		case NECP_POLICY_CONDITION_AGENT_TYPE: {
			if (condition_length >= sizeof(cond_agent_type)) {
				master_condition_mask |= NECP_KERNEL_CONDITION_AGENT_TYPE;
				memcpy(&cond_agent_type, condition_value, sizeof(cond_agent_type));
				socket_only_conditions = TRUE;
			}
			break;
		}
		case NECP_POLICY_CONDITION_CLIENT_FLAGS: {
			if (condition_is_negative) {
				master_condition_negated_mask |= NECP_KERNEL_CONDITION_CLIENT_FLAGS;
			}
			master_condition_mask |= NECP_KERNEL_CONDITION_CLIENT_FLAGS;
			socket_only_conditions = TRUE;
			if (condition_length >= sizeof(u_int32_t)) {
				memcpy(&cond_client_flags, condition_value, sizeof(cond_client_flags));
			} else {
				// Empty means match on fallback traffic
				cond_client_flags = NECP_CLIENT_PARAMETER_FLAG_FALLBACK_TRAFFIC;
			}
			break;
		}
		case NECP_POLICY_CONDITION_FLOW_LOCAL_ADDR_EMPTY: {
			master_condition_mask |= NECP_KERNEL_CONDITION_LOCAL_EMPTY;
			if (condition_is_negative) {
				master_condition_negated_mask |= NECP_KERNEL_CONDITION_LOCAL_EMPTY;
			}
			socket_only_conditions = TRUE;
			break;
		}
		case NECP_POLICY_CONDITION_FLOW_REMOTE_ADDR_EMPTY: {
			master_condition_mask |= NECP_KERNEL_CONDITION_REMOTE_EMPTY;
			if (condition_is_negative) {
				master_condition_negated_mask |= NECP_KERNEL_CONDITION_REMOTE_EMPTY;
			}
			socket_only_conditions = TRUE;
			break;
		}
		default: {
			break;
		}
		}

		offset += sizeof(u_int8_t) + sizeof(u_int32_t) + length;
	}

	// Process result
	ultimate_result = necp_policy_get_result_type(policy);
	switch (ultimate_result) {
	case NECP_POLICY_RESULT_PASS: {
		if (socket_only_conditions) {         // socket_ip_conditions can be TRUE or FALSE
			socket_layer_non_id_conditions = TRUE;
			ip_output_layer_id_condition = TRUE;
		} else if (socket_ip_conditions) {
			socket_layer_non_id_conditions = TRUE;
			ip_output_layer_id_condition = TRUE;
			ip_output_layer_non_id_conditions = TRUE;
		}
		break;
	}
	case NECP_POLICY_RESULT_DROP: {
		if (socket_only_conditions) {         // socket_ip_conditions can be TRUE or FALSE
			socket_layer_non_id_conditions = TRUE;
		} else if (socket_ip_conditions) {
			socket_layer_non_id_conditions = TRUE;
			ip_output_layer_non_id_conditions = TRUE;
			ip_output_layer_non_id_only = TRUE;         // Only apply drop to packets that didn't go through socket layer
		}
		break;
	}
	case NECP_POLICY_RESULT_SKIP: {
		u_int32_t skip_policy_order = 0;
		if (necp_policy_get_result_parameter(policy, (u_int8_t *)&skip_policy_order, sizeof(skip_policy_order))) {
			ultimate_result_parameter.skip_policy_order = skip_policy_order;
		}

		if (socket_only_conditions) {         // socket_ip_conditions can be TRUE or FALSE
			socket_layer_non_id_conditions = TRUE;
			ip_output_layer_id_condition = TRUE;
		} else if (socket_ip_conditions) {
			socket_layer_non_id_conditions = TRUE;
			ip_output_layer_non_id_conditions = TRUE;
		}
		break;
	}
	case NECP_POLICY_RESULT_SOCKET_DIVERT:
	case NECP_POLICY_RESULT_SOCKET_FILTER: {
		u_int32_t control_unit = 0;
		if (necp_policy_get_result_parameter(policy, (u_int8_t *)&control_unit, sizeof(control_unit))) {
			ultimate_result_parameter.flow_divert_control_unit = control_unit;
		}
		socket_layer_non_id_conditions = TRUE;
		break;
	}
	case NECP_POLICY_RESULT_IP_TUNNEL: {
		struct necp_policy_result_ip_tunnel tunnel_parameters;
		u_int32_t tunnel_parameters_length = necp_policy_get_result_parameter_length(policy);
		if (tunnel_parameters_length > sizeof(u_int32_t) &&
		    tunnel_parameters_length <= sizeof(struct necp_policy_result_ip_tunnel) &&
		    necp_policy_get_result_parameter(policy, (u_int8_t *)&tunnel_parameters, sizeof(tunnel_parameters))) {
			ifnet_t tunnel_interface = NULL;
			tunnel_parameters.interface_name[tunnel_parameters_length - sizeof(u_int32_t) - 1] = 0;         // Make sure the string is NULL terminated
			if (ifnet_find_by_name(tunnel_parameters.interface_name, &tunnel_interface) == 0) {
				ultimate_result_parameter.tunnel_interface_index = tunnel_interface->if_index;
				ifnet_release(tunnel_interface);
			}

			secondary_result = tunnel_parameters.secondary_result;
			if (secondary_result) {
				cond_last_interface_index = ultimate_result_parameter.tunnel_interface_index;
			}
		}

		if (socket_only_conditions) {         // socket_ip_conditions can be TRUE or FALSE
			socket_layer_non_id_conditions = TRUE;
			ip_output_layer_id_condition = TRUE;
			if (secondary_result) {
				ip_output_layer_tunnel_condition_from_id = TRUE;
			}
		} else if (socket_ip_conditions) {
			socket_layer_non_id_conditions = TRUE;
			ip_output_layer_id_condition = TRUE;
			ip_output_layer_non_id_conditions = TRUE;
			if (secondary_result) {
				ip_output_layer_tunnel_condition_from_id = TRUE;
				ip_output_layer_tunnel_condition_from_non_id = TRUE;
			}
		}
		break;
	}
	case NECP_POLICY_RESULT_TRIGGER:
	case NECP_POLICY_RESULT_TRIGGER_IF_NEEDED:
	case NECP_POLICY_RESULT_TRIGGER_SCOPED:
	case NECP_POLICY_RESULT_NO_TRIGGER_SCOPED: {
		struct necp_policy_result_service service_parameters;
		u_int32_t service_result_length = necp_policy_get_result_parameter_length(policy);
		bool has_extra_service_data = FALSE;
		if (service_result_length >= (sizeof(service_parameters))) {
			has_extra_service_data = TRUE;
		}
		if (necp_policy_get_result_parameter(policy, (u_int8_t *)&service_parameters, sizeof(service_parameters))) {
			ultimate_result_parameter.service.identifier = necp_create_uuid_service_id_mapping(service_parameters.identifier);
			if (ultimate_result_parameter.service.identifier != 0) {
				uuid_copy(policy->applied_result_uuid, service_parameters.identifier);
				socket_layer_non_id_conditions = TRUE;
				if (has_extra_service_data) {
					ultimate_result_parameter.service.data = service_parameters.data;
				} else {
					ultimate_result_parameter.service.data = 0;
				}
			}
		}
		break;
	}
	case NECP_POLICY_RESULT_USE_NETAGENT:
	case NECP_POLICY_RESULT_NETAGENT_SCOPED: {
		uuid_t netagent_uuid;
		if (necp_policy_get_result_parameter(policy, (u_int8_t *)&netagent_uuid, sizeof(netagent_uuid))) {
			ultimate_result_parameter.netagent_id = necp_create_uuid_service_id_mapping(netagent_uuid);
			if (ultimate_result_parameter.netagent_id != 0) {
				uuid_copy(policy->applied_result_uuid, netagent_uuid);
				socket_layer_non_id_conditions = TRUE;
			}
		}
		break;
	}
	case NECP_POLICY_RESULT_SOCKET_SCOPED: {
		u_int32_t interface_name_length = necp_policy_get_result_parameter_length(policy);
		if (interface_name_length <= IFXNAMSIZ && interface_name_length > 0) {
			char interface_name[IFXNAMSIZ];
			ifnet_t scope_interface = NULL;
			necp_policy_get_result_parameter(policy, (u_int8_t *)interface_name, interface_name_length);
			interface_name[interface_name_length - 1] = 0;         // Make sure the string is NULL terminated
			if (ifnet_find_by_name(interface_name, &scope_interface) == 0) {
				ultimate_result_parameter.scoped_interface_index = scope_interface->if_index;
				socket_layer_non_id_conditions = TRUE;
				ifnet_release(scope_interface);
			}
		}
		break;
	}
	case NECP_POLICY_RESULT_SCOPED_DIRECT: {
		socket_layer_non_id_conditions = TRUE;
		break;
	}
	case NECP_POLICY_RESULT_ALLOW_UNENTITLED: {
		socket_layer_non_id_conditions = TRUE;
		break;
	}
	case NECP_POLICY_RESULT_ROUTE_RULES: {
		if (policy->route_rules != NULL && policy->route_rules_size > 0) {
			u_int32_t route_rule_id = necp_create_route_rule(&necp_route_rules, policy->route_rules, policy->route_rules_size);
			if (route_rule_id > 0) {
				policy->applied_route_rules_id = route_rule_id;
				ultimate_result_parameter.route_rule_id = route_rule_id;
				if (socket_only_conditions) { // socket_ip_conditions can be TRUE or FALSE
					socket_layer_non_id_conditions = TRUE;
				} else if (socket_ip_conditions) {
					socket_layer_non_id_conditions = TRUE;
					ip_output_layer_non_id_conditions = TRUE;
					ip_output_layer_non_id_only = TRUE; // Only apply route rules to packets that didn't go through socket layer
				}
			}
		}
		break;
	}
	default: {
		break;
	}
	}

	if (socket_layer_non_id_conditions) {
		necp_kernel_policy_id policy_id = necp_kernel_socket_policy_add(policy->order, session->session_order, session->proc_pid, master_condition_mask, master_condition_negated_mask, cond_app_id, cond_real_app_id, cond_custom_entitlement, cond_account_id, cond_domain, cond_pid, cond_uid, cond_bound_interface, cond_traffic_class, cond_protocol, &cond_local_start, &cond_local_end, cond_local_prefix, &cond_remote_start, &cond_remote_end, cond_remote_prefix, &cond_agent_type, cond_client_flags, ultimate_result, ultimate_result_parameter);

		if (policy_id == 0) {
			NECPLOG0(LOG_DEBUG, "Error applying socket kernel policy");
			goto fail;
		}

		cond_ip_output_layer_id = policy_id;
		policy->kernel_socket_policies[0] = policy_id;
	}

	if (ip_output_layer_non_id_conditions) {
		u_int32_t condition_mask = master_condition_mask;
		if (ip_output_layer_non_id_only) {
			condition_mask |= NECP_KERNEL_CONDITION_POLICY_ID;
		}

		necp_kernel_policy_id policy_id = necp_kernel_ip_output_policy_add(policy->order, NECP_KERNEL_POLICY_SUBORDER_NON_ID_CONDITIONS, session->session_order, session->proc_pid, condition_mask, master_condition_negated_mask, NECP_KERNEL_POLICY_ID_NONE, cond_bound_interface, 0, cond_protocol, &cond_local_start, &cond_local_end, cond_local_prefix, &cond_remote_start, &cond_remote_end, cond_remote_prefix, ultimate_result, ultimate_result_parameter);

		if (policy_id == 0) {
			NECPLOG0(LOG_DEBUG, "Error applying IP output kernel policy");
			goto fail;
		}

		policy->kernel_ip_output_policies[NECP_KERNEL_POLICY_SUBORDER_NON_ID_CONDITIONS] = policy_id;
	}

	if (ip_output_layer_id_condition) {
		necp_kernel_policy_id policy_id = necp_kernel_ip_output_policy_add(policy->order, NECP_KERNEL_POLICY_SUBORDER_ID_CONDITION, session->session_order, session->proc_pid, NECP_KERNEL_CONDITION_POLICY_ID | NECP_KERNEL_CONDITION_ALL_INTERFACES, 0, cond_ip_output_layer_id, NULL, 0, 0, NULL, NULL, 0, NULL, NULL, 0, ultimate_result, ultimate_result_parameter);

		if (policy_id == 0) {
			NECPLOG0(LOG_DEBUG, "Error applying IP output kernel policy");
			goto fail;
		}

		policy->kernel_ip_output_policies[NECP_KERNEL_POLICY_SUBORDER_ID_CONDITION] = policy_id;
	}

	// Extra policies for IP Output tunnels for when packets loop back
	if (ip_output_layer_tunnel_condition_from_id) {
		necp_kernel_policy_id policy_id = necp_kernel_ip_output_policy_add(policy->order, NECP_KERNEL_POLICY_SUBORDER_NON_ID_TUNNEL_CONDITION, session->session_order, session->proc_pid, NECP_KERNEL_CONDITION_POLICY_ID | NECP_KERNEL_CONDITION_LAST_INTERFACE | NECP_KERNEL_CONDITION_ALL_INTERFACES, 0, policy->kernel_ip_output_policies[NECP_KERNEL_POLICY_SUBORDER_NON_ID_CONDITIONS], NULL, cond_last_interface_index, 0, NULL, NULL, 0, NULL, NULL, 0, secondary_result, secondary_result_parameter);

		if (policy_id == 0) {
			NECPLOG0(LOG_DEBUG, "Error applying IP output kernel policy");
			goto fail;
		}

		policy->kernel_ip_output_policies[NECP_KERNEL_POLICY_SUBORDER_NON_ID_TUNNEL_CONDITION] = policy_id;
	}

	if (ip_output_layer_tunnel_condition_from_id) {
		necp_kernel_policy_id policy_id = necp_kernel_ip_output_policy_add(policy->order, NECP_KERNEL_POLICY_SUBORDER_ID_TUNNEL_CONDITION, session->session_order, session->proc_pid, NECP_KERNEL_CONDITION_POLICY_ID | NECP_KERNEL_CONDITION_LAST_INTERFACE | NECP_KERNEL_CONDITION_ALL_INTERFACES, 0, policy->kernel_ip_output_policies[NECP_KERNEL_POLICY_SUBORDER_ID_CONDITION], NULL, cond_last_interface_index, 0, NULL, NULL, 0, NULL, NULL, 0, secondary_result, secondary_result_parameter);

		if (policy_id == 0) {
			NECPLOG0(LOG_DEBUG, "Error applying IP output kernel policy");
			goto fail;
		}

		policy->kernel_ip_output_policies[NECP_KERNEL_POLICY_SUBORDER_ID_TUNNEL_CONDITION] = policy_id;
	}

	policy->applied = TRUE;
	policy->pending_update = FALSE;
	return TRUE;

fail:
	return FALSE;
}

static void
necp_policy_apply_all(struct necp_session *session)
{
	struct necp_session_policy *policy = NULL;
	struct necp_session_policy *temp_policy = NULL;
	struct kev_necp_policies_changed_data kev_data;
	kev_data.changed_count = 0;

	lck_rw_lock_exclusive(&necp_kernel_policy_lock);

	// Remove exisiting applied policies
	if (session->dirty) {
		LIST_FOREACH_SAFE(policy, &session->policies, chain, temp_policy) {
			if (policy->pending_deletion) {
				if (policy->applied) {
					necp_policy_unapply(policy);
				}
				// Delete the policy
				necp_policy_delete(session, policy);
			} else if (!policy->applied) {
				necp_policy_apply(session, policy);
			} else if (policy->pending_update) {
				// Must have been applied, but needs an update. Remove and re-add.
				necp_policy_unapply(policy);
				necp_policy_apply(session, policy);
			}
		}

		necp_kernel_socket_policies_update_uuid_table();
		necp_kernel_socket_policies_reprocess();
		necp_kernel_ip_output_policies_reprocess();

		// Clear dirty bit flags
		session->dirty = FALSE;
	}

	lck_rw_done(&necp_kernel_policy_lock);

	necp_update_all_clients();
	necp_post_change_event(&kev_data);

	if (necp_debug) {
		NECPLOG0(LOG_DEBUG, "Applied NECP policies");
	}
}

// Kernel Policy Management
// ---------------------
// Kernel policies are derived from session policies
static necp_kernel_policy_id
necp_kernel_policy_get_new_id(bool socket_level)
{
	static necp_kernel_policy_id necp_last_kernel_socket_policy_id = 0;
	static necp_kernel_policy_id necp_last_kernel_ip_policy_id = 0;

	necp_kernel_policy_id newid = NECP_KERNEL_POLICY_ID_NONE;

	LCK_RW_ASSERT(&necp_kernel_policy_lock, LCK_RW_ASSERT_EXCLUSIVE);

	if (socket_level) {
		bool wrapped = FALSE;
		do {
			necp_last_kernel_socket_policy_id++;
			if (necp_last_kernel_socket_policy_id < NECP_KERNEL_POLICY_ID_FIRST_VALID_SOCKET ||
			    necp_last_kernel_socket_policy_id >= NECP_KERNEL_POLICY_ID_FIRST_VALID_IP) {
				if (wrapped) {
					// Already wrapped, give up
					NECPLOG0(LOG_ERR, "Failed to find a free socket kernel policy ID.\n");
					return NECP_KERNEL_POLICY_ID_NONE;
				}
				necp_last_kernel_socket_policy_id = NECP_KERNEL_POLICY_ID_FIRST_VALID_SOCKET;
				wrapped = TRUE;
			}
			newid = necp_last_kernel_socket_policy_id;
		} while (necp_kernel_socket_policy_find(newid) != NULL); // If already used, keep trying
	} else {
		bool wrapped = FALSE;
		do {
			necp_last_kernel_ip_policy_id++;
			if (necp_last_kernel_ip_policy_id < NECP_KERNEL_POLICY_ID_FIRST_VALID_IP) {
				if (wrapped) {
					// Already wrapped, give up
					NECPLOG0(LOG_ERR, "Failed to find a free IP kernel policy ID.\n");
					return NECP_KERNEL_POLICY_ID_NONE;
				}
				necp_last_kernel_ip_policy_id = NECP_KERNEL_POLICY_ID_FIRST_VALID_IP;
				wrapped = TRUE;
			}
			newid = necp_last_kernel_ip_policy_id;
		} while (necp_kernel_ip_output_policy_find(newid) != NULL); // If already used, keep trying
	}

	if (newid == NECP_KERNEL_POLICY_ID_NONE) {
		NECPLOG0(LOG_ERR, "Allocate kernel policy id failed.\n");
		return NECP_KERNEL_POLICY_ID_NONE;
	}

	return newid;
}

#define NECP_KERNEL_VALID_SOCKET_CONDITIONS (NECP_KERNEL_CONDITION_APP_ID | NECP_KERNEL_CONDITION_REAL_APP_ID | NECP_KERNEL_CONDITION_DOMAIN | NECP_KERNEL_CONDITION_ACCOUNT_ID | NECP_KERNEL_CONDITION_PID | NECP_KERNEL_CONDITION_UID | NECP_KERNEL_CONDITION_ALL_INTERFACES | NECP_KERNEL_CONDITION_BOUND_INTERFACE | NECP_KERNEL_CONDITION_TRAFFIC_CLASS | NECP_KERNEL_CONDITION_PROTOCOL | NECP_KERNEL_CONDITION_LOCAL_START | NECP_KERNEL_CONDITION_LOCAL_END | NECP_KERNEL_CONDITION_LOCAL_PREFIX | NECP_KERNEL_CONDITION_REMOTE_START | NECP_KERNEL_CONDITION_REMOTE_END | NECP_KERNEL_CONDITION_REMOTE_PREFIX | NECP_KERNEL_CONDITION_ENTITLEMENT | NECP_KERNEL_CONDITION_CUSTOM_ENTITLEMENT | NECP_KERNEL_CONDITION_AGENT_TYPE | NECP_KERNEL_CONDITION_HAS_CLIENT | NECP_KERNEL_CONDITION_LOCAL_NETWORKS | NECP_KERNEL_CONDITION_CLIENT_FLAGS | NECP_KERNEL_CONDITION_LOCAL_EMPTY | NECP_KERNEL_CONDITION_REMOTE_EMPTY | NECP_KERNEL_CONDITION_PLATFORM_BINARY)

static necp_kernel_policy_id
necp_kernel_socket_policy_add(necp_policy_order order, u_int32_t session_order, int session_pid, u_int32_t condition_mask, u_int32_t condition_negated_mask, necp_app_id cond_app_id, necp_app_id cond_real_app_id, char *cond_custom_entitlement, u_int32_t cond_account_id, char *cond_domain, pid_t cond_pid, uid_t cond_uid, ifnet_t cond_bound_interface, struct necp_policy_condition_tc_range cond_traffic_class, u_int16_t cond_protocol, union necp_sockaddr_union *cond_local_start, union necp_sockaddr_union *cond_local_end, u_int8_t cond_local_prefix, union necp_sockaddr_union *cond_remote_start, union necp_sockaddr_union *cond_remote_end, u_int8_t cond_remote_prefix, struct necp_policy_condition_agent_type *cond_agent_type, u_int32_t cond_client_flags, necp_kernel_policy_result result, necp_kernel_policy_result_parameter result_parameter)
{
	struct necp_kernel_socket_policy *new_kernel_policy = NULL;
	struct necp_kernel_socket_policy *tmp_kernel_policy = NULL;

	MALLOC_ZONE(new_kernel_policy, struct necp_kernel_socket_policy *, sizeof(*new_kernel_policy), M_NECP_SOCKET_POLICY, M_WAITOK);
	if (new_kernel_policy == NULL) {
		goto done;
	}

	memset(new_kernel_policy, 0, sizeof(*new_kernel_policy)); // M_ZERO is not supported for MALLOC_ZONE
	new_kernel_policy->id = necp_kernel_policy_get_new_id(true);
	new_kernel_policy->order = order;
	new_kernel_policy->session_order = session_order;
	new_kernel_policy->session_pid = session_pid;

	// Sanitize condition mask
	new_kernel_policy->condition_mask = (condition_mask & NECP_KERNEL_VALID_SOCKET_CONDITIONS);
	if ((new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_ALL_INTERFACES) && (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_BOUND_INTERFACE)) {
		new_kernel_policy->condition_mask &= ~NECP_KERNEL_CONDITION_BOUND_INTERFACE;
	}
	if ((new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_REAL_APP_ID) && !(new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_APP_ID)) {
		new_kernel_policy->condition_mask &= ~NECP_KERNEL_CONDITION_REAL_APP_ID;
	}
	if ((new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_ENTITLEMENT) && !(new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_APP_ID)) {
		new_kernel_policy->condition_mask &= ~NECP_KERNEL_CONDITION_ENTITLEMENT;
	}
	if ((new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_END) && (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_PREFIX)) {
		new_kernel_policy->condition_mask &= ~NECP_KERNEL_CONDITION_LOCAL_PREFIX;
	}
	if ((new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_REMOTE_END) && (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_REMOTE_PREFIX)) {
		new_kernel_policy->condition_mask &= ~NECP_KERNEL_CONDITION_REMOTE_PREFIX;
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_EMPTY) {
		new_kernel_policy->condition_mask &= ~(NECP_KERNEL_CONDITION_LOCAL_PREFIX | NECP_KERNEL_CONDITION_LOCAL_END);
	}
	if ((new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_REMOTE_EMPTY)) {
		new_kernel_policy->condition_mask &= ~(NECP_KERNEL_CONDITION_REMOTE_PREFIX | NECP_KERNEL_CONDITION_REMOTE_END);
	}
	new_kernel_policy->condition_negated_mask = condition_negated_mask & new_kernel_policy->condition_mask;

	// Set condition values
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_APP_ID) {
		new_kernel_policy->cond_app_id = cond_app_id;
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_REAL_APP_ID) {
		new_kernel_policy->cond_real_app_id = cond_real_app_id;
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_CUSTOM_ENTITLEMENT) {
		new_kernel_policy->cond_custom_entitlement = cond_custom_entitlement;
		new_kernel_policy->cond_custom_entitlement_matched = necp_boolean_state_unknown;
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_ACCOUNT_ID) {
		new_kernel_policy->cond_account_id = cond_account_id;
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_DOMAIN) {
		new_kernel_policy->cond_domain = cond_domain;
		new_kernel_policy->cond_domain_dot_count = necp_count_dots(cond_domain, strlen(cond_domain));
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_PID) {
		new_kernel_policy->cond_pid = cond_pid;
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_UID) {
		new_kernel_policy->cond_uid = cond_uid;
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_BOUND_INTERFACE) {
		if (cond_bound_interface) {
			ifnet_reference(cond_bound_interface);
		}
		new_kernel_policy->cond_bound_interface = cond_bound_interface;
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_TRAFFIC_CLASS) {
		new_kernel_policy->cond_traffic_class = cond_traffic_class;
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_PROTOCOL) {
		new_kernel_policy->cond_protocol = cond_protocol;
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_START) {
		memcpy(&new_kernel_policy->cond_local_start, cond_local_start, cond_local_start->sa.sa_len);
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_END) {
		memcpy(&new_kernel_policy->cond_local_end, cond_local_end, cond_local_end->sa.sa_len);
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_PREFIX) {
		new_kernel_policy->cond_local_prefix = cond_local_prefix;
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_REMOTE_START) {
		memcpy(&new_kernel_policy->cond_remote_start, cond_remote_start, cond_remote_start->sa.sa_len);
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_REMOTE_END) {
		memcpy(&new_kernel_policy->cond_remote_end, cond_remote_end, cond_remote_end->sa.sa_len);
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_REMOTE_PREFIX) {
		new_kernel_policy->cond_remote_prefix = cond_remote_prefix;
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_AGENT_TYPE) {
		memcpy(&new_kernel_policy->cond_agent_type, cond_agent_type, sizeof(*cond_agent_type));
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_CLIENT_FLAGS) {
		new_kernel_policy->cond_client_flags = cond_client_flags;
	}

	new_kernel_policy->result = result;
	memcpy(&new_kernel_policy->result_parameter, &result_parameter, sizeof(result_parameter));

	if (necp_debug) {
		NECPLOG(LOG_DEBUG, "Added kernel policy: socket, id=%d, mask=%x\n", new_kernel_policy->id, new_kernel_policy->condition_mask);
	}
	LIST_INSERT_SORTED_TWICE_ASCENDING(&necp_kernel_socket_policies, new_kernel_policy, chain, session_order, order, tmp_kernel_policy);
done:
	return new_kernel_policy ? new_kernel_policy->id : 0;
}

static struct necp_kernel_socket_policy *
necp_kernel_socket_policy_find(necp_kernel_policy_id policy_id)
{
	struct necp_kernel_socket_policy *kernel_policy = NULL;
	struct necp_kernel_socket_policy *tmp_kernel_policy = NULL;

	if (policy_id == 0) {
		return NULL;
	}

	LIST_FOREACH_SAFE(kernel_policy, &necp_kernel_socket_policies, chain, tmp_kernel_policy) {
		if (kernel_policy->id == policy_id) {
			return kernel_policy;
		}
	}

	return NULL;
}

static bool
necp_kernel_socket_policy_delete(necp_kernel_policy_id policy_id)
{
	struct necp_kernel_socket_policy *policy = NULL;

	LCK_RW_ASSERT(&necp_kernel_policy_lock, LCK_RW_ASSERT_EXCLUSIVE);

	policy = necp_kernel_socket_policy_find(policy_id);
	if (policy) {
		LIST_REMOVE(policy, chain);

		if (policy->cond_bound_interface) {
			ifnet_release(policy->cond_bound_interface);
			policy->cond_bound_interface = NULL;
		}

		if (policy->cond_domain) {
			FREE(policy->cond_domain, M_NECP);
			policy->cond_domain = NULL;
		}

		if (policy->cond_custom_entitlement) {
			FREE(policy->cond_custom_entitlement, M_NECP);
			policy->cond_custom_entitlement = NULL;
		}

		FREE_ZONE(policy, sizeof(*policy), M_NECP_SOCKET_POLICY);
		return TRUE;
	}

	return FALSE;
}

static inline const char *
necp_get_result_description(char *result_string, necp_kernel_policy_result result, necp_kernel_policy_result_parameter result_parameter)
{
	uuid_string_t uuid_string;
	switch (result) {
	case NECP_KERNEL_POLICY_RESULT_NONE: {
		snprintf(result_string, MAX_RESULT_STRING_LEN, "None");
		break;
	}
	case NECP_KERNEL_POLICY_RESULT_PASS: {
		snprintf(result_string, MAX_RESULT_STRING_LEN, "Pass");
		break;
	}
	case NECP_KERNEL_POLICY_RESULT_SKIP: {
		snprintf(result_string, MAX_RESULT_STRING_LEN, "Skip (%u)", result_parameter.skip_policy_order);
		break;
	}
	case NECP_KERNEL_POLICY_RESULT_DROP: {
		snprintf(result_string, MAX_RESULT_STRING_LEN, "Drop");
		break;
	}
	case NECP_KERNEL_POLICY_RESULT_SOCKET_DIVERT: {
		snprintf(result_string, MAX_RESULT_STRING_LEN, "SocketDivert (%d)", result_parameter.flow_divert_control_unit);
		break;
	}
	case NECP_KERNEL_POLICY_RESULT_SOCKET_FILTER: {
		snprintf(result_string, MAX_RESULT_STRING_LEN, "SocketFilter (%d)", result_parameter.filter_control_unit);
		break;
	}
	case NECP_KERNEL_POLICY_RESULT_IP_TUNNEL: {
		ifnet_t interface = ifindex2ifnet[result_parameter.tunnel_interface_index];
		snprintf(result_string, MAX_RESULT_STRING_LEN, "IPTunnel (%s%d)", ifnet_name(interface), ifnet_unit(interface));
		break;
	}
	case NECP_KERNEL_POLICY_RESULT_IP_FILTER: {
		snprintf(result_string, MAX_RESULT_STRING_LEN, "IPFilter");
		break;
	}
	case NECP_KERNEL_POLICY_RESULT_SOCKET_SCOPED: {
		ifnet_t interface = ifindex2ifnet[result_parameter.scoped_interface_index];
		snprintf(result_string, MAX_RESULT_STRING_LEN, "SocketScoped (%s%d)", ifnet_name(interface), ifnet_unit(interface));
		break;
	}
	case NECP_KERNEL_POLICY_RESULT_SCOPED_DIRECT: {
		snprintf(result_string, MAX_RESULT_STRING_LEN, "ScopedDirect");
		break;
	}
	case NECP_KERNEL_POLICY_RESULT_ALLOW_UNENTITLED: {
		snprintf(result_string, MAX_RESULT_STRING_LEN, "AllowUnentitled");
		break;
	}
	case NECP_KERNEL_POLICY_RESULT_ROUTE_RULES: {
		int index = 0;
		char interface_names[MAX_ROUTE_RULE_INTERFACES][IFXNAMSIZ];
		struct necp_route_rule *route_rule = necp_lookup_route_rule_locked(&necp_route_rules, result_parameter.route_rule_id);
		if (route_rule != NULL) {
			for (index = 0; index < MAX_ROUTE_RULE_INTERFACES; index++) {
				if (route_rule->exception_if_indices[index] != 0) {
					ifnet_t interface = ifindex2ifnet[route_rule->exception_if_indices[index]];
					snprintf(interface_names[index], IFXNAMSIZ, "%s%d", ifnet_name(interface), ifnet_unit(interface));
				} else {
					memset(interface_names[index], 0, IFXNAMSIZ);
				}
			}
			switch (route_rule->default_action) {
			case NECP_ROUTE_RULE_DENY_INTERFACE:
				snprintf(result_string, MAX_RESULT_STRING_LEN, "RouteRules (Only %s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s)",
				    (route_rule->cellular_action == NECP_ROUTE_RULE_ALLOW_INTERFACE) ? "Cell " : "",
				    (route_rule->wifi_action == NECP_ROUTE_RULE_ALLOW_INTERFACE) ? "WiFi " : "",
				    (route_rule->wired_action == NECP_ROUTE_RULE_ALLOW_INTERFACE) ? "Wired " : "",
				    (route_rule->expensive_action == NECP_ROUTE_RULE_ALLOW_INTERFACE) ? "Exp " : "",
				    (route_rule->constrained_action == NECP_ROUTE_RULE_ALLOW_INTERFACE) ? "Constrained " : "",
				    (route_rule->exception_if_actions[0] == NECP_ROUTE_RULE_ALLOW_INTERFACE) ? interface_names[0] : "",
				    (route_rule->exception_if_actions[0] == NECP_ROUTE_RULE_ALLOW_INTERFACE) ? " " : "",
				    (route_rule->exception_if_actions[1] == NECP_ROUTE_RULE_ALLOW_INTERFACE) ? interface_names[1] : "",
				    (route_rule->exception_if_actions[1] == NECP_ROUTE_RULE_ALLOW_INTERFACE) ? " " : "",
				    (route_rule->exception_if_actions[2] == NECP_ROUTE_RULE_ALLOW_INTERFACE) ? interface_names[2] : "",
				    (route_rule->exception_if_actions[2] == NECP_ROUTE_RULE_ALLOW_INTERFACE) ? " " : "",
				    (route_rule->exception_if_actions[3] == NECP_ROUTE_RULE_ALLOW_INTERFACE) ? interface_names[3] : "",
				    (route_rule->exception_if_actions[3] == NECP_ROUTE_RULE_ALLOW_INTERFACE) ? " " : "",
				    (route_rule->exception_if_actions[4] == NECP_ROUTE_RULE_ALLOW_INTERFACE) ? interface_names[4] : "",
				    (route_rule->exception_if_actions[4] == NECP_ROUTE_RULE_ALLOW_INTERFACE) ? " " : "",
				    (route_rule->exception_if_actions[5] == NECP_ROUTE_RULE_ALLOW_INTERFACE) ? interface_names[5] : "",
				    (route_rule->exception_if_actions[5] == NECP_ROUTE_RULE_ALLOW_INTERFACE) ? " " : "",
				    (route_rule->exception_if_actions[6] == NECP_ROUTE_RULE_ALLOW_INTERFACE) ? interface_names[6] : "",
				    (route_rule->exception_if_actions[6] == NECP_ROUTE_RULE_ALLOW_INTERFACE) ? " " : "",
				    (route_rule->exception_if_actions[7] == NECP_ROUTE_RULE_ALLOW_INTERFACE) ? interface_names[7] : "",
				    (route_rule->exception_if_actions[7] == NECP_ROUTE_RULE_ALLOW_INTERFACE) ? " " : "",
				    (route_rule->exception_if_actions[8] == NECP_ROUTE_RULE_ALLOW_INTERFACE) ? interface_names[8] : "",
				    (route_rule->exception_if_actions[8] == NECP_ROUTE_RULE_ALLOW_INTERFACE) ? " " : "",
				    (route_rule->exception_if_actions[9] == NECP_ROUTE_RULE_ALLOW_INTERFACE) ? interface_names[9] : "");
				break;
			case NECP_ROUTE_RULE_ALLOW_INTERFACE:
				snprintf(result_string, MAX_RESULT_STRING_LEN, "RouteRules (%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s)",
				    (route_rule->cellular_action == NECP_ROUTE_RULE_DENY_INTERFACE) ? "!Cell " : "",
				    (route_rule->wifi_action == NECP_ROUTE_RULE_DENY_INTERFACE) ? "!WiFi " : "",
				    (route_rule->wired_action == NECP_ROUTE_RULE_DENY_INTERFACE) ? "!Wired " : "",
				    (route_rule->expensive_action == NECP_ROUTE_RULE_DENY_INTERFACE) ? "!Exp " : "",
				    (route_rule->constrained_action == NECP_ROUTE_RULE_DENY_INTERFACE) ? "!Constrained " : "",
				    (route_rule->exception_if_actions[0] == NECP_ROUTE_RULE_DENY_INTERFACE) ? "!" : "",
				    (route_rule->exception_if_actions[0] == NECP_ROUTE_RULE_DENY_INTERFACE) ? interface_names[0] : "",
				    (route_rule->exception_if_actions[1] == NECP_ROUTE_RULE_DENY_INTERFACE) ? "!" : "",
				    (route_rule->exception_if_actions[1] == NECP_ROUTE_RULE_DENY_INTERFACE) ? interface_names[1] : "",
				    (route_rule->exception_if_actions[2] == NECP_ROUTE_RULE_DENY_INTERFACE) ? "!" : "",
				    (route_rule->exception_if_actions[2] == NECP_ROUTE_RULE_DENY_INTERFACE) ? interface_names[2] : "",
				    (route_rule->exception_if_actions[3] == NECP_ROUTE_RULE_DENY_INTERFACE) ? "!" : "",
				    (route_rule->exception_if_actions[3] == NECP_ROUTE_RULE_DENY_INTERFACE) ? interface_names[3] : "",
				    (route_rule->exception_if_actions[4] == NECP_ROUTE_RULE_DENY_INTERFACE) ? "!" : "",
				    (route_rule->exception_if_actions[4] == NECP_ROUTE_RULE_DENY_INTERFACE) ? interface_names[4] : "",
				    (route_rule->exception_if_actions[5] == NECP_ROUTE_RULE_DENY_INTERFACE) ? "!" : "",
				    (route_rule->exception_if_actions[5] == NECP_ROUTE_RULE_DENY_INTERFACE) ? interface_names[5] : "",
				    (route_rule->exception_if_actions[6] == NECP_ROUTE_RULE_DENY_INTERFACE) ? "!" : "",
				    (route_rule->exception_if_actions[6] == NECP_ROUTE_RULE_DENY_INTERFACE) ? interface_names[6] : "",
				    (route_rule->exception_if_actions[7] == NECP_ROUTE_RULE_DENY_INTERFACE) ? "!" : "",
				    (route_rule->exception_if_actions[7] == NECP_ROUTE_RULE_DENY_INTERFACE) ? interface_names[7] : "",
				    (route_rule->exception_if_actions[8] == NECP_ROUTE_RULE_DENY_INTERFACE) ? "!" : "",
				    (route_rule->exception_if_actions[8] == NECP_ROUTE_RULE_DENY_INTERFACE) ? interface_names[8] : "",
				    (route_rule->exception_if_actions[9] == NECP_ROUTE_RULE_DENY_INTERFACE) ? "!" : "",
				    (route_rule->exception_if_actions[9] == NECP_ROUTE_RULE_DENY_INTERFACE) ? interface_names[9] : "");
				break;
			case NECP_ROUTE_RULE_QOS_MARKING:
				snprintf(result_string, MAX_RESULT_STRING_LEN, "RouteRules (QoSMarking %s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s)",
				    (route_rule->cellular_action == NECP_ROUTE_RULE_QOS_MARKING) ? "Cell " : "",
				    (route_rule->wifi_action == NECP_ROUTE_RULE_QOS_MARKING) ? "WiFi " : "",
				    (route_rule->wired_action == NECP_ROUTE_RULE_QOS_MARKING) ? "Wired " : "",
				    (route_rule->expensive_action == NECP_ROUTE_RULE_QOS_MARKING) ? "Exp " : "",
				    (route_rule->constrained_action == NECP_ROUTE_RULE_QOS_MARKING) ? "Constrained " : "",
				    (route_rule->exception_if_actions[0] == NECP_ROUTE_RULE_QOS_MARKING) ? interface_names[0] : "",
				    (route_rule->exception_if_actions[0] == NECP_ROUTE_RULE_QOS_MARKING) ? " " : "",
				    (route_rule->exception_if_actions[1] == NECP_ROUTE_RULE_QOS_MARKING) ? interface_names[1] : "",
				    (route_rule->exception_if_actions[1] == NECP_ROUTE_RULE_QOS_MARKING) ? " " : "",
				    (route_rule->exception_if_actions[2] == NECP_ROUTE_RULE_QOS_MARKING) ? interface_names[2] : "",
				    (route_rule->exception_if_actions[2] == NECP_ROUTE_RULE_QOS_MARKING) ? " " : "",
				    (route_rule->exception_if_actions[3] == NECP_ROUTE_RULE_QOS_MARKING) ? interface_names[3] : "",
				    (route_rule->exception_if_actions[3] == NECP_ROUTE_RULE_QOS_MARKING) ? " " : "",
				    (route_rule->exception_if_actions[4] == NECP_ROUTE_RULE_QOS_MARKING) ? interface_names[4] : "",
				    (route_rule->exception_if_actions[4] == NECP_ROUTE_RULE_QOS_MARKING) ? " " : "",
				    (route_rule->exception_if_actions[5] == NECP_ROUTE_RULE_QOS_MARKING) ? interface_names[5] : "",
				    (route_rule->exception_if_actions[5] == NECP_ROUTE_RULE_QOS_MARKING) ? " " : "",
				    (route_rule->exception_if_actions[6] == NECP_ROUTE_RULE_QOS_MARKING) ? interface_names[6] : "",
				    (route_rule->exception_if_actions[6] == NECP_ROUTE_RULE_QOS_MARKING) ? " " : "",
				    (route_rule->exception_if_actions[7] == NECP_ROUTE_RULE_QOS_MARKING) ? interface_names[7] : "",
				    (route_rule->exception_if_actions[7] == NECP_ROUTE_RULE_QOS_MARKING) ? " " : "",
				    (route_rule->exception_if_actions[8] == NECP_ROUTE_RULE_QOS_MARKING) ? interface_names[8] : "",
				    (route_rule->exception_if_actions[8] == NECP_ROUTE_RULE_QOS_MARKING) ? " " : "",
				    (route_rule->exception_if_actions[9] == NECP_ROUTE_RULE_QOS_MARKING) ? interface_names[9] : "");
				break;
			default:
				snprintf(result_string, MAX_RESULT_STRING_LEN, "RouteRules (Unknown)");
				break;
			}
		}
		break;
	}
	case NECP_KERNEL_POLICY_RESULT_USE_NETAGENT: {
		bool found_mapping = FALSE;
		struct necp_uuid_id_mapping *mapping = necp_uuid_lookup_uuid_with_service_id_locked(result_parameter.netagent_id);
		if (mapping != NULL) {
			uuid_unparse(mapping->uuid, uuid_string);
			found_mapping = TRUE;
		}
		snprintf(result_string, MAX_RESULT_STRING_LEN, "UseNetAgent (%s)", found_mapping ? uuid_string : "Unknown");
		break;
	}
	case NECP_KERNEL_POLICY_RESULT_NETAGENT_SCOPED: {
		bool found_mapping = FALSE;
		struct necp_uuid_id_mapping *mapping = necp_uuid_lookup_uuid_with_service_id_locked(result_parameter.netagent_id);
		if (mapping != NULL) {
			uuid_unparse(mapping->uuid, uuid_string);
			found_mapping = TRUE;
		}
		snprintf(result_string, MAX_RESULT_STRING_LEN, "NetAgentScoped (%s)", found_mapping ? uuid_string : "Unknown");
		break;
	}
	case NECP_POLICY_RESULT_TRIGGER: {
		bool found_mapping = FALSE;
		struct necp_uuid_id_mapping *mapping = necp_uuid_lookup_uuid_with_service_id_locked(result_parameter.service.identifier);
		if (mapping != NULL) {
			uuid_unparse(mapping->uuid, uuid_string);
			found_mapping = TRUE;
		}
		snprintf(result_string, MAX_RESULT_STRING_LEN, "Trigger (%s.%d)", found_mapping ? uuid_string : "Unknown", result_parameter.service.data);
		break;
	}
	case NECP_POLICY_RESULT_TRIGGER_IF_NEEDED: {
		bool found_mapping = FALSE;
		struct necp_uuid_id_mapping *mapping = necp_uuid_lookup_uuid_with_service_id_locked(result_parameter.service.identifier);
		if (mapping != NULL) {
			uuid_unparse(mapping->uuid, uuid_string);
			found_mapping = TRUE;
		}
		snprintf(result_string, MAX_RESULT_STRING_LEN, "TriggerIfNeeded (%s.%d)", found_mapping ? uuid_string : "Unknown", result_parameter.service.data);
		break;
	}
	case NECP_POLICY_RESULT_TRIGGER_SCOPED: {
		bool found_mapping = FALSE;
		struct necp_uuid_id_mapping *mapping = necp_uuid_lookup_uuid_with_service_id_locked(result_parameter.service.identifier);
		if (mapping != NULL) {
			uuid_unparse(mapping->uuid, uuid_string);
			found_mapping = TRUE;
		}
		snprintf(result_string, MAX_RESULT_STRING_LEN, "TriggerScoped (%s.%d)", found_mapping ? uuid_string : "Unknown", result_parameter.service.data);
		break;
	}
	case NECP_POLICY_RESULT_NO_TRIGGER_SCOPED: {
		bool found_mapping = FALSE;
		struct necp_uuid_id_mapping *mapping = necp_uuid_lookup_uuid_with_service_id_locked(result_parameter.service.identifier);
		if (mapping != NULL) {
			uuid_unparse(mapping->uuid, uuid_string);
			found_mapping = TRUE;
		}
		snprintf(result_string, MAX_RESULT_STRING_LEN, "NoTriggerScoped (%s.%d)", found_mapping ? uuid_string : "Unknown", result_parameter.service.data);
		break;
	}
	default: {
		snprintf(result_string, MAX_RESULT_STRING_LEN, "Unknown %d (%d)", result, result_parameter.tunnel_interface_index);
		break;
	}
	}
	return result_string;
}

static void
necp_kernel_socket_policies_dump_all(void)
{
	if (necp_debug) {
		struct necp_kernel_socket_policy *policy = NULL;
		int policy_i;
		int app_i;
		char result_string[MAX_RESULT_STRING_LEN];
		char proc_name_string[MAXCOMLEN + 1];
		memset(result_string, 0, MAX_RESULT_STRING_LEN);
		memset(proc_name_string, 0, MAXCOMLEN + 1);

		NECPLOG0(LOG_DEBUG, "NECP Application Policies:\n");
		NECPLOG0(LOG_DEBUG, "-----------\n");
		for (policy_i = 0; necp_kernel_socket_policies_app_layer_map != NULL && necp_kernel_socket_policies_app_layer_map[policy_i] != NULL; policy_i++) {
			policy = necp_kernel_socket_policies_app_layer_map[policy_i];
			proc_name(policy->session_pid, proc_name_string, MAXCOMLEN);
			NECPLOG(LOG_DEBUG, "\t%3d. Policy ID: %5d\tProcess: %10.10s\tOrder: %04d.%04d\tMask: %5x\tResult: %s\n", policy_i, policy->id, proc_name_string, policy->session_order, policy->order, policy->condition_mask, necp_get_result_description(result_string, policy->result, policy->result_parameter));
		}
		if (necp_kernel_socket_policies_app_layer_map[0] != NULL) {
			NECPLOG0(LOG_DEBUG, "-----------\n");
		}

		NECPLOG0(LOG_DEBUG, "NECP Socket Policies:\n");
		NECPLOG0(LOG_DEBUG, "-----------\n");
		for (app_i = 0; app_i < NECP_KERNEL_SOCKET_POLICIES_MAP_NUM_APP_ID_BUCKETS; app_i++) {
			NECPLOG(LOG_DEBUG, "\tApp Bucket: %d\n", app_i);
			for (policy_i = 0; necp_kernel_socket_policies_map[app_i] != NULL && (necp_kernel_socket_policies_map[app_i])[policy_i] != NULL; policy_i++) {
				policy = (necp_kernel_socket_policies_map[app_i])[policy_i];
				proc_name(policy->session_pid, proc_name_string, MAXCOMLEN);
				NECPLOG(LOG_DEBUG, "\t%3d. Policy ID: %5d\tProcess: %10.10s\tOrder: %04d.%04d\tMask: %5x\tResult: %s\n", policy_i, policy->id, proc_name_string, policy->session_order, policy->order, policy->condition_mask, necp_get_result_description(result_string, policy->result, policy->result_parameter));
			}
			NECPLOG0(LOG_DEBUG, "-----------\n");
		}
	}
}

static inline bool
necp_kernel_socket_result_is_trigger_service_type(struct necp_kernel_socket_policy *kernel_policy)
{
	return kernel_policy->result >= NECP_KERNEL_POLICY_RESULT_TRIGGER && kernel_policy->result <= NECP_KERNEL_POLICY_RESULT_NO_TRIGGER_SCOPED;
}

static inline bool
necp_kernel_socket_policy_results_overlap(struct necp_kernel_socket_policy *upper_policy, struct necp_kernel_socket_policy *lower_policy)
{
	if (upper_policy->result == NECP_KERNEL_POLICY_RESULT_DROP) {
		// Drop always cancels out lower policies
		return TRUE;
	} else if (upper_policy->result == NECP_KERNEL_POLICY_RESULT_SOCKET_FILTER ||
	    upper_policy->result == NECP_KERNEL_POLICY_RESULT_ROUTE_RULES ||
	    upper_policy->result == NECP_KERNEL_POLICY_RESULT_USE_NETAGENT ||
	    upper_policy->result == NECP_KERNEL_POLICY_RESULT_NETAGENT_SCOPED ||
	    upper_policy->result == NECP_KERNEL_POLICY_RESULT_ALLOW_UNENTITLED) {
		// Filters and route rules never cancel out lower policies
		return FALSE;
	} else if (necp_kernel_socket_result_is_trigger_service_type(upper_policy)) {
		// Trigger/Scoping policies can overlap one another, but not other results
		return necp_kernel_socket_result_is_trigger_service_type(lower_policy);
	} else if (upper_policy->result == NECP_KERNEL_POLICY_RESULT_SKIP) {
		if (upper_policy->session_order != lower_policy->session_order) {
			// A skip cannot override a policy of a different session
			return FALSE;
		} else {
			if (upper_policy->result_parameter.skip_policy_order == 0 ||
			    lower_policy->order >= upper_policy->result_parameter.skip_policy_order) {
				// This policy is beyond the skip
				return FALSE;
			} else {
				// This policy is inside the skip
				return TRUE;
			}
		}
	}

	// A hard pass, flow divert, tunnel, or scope will currently block out lower policies
	return TRUE;
}

static bool
necp_kernel_socket_policy_is_unnecessary(struct necp_kernel_socket_policy *policy, struct necp_kernel_socket_policy **policy_array, int valid_indices)
{
	bool can_skip = FALSE;
	u_int32_t highest_skip_session_order = 0;
	u_int32_t highest_skip_order = 0;
	int i;
	for (i = 0; i < valid_indices; i++) {
		struct necp_kernel_socket_policy *compared_policy = policy_array[i];

		// For policies in a skip window, we can't mark conflicting policies as unnecessary
		if (can_skip) {
			if (highest_skip_session_order != compared_policy->session_order ||
			    (highest_skip_order != 0 && compared_policy->order >= highest_skip_order)) {
				// If we've moved on to the next session, or passed the skip window
				highest_skip_session_order = 0;
				highest_skip_order = 0;
				can_skip = FALSE;
			} else {
				// If this policy is also a skip, in can increase the skip window
				if (compared_policy->result == NECP_KERNEL_POLICY_RESULT_SKIP) {
					if (compared_policy->result_parameter.skip_policy_order > highest_skip_order) {
						highest_skip_order = compared_policy->result_parameter.skip_policy_order;
					}
				}
				continue;
			}
		}

		if (compared_policy->result == NECP_KERNEL_POLICY_RESULT_SKIP) {
			// This policy is a skip. Set the skip window accordingly
			can_skip = TRUE;
			highest_skip_session_order = compared_policy->session_order;
			highest_skip_order = compared_policy->result_parameter.skip_policy_order;
		}

		// The result of the compared policy must be able to block out this policy result
		if (!necp_kernel_socket_policy_results_overlap(compared_policy, policy)) {
			continue;
		}

		// If new policy matches All Interfaces, compared policy must also
		if ((policy->condition_mask & NECP_KERNEL_CONDITION_ALL_INTERFACES) && !(compared_policy->condition_mask & NECP_KERNEL_CONDITION_ALL_INTERFACES)) {
			continue;
		}

		// If new policy matches Local Networks, compared policy must also
		if ((policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_NETWORKS) && !(compared_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_NETWORKS)) {
			continue;
		}

		// Default makes lower policies unecessary always
		if (compared_policy->condition_mask == 0) {
			return TRUE;
		}

		// Compared must be more general than policy, and include only conditions within policy
		if ((policy->condition_mask & compared_policy->condition_mask) != compared_policy->condition_mask) {
			continue;
		}

		// Negative conditions must match for the overlapping conditions
		if ((policy->condition_negated_mask & compared_policy->condition_mask) != (compared_policy->condition_negated_mask & compared_policy->condition_mask)) {
			continue;
		}

		if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_DOMAIN &&
		    strcmp(compared_policy->cond_domain, policy->cond_domain) != 0) {
			continue;
		}

		if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_CUSTOM_ENTITLEMENT &&
		    strcmp(compared_policy->cond_custom_entitlement, policy->cond_custom_entitlement) != 0) {
			continue;
		}

		if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_ACCOUNT_ID &&
		    compared_policy->cond_account_id != policy->cond_account_id) {
			continue;
		}

		if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_POLICY_ID &&
		    compared_policy->cond_policy_id != policy->cond_policy_id) {
			continue;
		}

		if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_APP_ID &&
		    compared_policy->cond_app_id != policy->cond_app_id) {
			continue;
		}

		if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_REAL_APP_ID &&
		    compared_policy->cond_real_app_id != policy->cond_real_app_id) {
			continue;
		}

		if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_PID &&
		    compared_policy->cond_pid != policy->cond_pid) {
			continue;
		}

		if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_UID &&
		    compared_policy->cond_uid != policy->cond_uid) {
			continue;
		}

		if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_BOUND_INTERFACE &&
		    compared_policy->cond_bound_interface != policy->cond_bound_interface) {
			continue;
		}

		if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_PROTOCOL &&
		    compared_policy->cond_protocol != policy->cond_protocol) {
			continue;
		}

		if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_CLIENT_FLAGS &&
		    compared_policy->cond_client_flags != policy->cond_client_flags) {
			continue;
		}

		if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_TRAFFIC_CLASS &&
		    !(compared_policy->cond_traffic_class.start_tc <= policy->cond_traffic_class.start_tc &&
		    compared_policy->cond_traffic_class.end_tc >= policy->cond_traffic_class.end_tc)) {
			continue;
		}

		if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_START) {
			if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_END) {
				if (!necp_is_range_in_range((struct sockaddr *)&policy->cond_local_start, (struct sockaddr *)&policy->cond_local_end, (struct sockaddr *)&compared_policy->cond_local_start, (struct sockaddr *)&compared_policy->cond_local_end)) {
					continue;
				}
			} else if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_PREFIX) {
				if (compared_policy->cond_local_prefix > policy->cond_local_prefix ||
				    !necp_is_addr_in_subnet((struct sockaddr *)&policy->cond_local_start, (struct sockaddr *)&compared_policy->cond_local_start, compared_policy->cond_local_prefix)) {
					continue;
				}
			}
		}

		if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_REMOTE_START) {
			if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_REMOTE_END) {
				if (!necp_is_range_in_range((struct sockaddr *)&policy->cond_remote_start, (struct sockaddr *)&policy->cond_remote_end, (struct sockaddr *)&compared_policy->cond_remote_start, (struct sockaddr *)&compared_policy->cond_remote_end)) {
					continue;
				}
			} else if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_REMOTE_PREFIX) {
				if (compared_policy->cond_remote_prefix > policy->cond_remote_prefix ||
				    !necp_is_addr_in_subnet((struct sockaddr *)&policy->cond_remote_start, (struct sockaddr *)&compared_policy->cond_remote_start, compared_policy->cond_remote_prefix)) {
					continue;
				}
			}
		}

		if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_AGENT_TYPE &&
		    memcmp(&compared_policy->cond_agent_type, &policy->cond_agent_type, sizeof(policy->cond_agent_type)) == 0) {
			continue;
		}

		return TRUE;
	}

	return FALSE;
}

static bool
necp_kernel_socket_policies_reprocess(void)
{
	int app_i;
	int bucket_allocation_counts[NECP_KERNEL_SOCKET_POLICIES_MAP_NUM_APP_ID_BUCKETS];
	int bucket_current_free_index[NECP_KERNEL_SOCKET_POLICIES_MAP_NUM_APP_ID_BUCKETS];
	int app_layer_allocation_count = 0;
	int app_layer_current_free_index = 0;
	struct necp_kernel_socket_policy *kernel_policy = NULL;

	LCK_RW_ASSERT(&necp_kernel_policy_lock, LCK_RW_ASSERT_EXCLUSIVE);

	// Reset mask to 0
	necp_kernel_application_policies_condition_mask = 0;
	necp_kernel_socket_policies_condition_mask = 0;
	necp_kernel_application_policies_count = 0;
	necp_kernel_socket_policies_count = 0;
	necp_kernel_socket_policies_non_app_count = 0;

	// Reset all maps to NULL
	for (app_i = 0; app_i < NECP_KERNEL_SOCKET_POLICIES_MAP_NUM_APP_ID_BUCKETS; app_i++) {
		if (necp_kernel_socket_policies_map[app_i] != NULL) {
			FREE(necp_kernel_socket_policies_map[app_i], M_NECP);
			necp_kernel_socket_policies_map[app_i] = NULL;
		}

		// Init counts
		bucket_allocation_counts[app_i] = 0;
	}
	if (necp_kernel_socket_policies_app_layer_map != NULL) {
		FREE(necp_kernel_socket_policies_app_layer_map, M_NECP);
		necp_kernel_socket_policies_app_layer_map = NULL;
	}

	// Create masks and counts
	LIST_FOREACH(kernel_policy, &necp_kernel_socket_policies, chain) {
		// App layer mask/count
		necp_kernel_application_policies_condition_mask |= kernel_policy->condition_mask;
		necp_kernel_application_policies_count++;
		app_layer_allocation_count++;

		if ((kernel_policy->condition_mask & NECP_KERNEL_CONDITION_AGENT_TYPE)) {
			// Agent type conditions only apply to app layer
			continue;
		}

		// Update socket layer bucket mask/counts
		necp_kernel_socket_policies_condition_mask |= kernel_policy->condition_mask;
		necp_kernel_socket_policies_count++;

		if (!(kernel_policy->condition_mask & NECP_KERNEL_CONDITION_APP_ID) ||
		    kernel_policy->condition_negated_mask & NECP_KERNEL_CONDITION_APP_ID) {
			necp_kernel_socket_policies_non_app_count++;
			for (app_i = 0; app_i < NECP_KERNEL_SOCKET_POLICIES_MAP_NUM_APP_ID_BUCKETS; app_i++) {
				bucket_allocation_counts[app_i]++;
			}
		} else {
			bucket_allocation_counts[NECP_SOCKET_MAP_APP_ID_TO_BUCKET(kernel_policy->cond_app_id)]++;
		}
	}

	// Allocate maps
	for (app_i = 0; app_i < NECP_KERNEL_SOCKET_POLICIES_MAP_NUM_APP_ID_BUCKETS; app_i++) {
		if (bucket_allocation_counts[app_i] > 0) {
			// Allocate a NULL-terminated array of policy pointers for each bucket
			MALLOC(necp_kernel_socket_policies_map[app_i], struct necp_kernel_socket_policy **, sizeof(struct necp_kernel_socket_policy *) * (bucket_allocation_counts[app_i] + 1), M_NECP, M_WAITOK);
			if (necp_kernel_socket_policies_map[app_i] == NULL) {
				goto fail;
			}

			// Initialize the first entry to NULL
			(necp_kernel_socket_policies_map[app_i])[0] = NULL;
		}
		bucket_current_free_index[app_i] = 0;
	}
	MALLOC(necp_kernel_socket_policies_app_layer_map, struct necp_kernel_socket_policy **, sizeof(struct necp_kernel_socket_policy *) * (app_layer_allocation_count + 1), M_NECP, M_WAITOK);
	if (necp_kernel_socket_policies_app_layer_map == NULL) {
		goto fail;
	}
	necp_kernel_socket_policies_app_layer_map[0] = NULL;

	// Fill out maps
	LIST_FOREACH(kernel_policy, &necp_kernel_socket_policies, chain) {
		// Add app layer policies
		if (!necp_kernel_socket_policy_is_unnecessary(kernel_policy, necp_kernel_socket_policies_app_layer_map, app_layer_current_free_index)) {
			necp_kernel_socket_policies_app_layer_map[app_layer_current_free_index] = kernel_policy;
			app_layer_current_free_index++;
			necp_kernel_socket_policies_app_layer_map[app_layer_current_free_index] = NULL;
		}

		if ((kernel_policy->condition_mask & NECP_KERNEL_CONDITION_AGENT_TYPE)) {
			// Agent type conditions only apply to app layer
			continue;
		}

		// Add socket policies
		if (!(kernel_policy->condition_mask & NECP_KERNEL_CONDITION_APP_ID) ||
		    kernel_policy->condition_negated_mask & NECP_KERNEL_CONDITION_APP_ID) {
			for (app_i = 0; app_i < NECP_KERNEL_SOCKET_POLICIES_MAP_NUM_APP_ID_BUCKETS; app_i++) {
				if (!necp_kernel_socket_policy_is_unnecessary(kernel_policy, necp_kernel_socket_policies_map[app_i], bucket_current_free_index[app_i])) {
					(necp_kernel_socket_policies_map[app_i])[(bucket_current_free_index[app_i])] = kernel_policy;
					bucket_current_free_index[app_i]++;
					(necp_kernel_socket_policies_map[app_i])[(bucket_current_free_index[app_i])] = NULL;
				}
			}
		} else {
			app_i = NECP_SOCKET_MAP_APP_ID_TO_BUCKET(kernel_policy->cond_app_id);
			if (!necp_kernel_socket_policy_is_unnecessary(kernel_policy, necp_kernel_socket_policies_map[app_i], bucket_current_free_index[app_i])) {
				(necp_kernel_socket_policies_map[app_i])[(bucket_current_free_index[app_i])] = kernel_policy;
				bucket_current_free_index[app_i]++;
				(necp_kernel_socket_policies_map[app_i])[(bucket_current_free_index[app_i])] = NULL;
			}
		}
	}
	necp_kernel_socket_policies_dump_all();
	BUMP_KERNEL_SOCKET_POLICIES_GENERATION_COUNT();
	return TRUE;

fail:
	// Free memory, reset masks to 0
	necp_kernel_application_policies_condition_mask = 0;
	necp_kernel_socket_policies_condition_mask = 0;
	necp_kernel_application_policies_count = 0;
	necp_kernel_socket_policies_count = 0;
	necp_kernel_socket_policies_non_app_count = 0;
	for (app_i = 0; app_i < NECP_KERNEL_SOCKET_POLICIES_MAP_NUM_APP_ID_BUCKETS; app_i++) {
		if (necp_kernel_socket_policies_map[app_i] != NULL) {
			FREE(necp_kernel_socket_policies_map[app_i], M_NECP);
			necp_kernel_socket_policies_map[app_i] = NULL;
		}
	}
	if (necp_kernel_socket_policies_app_layer_map != NULL) {
		FREE(necp_kernel_socket_policies_app_layer_map, M_NECP);
		necp_kernel_socket_policies_app_layer_map = NULL;
	}
	return FALSE;
}

static u_int32_t
necp_get_new_string_id(void)
{
	static u_int32_t necp_last_string_id = 0;

	u_int32_t newid = 0;

	LCK_RW_ASSERT(&necp_kernel_policy_lock, LCK_RW_ASSERT_EXCLUSIVE);

	bool wrapped = FALSE;
	do {
		necp_last_string_id++;
		if (necp_last_string_id < 1) {
			if (wrapped) {
				// Already wrapped, give up
				NECPLOG0(LOG_ERR, "Failed to find a free app UUID.\n");
				return 0;
			}
			necp_last_string_id = 1;
			wrapped = TRUE;
		}
		newid = necp_last_string_id;
	} while (necp_lookup_string_with_id_locked(&necp_account_id_list, newid) != NULL); // If already used, keep trying

	if (newid == 0) {
		NECPLOG0(LOG_ERR, "Allocate string id failed.\n");
		return 0;
	}

	return newid;
}

static struct necp_string_id_mapping *
necp_lookup_string_to_id_locked(struct necp_string_id_mapping_list *list, char *string)
{
	struct necp_string_id_mapping *searchentry = NULL;
	struct necp_string_id_mapping *foundentry = NULL;

	LIST_FOREACH(searchentry, list, chain) {
		if (strcmp(searchentry->string, string) == 0) {
			foundentry = searchentry;
			break;
		}
	}

	return foundentry;
}

static struct necp_string_id_mapping *
necp_lookup_string_with_id_locked(struct necp_string_id_mapping_list *list, u_int32_t local_id)
{
	struct necp_string_id_mapping *searchentry = NULL;
	struct necp_string_id_mapping *foundentry = NULL;

	LIST_FOREACH(searchentry, list, chain) {
		if (searchentry->id == local_id) {
			foundentry = searchentry;
			break;
		}
	}

	return foundentry;
}

static u_int32_t
necp_create_string_to_id_mapping(struct necp_string_id_mapping_list *list, char *string)
{
	u_int32_t string_id = 0;
	struct necp_string_id_mapping *existing_mapping = NULL;

	LCK_RW_ASSERT(&necp_kernel_policy_lock, LCK_RW_ASSERT_EXCLUSIVE);

	existing_mapping = necp_lookup_string_to_id_locked(list, string);
	if (existing_mapping != NULL) {
		string_id = existing_mapping->id;
		os_ref_retain_locked(&existing_mapping->refcount);
	} else {
		struct necp_string_id_mapping *new_mapping = NULL;
		MALLOC(new_mapping, struct necp_string_id_mapping *, sizeof(struct necp_string_id_mapping), M_NECP, M_WAITOK);
		if (new_mapping != NULL) {
			memset(new_mapping, 0, sizeof(struct necp_string_id_mapping));

			size_t length = strlen(string) + 1;
			MALLOC(new_mapping->string, char *, length, M_NECP, M_WAITOK);
			if (new_mapping->string != NULL) {
				memcpy(new_mapping->string, string, length);
				new_mapping->id = necp_get_new_string_id();
				os_ref_init(&new_mapping->refcount, &necp_refgrp);
				LIST_INSERT_HEAD(list, new_mapping, chain);
				string_id = new_mapping->id;
			} else {
				FREE(new_mapping, M_NECP);
				new_mapping = NULL;
			}
		}
	}
	return string_id;
}

static bool
necp_remove_string_to_id_mapping(struct necp_string_id_mapping_list *list, char *string)
{
	struct necp_string_id_mapping *existing_mapping = NULL;

	LCK_RW_ASSERT(&necp_kernel_policy_lock, LCK_RW_ASSERT_EXCLUSIVE);

	existing_mapping = necp_lookup_string_to_id_locked(list, string);
	if (existing_mapping != NULL) {
		if (os_ref_release_locked(&existing_mapping->refcount) == 0) {
			LIST_REMOVE(existing_mapping, chain);
			FREE(existing_mapping->string, M_NECP);
			FREE(existing_mapping, M_NECP);
		}
		return TRUE;
	}

	return FALSE;
}

#define NECP_FIRST_VALID_ROUTE_RULE_ID 1
#define NECP_FIRST_VALID_AGGREGATE_ROUTE_RULE_ID UINT16_MAX
static u_int32_t
necp_get_new_route_rule_id(bool aggregate)
{
	static u_int32_t necp_last_route_rule_id = 0;
	static u_int32_t necp_last_aggregate_route_rule_id = 0;

	u_int32_t newid = 0;

	if (!aggregate) {
		// Main necp_kernel_policy_lock protects non-aggregate rule IDs
		LCK_RW_ASSERT(&necp_kernel_policy_lock, LCK_RW_ASSERT_EXCLUSIVE);

		bool wrapped = FALSE;
		do {
			necp_last_route_rule_id++;
			if (necp_last_route_rule_id < NECP_FIRST_VALID_ROUTE_RULE_ID ||
			    necp_last_route_rule_id >= NECP_FIRST_VALID_AGGREGATE_ROUTE_RULE_ID) {
				if (wrapped) {
					// Already wrapped, give up
					NECPLOG0(LOG_ERR, "Failed to find a free route rule id.\n");
					return 0;
				}
				necp_last_route_rule_id = NECP_FIRST_VALID_ROUTE_RULE_ID;
				wrapped = TRUE;
			}
			newid = necp_last_route_rule_id;
		} while (necp_lookup_route_rule_locked(&necp_route_rules, newid) != NULL); // If already used, keep trying
	} else {
		// necp_route_rule_lock protects aggregate rule IDs
		LCK_RW_ASSERT(&necp_route_rule_lock, LCK_RW_ASSERT_EXCLUSIVE);

		bool wrapped = FALSE;
		do {
			necp_last_aggregate_route_rule_id++;
			if (necp_last_aggregate_route_rule_id < NECP_FIRST_VALID_AGGREGATE_ROUTE_RULE_ID) {
				if (wrapped) {
					// Already wrapped, give up
					NECPLOG0(LOG_ERR, "Failed to find a free aggregate route rule id.\n");
					return 0;
				}
				necp_last_aggregate_route_rule_id = NECP_FIRST_VALID_AGGREGATE_ROUTE_RULE_ID;
				wrapped = TRUE;
			}
			newid = necp_last_aggregate_route_rule_id;
		} while (necp_lookup_route_rule_locked(&necp_route_rules, newid) != NULL); // If already used, keep trying
	}

	if (newid == 0) {
		NECPLOG0(LOG_ERR, "Allocate route rule ID failed.\n");
		return 0;
	}

	return newid;
}

static struct necp_route_rule *
necp_lookup_route_rule_locked(struct necp_route_rule_list *list, u_int32_t route_rule_id)
{
	struct necp_route_rule *searchentry = NULL;
	struct necp_route_rule *foundentry = NULL;

	LIST_FOREACH(searchentry, list, chain) {
		if (searchentry->id == route_rule_id) {
			foundentry = searchentry;
			break;
		}
	}

	return foundentry;
}

static struct necp_route_rule *
necp_lookup_route_rule_by_contents_locked(struct necp_route_rule_list *list, u_int32_t default_action, u_int8_t cellular_action, u_int8_t wifi_action, u_int8_t wired_action, u_int8_t expensive_action, u_int8_t constrained_action, u_int32_t *if_indices, u_int8_t *if_actions)
{
	struct necp_route_rule *searchentry = NULL;
	struct necp_route_rule *foundentry = NULL;

	LIST_FOREACH(searchentry, list, chain) {
		if (searchentry->default_action == default_action &&
		    searchentry->cellular_action == cellular_action &&
		    searchentry->wifi_action == wifi_action &&
		    searchentry->wired_action == wired_action &&
		    searchentry->expensive_action == expensive_action &&
		    searchentry->constrained_action == constrained_action) {
			bool match_failed = FALSE;
			size_t index_a = 0;
			size_t index_b = 0;
			size_t count_a = 0;
			size_t count_b = 0;
			for (index_a = 0; index_a < MAX_ROUTE_RULE_INTERFACES; index_a++) {
				bool found_index = FALSE;
				if (searchentry->exception_if_indices[index_a] == 0) {
					break;
				}
				count_a++;
				for (index_b = 0; index_b < MAX_ROUTE_RULE_INTERFACES; index_b++) {
					if (if_indices[index_b] == 0) {
						break;
					}
					if (index_b >= count_b) {
						count_b = index_b + 1;
					}
					if (searchentry->exception_if_indices[index_a] == if_indices[index_b] &&
					    searchentry->exception_if_actions[index_a] == if_actions[index_b]) {
						found_index = TRUE;
						break;
					}
				}
				if (!found_index) {
					match_failed = TRUE;
					break;
				}
			}
			if (!match_failed && count_a == count_b) {
				foundentry = searchentry;
				break;
			}
		}
	}

	return foundentry;
}

static u_int32_t
necp_create_route_rule(struct necp_route_rule_list *list, u_int8_t *route_rules_array, u_int32_t route_rules_array_size)
{
	size_t offset = 0;
	u_int32_t route_rule_id = 0;
	struct necp_route_rule *existing_rule = NULL;
	u_int32_t default_action = NECP_ROUTE_RULE_ALLOW_INTERFACE;
	u_int8_t cellular_action = NECP_ROUTE_RULE_NONE;
	u_int8_t wifi_action = NECP_ROUTE_RULE_NONE;
	u_int8_t wired_action = NECP_ROUTE_RULE_NONE;
	u_int8_t expensive_action = NECP_ROUTE_RULE_NONE;
	u_int8_t constrained_action = NECP_ROUTE_RULE_NONE;
	u_int32_t if_indices[MAX_ROUTE_RULE_INTERFACES];
	size_t num_valid_indices = 0;
	memset(&if_indices, 0, sizeof(if_indices));
	u_int8_t if_actions[MAX_ROUTE_RULE_INTERFACES];
	memset(&if_actions, 0, sizeof(if_actions));

	LCK_RW_ASSERT(&necp_kernel_policy_lock, LCK_RW_ASSERT_EXCLUSIVE);

	if (route_rules_array == NULL || route_rules_array_size == 0) {
		return 0;
	}

	// Process rules
	while (offset < route_rules_array_size) {
		ifnet_t rule_interface = NULL;
		char interface_name[IFXNAMSIZ];
		u_int32_t length = 0;
		u_int8_t *value = necp_buffer_get_tlv_value(route_rules_array, offset, &length);

		u_int8_t rule_type = necp_policy_condition_get_type_from_buffer(value, length);
		u_int8_t rule_flags = necp_policy_condition_get_flags_from_buffer(value, length);
		u_int32_t rule_length = necp_policy_condition_get_value_length_from_buffer(value, length);
		u_int8_t *rule_value = necp_policy_condition_get_value_pointer_from_buffer(value, length);

		if (rule_type == NECP_ROUTE_RULE_NONE) {
			// Don't allow an explicit rule to be None action
			continue;
		}

		if (rule_length == 0) {
			if (rule_flags & NECP_ROUTE_RULE_FLAG_CELLULAR) {
				cellular_action = rule_type;
			}
			if (rule_flags & NECP_ROUTE_RULE_FLAG_WIFI) {
				wifi_action = rule_type;
			}
			if (rule_flags & NECP_ROUTE_RULE_FLAG_WIRED) {
				wired_action = rule_type;
			}
			if (rule_flags & NECP_ROUTE_RULE_FLAG_EXPENSIVE) {
				expensive_action = rule_type;
			}
			if (rule_flags & NECP_ROUTE_RULE_FLAG_CONSTRAINED) {
				constrained_action = rule_type;
			}
			if (rule_flags == 0) {
				default_action = rule_type;
			}
			offset += sizeof(u_int8_t) + sizeof(u_int32_t) + length;
			continue;
		}

		if (num_valid_indices >= MAX_ROUTE_RULE_INTERFACES) {
			offset += sizeof(u_int8_t) + sizeof(u_int32_t) + length;
			continue;
		}

		if (rule_length <= IFXNAMSIZ) {
			memcpy(interface_name, rule_value, rule_length);
			interface_name[rule_length - 1] = 0; // Make sure the string is NULL terminated
			if (ifnet_find_by_name(interface_name, &rule_interface) == 0) {
				if_actions[num_valid_indices] = rule_type;
				if_indices[num_valid_indices++] = rule_interface->if_index;
				ifnet_release(rule_interface);
			}
		}
		offset += sizeof(u_int8_t) + sizeof(u_int32_t) + length;
	}

	existing_rule = necp_lookup_route_rule_by_contents_locked(list, default_action, cellular_action, wifi_action, wired_action, expensive_action, constrained_action, if_indices, if_actions);
	if (existing_rule != NULL) {
		route_rule_id = existing_rule->id;
		os_ref_retain_locked(&existing_rule->refcount);
	} else {
		struct necp_route_rule *new_rule = NULL;
		MALLOC(new_rule, struct necp_route_rule *, sizeof(struct necp_route_rule), M_NECP, M_WAITOK);
		if (new_rule != NULL) {
			memset(new_rule, 0, sizeof(struct necp_route_rule));
			route_rule_id = new_rule->id = necp_get_new_route_rule_id(false);
			new_rule->default_action = default_action;
			new_rule->cellular_action = cellular_action;
			new_rule->wifi_action = wifi_action;
			new_rule->wired_action = wired_action;
			new_rule->expensive_action = expensive_action;
			new_rule->constrained_action =  constrained_action;
			memcpy(&new_rule->exception_if_indices, &if_indices, sizeof(if_indices));
			memcpy(&new_rule->exception_if_actions, &if_actions, sizeof(if_actions));
			os_ref_init(&new_rule->refcount, &necp_refgrp);
			LIST_INSERT_HEAD(list, new_rule, chain);
		}
	}
	return route_rule_id;
}

static void
necp_remove_aggregate_route_rule_for_id(u_int32_t rule_id)
{
	if (rule_id) {
		lck_rw_lock_exclusive(&necp_route_rule_lock);

		struct necp_aggregate_route_rule *existing_rule = NULL;
		struct necp_aggregate_route_rule *tmp_rule = NULL;

		LIST_FOREACH_SAFE(existing_rule, &necp_aggregate_route_rules, chain, tmp_rule) {
			int index = 0;
			for (index = 0; index < MAX_AGGREGATE_ROUTE_RULES; index++) {
				u_int32_t route_rule_id = existing_rule->rule_ids[index];
				if (route_rule_id == rule_id) {
					LIST_REMOVE(existing_rule, chain);
					FREE(existing_rule, M_NECP);
					break;
				}
			}
		}

		lck_rw_done(&necp_route_rule_lock);
	}
}

static bool
necp_remove_route_rule(struct necp_route_rule_list *list, u_int32_t route_rule_id)
{
	struct necp_route_rule *existing_rule = NULL;

	LCK_RW_ASSERT(&necp_kernel_policy_lock, LCK_RW_ASSERT_EXCLUSIVE);

	existing_rule = necp_lookup_route_rule_locked(list, route_rule_id);
	if (existing_rule != NULL) {
		if (os_ref_release_locked(&existing_rule->refcount) == 0) {
			necp_remove_aggregate_route_rule_for_id(existing_rule->id);
			LIST_REMOVE(existing_rule, chain);
			FREE(existing_rule, M_NECP);
		}
		return TRUE;
	}

	return FALSE;
}

static struct necp_aggregate_route_rule *
necp_lookup_aggregate_route_rule_locked(u_int32_t route_rule_id)
{
	struct necp_aggregate_route_rule *searchentry = NULL;
	struct necp_aggregate_route_rule *foundentry = NULL;

	lck_rw_lock_shared(&necp_route_rule_lock);

	LIST_FOREACH(searchentry, &necp_aggregate_route_rules, chain) {
		if (searchentry->id == route_rule_id) {
			foundentry = searchentry;
			break;
		}
	}

	lck_rw_done(&necp_route_rule_lock);

	return foundentry;
}

static u_int32_t
necp_create_aggregate_route_rule(u_int32_t *rule_ids)
{
	u_int32_t aggregate_route_rule_id = 0;
	struct necp_aggregate_route_rule *new_rule = NULL;
	struct necp_aggregate_route_rule *existing_rule = NULL;

	lck_rw_lock_exclusive(&necp_route_rule_lock);

	// Check if the rule already exists
	LIST_FOREACH(existing_rule, &necp_aggregate_route_rules, chain) {
		if (memcmp(existing_rule->rule_ids, rule_ids, (sizeof(u_int32_t) * MAX_AGGREGATE_ROUTE_RULES)) == 0) {
			lck_rw_done(&necp_route_rule_lock);
			return existing_rule->id;
		}
	}

	MALLOC(new_rule, struct necp_aggregate_route_rule *, sizeof(struct necp_aggregate_route_rule), M_NECP, M_WAITOK);
	if (new_rule != NULL) {
		memset(new_rule, 0, sizeof(struct necp_aggregate_route_rule));
		aggregate_route_rule_id = new_rule->id = necp_get_new_route_rule_id(true);
		new_rule->id = aggregate_route_rule_id;
		memcpy(new_rule->rule_ids, rule_ids, (sizeof(u_int32_t) * MAX_AGGREGATE_ROUTE_RULES));
		LIST_INSERT_HEAD(&necp_aggregate_route_rules, new_rule, chain);
	}
	lck_rw_done(&necp_route_rule_lock);

	return aggregate_route_rule_id;
}

#define NECP_NULL_SERVICE_ID 1
#define NECP_FIRST_VALID_SERVICE_ID  2
#define NECP_FIRST_VALID_APP_ID  UINT16_MAX
static u_int32_t
necp_get_new_uuid_id(bool service)
{
	static u_int32_t necp_last_service_uuid_id = 0;
	static u_int32_t necp_last_app_uuid_id = 0;

	u_int32_t newid = 0;

	LCK_RW_ASSERT(&necp_kernel_policy_lock, LCK_RW_ASSERT_EXCLUSIVE);

	if (service) {
		bool wrapped = FALSE;
		do {
			necp_last_service_uuid_id++;
			if (necp_last_service_uuid_id < NECP_FIRST_VALID_SERVICE_ID ||
			    necp_last_service_uuid_id >= NECP_FIRST_VALID_APP_ID) {
				if (wrapped) {
					// Already wrapped, give up
					NECPLOG0(LOG_ERR, "Failed to find a free service UUID.\n");
					return NECP_NULL_SERVICE_ID;
				}
				necp_last_service_uuid_id = NECP_FIRST_VALID_SERVICE_ID;
				wrapped = TRUE;
			}
			newid = necp_last_service_uuid_id;
		} while (necp_uuid_lookup_uuid_with_service_id_locked(newid) != NULL); // If already used, keep trying
	} else {
		bool wrapped = FALSE;
		do {
			necp_last_app_uuid_id++;
			if (necp_last_app_uuid_id < NECP_FIRST_VALID_APP_ID) {
				if (wrapped) {
					// Already wrapped, give up
					NECPLOG0(LOG_ERR, "Failed to find a free app UUID.\n");
					return NECP_NULL_SERVICE_ID;
				}
				necp_last_app_uuid_id = NECP_FIRST_VALID_APP_ID;
				wrapped = TRUE;
			}
			newid = necp_last_app_uuid_id;
		} while (necp_uuid_lookup_uuid_with_app_id_locked(newid) != NULL); // If already used, keep trying
	}

	if (newid == NECP_NULL_SERVICE_ID) {
		NECPLOG0(LOG_ERR, "Allocate uuid ID failed.\n");
		return NECP_NULL_SERVICE_ID;
	}

	return newid;
}

static struct necp_uuid_id_mapping *
necp_uuid_lookup_app_id_locked(uuid_t uuid)
{
	struct necp_uuid_id_mapping *searchentry = NULL;
	struct necp_uuid_id_mapping *foundentry = NULL;

	LIST_FOREACH(searchentry, APPUUIDHASH(uuid), chain) {
		if (uuid_compare(searchentry->uuid, uuid) == 0) {
			foundentry = searchentry;
			break;
		}
	}

	return foundentry;
}

static struct necp_uuid_id_mapping *
necp_uuid_lookup_uuid_with_app_id_locked(u_int32_t local_id)
{
	struct necp_uuid_id_mapping *searchentry = NULL;
	struct necp_uuid_id_mapping *foundentry = NULL;

	struct necp_uuid_id_mapping_head *uuid_list_head = NULL;
	for (uuid_list_head = &necp_uuid_app_id_hashtbl[necp_uuid_app_id_hash_num_buckets - 1]; uuid_list_head >= necp_uuid_app_id_hashtbl; uuid_list_head--) {
		LIST_FOREACH(searchentry, uuid_list_head, chain) {
			if (searchentry->id == local_id) {
				foundentry = searchentry;
				break;
			}
		}
	}

	return foundentry;
}

static u_int32_t
necp_create_uuid_app_id_mapping(uuid_t uuid, bool *allocated_mapping, bool uuid_policy_table)
{
	u_int32_t local_id = 0;
	struct necp_uuid_id_mapping *existing_mapping = NULL;

	LCK_RW_ASSERT(&necp_kernel_policy_lock, LCK_RW_ASSERT_EXCLUSIVE);

	if (allocated_mapping) {
		*allocated_mapping = FALSE;
	}

	existing_mapping = necp_uuid_lookup_app_id_locked(uuid);
	if (existing_mapping != NULL) {
		local_id = existing_mapping->id;
		os_ref_retain_locked(&existing_mapping->refcount);
		if (uuid_policy_table) {
			existing_mapping->table_usecount++;
		}
	} else {
		struct necp_uuid_id_mapping *new_mapping = NULL;
		MALLOC(new_mapping, struct necp_uuid_id_mapping *, sizeof(*new_mapping), M_NECP, M_WAITOK);
		if (new_mapping != NULL) {
			uuid_copy(new_mapping->uuid, uuid);
			new_mapping->id = necp_get_new_uuid_id(false);
			os_ref_init(&new_mapping->refcount, &necp_refgrp);
			if (uuid_policy_table) {
				new_mapping->table_usecount = 1;
			} else {
				new_mapping->table_usecount = 0;
			}

			LIST_INSERT_HEAD(APPUUIDHASH(uuid), new_mapping, chain);

			if (allocated_mapping) {
				*allocated_mapping = TRUE;
			}

			local_id = new_mapping->id;
		}
	}

	return local_id;
}

static bool
necp_remove_uuid_app_id_mapping(uuid_t uuid, bool *removed_mapping, bool uuid_policy_table)
{
	struct necp_uuid_id_mapping *existing_mapping = NULL;

	LCK_RW_ASSERT(&necp_kernel_policy_lock, LCK_RW_ASSERT_EXCLUSIVE);

	if (removed_mapping) {
		*removed_mapping = FALSE;
	}

	existing_mapping = necp_uuid_lookup_app_id_locked(uuid);
	if (existing_mapping != NULL) {
		if (uuid_policy_table) {
			existing_mapping->table_usecount--;
		}
		if (os_ref_release_locked(&existing_mapping->refcount) == 0) {
			LIST_REMOVE(existing_mapping, chain);
			FREE(existing_mapping, M_NECP);
			if (removed_mapping) {
				*removed_mapping = TRUE;
			}
		}
		return TRUE;
	}

	return FALSE;
}

static struct necp_uuid_id_mapping *
necp_uuid_get_null_service_id_mapping(void)
{
	static struct necp_uuid_id_mapping null_mapping;
	uuid_clear(null_mapping.uuid);
	null_mapping.id = NECP_NULL_SERVICE_ID;

	return &null_mapping;
}

static struct necp_uuid_id_mapping *
necp_uuid_lookup_service_id_locked(uuid_t uuid)
{
	struct necp_uuid_id_mapping *searchentry = NULL;
	struct necp_uuid_id_mapping *foundentry = NULL;

	if (uuid_is_null(uuid)) {
		return necp_uuid_get_null_service_id_mapping();
	}

	LIST_FOREACH(searchentry, &necp_uuid_service_id_list, chain) {
		if (uuid_compare(searchentry->uuid, uuid) == 0) {
			foundentry = searchentry;
			break;
		}
	}

	return foundentry;
}

static struct necp_uuid_id_mapping *
necp_uuid_lookup_uuid_with_service_id_locked(u_int32_t local_id)
{
	struct necp_uuid_id_mapping *searchentry = NULL;
	struct necp_uuid_id_mapping *foundentry = NULL;

	if (local_id == NECP_NULL_SERVICE_ID) {
		return necp_uuid_get_null_service_id_mapping();
	}

	LIST_FOREACH(searchentry, &necp_uuid_service_id_list, chain) {
		if (searchentry->id == local_id) {
			foundentry = searchentry;
			break;
		}
	}

	return foundentry;
}

static u_int32_t
necp_create_uuid_service_id_mapping(uuid_t uuid)
{
	u_int32_t local_id = 0;
	struct necp_uuid_id_mapping *existing_mapping = NULL;

	if (uuid_is_null(uuid)) {
		return NECP_NULL_SERVICE_ID;
	}

	LCK_RW_ASSERT(&necp_kernel_policy_lock, LCK_RW_ASSERT_EXCLUSIVE);

	existing_mapping = necp_uuid_lookup_service_id_locked(uuid);
	if (existing_mapping != NULL) {
		local_id = existing_mapping->id;
		os_ref_retain_locked(&existing_mapping->refcount);
	} else {
		struct necp_uuid_id_mapping *new_mapping = NULL;
		MALLOC(new_mapping, struct necp_uuid_id_mapping *, sizeof(*new_mapping), M_NECP, M_WAITOK);
		if (new_mapping != NULL) {
			uuid_copy(new_mapping->uuid, uuid);
			new_mapping->id = necp_get_new_uuid_id(true);
			os_ref_init(&new_mapping->refcount, &necp_refgrp);

			LIST_INSERT_HEAD(&necp_uuid_service_id_list, new_mapping, chain);

			local_id = new_mapping->id;
		}
	}

	return local_id;
}

static bool
necp_remove_uuid_service_id_mapping(uuid_t uuid)
{
	struct necp_uuid_id_mapping *existing_mapping = NULL;

	if (uuid_is_null(uuid)) {
		return TRUE;
	}

	LCK_RW_ASSERT(&necp_kernel_policy_lock, LCK_RW_ASSERT_EXCLUSIVE);

	existing_mapping = necp_uuid_lookup_service_id_locked(uuid);
	if (existing_mapping != NULL) {
		if (os_ref_release_locked(&existing_mapping->refcount) == 0) {
			LIST_REMOVE(existing_mapping, chain);
			FREE(existing_mapping, M_NECP);
		}
		return TRUE;
	}

	return FALSE;
}


static bool
necp_kernel_socket_policies_update_uuid_table(void)
{
	LCK_RW_ASSERT(&necp_kernel_policy_lock, LCK_RW_ASSERT_EXCLUSIVE);

	if (necp_uuid_app_id_mappings_dirty) {
		if (proc_uuid_policy_kernel(PROC_UUID_POLICY_OPERATION_CLEAR, NULL, PROC_UUID_NECP_APP_POLICY) < 0) {
			NECPLOG0(LOG_DEBUG, "Error clearing uuids from policy table\n");
			return FALSE;
		}

		if (necp_num_uuid_app_id_mappings > 0) {
			struct necp_uuid_id_mapping_head *uuid_list_head = NULL;
			for (uuid_list_head = &necp_uuid_app_id_hashtbl[necp_uuid_app_id_hash_num_buckets - 1]; uuid_list_head >= necp_uuid_app_id_hashtbl; uuid_list_head--) {
				struct necp_uuid_id_mapping *mapping = NULL;
				LIST_FOREACH(mapping, uuid_list_head, chain) {
					if (mapping->table_usecount > 0 &&
					    proc_uuid_policy_kernel(PROC_UUID_POLICY_OPERATION_ADD, mapping->uuid, PROC_UUID_NECP_APP_POLICY) < 0) {
						NECPLOG0(LOG_DEBUG, "Error adding uuid to policy table\n");
					}
				}
			}
		}

		necp_uuid_app_id_mappings_dirty = FALSE;
	}

	return TRUE;
}

#define NECP_KERNEL_VALID_IP_OUTPUT_CONDITIONS (NECP_KERNEL_CONDITION_ALL_INTERFACES | NECP_KERNEL_CONDITION_BOUND_INTERFACE | NECP_KERNEL_CONDITION_PROTOCOL | NECP_KERNEL_CONDITION_LOCAL_START | NECP_KERNEL_CONDITION_LOCAL_END | NECP_KERNEL_CONDITION_LOCAL_PREFIX | NECP_KERNEL_CONDITION_REMOTE_START | NECP_KERNEL_CONDITION_REMOTE_END | NECP_KERNEL_CONDITION_REMOTE_PREFIX | NECP_KERNEL_CONDITION_POLICY_ID | NECP_KERNEL_CONDITION_LAST_INTERFACE | NECP_KERNEL_CONDITION_LOCAL_NETWORKS)
static necp_kernel_policy_id
necp_kernel_ip_output_policy_add(necp_policy_order order, necp_policy_order suborder, u_int32_t session_order, int session_pid, u_int32_t condition_mask, u_int32_t condition_negated_mask, necp_kernel_policy_id cond_policy_id, ifnet_t cond_bound_interface, u_int32_t cond_last_interface_index, u_int16_t cond_protocol, union necp_sockaddr_union *cond_local_start, union necp_sockaddr_union *cond_local_end, u_int8_t cond_local_prefix, union necp_sockaddr_union *cond_remote_start, union necp_sockaddr_union *cond_remote_end, u_int8_t cond_remote_prefix, necp_kernel_policy_result result, necp_kernel_policy_result_parameter result_parameter)
{
	struct necp_kernel_ip_output_policy *new_kernel_policy = NULL;
	struct necp_kernel_ip_output_policy *tmp_kernel_policy = NULL;

	MALLOC_ZONE(new_kernel_policy, struct necp_kernel_ip_output_policy *, sizeof(*new_kernel_policy), M_NECP_IP_POLICY, M_WAITOK);
	if (new_kernel_policy == NULL) {
		goto done;
	}

	memset(new_kernel_policy, 0, sizeof(*new_kernel_policy)); // M_ZERO is not supported for MALLOC_ZONE
	new_kernel_policy->id = necp_kernel_policy_get_new_id(false);
	new_kernel_policy->suborder = suborder;
	new_kernel_policy->order = order;
	new_kernel_policy->session_order = session_order;
	new_kernel_policy->session_pid = session_pid;

	// Sanitize condition mask
	new_kernel_policy->condition_mask = (condition_mask & NECP_KERNEL_VALID_IP_OUTPUT_CONDITIONS);
	if ((new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_ALL_INTERFACES) && (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_BOUND_INTERFACE)) {
		new_kernel_policy->condition_mask &= ~NECP_KERNEL_CONDITION_BOUND_INTERFACE;
	}
	if ((new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_END) && (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_PREFIX)) {
		new_kernel_policy->condition_mask &= ~NECP_KERNEL_CONDITION_LOCAL_PREFIX;
	}
	if ((new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_REMOTE_END) && (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_REMOTE_PREFIX)) {
		new_kernel_policy->condition_mask &= ~NECP_KERNEL_CONDITION_REMOTE_PREFIX;
	}
	new_kernel_policy->condition_negated_mask = condition_negated_mask & new_kernel_policy->condition_mask;

	// Set condition values
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_POLICY_ID) {
		new_kernel_policy->cond_policy_id = cond_policy_id;
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_BOUND_INTERFACE) {
		if (cond_bound_interface) {
			ifnet_reference(cond_bound_interface);
		}
		new_kernel_policy->cond_bound_interface = cond_bound_interface;
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_LAST_INTERFACE) {
		new_kernel_policy->cond_last_interface_index = cond_last_interface_index;
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_PROTOCOL) {
		new_kernel_policy->cond_protocol = cond_protocol;
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_START) {
		memcpy(&new_kernel_policy->cond_local_start, cond_local_start, cond_local_start->sa.sa_len);
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_END) {
		memcpy(&new_kernel_policy->cond_local_end, cond_local_end, cond_local_end->sa.sa_len);
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_PREFIX) {
		new_kernel_policy->cond_local_prefix = cond_local_prefix;
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_REMOTE_START) {
		memcpy(&new_kernel_policy->cond_remote_start, cond_remote_start, cond_remote_start->sa.sa_len);
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_REMOTE_END) {
		memcpy(&new_kernel_policy->cond_remote_end, cond_remote_end, cond_remote_end->sa.sa_len);
	}
	if (new_kernel_policy->condition_mask & NECP_KERNEL_CONDITION_REMOTE_PREFIX) {
		new_kernel_policy->cond_remote_prefix = cond_remote_prefix;
	}

	new_kernel_policy->result = result;
	memcpy(&new_kernel_policy->result_parameter, &result_parameter, sizeof(result_parameter));

	if (necp_debug) {
		NECPLOG(LOG_DEBUG, "Added kernel policy: ip output, id=%d, mask=%x\n", new_kernel_policy->id, new_kernel_policy->condition_mask);
	}
	LIST_INSERT_SORTED_THRICE_ASCENDING(&necp_kernel_ip_output_policies, new_kernel_policy, chain, session_order, order, suborder, tmp_kernel_policy);
done:
	return new_kernel_policy ? new_kernel_policy->id : 0;
}

static struct necp_kernel_ip_output_policy *
necp_kernel_ip_output_policy_find(necp_kernel_policy_id policy_id)
{
	struct necp_kernel_ip_output_policy *kernel_policy = NULL;
	struct necp_kernel_ip_output_policy *tmp_kernel_policy = NULL;

	if (policy_id == 0) {
		return NULL;
	}

	LIST_FOREACH_SAFE(kernel_policy, &necp_kernel_ip_output_policies, chain, tmp_kernel_policy) {
		if (kernel_policy->id == policy_id) {
			return kernel_policy;
		}
	}

	return NULL;
}

static bool
necp_kernel_ip_output_policy_delete(necp_kernel_policy_id policy_id)
{
	struct necp_kernel_ip_output_policy *policy = NULL;

	LCK_RW_ASSERT(&necp_kernel_policy_lock, LCK_RW_ASSERT_EXCLUSIVE);

	policy = necp_kernel_ip_output_policy_find(policy_id);
	if (policy) {
		LIST_REMOVE(policy, chain);

		if (policy->cond_bound_interface) {
			ifnet_release(policy->cond_bound_interface);
			policy->cond_bound_interface = NULL;
		}

		FREE_ZONE(policy, sizeof(*policy), M_NECP_IP_POLICY);
		return TRUE;
	}

	return FALSE;
}

static void
necp_kernel_ip_output_policies_dump_all(void)
{
	if (necp_debug) {
		struct necp_kernel_ip_output_policy *policy = NULL;
		int policy_i;
		int id_i;
		char result_string[MAX_RESULT_STRING_LEN];
		char proc_name_string[MAXCOMLEN + 1];
		memset(result_string, 0, MAX_RESULT_STRING_LEN);
		memset(proc_name_string, 0, MAXCOMLEN + 1);

		NECPLOG0(LOG_DEBUG, "NECP IP Output Policies:\n");
		NECPLOG0(LOG_DEBUG, "-----------\n");
		for (id_i = 0; id_i < NECP_KERNEL_IP_OUTPUT_POLICIES_MAP_NUM_ID_BUCKETS; id_i++) {
			NECPLOG(LOG_DEBUG, " ID Bucket: %d\n", id_i);
			for (policy_i = 0; necp_kernel_ip_output_policies_map[id_i] != NULL && (necp_kernel_ip_output_policies_map[id_i])[policy_i] != NULL; policy_i++) {
				policy = (necp_kernel_ip_output_policies_map[id_i])[policy_i];
				proc_name(policy->session_pid, proc_name_string, MAXCOMLEN);
				NECPLOG(LOG_DEBUG, "\t%3d. Policy ID: %5d\tProcess: %10.10s\tOrder: %04d.%04d.%d\tMask: %5x\tResult: %s\n", policy_i, policy->id, proc_name_string, policy->session_order, policy->order, policy->suborder, policy->condition_mask, necp_get_result_description(result_string, policy->result, policy->result_parameter));
			}
			NECPLOG0(LOG_DEBUG, "-----------\n");
		}
	}
}

static inline bool
necp_kernel_ip_output_policy_results_overlap(struct necp_kernel_ip_output_policy *upper_policy, struct necp_kernel_ip_output_policy *lower_policy)
{
	if (upper_policy->result == NECP_KERNEL_POLICY_RESULT_SKIP) {
		if (upper_policy->session_order != lower_policy->session_order) {
			// A skip cannot override a policy of a different session
			return FALSE;
		} else {
			if (upper_policy->result_parameter.skip_policy_order == 0 ||
			    lower_policy->order >= upper_policy->result_parameter.skip_policy_order) {
				// This policy is beyond the skip
				return FALSE;
			} else {
				// This policy is inside the skip
				return TRUE;
			}
		}
	}

	// All other IP Output policy results (drop, tunnel, hard pass) currently overlap
	return TRUE;
}

static bool
necp_kernel_ip_output_policy_is_unnecessary(struct necp_kernel_ip_output_policy *policy, struct necp_kernel_ip_output_policy **policy_array, int valid_indices)
{
	bool can_skip = FALSE;
	u_int32_t highest_skip_session_order = 0;
	u_int32_t highest_skip_order = 0;
	int i;
	for (i = 0; i < valid_indices; i++) {
		struct necp_kernel_ip_output_policy *compared_policy = policy_array[i];

		// For policies in a skip window, we can't mark conflicting policies as unnecessary
		if (can_skip) {
			if (highest_skip_session_order != compared_policy->session_order ||
			    (highest_skip_order != 0 && compared_policy->order >= highest_skip_order)) {
				// If we've moved on to the next session, or passed the skip window
				highest_skip_session_order = 0;
				highest_skip_order = 0;
				can_skip = FALSE;
			} else {
				// If this policy is also a skip, in can increase the skip window
				if (compared_policy->result == NECP_KERNEL_POLICY_RESULT_SKIP) {
					if (compared_policy->result_parameter.skip_policy_order > highest_skip_order) {
						highest_skip_order = compared_policy->result_parameter.skip_policy_order;
					}
				}
				continue;
			}
		}

		if (compared_policy->result == NECP_KERNEL_POLICY_RESULT_SKIP) {
			// This policy is a skip. Set the skip window accordingly
			can_skip = TRUE;
			highest_skip_session_order = compared_policy->session_order;
			highest_skip_order = compared_policy->result_parameter.skip_policy_order;
		}

		// The result of the compared policy must be able to block out this policy result
		if (!necp_kernel_ip_output_policy_results_overlap(compared_policy, policy)) {
			continue;
		}

		// If new policy matches All Interfaces, compared policy must also
		if ((policy->condition_mask & NECP_KERNEL_CONDITION_ALL_INTERFACES) && !(compared_policy->condition_mask & NECP_KERNEL_CONDITION_ALL_INTERFACES)) {
			continue;
		}

		// If new policy matches Local Networks, compared policy must also
		if ((policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_NETWORKS) && !(compared_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_NETWORKS)) {
			continue;
		}

		// Default makes lower policies unecessary always
		if (compared_policy->condition_mask == 0) {
			return TRUE;
		}

		// Compared must be more general than policy, and include only conditions within policy
		if ((policy->condition_mask & compared_policy->condition_mask) != compared_policy->condition_mask) {
			continue;
		}

		// Negative conditions must match for the overlapping conditions
		if ((policy->condition_negated_mask & compared_policy->condition_mask) != (compared_policy->condition_negated_mask & compared_policy->condition_mask)) {
			continue;
		}

		if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_POLICY_ID &&
		    compared_policy->cond_policy_id != policy->cond_policy_id) {
			continue;
		}

		if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_BOUND_INTERFACE &&
		    compared_policy->cond_bound_interface != policy->cond_bound_interface) {
			continue;
		}

		if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_PROTOCOL &&
		    compared_policy->cond_protocol != policy->cond_protocol) {
			continue;
		}

		if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_START) {
			if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_END) {
				if (!necp_is_range_in_range((struct sockaddr *)&policy->cond_local_start, (struct sockaddr *)&policy->cond_local_end, (struct sockaddr *)&compared_policy->cond_local_start, (struct sockaddr *)&compared_policy->cond_local_end)) {
					continue;
				}
			} else if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_PREFIX) {
				if (compared_policy->cond_local_prefix > policy->cond_local_prefix ||
				    !necp_is_addr_in_subnet((struct sockaddr *)&policy->cond_local_start, (struct sockaddr *)&compared_policy->cond_local_start, compared_policy->cond_local_prefix)) {
					continue;
				}
			}
		}

		if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_REMOTE_START) {
			if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_REMOTE_END) {
				if (!necp_is_range_in_range((struct sockaddr *)&policy->cond_remote_start, (struct sockaddr *)&policy->cond_remote_end, (struct sockaddr *)&compared_policy->cond_remote_start, (struct sockaddr *)&compared_policy->cond_remote_end)) {
					continue;
				}
			} else if (compared_policy->condition_mask & NECP_KERNEL_CONDITION_REMOTE_PREFIX) {
				if (compared_policy->cond_remote_prefix > policy->cond_remote_prefix ||
				    !necp_is_addr_in_subnet((struct sockaddr *)&policy->cond_remote_start, (struct sockaddr *)&compared_policy->cond_remote_start, compared_policy->cond_remote_prefix)) {
					continue;
				}
			}
		}

		return TRUE;
	}

	return FALSE;
}

static bool
necp_kernel_ip_output_policies_reprocess(void)
{
	int i;
	int bucket_allocation_counts[NECP_KERNEL_IP_OUTPUT_POLICIES_MAP_NUM_ID_BUCKETS];
	int bucket_current_free_index[NECP_KERNEL_IP_OUTPUT_POLICIES_MAP_NUM_ID_BUCKETS];
	struct necp_kernel_ip_output_policy *kernel_policy = NULL;

	LCK_RW_ASSERT(&necp_kernel_policy_lock, LCK_RW_ASSERT_EXCLUSIVE);

	// Reset mask to 0
	necp_kernel_ip_output_policies_condition_mask = 0;
	necp_kernel_ip_output_policies_count = 0;
	necp_kernel_ip_output_policies_non_id_count = 0;

	for (i = 0; i < NECP_KERNEL_IP_OUTPUT_POLICIES_MAP_NUM_ID_BUCKETS; i++) {
		if (necp_kernel_ip_output_policies_map[i] != NULL) {
			FREE(necp_kernel_ip_output_policies_map[i], M_NECP);
			necp_kernel_ip_output_policies_map[i] = NULL;
		}

		// Init counts
		bucket_allocation_counts[i] = 0;
	}

	LIST_FOREACH(kernel_policy, &necp_kernel_ip_output_policies, chain) {
		// Update mask
		necp_kernel_ip_output_policies_condition_mask |= kernel_policy->condition_mask;
		necp_kernel_ip_output_policies_count++;

		/* Update bucket counts:
		 * Non-id and SKIP policies will be added to all buckets
		 * Add local networks policy to all buckets for incoming IP
		 */
		if (!(kernel_policy->condition_mask & NECP_KERNEL_CONDITION_POLICY_ID) ||
		    (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_NETWORKS) ||
		    kernel_policy->result == NECP_KERNEL_POLICY_RESULT_SKIP) {
			for (i = 0; i < NECP_KERNEL_IP_OUTPUT_POLICIES_MAP_NUM_ID_BUCKETS; i++) {
				bucket_allocation_counts[i]++;
			}
		}
		if (!(kernel_policy->condition_mask & NECP_KERNEL_CONDITION_POLICY_ID)) {
			necp_kernel_ip_output_policies_non_id_count++;
		} else {
			bucket_allocation_counts[NECP_IP_OUTPUT_MAP_ID_TO_BUCKET(kernel_policy->cond_policy_id)]++;
		}
	}

	for (i = 0; i < NECP_KERNEL_IP_OUTPUT_POLICIES_MAP_NUM_ID_BUCKETS; i++) {
		if (bucket_allocation_counts[i] > 0) {
			// Allocate a NULL-terminated array of policy pointers for each bucket
			MALLOC(necp_kernel_ip_output_policies_map[i], struct necp_kernel_ip_output_policy **, sizeof(struct necp_kernel_ip_output_policy *) * (bucket_allocation_counts[i] + 1), M_NECP, M_WAITOK);
			if (necp_kernel_ip_output_policies_map[i] == NULL) {
				goto fail;
			}

			// Initialize the first entry to NULL
			(necp_kernel_ip_output_policies_map[i])[0] = NULL;
		}
		bucket_current_free_index[i] = 0;
	}

	LIST_FOREACH(kernel_policy, &necp_kernel_ip_output_policies, chain) {
		// Insert pointers into map
		if (!(kernel_policy->condition_mask & NECP_KERNEL_CONDITION_POLICY_ID) ||
		    (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_NETWORKS) ||
		    kernel_policy->result == NECP_KERNEL_POLICY_RESULT_SKIP) {
			for (i = 0; i < NECP_KERNEL_IP_OUTPUT_POLICIES_MAP_NUM_ID_BUCKETS; i++) {
				if (!necp_kernel_ip_output_policy_is_unnecessary(kernel_policy, necp_kernel_ip_output_policies_map[i], bucket_current_free_index[i])) {
					(necp_kernel_ip_output_policies_map[i])[(bucket_current_free_index[i])] = kernel_policy;
					bucket_current_free_index[i]++;
					(necp_kernel_ip_output_policies_map[i])[(bucket_current_free_index[i])] = NULL;
				}
			}
		} else {
			i = NECP_IP_OUTPUT_MAP_ID_TO_BUCKET(kernel_policy->cond_policy_id);
			if (!necp_kernel_ip_output_policy_is_unnecessary(kernel_policy, necp_kernel_ip_output_policies_map[i], bucket_current_free_index[i])) {
				(necp_kernel_ip_output_policies_map[i])[(bucket_current_free_index[i])] = kernel_policy;
				bucket_current_free_index[i]++;
				(necp_kernel_ip_output_policies_map[i])[(bucket_current_free_index[i])] = NULL;
			}
		}
	}
	necp_kernel_ip_output_policies_dump_all();
	return TRUE;

fail:
	// Free memory, reset mask to 0
	necp_kernel_ip_output_policies_condition_mask = 0;
	necp_kernel_ip_output_policies_count = 0;
	necp_kernel_ip_output_policies_non_id_count = 0;
	for (i = 0; i < NECP_KERNEL_IP_OUTPUT_POLICIES_MAP_NUM_ID_BUCKETS; i++) {
		if (necp_kernel_ip_output_policies_map[i] != NULL) {
			FREE(necp_kernel_ip_output_policies_map[i], M_NECP);
			necp_kernel_ip_output_policies_map[i] = NULL;
		}
	}
	return FALSE;
}

// Outbound Policy Matching
// ---------------------
struct substring {
	char *string;
	size_t length;
};

static struct substring
necp_trim_dots_and_stars(char *string, size_t length)
{
	struct substring sub;
	sub.string = string;
	sub.length = string ? length : 0;

	while (sub.length && (sub.string[0] == '.' || sub.string[0] == '*')) {
		sub.string++;
		sub.length--;
	}

	while (sub.length && (sub.string[sub.length - 1] == '.' || sub.string[sub.length - 1] == '*')) {
		sub.length--;
	}

	return sub;
}

static char *
necp_create_trimmed_domain(char *string, size_t length)
{
	char *trimmed_domain = NULL;
	struct substring sub = necp_trim_dots_and_stars(string, length);

	MALLOC(trimmed_domain, char *, sub.length + 1, M_NECP, M_WAITOK);
	if (trimmed_domain == NULL) {
		return NULL;
	}

	memcpy(trimmed_domain, sub.string, sub.length);
	trimmed_domain[sub.length] = 0;

	return trimmed_domain;
}

static inline int
necp_count_dots(char *string, size_t length)
{
	int dot_count = 0;
	size_t i = 0;

	for (i = 0; i < length; i++) {
		if (string[i] == '.') {
			dot_count++;
		}
	}

	return dot_count;
}

static bool
necp_check_suffix(struct substring parent, struct substring suffix, bool require_dot_before_suffix)
{
	if (parent.length <= suffix.length) {
		return FALSE;
	}

	size_t length_difference = (parent.length - suffix.length);

	if (require_dot_before_suffix) {
		if (((char *)(parent.string + length_difference - 1))[0] != '.') {
			return FALSE;
		}
	}

	// strncasecmp does case-insensitive check for all UTF-8 strings (ignores non-ASCII characters)
	return strncasecmp(parent.string + length_difference, suffix.string, suffix.length) == 0;
}

static bool
necp_hostname_matches_domain(struct substring hostname_substring, u_int8_t hostname_dot_count, char *domain, u_int8_t domain_dot_count)
{
	if (hostname_substring.string == NULL || domain == NULL) {
		return hostname_substring.string == domain;
	}

	struct substring domain_substring;
	domain_substring.string = domain;
	domain_substring.length = strlen(domain);

	if (hostname_dot_count == domain_dot_count) {
		// strncasecmp does case-insensitive check for all UTF-8 strings (ignores non-ASCII characters)
		if (hostname_substring.length == domain_substring.length &&
		    strncasecmp(hostname_substring.string, domain_substring.string, hostname_substring.length) == 0) {
			return TRUE;
		}
	} else if (domain_dot_count < hostname_dot_count) {
		if (necp_check_suffix(hostname_substring, domain_substring, TRUE)) {
			return TRUE;
		}
	}

	return FALSE;
}

bool
net_domain_contains_hostname(char *hostname_string, char *domain_string)
{
	if (hostname_string == NULL ||
	    domain_string == NULL) {
		return false;
	}

	struct substring hostname_substring;
	hostname_substring.string = hostname_string;
	hostname_substring.length = strlen(hostname_string);

	return necp_hostname_matches_domain(hostname_substring,
	           necp_count_dots(hostname_string, hostname_substring.length),
	           domain_string,
	           necp_count_dots(domain_string, strlen(domain_string)));
}

#define NECP_MAX_STRING_LEN 1024

static char *
necp_copy_string(char *string, size_t length)
{
	char *copied_string = NULL;

	if (length > NECP_MAX_STRING_LEN) {
		return NULL;
	}

	MALLOC(copied_string, char *, length + 1, M_NECP, M_WAITOK);
	if (copied_string == NULL) {
		return NULL;
	}

	memcpy(copied_string, string, length);
	copied_string[length] = 0;

	return copied_string;
}

static u_int32_t
necp_get_primary_direct_interface_index(void)
{
	u_int32_t interface_index = IFSCOPE_NONE;

	ifnet_head_lock_shared();
	struct ifnet *ordered_interface = NULL;
	TAILQ_FOREACH(ordered_interface, &ifnet_ordered_head, if_ordered_link) {
		const u_int8_t functional_type = if_functional_type(ordered_interface, TRUE);
		if (functional_type != IFRTYPE_FUNCTIONAL_UNKNOWN &&
		    functional_type != IFRTYPE_FUNCTIONAL_LOOPBACK) {
			// All known, non-loopback functional types represent direct physical interfaces (Wi-Fi, Cellular, Wired)
			interface_index = ordered_interface->if_index;
			break;
		}
	}
	ifnet_head_done();

	return interface_index;
}

static inline void
necp_get_parent_cred_result(proc_t proc, struct necp_socket_info *info)
{
	task_t task = proc_task(proc ? proc : current_proc());
	coalition_t coal = task_get_coalition(task, COALITION_TYPE_JETSAM);

	if (coal == COALITION_NULL || coalition_is_leader(task, coal)) {
		// No parent, nothing to do
		return;
	}

	task_t lead_task = coalition_get_leader(coal);
	if (lead_task != NULL) {
		proc_t lead_proc = get_bsdtask_info(lead_task);
		if (lead_proc != NULL) {
			kauth_cred_t lead_cred = kauth_cred_proc_ref(lead_proc);
			if (lead_cred != NULL) {
				errno_t cred_result = priv_check_cred(lead_cred, PRIV_NET_PRIVILEGED_NECP_MATCH, 0);
				kauth_cred_unref(&lead_cred);
				info->cred_result = cred_result;
			}
		}
		task_deallocate(lead_task);
	}
}

#define NECP_KERNEL_ADDRESS_TYPE_CONDITIONS (NECP_KERNEL_CONDITION_LOCAL_START | NECP_KERNEL_CONDITION_LOCAL_END | NECP_KERNEL_CONDITION_LOCAL_PREFIX | NECP_KERNEL_CONDITION_REMOTE_START | NECP_KERNEL_CONDITION_REMOTE_END | NECP_KERNEL_CONDITION_REMOTE_PREFIX | NECP_KERNEL_CONDITION_LOCAL_EMPTY | NECP_KERNEL_CONDITION_REMOTE_EMPTY | NECP_KERNEL_CONDITION_LOCAL_NETWORKS)
static void
necp_application_fillout_info_locked(uuid_t application_uuid, uuid_t real_application_uuid, char *account, char *domain, pid_t pid, uid_t uid, u_int16_t protocol, u_int32_t bound_interface_index, u_int32_t traffic_class, union necp_sockaddr_union *local_addr, union necp_sockaddr_union *remote_addr, u_int16_t local_port, u_int16_t remote_port, bool has_client, proc_t proc, u_int32_t drop_order, u_int32_t client_flags, struct necp_socket_info *info)
{
	memset(info, 0, sizeof(struct necp_socket_info));

	info->pid = pid;
	info->uid = uid;
	info->protocol = protocol;
	info->bound_interface_index = bound_interface_index;
	info->traffic_class = traffic_class;
	info->has_client = has_client;
	info->drop_order = drop_order;
	info->client_flags = client_flags;

	if (necp_kernel_application_policies_condition_mask & NECP_KERNEL_CONDITION_ENTITLEMENT && proc != NULL) {
		info->cred_result = priv_check_cred(proc_ucred(proc), PRIV_NET_PRIVILEGED_NECP_MATCH, 0);
		if (info->cred_result != 0) {
			// Process does not have entitlement, check the parent process
			necp_get_parent_cred_result(proc, info);
		}
	}

	if (necp_kernel_application_policies_condition_mask & NECP_KERNEL_CONDITION_PLATFORM_BINARY && proc != NULL) {
		info->is_platform_binary = csproc_get_platform_binary(proc) ? true : false;
	}

	if (necp_kernel_application_policies_condition_mask & NECP_KERNEL_CONDITION_APP_ID && !uuid_is_null(application_uuid)) {
		struct necp_uuid_id_mapping *existing_mapping = necp_uuid_lookup_app_id_locked(application_uuid);
		if (existing_mapping) {
			info->application_id = existing_mapping->id;
		}
	}

	if (necp_kernel_application_policies_condition_mask & NECP_KERNEL_CONDITION_REAL_APP_ID && !uuid_is_null(real_application_uuid)) {
		if (uuid_compare(application_uuid, real_application_uuid) == 0) {
			info->real_application_id = info->application_id;
		} else {
			struct necp_uuid_id_mapping *existing_mapping = necp_uuid_lookup_app_id_locked(real_application_uuid);
			if (existing_mapping) {
				info->real_application_id = existing_mapping->id;
			}
		}
	}

	if (necp_kernel_application_policies_condition_mask & NECP_KERNEL_CONDITION_ACCOUNT_ID && account != NULL) {
		struct necp_string_id_mapping *existing_mapping = necp_lookup_string_to_id_locked(&necp_account_id_list, account);
		if (existing_mapping) {
			info->account_id = existing_mapping->id;
		}
	}

	if (necp_kernel_application_policies_condition_mask & NECP_KERNEL_CONDITION_DOMAIN) {
		info->domain = domain;
	}

	if (necp_kernel_application_policies_condition_mask & NECP_KERNEL_ADDRESS_TYPE_CONDITIONS) {
		if (local_addr && local_addr->sa.sa_len > 0) {
			memcpy(&info->local_addr, local_addr, local_addr->sa.sa_len);
			if (local_port != 0) {
				info->local_addr.sin6.sin6_port = local_port;
			}
		} else if (local_port != 0) {
			info->local_addr.sin6.sin6_len = sizeof(struct sockaddr_in6);
			info->local_addr.sin6.sin6_family = AF_INET6;
			info->local_addr.sin6.sin6_port = local_port;
		}
		if (remote_addr && remote_addr->sa.sa_len > 0) {
			memcpy(&info->remote_addr, remote_addr, remote_addr->sa.sa_len);
			if (remote_port != 0) {
				info->remote_addr.sin6.sin6_port = remote_port;
			}
		} else if (remote_port != 0) {
			info->remote_addr.sin6.sin6_len = sizeof(struct sockaddr_in6);
			info->remote_addr.sin6.sin6_family = AF_INET6;
			info->remote_addr.sin6.sin6_port = remote_port;
		}
	}
}

static void
necp_send_application_interface_denied_event(pid_t pid, uuid_t proc_uuid, u_int32_t if_functional_type)
{
	struct kev_netpolicy_ifdenied ev_ifdenied;

	bzero(&ev_ifdenied, sizeof(ev_ifdenied));

	ev_ifdenied.ev_data.epid = pid;
	uuid_copy(ev_ifdenied.ev_data.euuid, proc_uuid);
	ev_ifdenied.ev_if_functional_type = if_functional_type;

	netpolicy_post_msg(KEV_NETPOLICY_IFDENIED, &ev_ifdenied.ev_data, sizeof(ev_ifdenied));
}

extern char *proc_name_address(void *p);

#define NECP_VERIFY_DELEGATION_ENTITLEMENT(_p, _d) \
	if (!has_checked_delegation_entitlement) { \
	        has_delegation_entitlement = (priv_check_cred(proc_ucred(_p), PRIV_NET_PRIVILEGED_SOCKET_DELEGATE, 0) == 0); \
	        has_checked_delegation_entitlement = TRUE; \
	} \
	if (!has_delegation_entitlement) { \
	        NECPLOG(LOG_ERR, "%s(%d) does not hold the necessary entitlement to delegate network traffic for other processes by %s", \
	                                          proc_name_address(_p), proc_pid(_p), _d); \
	        break; \
	}

int
necp_application_find_policy_match_internal(proc_t proc,
    u_int8_t *parameters,
    u_int32_t parameters_size,
    struct necp_aggregate_result *returned_result,
    u_int32_t *flags,
    u_int32_t *reason,
    u_int required_interface_index,
    const union necp_sockaddr_union *override_local_addr,
    const union necp_sockaddr_union *override_remote_addr,
    struct necp_client_endpoint *returned_v4_gateway,
    struct necp_client_endpoint *returned_v6_gateway,
    struct rtentry **returned_route, bool ignore_address,
    bool has_client)
{
	int error = 0;
	size_t offset = 0;

	struct necp_kernel_socket_policy *matched_policy = NULL;
	struct necp_socket_info info;
	necp_kernel_policy_filter filter_control_unit = 0;
	necp_kernel_policy_result service_action = 0;
	necp_kernel_policy_service service = { 0, 0 };

	u_int16_t protocol = 0;
	u_int32_t bound_interface_index = required_interface_index;
	u_int32_t traffic_class = 0;
	u_int32_t client_flags = 0;
	union necp_sockaddr_union local_addr;
	union necp_sockaddr_union remote_addr;
	bool no_remote_addr = FALSE;
	u_int8_t remote_family = 0;
	bool no_local_addr = FALSE;
	u_int16_t local_port = 0;
	u_int16_t remote_port = 0;
	necp_drop_all_bypass_check_result_t drop_all_bypass = NECP_DROP_ALL_BYPASS_CHECK_RESULT_NONE;

	if (override_local_addr) {
		memcpy(&local_addr, override_local_addr, sizeof(local_addr));
	} else {
		memset(&local_addr, 0, sizeof(local_addr));
	}
	if (override_remote_addr) {
		memcpy(&remote_addr, override_remote_addr, sizeof(remote_addr));
	} else {
		memset(&remote_addr, 0, sizeof(remote_addr));
	}

	// Initialize UID, PID, and UUIDs to the current process
	uid_t uid = kauth_cred_getuid(proc_ucred(proc));
	pid_t pid = proc_pid(proc);
	uuid_t application_uuid;
	uuid_clear(application_uuid);
	uuid_t real_application_uuid;
	uuid_clear(real_application_uuid);
	proc_getexecutableuuid(proc, real_application_uuid, sizeof(real_application_uuid));
	uuid_copy(application_uuid, real_application_uuid);

	char *domain = NULL;
	char *account = NULL;

#define NECP_MAX_REQUIRED_AGENTS 16
	u_int32_t num_required_agent_types = 0;
	struct necp_client_parameter_netagent_type required_agent_types[NECP_MAX_REQUIRED_AGENTS];
	memset(&required_agent_types, 0, sizeof(required_agent_types));

	u_int32_t netagent_ids[NECP_MAX_NETAGENTS];
	u_int32_t netagent_use_flags[NECP_MAX_NETAGENTS];
	memset(&netagent_ids, 0, sizeof(netagent_ids));
	memset(&netagent_use_flags, 0, sizeof(netagent_use_flags));
	int netagent_cursor;

	bool has_checked_delegation_entitlement = FALSE;
	bool has_delegation_entitlement = FALSE;

	if (returned_result == NULL) {
		return EINVAL;
	}

	if (returned_v4_gateway != NULL) {
		memset(returned_v4_gateway, 0, sizeof(struct necp_client_endpoint));
	}

	if (returned_v6_gateway != NULL) {
		memset(returned_v6_gateway, 0, sizeof(struct necp_client_endpoint));
	}

	memset(returned_result, 0, sizeof(struct necp_aggregate_result));

	u_int32_t drop_order = necp_process_drop_order(proc_ucred(proc));

	necp_kernel_policy_result drop_dest_policy_result = NECP_KERNEL_POLICY_RESULT_NONE;

	lck_rw_lock_shared(&necp_kernel_policy_lock);
	if (necp_kernel_application_policies_count == 0) {
		if (necp_drop_all_order > 0 || drop_order > 0) {
			returned_result->routing_result = NECP_KERNEL_POLICY_RESULT_DROP;
			lck_rw_done(&necp_kernel_policy_lock);
			return 0;
		}
	}
	lck_rw_done(&necp_kernel_policy_lock);

	while ((offset + sizeof(u_int8_t) + sizeof(u_int32_t)) <= parameters_size) {
		u_int8_t type = necp_buffer_get_tlv_type(parameters, offset);
		u_int32_t length = necp_buffer_get_tlv_length(parameters, offset);

		if (length > (parameters_size - (offset + sizeof(u_int8_t) + sizeof(u_int32_t)))) {
			// If the length is larger than what can fit in the remaining parameters size, bail
			NECPLOG(LOG_ERR, "Invalid TLV length (%u)", length);
			break;
		}

		if (length > 0) {
			u_int8_t *value = necp_buffer_get_tlv_value(parameters, offset, NULL);
			if (value != NULL) {
				switch (type) {
				case NECP_CLIENT_PARAMETER_APPLICATION: {
					if (length >= sizeof(uuid_t)) {
						if (uuid_compare(application_uuid, value) == 0) {
							// No delegation
							break;
						}

						NECP_VERIFY_DELEGATION_ENTITLEMENT(proc, "euuid");

						uuid_copy(application_uuid, value);
					}
					break;
				}
				case NECP_CLIENT_PARAMETER_REAL_APPLICATION: {
					if (length >= sizeof(uuid_t)) {
						if (uuid_compare(real_application_uuid, value) == 0) {
							// No delegation
							break;
						}

						NECP_VERIFY_DELEGATION_ENTITLEMENT(proc, "uuid");

						uuid_copy(real_application_uuid, value);
					}
					break;
				}
				case NECP_CLIENT_PARAMETER_PID: {
					if (length >= sizeof(pid_t)) {
						if (memcmp(&pid, value, sizeof(pid_t)) == 0) {
							// No delegation
							break;
						}

						NECP_VERIFY_DELEGATION_ENTITLEMENT(proc, "pid");

						memcpy(&pid, value, sizeof(pid_t));
					}
					break;
				}
				case NECP_CLIENT_PARAMETER_UID: {
					if (length >= sizeof(uid_t)) {
						if (memcmp(&uid, value, sizeof(uid_t)) == 0) {
							// No delegation
							break;
						}

						NECP_VERIFY_DELEGATION_ENTITLEMENT(proc, "uid");

						memcpy(&uid, value, sizeof(uid_t));
					}
					break;
				}
				case NECP_CLIENT_PARAMETER_DOMAIN: {
					domain = (char *)value;
					domain[length - 1] = 0;
					break;
				}
				case NECP_CLIENT_PARAMETER_ACCOUNT: {
					account = (char *)value;
					account[length - 1] = 0;
					break;
				}
				case NECP_CLIENT_PARAMETER_TRAFFIC_CLASS: {
					if (length >= sizeof(u_int32_t)) {
						memcpy(&traffic_class, value, sizeof(u_int32_t));
					}
					break;
				}
				case NECP_CLIENT_PARAMETER_IP_PROTOCOL: {
					if (length >= sizeof(u_int16_t)) {
						memcpy(&protocol, value, sizeof(u_int16_t));
					} else if (length >= sizeof(u_int8_t)) {
						memcpy(&protocol, value, sizeof(u_int8_t));
					}
					break;
				}
				case NECP_CLIENT_PARAMETER_BOUND_INTERFACE: {
					if (length <= IFXNAMSIZ && length > 0) {
						ifnet_t bound_interface = NULL;
						char interface_name[IFXNAMSIZ];
						memcpy(interface_name, value, length);
						interface_name[length - 1] = 0;         // Make sure the string is NULL terminated
						if (ifnet_find_by_name(interface_name, &bound_interface) == 0) {
							bound_interface_index = bound_interface->if_index;
							ifnet_release(bound_interface);
						}
					}
					break;
				}
				case NECP_CLIENT_PARAMETER_LOCAL_ADDRESS: {
					if (ignore_address || override_local_addr) {
						break;
					}

					if (length >= sizeof(struct necp_policy_condition_addr)) {
						struct necp_policy_condition_addr *address_struct = (struct necp_policy_condition_addr *)(void *)value;
						if (necp_address_is_valid(&address_struct->address.sa)) {
							memcpy(&local_addr, &address_struct->address, sizeof(address_struct->address));
						}
					}
					break;
				}
				case NECP_CLIENT_PARAMETER_REMOTE_ADDRESS: {
					if (ignore_address || override_remote_addr) {
						break;
					}

					if (length >= sizeof(struct necp_policy_condition_addr)) {
						struct necp_policy_condition_addr *address_struct = (struct necp_policy_condition_addr *)(void *)value;
						if (necp_address_is_valid(&address_struct->address.sa)) {
							memcpy(&remote_addr, &address_struct->address, sizeof(address_struct->address));
						}
					}
					break;
				}
				case NECP_CLIENT_PARAMETER_LOCAL_ENDPOINT: {
					if (ignore_address || override_local_addr) {
						break;
					}

					if (length >= sizeof(struct necp_client_endpoint)) {
						struct necp_client_endpoint *endpoint = (struct necp_client_endpoint *)(void *)value;
						if (endpoint->u.endpoint.endpoint_family == AF_UNSPEC &&
						    endpoint->u.endpoint.endpoint_port != 0) {
							// Save port
							local_port = endpoint->u.endpoint.endpoint_port;
						}
					}
					break;
				}
				case NECP_CLIENT_PARAMETER_REMOTE_ENDPOINT: {
					if (ignore_address || override_remote_addr) {
						break;
					}

					if (length >= sizeof(struct necp_client_endpoint)) {
						struct necp_client_endpoint *endpoint = (struct necp_client_endpoint *)(void *)value;
						if (endpoint->u.endpoint.endpoint_family == AF_UNSPEC &&
						    endpoint->u.endpoint.endpoint_port != 0) {
							// Save port
							remote_port = endpoint->u.endpoint.endpoint_port;
						}
					}
					break;
				}
				case NECP_CLIENT_PARAMETER_FLAGS: {
					if (length >= sizeof(client_flags)) {
						memcpy(&client_flags, value, sizeof(client_flags));
					}
					break;
				}
				case NECP_CLIENT_PARAMETER_REQUIRE_AGENT_TYPE:
				case NECP_CLIENT_PARAMETER_PREFER_AGENT_TYPE: {
					if (num_required_agent_types >= NECP_MAX_REQUIRED_AGENTS) {
						break;
					}
					if (length >= sizeof(struct necp_client_parameter_netagent_type)) {
						memcpy(&required_agent_types[num_required_agent_types], value, sizeof(struct necp_client_parameter_netagent_type));
						num_required_agent_types++;
					}
					break;
				}
				default: {
					break;
				}
				}
			}
		}

		offset += sizeof(u_int8_t) + sizeof(u_int32_t) + length;
	}

	// Check for loopback exception
	if (necp_pass_loopback > 0 && necp_is_loopback(&local_addr.sa, &remote_addr.sa, NULL, NULL, bound_interface_index)) {
		returned_result->policy_id = NECP_KERNEL_POLICY_ID_NO_MATCH;
		returned_result->routing_result = NECP_KERNEL_POLICY_RESULT_PASS;
		returned_result->routed_interface_index = lo_ifp->if_index;
		*flags |= (NECP_CLIENT_RESULT_FLAG_IS_LOCAL | NECP_CLIENT_RESULT_FLAG_IS_DIRECT);
		return 0;
	}

	// Lock
	lck_rw_lock_shared(&necp_kernel_policy_lock);

	u_int32_t route_rule_id_array[MAX_AGGREGATE_ROUTE_RULES];
	size_t route_rule_id_array_count = 0;
	necp_application_fillout_info_locked(application_uuid, real_application_uuid, account, domain, pid, uid, protocol, bound_interface_index, traffic_class, &local_addr, &remote_addr, local_port, remote_port, has_client, proc, drop_order, client_flags, &info);
	matched_policy = necp_socket_find_policy_match_with_info_locked(necp_kernel_socket_policies_app_layer_map, &info, &filter_control_unit, route_rule_id_array, &route_rule_id_array_count, MAX_AGGREGATE_ROUTE_RULES, &service_action, &service, netagent_ids, netagent_use_flags, NECP_MAX_NETAGENTS, required_agent_types, num_required_agent_types, proc, NULL, NULL, &drop_dest_policy_result, &drop_all_bypass);
	if (matched_policy) {
		returned_result->policy_id = matched_policy->id;
		returned_result->routing_result = matched_policy->result;
		memcpy(&returned_result->routing_result_parameter, &matched_policy->result_parameter, sizeof(returned_result->routing_result_parameter));
	} else {
		bool drop_all = false;
		if (necp_drop_all_order > 0 || info.drop_order > 0 || drop_dest_policy_result == NECP_KERNEL_POLICY_RESULT_DROP) {
			// Mark socket as a drop if drop_all is set
			drop_all = true;
			if (drop_all_bypass == NECP_DROP_ALL_BYPASS_CHECK_RESULT_NONE) {
				drop_all_bypass = necp_check_drop_all_bypass_result(proc);
			}
		}
		if (drop_all && drop_all_bypass == NECP_DROP_ALL_BYPASS_CHECK_RESULT_FALSE) {
			returned_result->policy_id = NECP_KERNEL_POLICY_ID_NO_MATCH;
			returned_result->routing_result = NECP_KERNEL_POLICY_RESULT_DROP;
		} else {
			returned_result->policy_id = 0;
			returned_result->routing_result = NECP_KERNEL_POLICY_RESULT_NONE;
		}
	}
	if (filter_control_unit == NECP_FILTER_UNIT_NO_FILTER) {
		returned_result->filter_control_unit = 0;
	} else {
		returned_result->filter_control_unit = filter_control_unit;
	}
	returned_result->service_action = service_action;

	// Handle trigger service
	if (service.identifier != 0) {
		struct necp_uuid_id_mapping *mapping = necp_uuid_lookup_uuid_with_service_id_locked(service.identifier);
		if (mapping != NULL) {
			struct necp_service_registration *service_registration = NULL;
			uuid_copy(returned_result->service_uuid, mapping->uuid);
			returned_result->service_data = service.data;
			if (service.identifier == NECP_NULL_SERVICE_ID) {
				// NULL service is always 'registered'
				returned_result->service_flags |= NECP_SERVICE_FLAGS_REGISTERED;
			} else {
				LIST_FOREACH(service_registration, &necp_registered_service_list, kernel_chain) {
					if (service.identifier == service_registration->service_id) {
						returned_result->service_flags |= NECP_SERVICE_FLAGS_REGISTERED;
						break;
					}
				}
			}
		}
	}

	// Handle netagents
	for (netagent_cursor = 0; netagent_cursor < NECP_MAX_NETAGENTS; netagent_cursor++) {
		struct necp_uuid_id_mapping *mapping = NULL;
		u_int32_t netagent_id = netagent_ids[netagent_cursor];
		if (netagent_id == 0) {
			break;
		}
		mapping = necp_uuid_lookup_uuid_with_service_id_locked(netagent_id);
		if (mapping != NULL) {
			uuid_copy(returned_result->netagents[netagent_cursor], mapping->uuid);
			returned_result->netagent_use_flags[netagent_cursor] = netagent_use_flags[netagent_cursor];
		}
	}

	// Do routing evaluation
	u_int output_bound_interface = bound_interface_index;
	if (returned_result->routing_result == NECP_KERNEL_POLICY_RESULT_SOCKET_SCOPED) {
		output_bound_interface = returned_result->routing_result_parameter.scoped_interface_index;
	} else if (returned_result->routing_result == NECP_KERNEL_POLICY_RESULT_IP_TUNNEL) {
		output_bound_interface = returned_result->routing_result_parameter.tunnel_interface_index;
	} else if (returned_result->routing_result == NECP_KERNEL_POLICY_RESULT_SCOPED_DIRECT) {
		output_bound_interface = necp_get_primary_direct_interface_index();
		if (output_bound_interface == IFSCOPE_NONE) {
			returned_result->routing_result = NECP_KERNEL_POLICY_RESULT_DROP;
		} else {
			returned_result->routing_result = NECP_KERNEL_POLICY_RESULT_SOCKET_SCOPED;
			returned_result->routing_result_parameter.scoped_interface_index = output_bound_interface;
		}
	}

	if (local_addr.sa.sa_len == 0 ||
	    (local_addr.sa.sa_family == AF_INET && local_addr.sin.sin_addr.s_addr == 0) ||
	    (local_addr.sa.sa_family == AF_INET6 && IN6_IS_ADDR_UNSPECIFIED(&local_addr.sin6.sin6_addr))) {
		no_local_addr = TRUE;
	}

	if (remote_addr.sa.sa_len == 0 ||
	    (remote_addr.sa.sa_family == AF_INET && remote_addr.sin.sin_addr.s_addr == 0) ||
	    (remote_addr.sa.sa_family == AF_INET6 && IN6_IS_ADDR_UNSPECIFIED(&remote_addr.sin6.sin6_addr))) {
		no_remote_addr = TRUE;
		remote_family = remote_addr.sa.sa_family;
	}

	returned_result->routed_interface_index = 0;
	struct rtentry *rt = NULL;
	if (!no_local_addr && (client_flags & NECP_CLIENT_PARAMETER_FLAG_LISTENER) != 0) {
		// Treat the output bound interface as the routed interface for local address
		// validation later.
		returned_result->routed_interface_index = output_bound_interface;
	} else {
		if (no_remote_addr) {
			memset(&remote_addr, 0, sizeof(remote_addr));
			if (remote_family == AF_INET6) {
				// Reset address to ::
				remote_addr.sa.sa_family = AF_INET6;
				remote_addr.sa.sa_len = sizeof(struct sockaddr_in6);
			} else {
				// Reset address to 0.0.0.0
				remote_addr.sa.sa_family = AF_INET;
				remote_addr.sa.sa_len = sizeof(struct sockaddr_in);
			}
		}

		rt = rtalloc1_scoped((struct sockaddr *)&remote_addr, 0, 0,
		    output_bound_interface);

		if (remote_addr.sa.sa_family == AF_INET && rt != NULL &&
		    IS_INTF_CLAT46(rt->rt_ifp)) {
			rtfree(rt);
			rt = NULL;
			returned_result->routed_interface_index = 0;
		}

		if (no_remote_addr && remote_family == AF_UNSPEC &&
		    (rt == NULL || rt->rt_ifp == NULL)) {
			// Route lookup for default IPv4 failed, try IPv6

			// Cleanup old route if necessary
			if (rt != NULL) {
				rtfree(rt);
				rt = NULL;
			}

			// Reset address to ::
			memset(&remote_addr, 0, sizeof(remote_addr));
			remote_addr.sa.sa_family = AF_INET6;
			remote_addr.sa.sa_len = sizeof(struct sockaddr_in6);

			// Get route
			rt = rtalloc1_scoped((struct sockaddr *)&remote_addr, 0, 0,
			    output_bound_interface);
		}

		if (rt != NULL &&
		    rt->rt_ifp != NULL) {
			returned_result->routed_interface_index = rt->rt_ifp->if_index;
			/*
			 * For local addresses, we allow the interface scope to be
			 * either the loopback interface or the interface hosting the
			 * local address.
			 */
			if (bound_interface_index != IFSCOPE_NONE &&
			    rt->rt_ifa != NULL && rt->rt_ifa->ifa_ifp &&
			    (output_bound_interface == lo_ifp->if_index ||
			    rt->rt_ifp->if_index == lo_ifp->if_index ||
			    rt->rt_ifa->ifa_ifp->if_index == bound_interface_index)) {
				struct sockaddr_storage dst;
				unsigned int ifscope = bound_interface_index;

				/*
				 * Transform dst into the internal routing table form
				 */
				(void) sa_copy((struct sockaddr *)&remote_addr,
				    &dst, &ifscope);

				if ((rt->rt_ifp->if_index == lo_ifp->if_index) ||
				    rt_ifa_is_dst((struct sockaddr *)&dst, rt->rt_ifa)) {
					returned_result->routed_interface_index =
					    bound_interface_index;
				}
			}
		}
	}

	if (returned_result->routed_interface_index != 0 &&
	    returned_result->routed_interface_index != lo_ifp->if_index &&     // Loopback can accept any local address
	    !no_local_addr) {
		// Transform local_addr into the ifaddr form
		// IPv6 Scope IDs are always embedded in the ifaddr list
		struct sockaddr_storage local_address_sanitized;
		u_int ifscope = IFSCOPE_NONE;
		(void)sa_copy(&local_addr.sa, &local_address_sanitized, &ifscope);
		SIN(&local_address_sanitized)->sin_port = 0;
		if (local_address_sanitized.ss_family == AF_INET6) {
			SIN6(&local_address_sanitized)->sin6_scope_id = 0;
		}

		// Validate local address on routed interface
		struct ifaddr *ifa = ifa_ifwithaddr_scoped((struct sockaddr *)&local_address_sanitized, returned_result->routed_interface_index);
		if (ifa == NULL) {
			// Interface address not found, reject route
			returned_result->routed_interface_index = 0;
			if (rt != NULL) {
				rtfree(rt);
				rt = NULL;
			}
		} else {
			ifaddr_release(ifa);
			ifa = NULL;
		}
	}

	if (flags != NULL) {
		if ((client_flags & NECP_CLIENT_PARAMETER_FLAG_LISTENER) == 0) {
			// Check for local/direct
			bool is_local = FALSE;
			if (rt != NULL && (rt->rt_flags & RTF_LOCAL)) {
				is_local = TRUE;
			} else if (returned_result->routed_interface_index != 0 &&
			    !no_remote_addr) {
				// Clean up the address before comparison with interface addresses

				// Transform remote_addr into the ifaddr form
				// IPv6 Scope IDs are always embedded in the ifaddr list
				struct sockaddr_storage remote_address_sanitized;
				u_int ifscope = IFSCOPE_NONE;
				(void)sa_copy(&remote_addr.sa, &remote_address_sanitized, &ifscope);
				SIN(&remote_address_sanitized)->sin_port = 0;
				if (remote_address_sanitized.ss_family == AF_INET6) {
					SIN6(&remote_address_sanitized)->sin6_scope_id = 0;
				}

				// Check if remote address is an interface address
				struct ifaddr *ifa = ifa_ifwithaddr((struct sockaddr *)&remote_address_sanitized);
				if (ifa != NULL && ifa->ifa_ifp != NULL) {
					u_int if_index_for_remote_addr = ifa->ifa_ifp->if_index;
					if (if_index_for_remote_addr == returned_result->routed_interface_index ||
					    if_index_for_remote_addr == lo_ifp->if_index) {
						is_local = TRUE;
					}
				}
				if (ifa != NULL) {
					ifaddr_release(ifa);
					ifa = NULL;
				}
			}

			if (is_local) {
				*flags |= (NECP_CLIENT_RESULT_FLAG_IS_LOCAL | NECP_CLIENT_RESULT_FLAG_IS_DIRECT);
			} else {
				if (rt != NULL &&
				    !(rt->rt_flags & RTF_GATEWAY) &&
				    (rt->rt_ifa && rt->rt_ifa->ifa_ifp && !(rt->rt_ifa->ifa_ifp->if_flags & IFF_POINTOPOINT))) {
					// Route is directly accessible
					*flags |= NECP_CLIENT_RESULT_FLAG_IS_DIRECT;
				}
			}

			if (rt != NULL &&
			    rt->rt_ifp != NULL) {
				// Check probe status
				if (rt->rt_ifp->if_eflags & IFEF_PROBE_CONNECTIVITY) {
					*flags |= NECP_CLIENT_RESULT_FLAG_PROBE_CONNECTIVITY;
				}

				if (rt->rt_ifp->if_type == IFT_CELLULAR) {
					struct if_cellular_status_v1 *ifsr;

					ifnet_lock_shared(rt->rt_ifp);
					lck_rw_lock_exclusive(&rt->rt_ifp->if_link_status_lock);

					if (rt->rt_ifp->if_link_status != NULL) {
						ifsr = &rt->rt_ifp->if_link_status->ifsr_u.ifsr_cell.if_cell_u.if_status_v1;

						if (ifsr->valid_bitmask & IF_CELL_UL_MSS_RECOMMENDED_VALID) {
							if (ifsr->mss_recommended == IF_CELL_UL_MSS_RECOMMENDED_NONE) {
								returned_result->mss_recommended = NECP_CLIENT_RESULT_RECOMMENDED_MSS_NONE;
							} else if (ifsr->mss_recommended == IF_CELL_UL_MSS_RECOMMENDED_MEDIUM) {
								returned_result->mss_recommended = NECP_CLIENT_RESULT_RECOMMENDED_MSS_MEDIUM;
							} else if (ifsr->mss_recommended == IF_CELL_UL_MSS_RECOMMENDED_LOW) {
								returned_result->mss_recommended = NECP_CLIENT_RESULT_RECOMMENDED_MSS_LOW;
							}
						}
					}
					lck_rw_done(&rt->rt_ifp->if_link_status_lock);
					ifnet_lock_done(rt->rt_ifp);
				}

				// Check link quality
				if ((client_flags & NECP_CLIENT_PARAMETER_FLAG_DISCRETIONARY) &&
				    (rt->rt_ifp->if_interface_state.valid_bitmask & IF_INTERFACE_STATE_LQM_STATE_VALID) &&
				    rt->rt_ifp->if_interface_state.lqm_state == IFNET_LQM_THRESH_ABORT) {
					*flags |= NECP_CLIENT_RESULT_FLAG_LINK_QUALITY_ABORT;
				}

				// Check QoS marking (fastlane)
				for (size_t route_rule_index = 0; route_rule_index < route_rule_id_array_count; route_rule_index++) {
					if (necp_update_qos_marking(rt->rt_ifp, route_rule_id_array[route_rule_index])) {
						*flags |= NECP_CLIENT_RESULT_FLAG_ALLOW_QOS_MARKING;
						// If the route can use QoS markings, stop iterating route rules
						break;
					}
				}

				if (IFNET_IS_LOW_POWER(rt->rt_ifp)) {
					*flags |= NECP_CLIENT_RESULT_FLAG_INTERFACE_LOW_POWER;
				}

				if (traffic_class == SO_TC_BK_SYS) {
					// Block BK_SYS traffic if interface is throttled
					u_int32_t throttle_level = 0;
					if (ifnet_get_throttle(rt->rt_ifp, &throttle_level) == 0) {
						if (throttle_level == IFNET_THROTTLE_OPPORTUNISTIC) {
							returned_result->routing_result = NECP_KERNEL_POLICY_RESULT_DROP;
							memset(&returned_result->routing_result_parameter, 0, sizeof(returned_result->routing_result_parameter));
						}
					}
				}
			}
		}

		if (returned_result->routed_interface_index != 0) {
			union necp_sockaddr_union default_address;
			struct rtentry *v4Route = NULL;
			struct rtentry *v6Route = NULL;

			memset(&default_address, 0, sizeof(default_address));

			// Reset address to 0.0.0.0
			default_address.sa.sa_family = AF_INET;
			default_address.sa.sa_len = sizeof(struct sockaddr_in);
			v4Route = rtalloc1_scoped((struct sockaddr *)&default_address, 0, 0,
			    returned_result->routed_interface_index);

			// Reset address to ::
			default_address.sa.sa_family = AF_INET6;
			default_address.sa.sa_len = sizeof(struct sockaddr_in6);
			v6Route = rtalloc1_scoped((struct sockaddr *)&default_address, 0, 0,
			    returned_result->routed_interface_index);

			if (v4Route != NULL) {
				if (v4Route->rt_ifp != NULL && !IS_INTF_CLAT46(v4Route->rt_ifp)) {
					*flags |= NECP_CLIENT_RESULT_FLAG_HAS_IPV4;
				}
				if (returned_v4_gateway != NULL &&
				    v4Route->rt_gateway != NULL &&
				    v4Route->rt_gateway->sa_len == sizeof(returned_v4_gateway->u.sin)) {
					memcpy(&returned_v4_gateway->u.sin, v4Route->rt_gateway, sizeof(returned_v4_gateway->u.sin));
					memset(&returned_v4_gateway->u.sin.sin_zero, 0, sizeof(returned_v4_gateway->u.sin.sin_zero));
				}
				rtfree(v4Route);
				v4Route = NULL;
			}

			if (v6Route != NULL) {
				if (v6Route->rt_ifp != NULL) {
					*flags |= NECP_CLIENT_RESULT_FLAG_HAS_IPV6;

					if (ifnet_get_nat64prefix(v6Route->rt_ifp, NULL) == 0) {
						*flags |= NECP_CLIENT_RESULT_FLAG_HAS_NAT64;
					}
				}
				if (returned_v6_gateway != NULL &&
				    v6Route->rt_gateway != NULL &&
				    v6Route->rt_gateway->sa_len == sizeof(returned_v6_gateway->u.sin6)) {
					memcpy(&returned_v6_gateway->u.sin6, v6Route->rt_gateway, sizeof(returned_v6_gateway->u.sin6));
				}
				rtfree(v6Route);
				v6Route = NULL;
			}
		}
	}

	for (size_t route_rule_index = 0; route_rule_index < route_rule_id_array_count; route_rule_index++) {
		u_int32_t interface_type_denied = IFRTYPE_FUNCTIONAL_UNKNOWN;
		bool route_is_allowed = necp_route_is_allowed(rt, NULL, route_rule_id_array[route_rule_index], &interface_type_denied);
		if (!route_is_allowed) {
			// If the route is blocked, treat the lookup as a drop
			returned_result->routing_result = NECP_KERNEL_POLICY_RESULT_DROP;
			memset(&returned_result->routing_result_parameter, 0, sizeof(returned_result->routing_result_parameter));

			if (interface_type_denied != IFRTYPE_FUNCTIONAL_UNKNOWN) {
				if (reason != NULL) {
					if (interface_type_denied == IFRTYPE_FUNCTIONAL_CELLULAR) {
						*reason = NECP_CLIENT_RESULT_REASON_CELLULAR_DENIED;
					} else if (interface_type_denied == IFRTYPE_FUNCTIONAL_WIFI_INFRA) {
						*reason = NECP_CLIENT_RESULT_REASON_WIFI_DENIED;
					}
				}
				necp_send_application_interface_denied_event(pid, application_uuid, interface_type_denied);
			}
			// If the route gets denied, stop matching rules
			break;
		}
	}

	if (rt != NULL && rt->rt_ifp != NULL) {
		const bool expensive_prohibited = ((client_flags & NECP_CLIENT_PARAMETER_FLAG_PROHIBIT_EXPENSIVE) &&
		    IFNET_IS_EXPENSIVE(rt->rt_ifp));
		const bool constrained_prohibited = ((client_flags & NECP_CLIENT_PARAMETER_FLAG_PROHIBIT_CONSTRAINED) &&
		    IFNET_IS_CONSTRAINED(rt->rt_ifp));
		if (reason != NULL) {
			if (expensive_prohibited) {
				*reason = NECP_CLIENT_RESULT_REASON_EXPENSIVE_PROHIBITED;
			} else if (constrained_prohibited) {
				*reason = NECP_CLIENT_RESULT_REASON_CONSTRAINED_PROHIBITED;
			}
		}
		if (expensive_prohibited || constrained_prohibited) {
			// If the client flags prohibited a property of the interface, treat it as a drop
			returned_result->routing_result = NECP_KERNEL_POLICY_RESULT_DROP;
			memset(&returned_result->routing_result_parameter, 0, sizeof(returned_result->routing_result_parameter));
		}
	}

	if (rt != NULL) {
		if (returned_route != NULL) {
			*returned_route = rt;
		} else {
			rtfree(rt);
		}
		rt = NULL;
	}
	// Unlock
	lck_rw_done(&necp_kernel_policy_lock);

	return error;
}

static bool
necp_is_route_local(union necp_sockaddr_union *remote_addr)
{
	bool no_remote_addr = FALSE;
	u_int8_t remote_family = 0;
	struct rtentry *rt = NULL;
	bool is_local = FALSE;

	if (remote_addr == NULL) {
		return NULL;
	}

	if (remote_addr->sa.sa_len == 0 ||
	    (remote_addr->sa.sa_family == AF_INET && remote_addr->sin.sin_addr.s_addr == 0) ||
	    (remote_addr->sa.sa_family == AF_INET6 && IN6_IS_ADDR_UNSPECIFIED(&remote_addr->sin6.sin6_addr))) {
		no_remote_addr = TRUE;
		remote_family = remote_addr->sa.sa_family;
	}

	if (no_remote_addr) {
		memset(remote_addr, 0, sizeof(union necp_sockaddr_union));
		if (remote_family == AF_INET6) {
			// Reset address to ::
			remote_addr->sa.sa_family = AF_INET6;
			remote_addr->sa.sa_len = sizeof(struct sockaddr_in6);
		} else {
			// Reset address to 0.0.0.0
			remote_addr->sa.sa_family = AF_INET;
			remote_addr->sa.sa_len = sizeof(struct sockaddr_in);
		}
	}

	// Lookup route regardless of the scoped interface to check if
	// remote address is in a local network.
	rt = rtalloc1_scoped((struct sockaddr *)remote_addr, 0, 0, 0);

	if (rt == NULL) {
		goto done;
	}
	if (remote_addr->sa.sa_family == AF_INET && IS_INTF_CLAT46(rt->rt_ifp)) {
		goto free_rt;
	}
	is_local = IS_NECP_DEST_IN_LOCAL_NETWORKS(rt);

free_rt:
	rtfree(rt);

done:
	return is_local;
}

static bool
necp_socket_check_policy(struct necp_kernel_socket_policy *kernel_policy, necp_app_id app_id, necp_app_id real_app_id, errno_t cred_result, u_int32_t account_id, struct substring domain, u_int8_t domain_dot_count, pid_t pid, uid_t uid, u_int32_t bound_interface_index, u_int32_t traffic_class, u_int16_t protocol, union necp_sockaddr_union *local, union necp_sockaddr_union *remote, struct necp_client_parameter_netagent_type *required_agent_types, u_int32_t num_required_agent_types, bool has_client, uint32_t client_flags, int is_platform_binary, proc_t proc, struct rtentry *rt)
{
	if (!(kernel_policy->condition_mask & NECP_KERNEL_CONDITION_ALL_INTERFACES)) {
		if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_BOUND_INTERFACE) {
			u_int32_t cond_bound_interface_index = kernel_policy->cond_bound_interface ? kernel_policy->cond_bound_interface->if_index : 0;
			if (kernel_policy->condition_negated_mask & NECP_KERNEL_CONDITION_BOUND_INTERFACE) {
				if (bound_interface_index == cond_bound_interface_index) {
					// No match, matches forbidden interface
					return FALSE;
				}
			} else {
				if (bound_interface_index != cond_bound_interface_index) {
					// No match, does not match required interface
					return FALSE;
				}
			}
		} else {
			if (bound_interface_index != 0) {
				// No match, requires a non-bound packet
				return FALSE;
			}
		}
	}

	if (kernel_policy->condition_mask == 0) {
		return TRUE;
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_APP_ID) {
		if (kernel_policy->condition_negated_mask & NECP_KERNEL_CONDITION_APP_ID) {
			if (app_id == kernel_policy->cond_app_id) {
				// No match, matches forbidden application
				return FALSE;
			}
		} else {
			if (app_id != kernel_policy->cond_app_id) {
				// No match, does not match required application
				return FALSE;
			}
		}
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_REAL_APP_ID) {
		if (kernel_policy->condition_negated_mask & NECP_KERNEL_CONDITION_REAL_APP_ID) {
			if (real_app_id == kernel_policy->cond_real_app_id) {
				// No match, matches forbidden application
				return FALSE;
			}
		} else {
			if (real_app_id != kernel_policy->cond_real_app_id) {
				// No match, does not match required application
				return FALSE;
			}
		}
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_HAS_CLIENT) {
		if (!has_client) {
			return FALSE;
		}
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_ENTITLEMENT) {
		if (cred_result != 0) {
			// Process is missing entitlement
			return FALSE;
		}
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_PLATFORM_BINARY) {
		if (is_platform_binary == 0) {
			// Process is not platform binary
			return FALSE;
		}
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_CUSTOM_ENTITLEMENT) {
		if (kernel_policy->cond_custom_entitlement_matched == necp_boolean_state_false) {
			// Process is missing entitlement based on previous check
			return FALSE;
		} else if (kernel_policy->cond_custom_entitlement_matched == necp_boolean_state_unknown) {
			if (kernel_policy->cond_custom_entitlement != NULL) {
				if (proc == NULL) {
					// No process found, cannot check entitlement
					return FALSE;
				}
				task_t task = proc_task(proc);
				if (task == NULL ||
				    !IOTaskHasEntitlement(task, kernel_policy->cond_custom_entitlement)) {
					// Process is missing custom entitlement
					kernel_policy->cond_custom_entitlement_matched = necp_boolean_state_false;
					return FALSE;
				} else {
					kernel_policy->cond_custom_entitlement_matched = necp_boolean_state_true;
				}
			}
		}
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_DOMAIN) {
		bool domain_matches = necp_hostname_matches_domain(domain, domain_dot_count, kernel_policy->cond_domain, kernel_policy->cond_domain_dot_count);
		if (kernel_policy->condition_negated_mask & NECP_KERNEL_CONDITION_DOMAIN) {
			if (domain_matches) {
				// No match, matches forbidden domain
				return FALSE;
			}
		} else {
			if (!domain_matches) {
				// No match, does not match required domain
				return FALSE;
			}
		}
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_ACCOUNT_ID) {
		if (kernel_policy->condition_negated_mask & NECP_KERNEL_CONDITION_ACCOUNT_ID) {
			if (account_id == kernel_policy->cond_account_id) {
				// No match, matches forbidden account
				return FALSE;
			}
		} else {
			if (account_id != kernel_policy->cond_account_id) {
				// No match, does not match required account
				return FALSE;
			}
		}
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_PID) {
		if (kernel_policy->condition_negated_mask & NECP_KERNEL_CONDITION_PID) {
			if (pid == kernel_policy->cond_pid) {
				// No match, matches forbidden pid
				return FALSE;
			}
		} else {
			if (pid != kernel_policy->cond_pid) {
				// No match, does not match required pid
				return FALSE;
			}
		}
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_UID) {
		if (kernel_policy->condition_negated_mask & NECP_KERNEL_CONDITION_UID) {
			if (uid == kernel_policy->cond_uid) {
				// No match, matches forbidden uid
				return FALSE;
			}
		} else {
			if (uid != kernel_policy->cond_uid) {
				// No match, does not match required uid
				return FALSE;
			}
		}
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_TRAFFIC_CLASS) {
		if (kernel_policy->condition_negated_mask & NECP_KERNEL_CONDITION_TRAFFIC_CLASS) {
			if (traffic_class >= kernel_policy->cond_traffic_class.start_tc &&
			    traffic_class <= kernel_policy->cond_traffic_class.end_tc) {
				// No match, matches forbidden traffic class
				return FALSE;
			}
		} else {
			if (traffic_class < kernel_policy->cond_traffic_class.start_tc ||
			    traffic_class > kernel_policy->cond_traffic_class.end_tc) {
				// No match, does not match required traffic class
				return FALSE;
			}
		}
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_PROTOCOL) {
		if (kernel_policy->condition_negated_mask & NECP_KERNEL_CONDITION_PROTOCOL) {
			if (protocol == kernel_policy->cond_protocol) {
				// No match, matches forbidden protocol
				return FALSE;
			}
		} else {
			if (protocol != kernel_policy->cond_protocol) {
				// No match, does not match required protocol
				return FALSE;
			}
		}
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_AGENT_TYPE) {
		bool matches_agent_type = FALSE;
		for (u_int32_t i = 0; i < num_required_agent_types; i++) {
			struct necp_client_parameter_netagent_type *required_agent_type = &required_agent_types[i];
			if ((strlen(kernel_policy->cond_agent_type.agent_domain) == 0 ||
			    strncmp(required_agent_type->netagent_domain, kernel_policy->cond_agent_type.agent_domain, NETAGENT_DOMAINSIZE) == 0) &&
			    (strlen(kernel_policy->cond_agent_type.agent_type) == 0 ||
			    strncmp(required_agent_type->netagent_type, kernel_policy->cond_agent_type.agent_type, NETAGENT_TYPESIZE) == 0)) {
				// Found a required agent that matches
				matches_agent_type = TRUE;
				break;
			}
		}
		if (!matches_agent_type) {
			return FALSE;
		}
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_NETWORKS) {
		bool is_local = FALSE;

		if (rt != NULL) {
			is_local = IS_NECP_DEST_IN_LOCAL_NETWORKS(rt);
		} else {
			is_local = necp_is_route_local(remote);
		}

		if (!is_local) {
			// Either no route to validate or no match for local networks
			return FALSE;
		}
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_START) {
		if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_END) {
			bool inRange = necp_is_addr_in_range((struct sockaddr *)local, (struct sockaddr *)&kernel_policy->cond_local_start, (struct sockaddr *)&kernel_policy->cond_local_end);
			if (kernel_policy->condition_negated_mask & NECP_KERNEL_CONDITION_LOCAL_END) {
				if (inRange) {
					return FALSE;
				}
			} else {
				if (!inRange) {
					return FALSE;
				}
			}
		} else if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_PREFIX) {
			bool inSubnet = necp_is_addr_in_subnet((struct sockaddr *)local, (struct sockaddr *)&kernel_policy->cond_local_start, kernel_policy->cond_local_prefix);
			if (kernel_policy->condition_negated_mask & NECP_KERNEL_CONDITION_LOCAL_PREFIX) {
				if (inSubnet) {
					return FALSE;
				}
			} else {
				if (!inSubnet) {
					return FALSE;
				}
			}
		}
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_REMOTE_START) {
		if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_REMOTE_END) {
			bool inRange = necp_is_addr_in_range((struct sockaddr *)remote, (struct sockaddr *)&kernel_policy->cond_remote_start, (struct sockaddr *)&kernel_policy->cond_remote_end);
			if (kernel_policy->condition_negated_mask & NECP_KERNEL_CONDITION_REMOTE_END) {
				if (inRange) {
					return FALSE;
				}
			} else {
				if (!inRange) {
					return FALSE;
				}
			}
		} else if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_REMOTE_PREFIX) {
			bool inSubnet = necp_is_addr_in_subnet((struct sockaddr *)remote, (struct sockaddr *)&kernel_policy->cond_remote_start, kernel_policy->cond_remote_prefix);
			if (kernel_policy->condition_negated_mask & NECP_KERNEL_CONDITION_REMOTE_PREFIX) {
				if (inSubnet) {
					return FALSE;
				}
			} else {
				if (!inSubnet) {
					return FALSE;
				}
			}
		}
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_CLIENT_FLAGS) {
		if (kernel_policy->condition_negated_mask & NECP_KERNEL_CONDITION_CLIENT_FLAGS) {
			if ((client_flags & kernel_policy->cond_client_flags) == kernel_policy->cond_client_flags) {
				// Flags do match, and condition is negative, fail.
				return FALSE;
			}
		} else {
			if ((client_flags & kernel_policy->cond_client_flags) != kernel_policy->cond_client_flags) {
				// Flags do not match, fail.
				return FALSE;
			}
		}
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_EMPTY) {
		bool isEmpty = necp_addr_is_empty((struct sockaddr *)local);
		if (kernel_policy->condition_negated_mask & NECP_KERNEL_CONDITION_LOCAL_EMPTY) {
			if (isEmpty) {
				return FALSE;
			}
		} else {
			if (!isEmpty) {
				return FALSE;
			}
		}
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_REMOTE_EMPTY) {
		bool isEmpty = necp_addr_is_empty((struct sockaddr *)remote);
		if (kernel_policy->condition_negated_mask & NECP_KERNEL_CONDITION_REMOTE_EMPTY) {
			if (isEmpty) {
				return FALSE;
			}
		} else {
			if (!isEmpty) {
				return FALSE;
			}
		}
	}

	return TRUE;
}

static inline u_int32_t
necp_socket_calc_flowhash_locked(struct necp_socket_info *info)
{
	return net_flowhash(info, sizeof(*info), necp_kernel_socket_policies_gencount);
}

static void
necp_socket_fillout_info_locked(struct inpcb *inp, struct sockaddr *override_local_addr, struct sockaddr *override_remote_addr, u_int32_t override_bound_interface, u_int32_t drop_order, struct necp_socket_info *info)
{
	struct socket *so = NULL;

	memset(info, 0, sizeof(struct necp_socket_info));

	so = inp->inp_socket;

	info->drop_order = drop_order;

	if (necp_kernel_socket_policies_condition_mask & NECP_KERNEL_CONDITION_PID) {
		info->pid = ((so->so_flags & SOF_DELEGATED) ? so->e_pid : so->last_pid);
	}

	if (necp_kernel_socket_policies_condition_mask & NECP_KERNEL_CONDITION_UID) {
		info->uid = kauth_cred_getuid(so->so_cred);
	}

	if (necp_kernel_socket_policies_condition_mask & NECP_KERNEL_CONDITION_TRAFFIC_CLASS) {
		info->traffic_class = so->so_traffic_class;
	}

	if (necp_kernel_socket_policies_condition_mask & NECP_KERNEL_CONDITION_HAS_CLIENT) {
		info->has_client = !uuid_is_null(inp->necp_client_uuid);
	}

	if (necp_kernel_socket_policies_condition_mask & NECP_KERNEL_CONDITION_CLIENT_FLAGS) {
		info->client_flags = 0;
		if (INP_NO_CONSTRAINED(inp)) {
			info->client_flags |= NECP_CLIENT_PARAMETER_FLAG_PROHIBIT_CONSTRAINED;
		}
		if (INP_NO_EXPENSIVE(inp)) {
			info->client_flags |= NECP_CLIENT_PARAMETER_FLAG_PROHIBIT_EXPENSIVE;
		}
		if (inp->inp_socket->so_flags1 & SOF1_CELLFALLBACK) {
			info->client_flags |= NECP_CLIENT_PARAMETER_FLAG_FALLBACK_TRAFFIC;
		}
		if (inp->inp_socket->so_flags1 & SOF1_INBOUND) {
			info->client_flags |= NECP_CLIENT_PARAMETER_FLAG_INBOUND;
		}
		if (inp->inp_socket->so_options & SO_ACCEPTCONN ||
		    inp->inp_flags2 & INP2_EXTERNAL_PORT) {
			info->client_flags |= NECP_CLIENT_PARAMETER_FLAG_LISTENER;
		}
	}

	if (necp_kernel_socket_policies_condition_mask & NECP_KERNEL_CONDITION_PROTOCOL) {
		if (inp->inp_ip_p) {
			info->protocol = inp->inp_ip_p;
		} else {
			info->protocol = SOCK_PROTO(so);
		}
	}

	if (inp->inp_flags2 & INP2_WANT_APP_POLICY && necp_kernel_socket_policies_condition_mask & NECP_KERNEL_CONDITION_APP_ID) {
		struct necp_uuid_id_mapping *existing_mapping = necp_uuid_lookup_app_id_locked(((so->so_flags & SOF_DELEGATED) ? so->e_uuid : so->last_uuid));
		if (existing_mapping) {
			info->application_id = existing_mapping->id;
		}

		if (!(so->so_flags & SOF_DELEGATED)) {
			info->real_application_id = info->application_id;
		} else if (necp_kernel_socket_policies_condition_mask & NECP_KERNEL_CONDITION_REAL_APP_ID) {
			struct necp_uuid_id_mapping *real_existing_mapping = necp_uuid_lookup_app_id_locked(so->last_uuid);
			if (real_existing_mapping) {
				info->real_application_id = real_existing_mapping->id;
			}
		}

		if (necp_kernel_socket_policies_condition_mask & NECP_KERNEL_CONDITION_ENTITLEMENT) {
			info->cred_result = priv_check_cred(so->so_cred, PRIV_NET_PRIVILEGED_NECP_MATCH, 0);
			if (info->cred_result != 0) {
				// Process does not have entitlement, check the parent process
				necp_get_parent_cred_result(NULL, info);
			}
		}

		if (necp_kernel_socket_policies_condition_mask & NECP_KERNEL_CONDITION_PLATFORM_BINARY) {
			info->is_platform_binary = csproc_get_platform_binary(current_proc()) ? true : false;
		}
	}

	if (necp_kernel_socket_policies_condition_mask & NECP_KERNEL_CONDITION_ACCOUNT_ID && inp->inp_necp_attributes.inp_account != NULL) {
		struct necp_string_id_mapping *existing_mapping = necp_lookup_string_to_id_locked(&necp_account_id_list, inp->inp_necp_attributes.inp_account);
		if (existing_mapping) {
			info->account_id = existing_mapping->id;
		}
	}

	if (necp_kernel_socket_policies_condition_mask & NECP_KERNEL_CONDITION_DOMAIN) {
		info->domain = inp->inp_necp_attributes.inp_domain;
	}

	if (override_bound_interface) {
		info->bound_interface_index = override_bound_interface;
	} else {
		if ((inp->inp_flags & INP_BOUND_IF) && inp->inp_boundifp) {
			info->bound_interface_index = inp->inp_boundifp->if_index;
		}
	}

	if (necp_kernel_socket_policies_condition_mask & NECP_KERNEL_ADDRESS_TYPE_CONDITIONS) {
		if (override_local_addr != NULL) {
			if (override_local_addr->sa_family == AF_INET6 && override_local_addr->sa_len <= sizeof(struct sockaddr_in6)) {
				memcpy(&info->local_addr, override_local_addr, override_local_addr->sa_len);
				if (IN6_IS_ADDR_V4MAPPED(&(info->local_addr.sin6.sin6_addr))) {
					struct sockaddr_in sin;
					in6_sin6_2_sin(&sin, &(info->local_addr.sin6));
					memset(&info->local_addr, 0, sizeof(union necp_sockaddr_union));
					memcpy(&info->local_addr, &sin, sin.sin_len);
				}
			} else if (override_local_addr->sa_family == AF_INET && override_local_addr->sa_len <= sizeof(struct sockaddr_in)) {
				memcpy(&info->local_addr, override_local_addr, override_local_addr->sa_len);
			}
		} else {
			if (inp->inp_vflag & INP_IPV4) {
				((struct sockaddr_in *)&info->local_addr)->sin_family = AF_INET;
				((struct sockaddr_in *)&info->local_addr)->sin_len = sizeof(struct sockaddr_in);
				((struct sockaddr_in *)&info->local_addr)->sin_port = inp->inp_lport;
				memcpy(&((struct sockaddr_in *)&info->local_addr)->sin_addr, &inp->inp_laddr, sizeof(struct in_addr));
			} else if (inp->inp_vflag & INP_IPV6) {
				((struct sockaddr_in6 *)&info->local_addr)->sin6_family = AF_INET6;
				((struct sockaddr_in6 *)&info->local_addr)->sin6_len = sizeof(struct sockaddr_in6);
				((struct sockaddr_in6 *)&info->local_addr)->sin6_port = inp->inp_lport;
				memcpy(&((struct sockaddr_in6 *)&info->local_addr)->sin6_addr, &inp->in6p_laddr, sizeof(struct in6_addr));
			}
		}

		if (override_remote_addr != NULL) {
			if (override_remote_addr->sa_family == AF_INET6 && override_remote_addr->sa_len <= sizeof(struct sockaddr_in6)) {
				memcpy(&info->remote_addr, override_remote_addr, override_remote_addr->sa_len);
				if (IN6_IS_ADDR_V4MAPPED(&(info->remote_addr.sin6.sin6_addr))) {
					struct sockaddr_in sin;
					in6_sin6_2_sin(&sin, &(info->remote_addr.sin6));
					memset(&info->remote_addr, 0, sizeof(union necp_sockaddr_union));
					memcpy(&info->remote_addr, &sin, sin.sin_len);
				}
			} else if (override_remote_addr->sa_family == AF_INET && override_remote_addr->sa_len <= sizeof(struct sockaddr_in)) {
				memcpy(&info->remote_addr, override_remote_addr, override_remote_addr->sa_len);
			}
		} else {
			if (inp->inp_vflag & INP_IPV4) {
				((struct sockaddr_in *)&info->remote_addr)->sin_family = AF_INET;
				((struct sockaddr_in *)&info->remote_addr)->sin_len = sizeof(struct sockaddr_in);
				((struct sockaddr_in *)&info->remote_addr)->sin_port = inp->inp_fport;
				memcpy(&((struct sockaddr_in *)&info->remote_addr)->sin_addr, &inp->inp_faddr, sizeof(struct in_addr));
			} else if (inp->inp_vflag & INP_IPV6) {
				((struct sockaddr_in6 *)&info->remote_addr)->sin6_family = AF_INET6;
				((struct sockaddr_in6 *)&info->remote_addr)->sin6_len = sizeof(struct sockaddr_in6);
				((struct sockaddr_in6 *)&info->remote_addr)->sin6_port = inp->inp_fport;
				memcpy(&((struct sockaddr_in6 *)&info->remote_addr)->sin6_addr, &inp->in6p_faddr, sizeof(struct in6_addr));
			}
		}
	}
}

static inline struct necp_kernel_socket_policy *
necp_socket_find_policy_match_with_info_locked(struct necp_kernel_socket_policy **policy_search_array, struct necp_socket_info *info,
    necp_kernel_policy_filter *return_filter,
    u_int32_t *return_route_rule_id_array, size_t *return_route_rule_id_array_count, size_t route_rule_id_array_count,
    necp_kernel_policy_result *return_service_action, necp_kernel_policy_service *return_service,
    u_int32_t *return_netagent_array, u_int32_t *return_netagent_use_flags_array, size_t netagent_array_count,
    struct necp_client_parameter_netagent_type *required_agent_types,
    u_int32_t num_required_agent_types, proc_t proc, necp_kernel_policy_id *skip_policy_id, struct rtentry *rt,
    necp_kernel_policy_result *return_drop_dest_policy_result, necp_drop_all_bypass_check_result_t *return_drop_all_bypass)
{
	struct necp_kernel_socket_policy *matched_policy = NULL;
	u_int32_t skip_order = 0;
	u_int32_t skip_session_order = 0;
	size_t route_rule_id_count = 0;
	int i;
	size_t netagent_cursor = 0;
	necp_drop_all_bypass_check_result_t drop_all_bypass = NECP_DROP_ALL_BYPASS_CHECK_RESULT_NONE;
	if (return_drop_all_bypass != NULL) {
		*return_drop_all_bypass = drop_all_bypass;
	}

	// Pre-process domain for quick matching
	struct substring domain_substring = necp_trim_dots_and_stars(info->domain, info->domain ? strlen(info->domain) : 0);
	u_int8_t domain_dot_count = necp_count_dots(domain_substring.string, domain_substring.length);

	if (return_filter != NULL) {
		*return_filter = 0;
	}

	if (return_route_rule_id_array_count != NULL) {
		*return_route_rule_id_array_count = 0;
	}

	if (return_service_action != NULL) {
		*return_service_action = 0;
	}

	if (return_service != NULL) {
		return_service->identifier = 0;
		return_service->data = 0;
	}

	// Do not subject layer-2 filter to NECP policies, return a PASS policy
	if (necp_pass_interpose > 0 && info->client_flags & NECP_CLIENT_PARAMETER_FLAG_INTERPOSE) {
		return &pass_policy;
	}

	*return_drop_dest_policy_result = NECP_KERNEL_POLICY_RESULT_NONE;

	if (policy_search_array != NULL) {
		for (i = 0; policy_search_array[i] != NULL; i++) {
			if (necp_drop_all_order != 0 && policy_search_array[i]->session_order >= necp_drop_all_order) {
				// We've hit a drop all rule
				if (drop_all_bypass == NECP_DROP_ALL_BYPASS_CHECK_RESULT_NONE) {
					drop_all_bypass = necp_check_drop_all_bypass_result(proc);
					if (return_drop_all_bypass != NULL) {
						*return_drop_all_bypass = drop_all_bypass;
					}
				}
				if (drop_all_bypass == NECP_DROP_ALL_BYPASS_CHECK_RESULT_FALSE) {
					break;
				}
			}
			if (necp_drop_dest_policy.entry_count != 0 &&
			    necp_address_matches_drop_dest_policy(&info->remote_addr, policy_search_array[i]->session_order)) {
				// We've hit a drop by destination address rule
				*return_drop_dest_policy_result = NECP_KERNEL_POLICY_RESULT_DROP;
				break;
			}
			if (info->drop_order != 0 && policy_search_array[i]->session_order >= info->drop_order) {
				// We've hit a drop order for this socket
				break;
			}
			if (skip_session_order && policy_search_array[i]->session_order >= skip_session_order) {
				// Done skipping
				skip_order = 0;
				skip_session_order = 0;
			}
			if (skip_order) {
				if (policy_search_array[i]->order < skip_order) {
					// Skip this policy
					continue;
				} else {
					// Done skipping
					skip_order = 0;
					skip_session_order = 0;
				}
			} else if (skip_session_order) {
				// Skip this policy
				continue;
			}

			if (necp_socket_check_policy(policy_search_array[i], info->application_id, info->real_application_id, info->cred_result, info->account_id, domain_substring, domain_dot_count, info->pid, info->uid, info->bound_interface_index, info->traffic_class, info->protocol, &info->local_addr, &info->remote_addr, required_agent_types, num_required_agent_types, info->has_client, info->client_flags, info->is_platform_binary, proc, rt)) {
				if (policy_search_array[i]->result == NECP_KERNEL_POLICY_RESULT_SOCKET_FILTER) {
					if (return_filter && *return_filter != NECP_FILTER_UNIT_NO_FILTER) {
						necp_kernel_policy_filter control_unit = policy_search_array[i]->result_parameter.filter_control_unit;
						if (control_unit == NECP_FILTER_UNIT_NO_FILTER) {
							*return_filter = control_unit;
						} else {
							*return_filter |= control_unit;
						}
						if (necp_debug > 1) {
							NECPLOG(LOG_DEBUG, "Socket Policy: (Application %d Real Application %d BoundInterface %d Proto %d) Filter %d", info->application_id, info->real_application_id, info->bound_interface_index, info->protocol, policy_search_array[i]->result_parameter.filter_control_unit);
						}
					}
					continue;
				} else if (policy_search_array[i]->result == NECP_KERNEL_POLICY_RESULT_ROUTE_RULES) {
					if (return_route_rule_id_array && route_rule_id_count < route_rule_id_array_count) {
						return_route_rule_id_array[route_rule_id_count++] = policy_search_array[i]->result_parameter.route_rule_id;
						if (necp_debug > 1) {
							NECPLOG(LOG_DEBUG, "Socket Policy: (Application %d Real Application %d BoundInterface %d Proto %d) Route Rule %d", info->application_id, info->real_application_id, info->bound_interface_index, info->protocol, policy_search_array[i]->result_parameter.route_rule_id);
						}
					}
					continue;
				} else if (necp_kernel_socket_result_is_trigger_service_type(policy_search_array[i])) {
					if (return_service_action && *return_service_action == 0) {
						*return_service_action = policy_search_array[i]->result;
						if (necp_debug > 1) {
							NECPLOG(LOG_DEBUG, "Socket Policy: (Application %d Real Application %d BoundInterface %d Proto %d) Service Action %d", info->application_id, info->real_application_id, info->bound_interface_index, info->protocol, policy_search_array[i]->result);
						}
					}
					if (return_service && return_service->identifier == 0) {
						return_service->identifier = policy_search_array[i]->result_parameter.service.identifier;
						return_service->data = policy_search_array[i]->result_parameter.service.data;
						if (necp_debug > 1) {
							NECPLOG(LOG_DEBUG, "Socket Policy: (Application %d Real Application %d BoundInterface %d Proto %d) Service ID %d Data %d", info->application_id, info->real_application_id, info->bound_interface_index, info->protocol, policy_search_array[i]->result_parameter.service.identifier, policy_search_array[i]->result_parameter.service.data);
						}
					}
					continue;
				} else if (policy_search_array[i]->result == NECP_KERNEL_POLICY_RESULT_USE_NETAGENT ||
				    policy_search_array[i]->result == NECP_KERNEL_POLICY_RESULT_NETAGENT_SCOPED) {
					if (return_netagent_array != NULL &&
					    netagent_cursor < netagent_array_count) {
						return_netagent_array[netagent_cursor] = policy_search_array[i]->result_parameter.netagent_id;
						if (return_netagent_use_flags_array != NULL &&
						    policy_search_array[i]->result == NECP_KERNEL_POLICY_RESULT_NETAGENT_SCOPED) {
							return_netagent_use_flags_array[netagent_cursor] |= NECP_AGENT_USE_FLAG_SCOPE;
						}
						netagent_cursor++;
						if (necp_debug > 1) {
							NECPLOG(LOG_DEBUG, "Socket Policy: (Application %d Real Application %d BoundInterface %d Proto %d) %s Netagent %d",
							    info->application_id, info->real_application_id, info->bound_interface_index, info->protocol,
							    policy_search_array[i]->result == NECP_KERNEL_POLICY_RESULT_USE_NETAGENT ? "Use" : "Scope",
							    policy_search_array[i]->result_parameter.netagent_id);
						}
					}
					continue;
				}

				// Matched policy is a skip. Do skip and continue.
				if (policy_search_array[i]->result == NECP_KERNEL_POLICY_RESULT_SKIP) {
					skip_order = policy_search_array[i]->result_parameter.skip_policy_order;
					skip_session_order = policy_search_array[i]->session_order + 1;
					if (skip_policy_id) {
						*skip_policy_id = policy_search_array[i]->id;
					}
					continue;
				}

				// Matched an allow unentitled, which clears any drop order
				if (policy_search_array[i]->result == NECP_KERNEL_POLICY_RESULT_ALLOW_UNENTITLED) {
					info->drop_order = 0;
					continue;
				}

				// Passed all tests, found a match
				matched_policy = policy_search_array[i];
				break;
			}
		}
	}

	if (return_route_rule_id_array_count != NULL) {
		*return_route_rule_id_array_count = route_rule_id_count;
	}
	return matched_policy;
}

static bool
necp_socket_uses_interface(struct inpcb *inp, u_int32_t interface_index)
{
	bool found_match = FALSE;
	errno_t result = 0;
	ifaddr_t *addresses = NULL;
	union necp_sockaddr_union address_storage;
	int i;
	int family = AF_INET;
	ifnet_t interface = ifindex2ifnet[interface_index];

	if (inp == NULL || interface == NULL) {
		return FALSE;
	}

	if (inp->inp_vflag & INP_IPV4) {
		family = AF_INET;
	} else if (inp->inp_vflag & INP_IPV6) {
		family = AF_INET6;
	}

	result = ifnet_get_address_list_family(interface, &addresses, family);
	if (result != 0) {
		NECPLOG(LOG_ERR, "Failed to get address list for %s%d", ifnet_name(interface), ifnet_unit(interface));
		return FALSE;
	}

	for (i = 0; addresses[i] != NULL; i++) {
		if (ifaddr_address(addresses[i], &address_storage.sa, sizeof(address_storage)) == 0) {
			if (family == AF_INET) {
				if (memcmp(&address_storage.sin.sin_addr, &inp->inp_laddr, sizeof(inp->inp_laddr)) == 0) {
					found_match = TRUE;
					goto done;
				}
			} else if (family == AF_INET6) {
				if (memcmp(&address_storage.sin6.sin6_addr, &inp->in6p_laddr, sizeof(inp->in6p_laddr)) == 0) {
					found_match = TRUE;
					goto done;
				}
			}
		}
	}

done:
	ifnet_free_address_list(addresses);
	addresses = NULL;
	return found_match;
}

static inline bool
necp_socket_is_connected(struct inpcb *inp)
{
	return inp->inp_socket->so_state & (SS_ISCONNECTING | SS_ISCONNECTED | SS_ISDISCONNECTING);
}

static inline bool
necp_socket_bypass(struct sockaddr *override_local_addr, struct sockaddr *override_remote_addr, struct inpcb *inp)
{
	if (necp_pass_loopback > 0 && necp_is_loopback(override_local_addr, override_remote_addr, inp, NULL, IFSCOPE_NONE)) {
		return true;
	} else if (necp_is_intcoproc(inp, NULL)) {
		return true;
	}

	return false;
}

necp_kernel_policy_id
necp_socket_find_policy_match(struct inpcb *inp, struct sockaddr *override_local_addr, struct sockaddr *override_remote_addr, u_int32_t override_bound_interface)
{
	struct socket *so = NULL;
	necp_kernel_policy_filter filter_control_unit = 0;
	struct necp_kernel_socket_policy *matched_policy = NULL;
	necp_kernel_policy_id matched_policy_id = NECP_KERNEL_POLICY_ID_NONE;
	necp_kernel_policy_result service_action = 0;
	necp_kernel_policy_service service = { 0, 0 };
	u_int32_t drop_dest_policy_result = NECP_KERNEL_POLICY_RESULT_NONE;
	necp_drop_all_bypass_check_result_t drop_all_bypass = NECP_DROP_ALL_BYPASS_CHECK_RESULT_NONE;

	u_int32_t netagent_ids[NECP_MAX_NETAGENTS];
	memset(&netagent_ids, 0, sizeof(netagent_ids));
	int netagent_cursor;

	struct necp_socket_info info;

	if (inp == NULL) {
		return NECP_KERNEL_POLICY_ID_NONE;
	}

	// Ignore invalid addresses
	if (override_local_addr != NULL &&
	    !necp_address_is_valid(override_local_addr)) {
		override_local_addr = NULL;
	}
	if (override_remote_addr != NULL &&
	    !necp_address_is_valid(override_remote_addr)) {
		override_remote_addr = NULL;
	}

	so = inp->inp_socket;

	u_int32_t drop_order = necp_process_drop_order(so->so_cred);

	// Don't lock. Possible race condition, but we don't want the performance hit.
	if (necp_kernel_socket_policies_count == 0 ||
	    (!(inp->inp_flags2 & INP2_WANT_APP_POLICY) && necp_kernel_socket_policies_non_app_count == 0)) {
		if (necp_drop_all_order > 0 || drop_order > 0) {
			inp->inp_policyresult.policy_id = NECP_KERNEL_POLICY_ID_NO_MATCH;
			inp->inp_policyresult.skip_policy_id = NECP_KERNEL_POLICY_ID_NO_MATCH;
			inp->inp_policyresult.policy_gencount = 0;
			inp->inp_policyresult.app_id = 0;
			inp->inp_policyresult.flowhash = 0;
			inp->inp_policyresult.results.filter_control_unit = 0;
			inp->inp_policyresult.results.route_rule_id = 0;
			if (necp_socket_bypass(override_local_addr, override_remote_addr, inp)) {
				inp->inp_policyresult.results.result = NECP_KERNEL_POLICY_RESULT_PASS;
			} else {
				inp->inp_policyresult.results.result = NECP_KERNEL_POLICY_RESULT_DROP;
			}
		}
		return NECP_KERNEL_POLICY_ID_NONE;
	}

	// Check for loopback exception
	if (necp_socket_bypass(override_local_addr, override_remote_addr, inp)) {
		// Mark socket as a pass
		inp->inp_policyresult.policy_id = NECP_KERNEL_POLICY_ID_NO_MATCH;
		inp->inp_policyresult.skip_policy_id = NECP_KERNEL_POLICY_ID_NO_MATCH;
		inp->inp_policyresult.policy_gencount = 0;
		inp->inp_policyresult.app_id = 0;
		inp->inp_policyresult.flowhash = 0;
		inp->inp_policyresult.results.filter_control_unit = 0;
		inp->inp_policyresult.results.route_rule_id = 0;
		inp->inp_policyresult.results.result = NECP_KERNEL_POLICY_RESULT_PASS;
		return NECP_KERNEL_POLICY_ID_NONE;
	}

	// Lock
	lck_rw_lock_shared(&necp_kernel_policy_lock);

	necp_socket_fillout_info_locked(inp, override_local_addr, override_remote_addr, override_bound_interface, drop_order, &info);
	inp->inp_policyresult.app_id = info.application_id;

	// Check info
	u_int32_t flowhash = necp_socket_calc_flowhash_locked(&info);
	if (inp->inp_policyresult.policy_id != NECP_KERNEL_POLICY_ID_NONE &&
	    inp->inp_policyresult.policy_gencount == necp_kernel_socket_policies_gencount &&
	    inp->inp_policyresult.flowhash == flowhash) {
		// If already matched this socket on this generation of table, skip

		// Unlock
		lck_rw_done(&necp_kernel_policy_lock);

		return inp->inp_policyresult.policy_id;
	}

	// Match socket to policy
	necp_kernel_policy_id skip_policy_id;
	u_int32_t route_rule_id_array[MAX_AGGREGATE_ROUTE_RULES];
	size_t route_rule_id_array_count = 0;
	matched_policy = necp_socket_find_policy_match_with_info_locked(necp_kernel_socket_policies_map[NECP_SOCKET_MAP_APP_ID_TO_BUCKET(info.application_id)], &info, &filter_control_unit, route_rule_id_array, &route_rule_id_array_count, MAX_AGGREGATE_ROUTE_RULES, &service_action, &service, netagent_ids, NULL, NECP_MAX_NETAGENTS, NULL, 0, current_proc(), &skip_policy_id, inp->inp_route.ro_rt, &drop_dest_policy_result, &drop_all_bypass);

	// If the socket matched a scoped service policy, mark as Drop if not registered.
	// This covers the cases in which a service is required (on demand) but hasn't started yet.
	if ((service_action == NECP_KERNEL_POLICY_RESULT_TRIGGER_SCOPED ||
	    service_action == NECP_KERNEL_POLICY_RESULT_NO_TRIGGER_SCOPED) &&
	    service.identifier != 0 &&
	    service.identifier != NECP_NULL_SERVICE_ID) {
		bool service_is_registered = FALSE;
		struct necp_service_registration *service_registration = NULL;
		LIST_FOREACH(service_registration, &necp_registered_service_list, kernel_chain) {
			if (service.identifier == service_registration->service_id) {
				service_is_registered = TRUE;
				break;
			}
		}
		if (!service_is_registered) {
			// Mark socket as a drop if service is not registered
			inp->inp_policyresult.policy_id = NECP_KERNEL_POLICY_ID_NO_MATCH;
			inp->inp_policyresult.skip_policy_id = NECP_KERNEL_POLICY_ID_NO_MATCH;
			inp->inp_policyresult.policy_gencount = necp_kernel_socket_policies_gencount;
			inp->inp_policyresult.flowhash = flowhash;
			inp->inp_policyresult.results.filter_control_unit = 0;
			inp->inp_policyresult.results.route_rule_id = 0;
			inp->inp_policyresult.results.result = NECP_KERNEL_POLICY_RESULT_DROP;

			if (necp_debug > 1) {
				NECPLOG(LOG_DEBUG, "Socket Policy: (BoundInterface %d Proto %d) Dropping packet because service is not registered", info.bound_interface_index, info.protocol);
			}

			// Unlock
			lck_rw_done(&necp_kernel_policy_lock);
			return NECP_KERNEL_POLICY_ID_NONE;
		}
	}
	// Verify netagents
	for (netagent_cursor = 0; netagent_cursor < NECP_MAX_NETAGENTS; netagent_cursor++) {
		struct necp_uuid_id_mapping *mapping = NULL;
		u_int32_t netagent_id = netagent_ids[netagent_cursor];
		if (netagent_id == 0) {
			break;
		}
		mapping = necp_uuid_lookup_uuid_with_service_id_locked(netagent_id);
		if (mapping != NULL) {
			u_int32_t agent_flags = 0;
			agent_flags = netagent_get_flags(mapping->uuid);
			if (agent_flags & NETAGENT_FLAG_REGISTERED) {
				if (agent_flags & NETAGENT_FLAG_ACTIVE) {
					continue;
				} else if ((agent_flags & NETAGENT_FLAG_VOLUNTARY) == 0) {
					if (agent_flags & NETAGENT_FLAG_KERNEL_ACTIVATED) {
						int trigger_error = 0;
						trigger_error = netagent_kernel_trigger(mapping->uuid);
						if (necp_debug > 1) {
							NECPLOG(LOG_DEBUG, "Socket Policy: Triggering inactive agent, error %d", trigger_error);
						}
					}

					// Mark socket as a drop if required agent is not active
					inp->inp_policyresult.policy_id = NECP_KERNEL_POLICY_ID_NO_MATCH;
					inp->inp_policyresult.skip_policy_id = NECP_KERNEL_POLICY_ID_NO_MATCH;
					inp->inp_policyresult.policy_gencount = necp_kernel_socket_policies_gencount;
					inp->inp_policyresult.flowhash = flowhash;
					inp->inp_policyresult.results.filter_control_unit = 0;
					inp->inp_policyresult.results.route_rule_id = 0;
					inp->inp_policyresult.results.result = NECP_KERNEL_POLICY_RESULT_DROP;

					if (necp_debug > 1) {
						NECPLOG(LOG_DEBUG, "Socket Policy: (BoundInterface %d Proto %d) Dropping packet because agent is not active", info.bound_interface_index, info.protocol);
					}

					// Unlock
					lck_rw_done(&necp_kernel_policy_lock);
					return NECP_KERNEL_POLICY_ID_NONE;
				}
			}
		}
	}

	u_int32_t route_rule_id = 0;
	if (route_rule_id_array_count == 1) {
		route_rule_id = route_rule_id_array[0];
	} else if (route_rule_id_array_count > 1) {
		route_rule_id = necp_create_aggregate_route_rule(route_rule_id_array);
	}

	bool reset_tcp_mss = false;
	if (matched_policy) {
		matched_policy_id = matched_policy->id;
		inp->inp_policyresult.policy_id = matched_policy->id;
		inp->inp_policyresult.skip_policy_id = skip_policy_id;
		inp->inp_policyresult.policy_gencount = necp_kernel_socket_policies_gencount;
		inp->inp_policyresult.flowhash = flowhash;
		inp->inp_policyresult.results.filter_control_unit = filter_control_unit;
		inp->inp_policyresult.results.route_rule_id = route_rule_id;
		inp->inp_policyresult.results.result = matched_policy->result;
		memcpy(&inp->inp_policyresult.results.result_parameter, &matched_policy->result_parameter, sizeof(matched_policy->result_parameter));

		if (necp_socket_is_connected(inp) &&
		    (matched_policy->result == NECP_KERNEL_POLICY_RESULT_DROP ||
		    (matched_policy->result == NECP_KERNEL_POLICY_RESULT_IP_TUNNEL && !necp_socket_uses_interface(inp, matched_policy->result_parameter.tunnel_interface_index)))) {
			if (necp_debug) {
				NECPLOG(LOG_DEBUG, "Marking socket in state %d as defunct", so->so_state);
			}
			sosetdefunct(current_proc(), so, SHUTDOWN_SOCKET_LEVEL_NECP | SHUTDOWN_SOCKET_LEVEL_DISCONNECT_ALL, TRUE);
		} else if (necp_socket_is_connected(inp) &&
		    matched_policy->result == NECP_KERNEL_POLICY_RESULT_IP_TUNNEL &&
		    info.protocol == IPPROTO_TCP) {
			// Reset MSS on TCP socket if tunnel policy changes
			reset_tcp_mss = true;
		}

		if (necp_debug > 1) {
			NECPLOG(LOG_DEBUG, "Socket Policy: %p (BoundInterface %d Proto %d) Policy %d Result %d Parameter %d", inp->inp_socket, info.bound_interface_index, info.protocol, matched_policy->id, matched_policy->result, matched_policy->result_parameter.tunnel_interface_index);
		}
	} else {
		bool drop_all = false;
		if (necp_drop_all_order > 0 || info.drop_order > 0 || drop_dest_policy_result == NECP_KERNEL_POLICY_RESULT_DROP) {
			// Mark socket as a drop if set
			drop_all = true;
			if (drop_all_bypass == NECP_DROP_ALL_BYPASS_CHECK_RESULT_NONE) {
				drop_all_bypass = necp_check_drop_all_bypass_result(NULL);
			}
		}
		if (drop_all && drop_all_bypass == NECP_DROP_ALL_BYPASS_CHECK_RESULT_FALSE) {
			inp->inp_policyresult.policy_id = NECP_KERNEL_POLICY_ID_NO_MATCH;
			inp->inp_policyresult.skip_policy_id = NECP_KERNEL_POLICY_ID_NO_MATCH;
			inp->inp_policyresult.policy_gencount = necp_kernel_socket_policies_gencount;
			inp->inp_policyresult.flowhash = flowhash;
			inp->inp_policyresult.results.filter_control_unit = 0;
			inp->inp_policyresult.results.route_rule_id = 0;
			inp->inp_policyresult.results.result = NECP_KERNEL_POLICY_RESULT_DROP;
		} else {
			// Mark non-matching socket so we don't re-check it
			inp->inp_policyresult.policy_id = NECP_KERNEL_POLICY_ID_NO_MATCH;
			inp->inp_policyresult.skip_policy_id = NECP_KERNEL_POLICY_ID_NO_MATCH;
			inp->inp_policyresult.policy_gencount = necp_kernel_socket_policies_gencount;
			inp->inp_policyresult.flowhash = flowhash;
			inp->inp_policyresult.results.filter_control_unit = filter_control_unit; // We may have matched a filter, so mark it!
			inp->inp_policyresult.results.route_rule_id = route_rule_id; // We may have matched a route rule, so mark it!
			inp->inp_policyresult.results.result = NECP_KERNEL_POLICY_RESULT_NONE;
		}
	}

	// Unlock
	lck_rw_done(&necp_kernel_policy_lock);

	if (reset_tcp_mss) {
		// Update MSS when not holding the policy lock to avoid recursive locking
		tcp_mtudisc(inp, 0);
	}

	return matched_policy_id;
}

static bool
necp_ip_output_check_policy(struct necp_kernel_ip_output_policy *kernel_policy, necp_kernel_policy_id socket_policy_id, necp_kernel_policy_id socket_skip_policy_id, u_int32_t bound_interface_index, u_int32_t last_interface_index, u_int16_t protocol, union necp_sockaddr_union *local, union necp_sockaddr_union *remote, struct rtentry *rt)
{
	if (!(kernel_policy->condition_mask & NECP_KERNEL_CONDITION_ALL_INTERFACES)) {
		if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_BOUND_INTERFACE) {
			u_int32_t cond_bound_interface_index = kernel_policy->cond_bound_interface ? kernel_policy->cond_bound_interface->if_index : 0;
			if (kernel_policy->condition_negated_mask & NECP_KERNEL_CONDITION_BOUND_INTERFACE) {
				if (bound_interface_index == cond_bound_interface_index) {
					// No match, matches forbidden interface
					return FALSE;
				}
			} else {
				if (bound_interface_index != cond_bound_interface_index) {
					// No match, does not match required interface
					return FALSE;
				}
			}
		} else {
			if (bound_interface_index != 0) {
				// No match, requires a non-bound packet
				return FALSE;
			}
		}
	}

	if (kernel_policy->condition_mask == 0) {
		return TRUE;
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_POLICY_ID) {
		necp_kernel_policy_id matched_policy_id =
		    kernel_policy->result == NECP_KERNEL_POLICY_RESULT_SKIP ? socket_skip_policy_id : socket_policy_id;
		if (matched_policy_id != kernel_policy->cond_policy_id) {
			// No match, does not match required id
			return FALSE;
		}
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_LAST_INTERFACE) {
		if (last_interface_index != kernel_policy->cond_last_interface_index) {
			return FALSE;
		}
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_PROTOCOL) {
		if (kernel_policy->condition_negated_mask & NECP_KERNEL_CONDITION_PROTOCOL) {
			if (protocol == kernel_policy->cond_protocol) {
				// No match, matches forbidden protocol
				return FALSE;
			}
		} else {
			if (protocol != kernel_policy->cond_protocol) {
				// No match, does not match required protocol
				return FALSE;
			}
		}
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_NETWORKS) {
		bool is_local = FALSE;

		if (rt != NULL) {
			is_local = IS_NECP_DEST_IN_LOCAL_NETWORKS(rt);
		} else {
			is_local = necp_is_route_local(remote);
		}

		if (!is_local) {
			// Either no route to validate or no match for local networks
			return FALSE;
		}
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_START) {
		if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_END) {
			bool inRange = necp_is_addr_in_range((struct sockaddr *)local, (struct sockaddr *)&kernel_policy->cond_local_start, (struct sockaddr *)&kernel_policy->cond_local_end);
			if (kernel_policy->condition_negated_mask & NECP_KERNEL_CONDITION_LOCAL_END) {
				if (inRange) {
					return FALSE;
				}
			} else {
				if (!inRange) {
					return FALSE;
				}
			}
		} else if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_LOCAL_PREFIX) {
			bool inSubnet = necp_is_addr_in_subnet((struct sockaddr *)local, (struct sockaddr *)&kernel_policy->cond_local_start, kernel_policy->cond_local_prefix);
			if (kernel_policy->condition_negated_mask & NECP_KERNEL_CONDITION_LOCAL_PREFIX) {
				if (inSubnet) {
					return FALSE;
				}
			} else {
				if (!inSubnet) {
					return FALSE;
				}
			}
		}
	}

	if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_REMOTE_START) {
		if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_REMOTE_END) {
			bool inRange = necp_is_addr_in_range((struct sockaddr *)remote, (struct sockaddr *)&kernel_policy->cond_remote_start, (struct sockaddr *)&kernel_policy->cond_remote_end);
			if (kernel_policy->condition_negated_mask & NECP_KERNEL_CONDITION_REMOTE_END) {
				if (inRange) {
					return FALSE;
				}
			} else {
				if (!inRange) {
					return FALSE;
				}
			}
		} else if (kernel_policy->condition_mask & NECP_KERNEL_CONDITION_REMOTE_PREFIX) {
			bool inSubnet = necp_is_addr_in_subnet((struct sockaddr *)remote, (struct sockaddr *)&kernel_policy->cond_remote_start, kernel_policy->cond_remote_prefix);
			if (kernel_policy->condition_negated_mask & NECP_KERNEL_CONDITION_REMOTE_PREFIX) {
				if (inSubnet) {
					return FALSE;
				}
			} else {
				if (!inSubnet) {
					return FALSE;
				}
			}
		}
	}

	return TRUE;
}

static inline struct necp_kernel_ip_output_policy *
necp_ip_output_find_policy_match_locked(necp_kernel_policy_id socket_policy_id, necp_kernel_policy_id socket_skip_policy_id, u_int32_t bound_interface_index, u_int32_t last_interface_index, u_int16_t protocol, union necp_sockaddr_union *local_addr, union necp_sockaddr_union *remote_addr, struct rtentry *rt, u_int32_t *return_route_rule_id, necp_kernel_policy_result *return_drop_dest_policy_result, necp_drop_all_bypass_check_result_t *return_drop_all_bypass)
{
	u_int32_t skip_order = 0;
	u_int32_t skip_session_order = 0;
	struct necp_kernel_ip_output_policy *matched_policy = NULL;
	struct necp_kernel_ip_output_policy **policy_search_array = necp_kernel_ip_output_policies_map[NECP_IP_OUTPUT_MAP_ID_TO_BUCKET(socket_policy_id)];
	u_int32_t route_rule_id_array[MAX_AGGREGATE_ROUTE_RULES];
	size_t route_rule_id_count = 0;
	necp_drop_all_bypass_check_result_t drop_all_bypass = NECP_DROP_ALL_BYPASS_CHECK_RESULT_NONE;
	if (return_drop_all_bypass != NULL) {
		*return_drop_all_bypass = drop_all_bypass;
	}

	if (return_route_rule_id != NULL) {
		*return_route_rule_id = 0;
	}

	*return_drop_dest_policy_result = NECP_KERNEL_POLICY_RESULT_NONE;

	if (policy_search_array != NULL) {
		for (int i = 0; policy_search_array[i] != NULL; i++) {
			if (necp_drop_all_order != 0 && policy_search_array[i]->session_order >= necp_drop_all_order) {
				// We've hit a drop all rule
				if (drop_all_bypass == NECP_DROP_ALL_BYPASS_CHECK_RESULT_NONE) {
					drop_all_bypass = necp_check_drop_all_bypass_result(NULL);
					if (return_drop_all_bypass != NULL) {
						*return_drop_all_bypass = drop_all_bypass;
					}
				}
				if (drop_all_bypass == NECP_DROP_ALL_BYPASS_CHECK_RESULT_FALSE) {
					break;
				}
			}
			if (necp_drop_dest_policy.entry_count > 0 &&
			    necp_address_matches_drop_dest_policy(remote_addr, policy_search_array[i]->session_order)) {
				// We've hit a drop by destination address rule
				*return_drop_dest_policy_result = NECP_KERNEL_POLICY_RESULT_DROP;
				break;
			}
			if (skip_session_order && policy_search_array[i]->session_order >= skip_session_order) {
				// Done skipping
				skip_order = 0;
				skip_session_order = 0;
			}
			if (skip_order) {
				if (policy_search_array[i]->order < skip_order) {
					// Skip this policy
					continue;
				} else {
					// Done skipping
					skip_order = 0;
					skip_session_order = 0;
				}
			} else if (skip_session_order) {
				// Skip this policy
				continue;
			}

			if (necp_ip_output_check_policy(policy_search_array[i], socket_policy_id, socket_skip_policy_id, bound_interface_index, last_interface_index, protocol, local_addr, remote_addr, rt)) {
				if (policy_search_array[i]->result == NECP_KERNEL_POLICY_RESULT_ROUTE_RULES) {
					if (return_route_rule_id != NULL && route_rule_id_count < MAX_AGGREGATE_ROUTE_RULES) {
						route_rule_id_array[route_rule_id_count++] = policy_search_array[i]->result_parameter.route_rule_id;
					}
					continue;
				} else if (policy_search_array[i]->result == NECP_KERNEL_POLICY_RESULT_SKIP) {
					skip_order = policy_search_array[i]->result_parameter.skip_policy_order;
					skip_session_order = policy_search_array[i]->session_order + 1;
					continue;
				}

				// Passed all tests, found a match
				matched_policy = policy_search_array[i];
				break;
			}
		}
	}

	if (route_rule_id_count == 1) {
		*return_route_rule_id = route_rule_id_array[0];
	} else if (route_rule_id_count > 1) {
		*return_route_rule_id = necp_create_aggregate_route_rule(route_rule_id_array);
	}

	return matched_policy;
}

static inline bool
necp_output_bypass(struct mbuf *packet)
{
	if (necp_pass_loopback > 0 && necp_is_loopback(NULL, NULL, NULL, packet, IFSCOPE_NONE)) {
		return true;
	}
	if (necp_pass_keepalives > 0 && necp_get_is_keepalive_from_packet(packet)) {
		return true;
	}
	if (necp_is_intcoproc(NULL, packet)) {
		return true;
	}
	return false;
}

necp_kernel_policy_id
necp_ip_output_find_policy_match(struct mbuf *packet, int flags, struct ip_out_args *ipoa, struct rtentry *rt,
    necp_kernel_policy_result *result, necp_kernel_policy_result_parameter *result_parameter)
{
	struct ip *ip = NULL;
	int hlen = sizeof(struct ip);
	necp_kernel_policy_id socket_policy_id = NECP_KERNEL_POLICY_ID_NONE;
	necp_kernel_policy_id socket_skip_policy_id = NECP_KERNEL_POLICY_ID_NONE;
	necp_kernel_policy_id matched_policy_id = NECP_KERNEL_POLICY_ID_NONE;
	struct necp_kernel_ip_output_policy *matched_policy = NULL;
	u_int16_t protocol = 0;
	u_int32_t bound_interface_index = 0;
	u_int32_t last_interface_index = 0;
	union necp_sockaddr_union local_addr;
	union necp_sockaddr_union remote_addr;
	u_int32_t drop_dest_policy_result = NECP_KERNEL_POLICY_RESULT_NONE;
	necp_drop_all_bypass_check_result_t drop_all_bypass = NECP_DROP_ALL_BYPASS_CHECK_RESULT_NONE;

	if (result) {
		*result = 0;
	}

	if (result_parameter) {
		memset(result_parameter, 0, sizeof(*result_parameter));
	}

	if (packet == NULL) {
		return NECP_KERNEL_POLICY_ID_NONE;
	}

	socket_policy_id = necp_get_policy_id_from_packet(packet);
	socket_skip_policy_id = necp_get_skip_policy_id_from_packet(packet);

	// Exit early for an empty list
	// Don't lock. Possible race condition, but we don't want the performance hit.
	if (necp_kernel_ip_output_policies_count == 0 ||
	    (socket_policy_id == NECP_KERNEL_POLICY_ID_NONE && necp_kernel_ip_output_policies_non_id_count == 0 && necp_drop_dest_policy.entry_count == 0)) {
		if (necp_drop_all_order > 0) {
			matched_policy_id = NECP_KERNEL_POLICY_ID_NO_MATCH;
			if (result) {
				if (necp_output_bypass(packet)) {
					*result = NECP_KERNEL_POLICY_RESULT_PASS;
				} else {
					*result = NECP_KERNEL_POLICY_RESULT_DROP;
				}
			}
		}

		return matched_policy_id;
	}

	// Check for loopback exception
	if (necp_output_bypass(packet)) {
		matched_policy_id = NECP_KERNEL_POLICY_ID_NO_MATCH;
		if (result) {
			*result = NECP_KERNEL_POLICY_RESULT_PASS;
		}
		return matched_policy_id;
	}

	last_interface_index = necp_get_last_interface_index_from_packet(packet);

	// Process packet to get relevant fields
	ip = mtod(packet, struct ip *);
#ifdef _IP_VHL
	hlen = _IP_VHL_HL(ip->ip_vhl) << 2;
#else
	hlen = ip->ip_hl << 2;
#endif

	protocol = ip->ip_p;

	if ((flags & IP_OUTARGS) && (ipoa != NULL) &&
	    (ipoa->ipoa_flags & IPOAF_BOUND_IF) &&
	    ipoa->ipoa_boundif != IFSCOPE_NONE) {
		bound_interface_index = ipoa->ipoa_boundif;
	}

	local_addr.sin.sin_family = AF_INET;
	local_addr.sin.sin_len = sizeof(struct sockaddr_in);
	memcpy(&local_addr.sin.sin_addr, &ip->ip_src, sizeof(ip->ip_src));

	remote_addr.sin.sin_family = AF_INET;
	remote_addr.sin.sin_len = sizeof(struct sockaddr_in);
	memcpy(&((struct sockaddr_in *)&remote_addr)->sin_addr, &ip->ip_dst, sizeof(ip->ip_dst));

	switch (protocol) {
	case IPPROTO_TCP: {
		struct tcphdr th;
		if ((int)(hlen + sizeof(th)) <= packet->m_pkthdr.len) {
			m_copydata(packet, hlen, sizeof(th), (u_int8_t *)&th);
			((struct sockaddr_in *)&local_addr)->sin_port = th.th_sport;
			((struct sockaddr_in *)&remote_addr)->sin_port = th.th_dport;
		}
		break;
	}
	case IPPROTO_UDP: {
		struct udphdr uh;
		if ((int)(hlen + sizeof(uh)) <= packet->m_pkthdr.len) {
			m_copydata(packet, hlen, sizeof(uh), (u_int8_t *)&uh);
			((struct sockaddr_in *)&local_addr)->sin_port = uh.uh_sport;
			((struct sockaddr_in *)&remote_addr)->sin_port = uh.uh_dport;
		}
		break;
	}
	default: {
		((struct sockaddr_in *)&local_addr)->sin_port = 0;
		((struct sockaddr_in *)&remote_addr)->sin_port = 0;
		break;
	}
	}

	// Match packet to policy
	lck_rw_lock_shared(&necp_kernel_policy_lock);
	u_int32_t route_rule_id = 0;
	matched_policy = necp_ip_output_find_policy_match_locked(socket_policy_id, socket_skip_policy_id, bound_interface_index, last_interface_index, protocol, &local_addr, &remote_addr, rt, &route_rule_id, &drop_dest_policy_result, &drop_all_bypass);
	if (matched_policy) {
		matched_policy_id = matched_policy->id;
		if (result) {
			*result = matched_policy->result;
		}

		if (result_parameter) {
			memcpy(result_parameter, &matched_policy->result_parameter, sizeof(matched_policy->result_parameter));
		}

		if (route_rule_id != 0 &&
		    packet->m_pkthdr.necp_mtag.necp_route_rule_id == 0) {
			packet->m_pkthdr.necp_mtag.necp_route_rule_id = route_rule_id;
		}

		if (necp_debug > 1) {
			NECPLOG(LOG_DEBUG, "IP Output: (ID %d BoundInterface %d LastInterface %d Proto %d) Policy %d Result %d Parameter %d Route Rule %u", socket_policy_id, bound_interface_index, last_interface_index, protocol, matched_policy->id, matched_policy->result, matched_policy->result_parameter.tunnel_interface_index, route_rule_id);
		}
	} else {
		bool drop_all = false;
		/*
		 * Apply drop-all only to packets which have never matched a primary policy (check
		 * if the packet saved policy id is none or falls within the socket policy id range).
		 */
		if (socket_policy_id < NECP_KERNEL_POLICY_ID_FIRST_VALID_IP &&
		    (necp_drop_all_order > 0 || drop_dest_policy_result == NECP_KERNEL_POLICY_RESULT_DROP)) {
			drop_all = true;
			if (drop_all_bypass == NECP_DROP_ALL_BYPASS_CHECK_RESULT_NONE) {
				drop_all_bypass = necp_check_drop_all_bypass_result(NULL);
			}
		}
		if (drop_all && drop_all_bypass == NECP_DROP_ALL_BYPASS_CHECK_RESULT_FALSE) {
			matched_policy_id = NECP_KERNEL_POLICY_ID_NO_MATCH;
			if (result) {
				*result = NECP_KERNEL_POLICY_RESULT_DROP;
			}
		} else if (route_rule_id != 0 &&
		    packet->m_pkthdr.necp_mtag.necp_route_rule_id == 0) {
			// If we matched a route rule, mark it
			packet->m_pkthdr.necp_mtag.necp_route_rule_id = route_rule_id;
		}
	}

	lck_rw_done(&necp_kernel_policy_lock);

	return matched_policy_id;
}

necp_kernel_policy_id
necp_ip6_output_find_policy_match(struct mbuf *packet, int flags, struct ip6_out_args *ip6oa, struct rtentry *rt,
    necp_kernel_policy_result *result, necp_kernel_policy_result_parameter *result_parameter)
{
	struct ip6_hdr *ip6 = NULL;
	int next = -1;
	int offset = 0;
	necp_kernel_policy_id socket_policy_id = NECP_KERNEL_POLICY_ID_NONE;
	necp_kernel_policy_id socket_skip_policy_id = NECP_KERNEL_POLICY_ID_NONE;
	necp_kernel_policy_id matched_policy_id = NECP_KERNEL_POLICY_ID_NONE;
	struct necp_kernel_ip_output_policy *matched_policy = NULL;
	u_int16_t protocol = 0;
	u_int32_t bound_interface_index = 0;
	u_int32_t last_interface_index = 0;
	union necp_sockaddr_union local_addr;
	union necp_sockaddr_union remote_addr;
	u_int32_t drop_dest_policy_result = NECP_KERNEL_POLICY_RESULT_NONE;
	necp_drop_all_bypass_check_result_t drop_all_bypass = NECP_DROP_ALL_BYPASS_CHECK_RESULT_NONE;

	if (result) {
		*result = 0;
	}

	if (result_parameter) {
		memset(result_parameter, 0, sizeof(*result_parameter));
	}

	if (packet == NULL) {
		return NECP_KERNEL_POLICY_ID_NONE;
	}

	socket_policy_id = necp_get_policy_id_from_packet(packet);
	socket_skip_policy_id = necp_get_skip_policy_id_from_packet(packet);

	// Exit early for an empty list
	// Don't lock. Possible race condition, but we don't want the performance hit.
	if (necp_kernel_ip_output_policies_count == 0 ||
	    (socket_policy_id == NECP_KERNEL_POLICY_ID_NONE && necp_kernel_ip_output_policies_non_id_count == 0 && necp_drop_dest_policy.entry_count == 0)) {
		if (necp_drop_all_order > 0) {
			matched_policy_id = NECP_KERNEL_POLICY_ID_NO_MATCH;
			if (result) {
				if (necp_output_bypass(packet)) {
					*result = NECP_KERNEL_POLICY_RESULT_PASS;
				} else {
					*result = NECP_KERNEL_POLICY_RESULT_DROP;
				}
			}
		}

		return matched_policy_id;
	}

	// Check for loopback exception
	if (necp_output_bypass(packet)) {
		matched_policy_id = NECP_KERNEL_POLICY_ID_NO_MATCH;
		if (result) {
			*result = NECP_KERNEL_POLICY_RESULT_PASS;
		}
		return matched_policy_id;
	}

	last_interface_index = necp_get_last_interface_index_from_packet(packet);

	// Process packet to get relevant fields
	ip6 = mtod(packet, struct ip6_hdr *);

	if ((flags & IPV6_OUTARGS) && (ip6oa != NULL) &&
	    (ip6oa->ip6oa_flags & IP6OAF_BOUND_IF) &&
	    ip6oa->ip6oa_boundif != IFSCOPE_NONE) {
		bound_interface_index = ip6oa->ip6oa_boundif;
	}

	((struct sockaddr_in6 *)&local_addr)->sin6_family = AF_INET6;
	((struct sockaddr_in6 *)&local_addr)->sin6_len = sizeof(struct sockaddr_in6);
	memcpy(&((struct sockaddr_in6 *)&local_addr)->sin6_addr, &ip6->ip6_src, sizeof(ip6->ip6_src));

	((struct sockaddr_in6 *)&remote_addr)->sin6_family = AF_INET6;
	((struct sockaddr_in6 *)&remote_addr)->sin6_len = sizeof(struct sockaddr_in6);
	memcpy(&((struct sockaddr_in6 *)&remote_addr)->sin6_addr, &ip6->ip6_dst, sizeof(ip6->ip6_dst));

	offset = ip6_lasthdr(packet, 0, IPPROTO_IPV6, &next);
	if (offset >= 0 && packet->m_pkthdr.len >= offset) {
		protocol = next;
		switch (protocol) {
		case IPPROTO_TCP: {
			struct tcphdr th;
			if ((int)(offset + sizeof(th)) <= packet->m_pkthdr.len) {
				m_copydata(packet, offset, sizeof(th), (u_int8_t *)&th);
				((struct sockaddr_in6 *)&local_addr)->sin6_port = th.th_sport;
				((struct sockaddr_in6 *)&remote_addr)->sin6_port = th.th_dport;
			}
			break;
		}
		case IPPROTO_UDP: {
			struct udphdr uh;
			if ((int)(offset + sizeof(uh)) <= packet->m_pkthdr.len) {
				m_copydata(packet, offset, sizeof(uh), (u_int8_t *)&uh);
				((struct sockaddr_in6 *)&local_addr)->sin6_port = uh.uh_sport;
				((struct sockaddr_in6 *)&remote_addr)->sin6_port = uh.uh_dport;
			}
			break;
		}
		default: {
			((struct sockaddr_in6 *)&local_addr)->sin6_port = 0;
			((struct sockaddr_in6 *)&remote_addr)->sin6_port = 0;
			break;
		}
		}
	}

	// Match packet to policy
	lck_rw_lock_shared(&necp_kernel_policy_lock);
	u_int32_t route_rule_id = 0;
	matched_policy = necp_ip_output_find_policy_match_locked(socket_policy_id, socket_skip_policy_id, bound_interface_index, last_interface_index, protocol, &local_addr, &remote_addr, rt, &route_rule_id, &drop_dest_policy_result, &drop_all_bypass);
	if (matched_policy) {
		matched_policy_id = matched_policy->id;
		if (result) {
			*result = matched_policy->result;
		}

		if (result_parameter) {
			memcpy(result_parameter, &matched_policy->result_parameter, sizeof(matched_policy->result_parameter));
		}

		if (route_rule_id != 0 &&
		    packet->m_pkthdr.necp_mtag.necp_route_rule_id == 0) {
			packet->m_pkthdr.necp_mtag.necp_route_rule_id = route_rule_id;
		}

		if (necp_debug > 1) {
			NECPLOG(LOG_DEBUG, "IP6 Output: (ID %d BoundInterface %d LastInterface %d Proto %d) Policy %d Result %d Parameter %d Route Rule %u", socket_policy_id, bound_interface_index, last_interface_index, protocol, matched_policy->id, matched_policy->result, matched_policy->result_parameter.tunnel_interface_index, route_rule_id);
		}
	} else {
		bool drop_all = false;
		/*
		 * Apply drop-all only to packets which have never matched a primary policy (check
		 * if the packet saved policy id is none or falls within the socket policy id range).
		 */
		if (socket_policy_id < NECP_KERNEL_POLICY_ID_FIRST_VALID_IP &&
		    (necp_drop_all_order > 0 || drop_dest_policy_result == NECP_KERNEL_POLICY_RESULT_DROP)) {
			drop_all = true;
			if (drop_all_bypass == NECP_DROP_ALL_BYPASS_CHECK_RESULT_NONE) {
				drop_all_bypass = necp_check_drop_all_bypass_result(NULL);
			}
		}
		if (drop_all && drop_all_bypass == NECP_DROP_ALL_BYPASS_CHECK_RESULT_FALSE) {
			matched_policy_id = NECP_KERNEL_POLICY_ID_NO_MATCH;
			if (result) {
				*result = NECP_KERNEL_POLICY_RESULT_DROP;
			}
		} else if (route_rule_id != 0 &&
		    packet->m_pkthdr.necp_mtag.necp_route_rule_id == 0) {
			// If we matched a route rule, mark it
			packet->m_pkthdr.necp_mtag.necp_route_rule_id = route_rule_id;
		}
	}

	lck_rw_done(&necp_kernel_policy_lock);

	return matched_policy_id;
}

// Utilities
static bool
necp_is_addr_in_range(struct sockaddr *addr, struct sockaddr *range_start, struct sockaddr *range_end)
{
	int cmp = 0;

	if (addr == NULL || range_start == NULL || range_end == NULL) {
		return FALSE;
	}

	/* Must be greater than or equal to start */
	cmp = necp_addr_compare(addr, range_start, 1);
	if (cmp != 0 && cmp != 1) {
		return FALSE;
	}

	/* Must be less than or equal to end */
	cmp = necp_addr_compare(addr, range_end, 1);
	if (cmp != 0 && cmp != -1) {
		return FALSE;
	}

	return TRUE;
}

static bool
necp_is_range_in_range(struct sockaddr *inner_range_start, struct sockaddr *inner_range_end, struct sockaddr *range_start, struct sockaddr *range_end)
{
	int cmp = 0;

	if (inner_range_start == NULL || inner_range_end == NULL || range_start == NULL || range_end == NULL) {
		return FALSE;
	}

	/* Must be greater than or equal to start */
	cmp = necp_addr_compare(inner_range_start, range_start, 1);
	if (cmp != 0 && cmp != 1) {
		return FALSE;
	}

	/* Must be less than or equal to end */
	cmp = necp_addr_compare(inner_range_end, range_end, 1);
	if (cmp != 0 && cmp != -1) {
		return FALSE;
	}

	return TRUE;
}

static bool
necp_is_addr_in_subnet(struct sockaddr *addr, struct sockaddr *subnet_addr, u_int8_t subnet_prefix)
{
	if (addr == NULL || subnet_addr == NULL) {
		return FALSE;
	}

	if (addr->sa_family != subnet_addr->sa_family || addr->sa_len != subnet_addr->sa_len) {
		return FALSE;
	}

	switch (addr->sa_family) {
	case AF_INET: {
		if (satosin(subnet_addr)->sin_port != 0 &&
		    satosin(addr)->sin_port != satosin(subnet_addr)->sin_port) {
			return FALSE;
		}
		return necp_buffer_compare_with_bit_prefix((u_int8_t *)&satosin(addr)->sin_addr, (u_int8_t *)&satosin(subnet_addr)->sin_addr, subnet_prefix);
	}
	case AF_INET6: {
		if (satosin6(subnet_addr)->sin6_port != 0 &&
		    satosin6(addr)->sin6_port != satosin6(subnet_addr)->sin6_port) {
			return FALSE;
		}
		if (satosin6(addr)->sin6_scope_id &&
		    satosin6(subnet_addr)->sin6_scope_id &&
		    satosin6(addr)->sin6_scope_id != satosin6(subnet_addr)->sin6_scope_id) {
			return FALSE;
		}
		return necp_buffer_compare_with_bit_prefix((u_int8_t *)&satosin6(addr)->sin6_addr, (u_int8_t *)&satosin6(subnet_addr)->sin6_addr, subnet_prefix);
	}
	default: {
		return FALSE;
	}
	}

	return FALSE;
}

/*
 * Return values:
 * -1: sa1 < sa2
 * 0: sa1 == sa2
 * 1: sa1 > sa2
 * 2: Not comparable or error
 */
static int
necp_addr_compare(struct sockaddr *sa1, struct sockaddr *sa2, int check_port)
{
	int result = 0;
	int port_result = 0;

	if (sa1->sa_family != sa2->sa_family || sa1->sa_len != sa2->sa_len) {
		return 2;
	}

	if (sa1->sa_len == 0) {
		return 0;
	}

	switch (sa1->sa_family) {
	case AF_INET: {
		if (sa1->sa_len != sizeof(struct sockaddr_in)) {
			return 2;
		}

		result = memcmp(&satosin(sa1)->sin_addr.s_addr, &satosin(sa2)->sin_addr.s_addr, sizeof(satosin(sa1)->sin_addr.s_addr));

		if (check_port) {
			if (satosin(sa1)->sin_port < satosin(sa2)->sin_port) {
				port_result = -1;
			} else if (satosin(sa1)->sin_port > satosin(sa2)->sin_port) {
				port_result = 1;
			}

			if (result == 0) {
				result = port_result;
			} else if ((result > 0 && port_result < 0) || (result < 0 && port_result > 0)) {
				return 2;
			}
		}

		break;
	}
	case AF_INET6: {
		if (sa1->sa_len != sizeof(struct sockaddr_in6)) {
			return 2;
		}

		if (satosin6(sa1)->sin6_scope_id != satosin6(sa2)->sin6_scope_id) {
			return 2;
		}

		result = memcmp(&satosin6(sa1)->sin6_addr.s6_addr[0], &satosin6(sa2)->sin6_addr.s6_addr[0], sizeof(struct in6_addr));

		if (check_port) {
			if (satosin6(sa1)->sin6_port < satosin6(sa2)->sin6_port) {
				port_result = -1;
			} else if (satosin6(sa1)->sin6_port > satosin6(sa2)->sin6_port) {
				port_result = 1;
			}

			if (result == 0) {
				result = port_result;
			} else if ((result > 0 && port_result < 0) || (result < 0 && port_result > 0)) {
				return 2;
			}
		}

		break;
	}
	default: {
		result = memcmp(sa1, sa2, sa1->sa_len);
		break;
	}
	}

	if (result < 0) {
		result = (-1);
	} else if (result > 0) {
		result = (1);
	}

	return result;
}

static bool
necp_buffer_compare_with_bit_prefix(u_int8_t *p1, u_int8_t *p2, u_int32_t bits)
{
	u_int8_t mask;

	/* Handle null pointers */
	if (p1 == NULL || p2 == NULL) {
		return p1 == p2;
	}

	while (bits >= 8) {
		if (*p1++ != *p2++) {
			return FALSE;
		}
		bits -= 8;
	}

	if (bits > 0) {
		mask = ~((1 << (8 - bits)) - 1);
		if ((*p1 & mask) != (*p2 & mask)) {
			return FALSE;
		}
	}
	return TRUE;
}

static bool
necp_addr_is_empty(struct sockaddr *addr)
{
	if (addr == NULL) {
		return TRUE;
	}

	if (addr->sa_len == 0) {
		return TRUE;
	}

	switch (addr->sa_family) {
	case AF_INET: {
		static struct sockaddr_in ipv4_empty_address = {
			.sin_len = sizeof(struct sockaddr_in),
			.sin_family = AF_INET,
			.sin_port = 0,
			.sin_addr = { .s_addr = 0 }, // 0.0.0.0
			.sin_zero = {0},
		};
		if (necp_addr_compare(addr, (struct sockaddr *)&ipv4_empty_address, 0) == 0) {
			return TRUE;
		} else {
			return FALSE;
		}
	}
	case AF_INET6: {
		static struct sockaddr_in6 ipv6_empty_address = {
			.sin6_len = sizeof(struct sockaddr_in6),
			.sin6_family = AF_INET6,
			.sin6_port = 0,
			.sin6_flowinfo = 0,
			.sin6_addr = IN6ADDR_ANY_INIT, // ::
			.sin6_scope_id = 0,
		};
		if (necp_addr_compare(addr, (struct sockaddr *)&ipv6_empty_address, 0) == 0) {
			return TRUE;
		} else {
			return FALSE;
		}
	}
	default:
		return FALSE;
	}

	return FALSE;
}

static bool
necp_update_qos_marking(struct ifnet *ifp, u_int32_t route_rule_id)
{
	bool qos_marking = FALSE;
	int exception_index = 0;
	struct necp_route_rule *route_rule = NULL;

	route_rule = necp_lookup_route_rule_locked(&necp_route_rules, route_rule_id);
	if (route_rule == NULL) {
		qos_marking = FALSE;
		goto done;
	}

	qos_marking = (route_rule->default_action == NECP_ROUTE_RULE_QOS_MARKING) ? TRUE : FALSE;

	if (ifp == NULL) {
		goto done;
	}

	for (exception_index = 0; exception_index < MAX_ROUTE_RULE_INTERFACES; exception_index++) {
		if (route_rule->exception_if_indices[exception_index] == 0) {
			break;
		}
		if (route_rule->exception_if_actions[exception_index] != NECP_ROUTE_RULE_QOS_MARKING) {
			continue;
		}
		if (route_rule->exception_if_indices[exception_index] == ifp->if_index) {
			qos_marking = TRUE;
			if (necp_debug > 2) {
				NECPLOG(LOG_DEBUG, "QoS Marking : Interface match %d for Rule %d Allowed %d",
				    route_rule->exception_if_indices[exception_index], route_rule_id, qos_marking);
			}
			goto done;
		}
	}

	if ((route_rule->cellular_action == NECP_ROUTE_RULE_QOS_MARKING && IFNET_IS_CELLULAR(ifp)) ||
	    (route_rule->wifi_action == NECP_ROUTE_RULE_QOS_MARKING && IFNET_IS_WIFI(ifp)) ||
	    (route_rule->wired_action == NECP_ROUTE_RULE_QOS_MARKING && IFNET_IS_WIRED(ifp)) ||
	    (route_rule->expensive_action == NECP_ROUTE_RULE_QOS_MARKING && IFNET_IS_EXPENSIVE(ifp)) ||
	    (route_rule->constrained_action == NECP_ROUTE_RULE_QOS_MARKING && IFNET_IS_CONSTRAINED(ifp))) {
		qos_marking = TRUE;
		if (necp_debug > 2) {
			NECPLOG(LOG_DEBUG, "QoS Marking: C:%d WF:%d W:%d E:%d Cn:%d for Rule %d Allowed %d",
			    route_rule->cellular_action, route_rule->wifi_action, route_rule->wired_action,
			    route_rule->expensive_action, route_rule->constrained_action, route_rule_id, qos_marking);
		}
		goto done;
	}
done:
	if (necp_debug > 1) {
		NECPLOG(LOG_DEBUG, "QoS Marking: Rule %d ifp %s Allowed %d",
		    route_rule_id, ifp ? ifp->if_xname : "", qos_marking);
	}
	return qos_marking;
}

void
necp_socket_update_qos_marking(struct inpcb *inp, struct rtentry *route, struct ifnet *interface, u_int32_t route_rule_id)
{
	bool qos_marking = FALSE;
	struct ifnet *ifp = interface = NULL;

	if (net_qos_policy_restricted == 0) {
		return;
	}
	if (inp->inp_socket == NULL) {
		return;
	}
	if ((inp->inp_socket->so_flags1 & SOF1_QOSMARKING_POLICY_OVERRIDE)) {
		return;
	}
	/*
	 * This is racy but we do not need the performance hit of taking necp_kernel_policy_lock
	 */
	if (inp->inp_policyresult.results.qos_marking_gencount == necp_kernel_socket_policies_gencount) {
		return;
	}

	lck_rw_lock_shared(&necp_kernel_policy_lock);

	if (ifp == NULL && route != NULL) {
		ifp = route->rt_ifp;
	}
	/*
	 * By default, until we have a interface, do not mark and reevaluate the Qos marking policy
	 */
	if (ifp == NULL || route_rule_id == 0) {
		qos_marking = FALSE;
		goto done;
	}

	if (ROUTE_RULE_IS_AGGREGATE(route_rule_id)) {
		struct necp_aggregate_route_rule *aggregate_route_rule = necp_lookup_aggregate_route_rule_locked(route_rule_id);
		if (aggregate_route_rule != NULL) {
			int index = 0;
			for (index = 0; index < MAX_AGGREGATE_ROUTE_RULES; index++) {
				u_int32_t sub_route_rule_id = aggregate_route_rule->rule_ids[index];
				if (sub_route_rule_id == 0) {
					break;
				}
				qos_marking = necp_update_qos_marking(ifp, sub_route_rule_id);
				if (qos_marking == TRUE) {
					break;
				}
			}
		}
	} else {
		qos_marking = necp_update_qos_marking(ifp, route_rule_id);
	}
	/*
	 * Now that we have an interface we remember the gencount
	 */
	inp->inp_policyresult.results.qos_marking_gencount = necp_kernel_socket_policies_gencount;

done:
	lck_rw_done(&necp_kernel_policy_lock);

	if (qos_marking == TRUE) {
		inp->inp_socket->so_flags1 |= SOF1_QOSMARKING_ALLOWED;
	} else {
		inp->inp_socket->so_flags1 &= ~SOF1_QOSMARKING_ALLOWED;
	}
}

static bool
necp_route_is_lqm_abort(struct ifnet *ifp, struct ifnet *delegated_ifp)
{
	if (ifp != NULL &&
	    (ifp->if_interface_state.valid_bitmask & IF_INTERFACE_STATE_LQM_STATE_VALID) &&
	    ifp->if_interface_state.lqm_state == IFNET_LQM_THRESH_ABORT) {
		return true;
	}
	if (delegated_ifp != NULL &&
	    (delegated_ifp->if_interface_state.valid_bitmask & IF_INTERFACE_STATE_LQM_STATE_VALID) &&
	    delegated_ifp->if_interface_state.lqm_state == IFNET_LQM_THRESH_ABORT) {
		return true;
	}
	return false;
}

static bool
necp_route_is_allowed_inner(struct rtentry *route, struct ifnet *ifp, u_int32_t route_rule_id, u_int32_t *interface_type_denied)
{
	bool default_is_allowed = TRUE;
	u_int8_t type_aggregate_action = NECP_ROUTE_RULE_NONE;
	int exception_index = 0;
	struct ifnet *delegated_ifp = NULL;
	struct necp_route_rule *route_rule = NULL;

	route_rule = necp_lookup_route_rule_locked(&necp_route_rules, route_rule_id);
	if (route_rule == NULL) {
		return TRUE;
	}

	default_is_allowed = (route_rule->default_action == NECP_ROUTE_RULE_DENY_INTERFACE) ? FALSE : TRUE;
	if (ifp == NULL) {
		ifp = route->rt_ifp;
	}
	if (ifp == NULL) {
		if (necp_debug > 1 && !default_is_allowed) {
			NECPLOG(LOG_DEBUG, "Route Allowed: No interface for route, using default for Rule %d Allowed %d", route_rule_id, default_is_allowed);
		}
		return default_is_allowed;
	}

	delegated_ifp = ifp->if_delegated.ifp;
	for (exception_index = 0; exception_index < MAX_ROUTE_RULE_INTERFACES; exception_index++) {
		if (route_rule->exception_if_indices[exception_index] == 0) {
			break;
		}
		if (route_rule->exception_if_indices[exception_index] == ifp->if_index ||
		    (delegated_ifp != NULL && route_rule->exception_if_indices[exception_index] == delegated_ifp->if_index)) {
			if (route_rule->exception_if_actions[exception_index] == NECP_ROUTE_RULE_DENY_LQM_ABORT) {
				const bool lqm_abort = necp_route_is_lqm_abort(ifp, delegated_ifp);
				if (necp_debug > 1 && lqm_abort) {
					NECPLOG(LOG_DEBUG, "Route Allowed: Interface match %d for Rule %d Deny LQM Abort",
					    route_rule->exception_if_indices[exception_index], route_rule_id);
				}
				return false;
			} else if (IS_NECP_ROUTE_RULE_ALLOW_OR_DENY(route_rule->exception_if_actions[exception_index])) {
				if (necp_debug > 1) {
					NECPLOG(LOG_DEBUG, "Route Allowed: Interface match %d for Rule %d Allowed %d", route_rule->exception_if_indices[exception_index], route_rule_id, ((route_rule->exception_if_actions[exception_index] == NECP_ROUTE_RULE_DENY_INTERFACE) ? FALSE : TRUE));
				}
				return (route_rule->exception_if_actions[exception_index] == NECP_ROUTE_RULE_DENY_INTERFACE) ? FALSE : TRUE;
			}
		}
	}

	if (IFNET_IS_CELLULAR(ifp)) {
		if (route_rule->cellular_action == NECP_ROUTE_RULE_DENY_LQM_ABORT) {
			if (necp_route_is_lqm_abort(ifp, delegated_ifp)) {
				if (interface_type_denied != NULL) {
					*interface_type_denied = IFRTYPE_FUNCTIONAL_CELLULAR;
				}
				// Mark aggregate action as deny
				type_aggregate_action = NECP_ROUTE_RULE_DENY_INTERFACE;
			}
		} else if (IS_NECP_ROUTE_RULE_ALLOW_OR_DENY(route_rule->cellular_action)) {
			if (interface_type_denied != NULL) {
				*interface_type_denied = IFRTYPE_FUNCTIONAL_CELLULAR;
			}
			if (type_aggregate_action == NECP_ROUTE_RULE_NONE ||
			    (type_aggregate_action == NECP_ROUTE_RULE_ALLOW_INTERFACE &&
			    route_rule->cellular_action == NECP_ROUTE_RULE_DENY_INTERFACE)) {
				// Deny wins if there is a conflict
				type_aggregate_action = route_rule->cellular_action;
			}
		}
	}

	if (IFNET_IS_WIFI(ifp)) {
		if (route_rule->wifi_action == NECP_ROUTE_RULE_DENY_LQM_ABORT) {
			if (necp_route_is_lqm_abort(ifp, delegated_ifp)) {
				if (interface_type_denied != NULL) {
					*interface_type_denied = IFRTYPE_FUNCTIONAL_WIFI_INFRA;
				}
				// Mark aggregate action as deny
				type_aggregate_action = NECP_ROUTE_RULE_DENY_INTERFACE;
			}
		} else if (IS_NECP_ROUTE_RULE_ALLOW_OR_DENY(route_rule->wifi_action)) {
			if (interface_type_denied != NULL) {
				*interface_type_denied = IFRTYPE_FUNCTIONAL_WIFI_INFRA;
			}
			if (type_aggregate_action == NECP_ROUTE_RULE_NONE ||
			    (type_aggregate_action == NECP_ROUTE_RULE_ALLOW_INTERFACE &&
			    route_rule->wifi_action == NECP_ROUTE_RULE_DENY_INTERFACE)) {
				// Deny wins if there is a conflict
				type_aggregate_action = route_rule->wifi_action;
			}
		}
	}

	if (IFNET_IS_WIRED(ifp)) {
		if (route_rule->wired_action == NECP_ROUTE_RULE_DENY_LQM_ABORT) {
			if (necp_route_is_lqm_abort(ifp, delegated_ifp)) {
				if (interface_type_denied != NULL) {
					*interface_type_denied = IFRTYPE_FUNCTIONAL_WIRED;
				}
				// Mark aggregate action as deny
				type_aggregate_action = NECP_ROUTE_RULE_DENY_INTERFACE;
			}
		} else if (IS_NECP_ROUTE_RULE_ALLOW_OR_DENY(route_rule->wired_action)) {
			if (interface_type_denied != NULL) {
				*interface_type_denied = IFRTYPE_FUNCTIONAL_WIRED;
			}
			if (type_aggregate_action == NECP_ROUTE_RULE_NONE ||
			    (type_aggregate_action == NECP_ROUTE_RULE_ALLOW_INTERFACE &&
			    route_rule->wired_action == NECP_ROUTE_RULE_DENY_INTERFACE)) {
				// Deny wins if there is a conflict
				type_aggregate_action = route_rule->wired_action;
			}
		}
	}

	if (IFNET_IS_EXPENSIVE(ifp)) {
		if (route_rule->expensive_action == NECP_ROUTE_RULE_DENY_LQM_ABORT) {
			if (necp_route_is_lqm_abort(ifp, delegated_ifp)) {
				// Mark aggregate action as deny
				type_aggregate_action = NECP_ROUTE_RULE_DENY_INTERFACE;
			}
		} else if (IS_NECP_ROUTE_RULE_ALLOW_OR_DENY(route_rule->expensive_action)) {
			if (type_aggregate_action == NECP_ROUTE_RULE_NONE ||
			    (type_aggregate_action == NECP_ROUTE_RULE_ALLOW_INTERFACE &&
			    route_rule->expensive_action == NECP_ROUTE_RULE_DENY_INTERFACE)) {
				// Deny wins if there is a conflict
				type_aggregate_action = route_rule->expensive_action;
			}
		}
	}

	if (IFNET_IS_CONSTRAINED(ifp)) {
		if (route_rule->constrained_action == NECP_ROUTE_RULE_DENY_LQM_ABORT) {
			if (necp_route_is_lqm_abort(ifp, delegated_ifp)) {
				// Mark aggregate action as deny
				type_aggregate_action = NECP_ROUTE_RULE_DENY_INTERFACE;
			}
		} else if (IS_NECP_ROUTE_RULE_ALLOW_OR_DENY(route_rule->constrained_action)) {
			if (type_aggregate_action == NECP_ROUTE_RULE_NONE ||
			    (type_aggregate_action == NECP_ROUTE_RULE_ALLOW_INTERFACE &&
			    route_rule->constrained_action == NECP_ROUTE_RULE_DENY_INTERFACE)) {
				// Deny wins if there is a conflict
				type_aggregate_action = route_rule->constrained_action;
			}
		}
	}

	if (type_aggregate_action != NECP_ROUTE_RULE_NONE) {
		if (necp_debug > 1) {
			NECPLOG(LOG_DEBUG, "Route Allowed: C:%d WF:%d W:%d E:%d for Rule %d Allowed %d", route_rule->cellular_action, route_rule->wifi_action, route_rule->wired_action, route_rule->expensive_action, route_rule_id, ((type_aggregate_action == NECP_ROUTE_RULE_DENY_INTERFACE) ? FALSE : TRUE));
		}
		return (type_aggregate_action == NECP_ROUTE_RULE_DENY_INTERFACE) ? FALSE : TRUE;
	}

	if (necp_debug > 1 && !default_is_allowed) {
		NECPLOG(LOG_DEBUG, "Route Allowed: Using default for Rule %d Allowed %d", route_rule_id, default_is_allowed);
	}
	return default_is_allowed;
}

static bool
necp_route_is_allowed(struct rtentry *route, struct ifnet *interface, u_int32_t route_rule_id, u_int32_t *interface_type_denied)
{
	if ((route == NULL && interface == NULL) || route_rule_id == 0) {
		if (necp_debug > 1) {
			NECPLOG(LOG_DEBUG, "Route Allowed: no route or interface, Rule %d Allowed %d", route_rule_id, TRUE);
		}
		return TRUE;
	}

	if (ROUTE_RULE_IS_AGGREGATE(route_rule_id)) {
		struct necp_aggregate_route_rule *aggregate_route_rule = necp_lookup_aggregate_route_rule_locked(route_rule_id);
		if (aggregate_route_rule != NULL) {
			int index = 0;
			for (index = 0; index < MAX_AGGREGATE_ROUTE_RULES; index++) {
				u_int32_t sub_route_rule_id = aggregate_route_rule->rule_ids[index];
				if (sub_route_rule_id == 0) {
					break;
				}
				if (!necp_route_is_allowed_inner(route, interface, sub_route_rule_id, interface_type_denied)) {
					return FALSE;
				}
			}
		}
	} else {
		return necp_route_is_allowed_inner(route, interface, route_rule_id, interface_type_denied);
	}

	return TRUE;
}

bool
necp_packet_is_allowed_over_interface(struct mbuf *packet, struct ifnet *interface)
{
	bool is_allowed = TRUE;
	u_int32_t route_rule_id = necp_get_route_rule_id_from_packet(packet);
	if (route_rule_id != 0 &&
	    interface != NULL) {
		lck_rw_lock_shared(&necp_kernel_policy_lock);
		is_allowed = necp_route_is_allowed(NULL, interface, necp_get_route_rule_id_from_packet(packet), NULL);
		lck_rw_done(&necp_kernel_policy_lock);
	}
	return is_allowed;
}

static bool
necp_netagents_allow_traffic(u_int32_t *netagent_ids, size_t netagent_id_count)
{
	size_t netagent_cursor;
	for (netagent_cursor = 0; netagent_cursor < netagent_id_count; netagent_cursor++) {
		struct necp_uuid_id_mapping *mapping = NULL;
		u_int32_t netagent_id = netagent_ids[netagent_cursor];
		if (netagent_id == 0) {
			break;
		}
		mapping = necp_uuid_lookup_uuid_with_service_id_locked(netagent_id);
		if (mapping != NULL) {
			u_int32_t agent_flags = 0;
			agent_flags = netagent_get_flags(mapping->uuid);
			if (agent_flags & NETAGENT_FLAG_REGISTERED) {
				if (agent_flags & NETAGENT_FLAG_ACTIVE) {
					continue;
				} else if ((agent_flags & NETAGENT_FLAG_VOLUNTARY) == 0) {
					return FALSE;
				}
			}
		}
	}
	return TRUE;
}

static bool
necp_socket_is_allowed_to_send_recv_internal(struct inpcb *inp, struct sockaddr *override_local_addr, struct sockaddr *override_remote_addr, ifnet_t interface, necp_kernel_policy_id *return_policy_id, u_int32_t *return_route_rule_id, necp_kernel_policy_id *return_skip_policy_id)
{
	u_int32_t verifyifindex = interface ? interface->if_index : 0;
	bool allowed_to_receive = TRUE;
	struct necp_socket_info info;
	u_int32_t flowhash = 0;
	necp_kernel_policy_result service_action = 0;
	necp_kernel_policy_service service = { 0, 0 };
	u_int32_t route_rule_id = 0;
	struct rtentry *route = NULL;
	u_int32_t interface_type_denied = IFRTYPE_FUNCTIONAL_UNKNOWN;
	necp_kernel_policy_result drop_dest_policy_result = NECP_KERNEL_POLICY_RESULT_NONE;
	necp_drop_all_bypass_check_result_t drop_all_bypass = NECP_DROP_ALL_BYPASS_CHECK_RESULT_NONE;
	u_int32_t netagent_ids[NECP_MAX_NETAGENTS];
	memset(&netagent_ids, 0, sizeof(netagent_ids));

	if (return_policy_id) {
		*return_policy_id = NECP_KERNEL_POLICY_ID_NONE;
	}
	if (return_skip_policy_id) {
		*return_skip_policy_id = NECP_KERNEL_POLICY_ID_NONE;
	}
	if (return_route_rule_id) {
		*return_route_rule_id = 0;
	}

	if (inp == NULL) {
		goto done;
	}

	route = inp->inp_route.ro_rt;

	struct socket *so = inp->inp_socket;

	u_int32_t drop_order = necp_process_drop_order(so->so_cred);

	// Don't lock. Possible race condition, but we don't want the performance hit.
	if (necp_kernel_socket_policies_count == 0 ||
	    (!(inp->inp_flags2 & INP2_WANT_APP_POLICY) && necp_kernel_socket_policies_non_app_count == 0)) {
		if (necp_drop_all_order > 0 || drop_order > 0) {
			if (necp_socket_bypass(override_local_addr, override_remote_addr, inp)) {
				allowed_to_receive = TRUE;
			} else {
				allowed_to_receive = FALSE;
			}
		}
		goto done;
	}

	// If this socket is connected, or we are not taking addresses into account, try to reuse last result
	if ((necp_socket_is_connected(inp) || (override_local_addr == NULL && override_remote_addr == NULL)) && inp->inp_policyresult.policy_id != NECP_KERNEL_POLICY_ID_NONE) {
		bool policies_have_changed = FALSE;
		bool route_allowed = TRUE;

		if (inp->inp_policyresult.policy_gencount != necp_kernel_socket_policies_gencount) {
			policies_have_changed = TRUE;
		} else {
			if (inp->inp_policyresult.results.route_rule_id != 0) {
				lck_rw_lock_shared(&necp_kernel_policy_lock);
				if (!necp_route_is_allowed(route, interface, inp->inp_policyresult.results.route_rule_id, &interface_type_denied)) {
					route_allowed = FALSE;
				}
				lck_rw_done(&necp_kernel_policy_lock);
			}
		}

		if (!policies_have_changed) {
			if (!route_allowed ||
			    inp->inp_policyresult.results.result == NECP_KERNEL_POLICY_RESULT_DROP ||
			    inp->inp_policyresult.results.result == NECP_KERNEL_POLICY_RESULT_SOCKET_DIVERT ||
			    (inp->inp_policyresult.results.result == NECP_KERNEL_POLICY_RESULT_IP_TUNNEL && interface &&
			    inp->inp_policyresult.results.result_parameter.tunnel_interface_index != verifyifindex)) {
				allowed_to_receive = FALSE;
			} else {
				if (return_policy_id) {
					*return_policy_id = inp->inp_policyresult.policy_id;
				}
				if (return_skip_policy_id) {
					*return_skip_policy_id = inp->inp_policyresult.skip_policy_id;
				}
				if (return_route_rule_id) {
					*return_route_rule_id = inp->inp_policyresult.results.route_rule_id;
				}
			}
			goto done;
		}
	}

	// Check for loopback exception
	if (necp_socket_bypass(override_local_addr, override_remote_addr, inp)) {
		allowed_to_receive = TRUE;
		goto done;
	}

	// Actually calculate policy result
	lck_rw_lock_shared(&necp_kernel_policy_lock);
	necp_socket_fillout_info_locked(inp, override_local_addr, override_remote_addr, 0, drop_order, &info);

	flowhash = necp_socket_calc_flowhash_locked(&info);
	if (inp->inp_policyresult.policy_id != NECP_KERNEL_POLICY_ID_NONE &&
	    inp->inp_policyresult.policy_gencount == necp_kernel_socket_policies_gencount &&
	    inp->inp_policyresult.flowhash == flowhash) {
		if (inp->inp_policyresult.results.result == NECP_KERNEL_POLICY_RESULT_DROP ||
		    inp->inp_policyresult.results.result == NECP_KERNEL_POLICY_RESULT_SOCKET_DIVERT ||
		    (inp->inp_policyresult.results.result == NECP_KERNEL_POLICY_RESULT_IP_TUNNEL && interface &&
		    inp->inp_policyresult.results.result_parameter.tunnel_interface_index != verifyifindex) ||
		    (inp->inp_policyresult.results.route_rule_id != 0 &&
		    !necp_route_is_allowed(route, interface, inp->inp_policyresult.results.route_rule_id, &interface_type_denied))) {
			allowed_to_receive = FALSE;
		} else {
			if (return_policy_id) {
				*return_policy_id = inp->inp_policyresult.policy_id;
			}
			if (return_route_rule_id) {
				*return_route_rule_id = inp->inp_policyresult.results.route_rule_id;
			}
			if (return_skip_policy_id) {
				*return_skip_policy_id = inp->inp_policyresult.skip_policy_id;
			}
		}
		lck_rw_done(&necp_kernel_policy_lock);
		goto done;
	}

	u_int32_t route_rule_id_array[MAX_AGGREGATE_ROUTE_RULES];
	size_t route_rule_id_array_count = 0;
	struct necp_kernel_socket_policy *matched_policy = necp_socket_find_policy_match_with_info_locked(necp_kernel_socket_policies_map[NECP_SOCKET_MAP_APP_ID_TO_BUCKET(info.application_id)], &info, NULL, route_rule_id_array, &route_rule_id_array_count, MAX_AGGREGATE_ROUTE_RULES, &service_action, &service, netagent_ids, NULL, NECP_MAX_NETAGENTS, NULL, 0, current_proc(), return_skip_policy_id, inp->inp_route.ro_rt, &drop_dest_policy_result, &drop_all_bypass);

	if (route_rule_id_array_count == 1) {
		route_rule_id = route_rule_id_array[0];
	} else if (route_rule_id_array_count > 1) {
		route_rule_id = necp_create_aggregate_route_rule(route_rule_id_array);
	}

	if (matched_policy != NULL) {
		if (matched_policy->result == NECP_KERNEL_POLICY_RESULT_DROP ||
		    matched_policy->result == NECP_KERNEL_POLICY_RESULT_SOCKET_DIVERT ||
		    (matched_policy->result == NECP_KERNEL_POLICY_RESULT_IP_TUNNEL && interface &&
		    matched_policy->result_parameter.tunnel_interface_index != verifyifindex) ||
		    ((service_action == NECP_KERNEL_POLICY_RESULT_TRIGGER_SCOPED ||
		    service_action == NECP_KERNEL_POLICY_RESULT_NO_TRIGGER_SCOPED) &&
		    service.identifier != 0 && service.identifier != NECP_NULL_SERVICE_ID) ||
		    (route_rule_id != 0 &&
		    !necp_route_is_allowed(route, interface, route_rule_id, &interface_type_denied)) ||
		    !necp_netagents_allow_traffic(netagent_ids, NECP_MAX_NETAGENTS)) {
			allowed_to_receive = FALSE;
		} else {
			if (return_policy_id) {
				*return_policy_id = matched_policy->id;
			}
			if (return_route_rule_id) {
				*return_route_rule_id = route_rule_id;
			}
		}
		lck_rw_done(&necp_kernel_policy_lock);

		if (necp_debug > 1 && matched_policy->id != inp->inp_policyresult.policy_id) {
			NECPLOG(LOG_DEBUG, "Socket Send/Recv Policy: Policy %d Allowed %d", return_policy_id ? *return_policy_id : 0, allowed_to_receive);
		}
		goto done;
	} else {
		bool drop_all = false;
		if (necp_drop_all_order > 0 || info.drop_order > 0 || drop_dest_policy_result == NECP_KERNEL_POLICY_RESULT_DROP) {
			drop_all = true;
			if (drop_all_bypass == NECP_DROP_ALL_BYPASS_CHECK_RESULT_NONE) {
				drop_all_bypass = necp_check_drop_all_bypass_result(NULL);
			}
		}
		if (drop_all && drop_all_bypass == NECP_DROP_ALL_BYPASS_CHECK_RESULT_FALSE) {
			allowed_to_receive = FALSE;
		} else {
			if (return_policy_id) {
				*return_policy_id = NECP_KERNEL_POLICY_ID_NO_MATCH;
			}
			if (return_route_rule_id) {
				*return_route_rule_id = route_rule_id;
			}
		}
	}

	lck_rw_done(&necp_kernel_policy_lock);

done:
	if (!allowed_to_receive && interface_type_denied != IFRTYPE_FUNCTIONAL_UNKNOWN) {
		soevent(inp->inp_socket, (SO_FILT_HINT_LOCKED | SO_FILT_HINT_IFDENIED));
	}

	return allowed_to_receive;
}

bool
necp_socket_is_allowed_to_send_recv_v4(struct inpcb *inp, u_int16_t local_port, u_int16_t remote_port, struct in_addr *local_addr, struct in_addr *remote_addr, ifnet_t interface, necp_kernel_policy_id *return_policy_id, u_int32_t *return_route_rule_id, necp_kernel_policy_id *return_skip_policy_id)
{
	struct sockaddr_in local = {};
	struct sockaddr_in remote = {};
	local.sin_family = remote.sin_family = AF_INET;
	local.sin_len = remote.sin_len = sizeof(struct sockaddr_in);
	local.sin_port = local_port;
	remote.sin_port = remote_port;
	memcpy(&local.sin_addr, local_addr, sizeof(local.sin_addr));
	memcpy(&remote.sin_addr, remote_addr, sizeof(remote.sin_addr));

	return necp_socket_is_allowed_to_send_recv_internal(inp, (struct sockaddr *)&local, (struct sockaddr *)&remote, interface,
	           return_policy_id, return_route_rule_id, return_skip_policy_id);
}

bool
necp_socket_is_allowed_to_send_recv_v6(struct inpcb *inp, u_int16_t local_port, u_int16_t remote_port, struct in6_addr *local_addr, struct in6_addr *remote_addr, ifnet_t interface, necp_kernel_policy_id *return_policy_id, u_int32_t *return_route_rule_id, necp_kernel_policy_id *return_skip_policy_id)
{
	struct sockaddr_in6 local = {};
	struct sockaddr_in6 remote = {};
	local.sin6_family = remote.sin6_family = AF_INET6;
	local.sin6_len = remote.sin6_len = sizeof(struct sockaddr_in6);
	local.sin6_port = local_port;
	remote.sin6_port = remote_port;
	memcpy(&local.sin6_addr, local_addr, sizeof(local.sin6_addr));
	memcpy(&remote.sin6_addr, remote_addr, sizeof(remote.sin6_addr));

	return necp_socket_is_allowed_to_send_recv_internal(inp, (struct sockaddr *)&local, (struct sockaddr *)&remote, interface,
	           return_policy_id, return_route_rule_id, return_skip_policy_id);
}

bool
necp_socket_is_allowed_to_send_recv(struct inpcb *inp, ifnet_t interface, necp_kernel_policy_id *return_policy_id,
    u_int32_t *return_route_rule_id,
    necp_kernel_policy_id *return_skip_policy_id)
{
	return necp_socket_is_allowed_to_send_recv_internal(inp, NULL, NULL, interface,
	           return_policy_id, return_route_rule_id,
	           return_skip_policy_id);
}

int
necp_mark_packet_from_socket(struct mbuf *packet, struct inpcb *inp, necp_kernel_policy_id policy_id, u_int32_t route_rule_id,
    necp_kernel_policy_id skip_policy_id)
{
	if (packet == NULL || inp == NULL || !(packet->m_flags & M_PKTHDR)) {
		return EINVAL;
	}

	// Mark ID for Pass and IP Tunnel
	if (policy_id != NECP_KERNEL_POLICY_ID_NONE) {
		packet->m_pkthdr.necp_mtag.necp_policy_id = policy_id;
	} else if (inp->inp_policyresult.results.result == NECP_KERNEL_POLICY_RESULT_PASS ||
	    inp->inp_policyresult.results.result == NECP_KERNEL_POLICY_RESULT_IP_TUNNEL) {
		packet->m_pkthdr.necp_mtag.necp_policy_id = inp->inp_policyresult.policy_id;
	} else {
		packet->m_pkthdr.necp_mtag.necp_policy_id = NECP_KERNEL_POLICY_ID_NONE;
	}
	packet->m_pkthdr.necp_mtag.necp_last_interface_index = 0;
	if (route_rule_id != 0) {
		packet->m_pkthdr.necp_mtag.necp_route_rule_id = route_rule_id;
	} else {
		packet->m_pkthdr.necp_mtag.necp_route_rule_id = inp->inp_policyresult.results.route_rule_id;
	}
	packet->m_pkthdr.necp_mtag.necp_app_id = inp->inp_policyresult.app_id;

	if (skip_policy_id != NECP_KERNEL_POLICY_ID_NONE &&
	    skip_policy_id != NECP_KERNEL_POLICY_ID_NO_MATCH) {
		// Only mark the skip policy if it is a valid policy ID
		packet->m_pkthdr.necp_mtag.necp_skip_policy_id = skip_policy_id;
	} else if (inp->inp_policyresult.results.filter_control_unit == NECP_FILTER_UNIT_NO_FILTER) {
		// Overload the meaning of "NECP_KERNEL_POLICY_ID_NO_MATCH"
		// to indicate that NECP_FILTER_UNIT_NO_FILTER was set
		// See necp_get_skip_policy_id_from_packet() and
		// necp_packet_should_skip_filters().
		packet->m_pkthdr.necp_mtag.necp_skip_policy_id = NECP_KERNEL_POLICY_ID_NO_MATCH;
	} else {
		packet->m_pkthdr.necp_mtag.necp_skip_policy_id = NECP_KERNEL_POLICY_ID_NONE;
	}

	return 0;
}

int
necp_mark_packet_from_ip(struct mbuf *packet, necp_kernel_policy_id policy_id)
{
	if (packet == NULL || !(packet->m_flags & M_PKTHDR)) {
		return EINVAL;
	}

	// Mark ID for Pass and IP Tunnel
	if (policy_id != NECP_KERNEL_POLICY_ID_NONE) {
		packet->m_pkthdr.necp_mtag.necp_policy_id = policy_id;
	} else {
		packet->m_pkthdr.necp_mtag.necp_policy_id = NECP_KERNEL_POLICY_ID_NONE;
	}

	return 0;
}

int
necp_mark_packet_from_interface(struct mbuf *packet, ifnet_t interface)
{
	if (packet == NULL || !(packet->m_flags & M_PKTHDR)) {
		return EINVAL;
	}

	// Mark ID for Pass and IP Tunnel
	if (interface != NULL) {
		packet->m_pkthdr.necp_mtag.necp_last_interface_index = interface->if_index;
	}

	return 0;
}

int
necp_mark_packet_as_keepalive(struct mbuf *packet, bool is_keepalive)
{
	if (packet == NULL || !(packet->m_flags & M_PKTHDR)) {
		return EINVAL;
	}

	if (is_keepalive) {
		packet->m_pkthdr.pkt_flags |= PKTF_KEEPALIVE;
	} else {
		packet->m_pkthdr.pkt_flags &= ~PKTF_KEEPALIVE;
	}

	return 0;
}

necp_kernel_policy_id
necp_get_policy_id_from_packet(struct mbuf *packet)
{
	if (packet == NULL || !(packet->m_flags & M_PKTHDR)) {
		return NECP_KERNEL_POLICY_ID_NONE;
	}

	return packet->m_pkthdr.necp_mtag.necp_policy_id;
}

necp_kernel_policy_id
necp_get_skip_policy_id_from_packet(struct mbuf *packet)
{
	if (packet == NULL || !(packet->m_flags & M_PKTHDR)) {
		return NECP_KERNEL_POLICY_ID_NONE;
	}

	// Check for overloaded value. See necp_mark_packet_from_socket().
	if (packet->m_pkthdr.necp_mtag.necp_skip_policy_id == NECP_KERNEL_POLICY_ID_NO_MATCH) {
		return NECP_KERNEL_POLICY_ID_NONE;
	}

	return packet->m_pkthdr.necp_mtag.necp_skip_policy_id;
}

bool
necp_packet_should_skip_filters(struct mbuf *packet)
{
	if (packet == NULL || !(packet->m_flags & M_PKTHDR)) {
		return false;
	}

	// Check for overloaded value. See necp_mark_packet_from_socket().
	return packet->m_pkthdr.necp_mtag.necp_skip_policy_id == NECP_KERNEL_POLICY_ID_NO_MATCH;
}

u_int32_t
necp_get_last_interface_index_from_packet(struct mbuf *packet)
{
	if (packet == NULL || !(packet->m_flags & M_PKTHDR)) {
		return 0;
	}

	return packet->m_pkthdr.necp_mtag.necp_last_interface_index;
}

u_int32_t
necp_get_route_rule_id_from_packet(struct mbuf *packet)
{
	if (packet == NULL || !(packet->m_flags & M_PKTHDR)) {
		return 0;
	}

	return packet->m_pkthdr.necp_mtag.necp_route_rule_id;
}

int
necp_get_app_uuid_from_packet(struct mbuf *packet,
    uuid_t app_uuid)
{
	if (packet == NULL || !(packet->m_flags & M_PKTHDR)) {
		return EINVAL;
	}

	bool found_mapping = FALSE;
	if (packet->m_pkthdr.necp_mtag.necp_app_id != 0) {
		lck_rw_lock_shared(&necp_kernel_policy_lock);
		struct necp_uuid_id_mapping *entry = necp_uuid_lookup_uuid_with_app_id_locked(packet->m_pkthdr.necp_mtag.necp_app_id);
		if (entry != NULL) {
			uuid_copy(app_uuid, entry->uuid);
			found_mapping = true;
		}
		lck_rw_done(&necp_kernel_policy_lock);
	}
	if (!found_mapping) {
		uuid_clear(app_uuid);
	}
	return 0;
}

bool
necp_get_is_keepalive_from_packet(struct mbuf *packet)
{
	if (packet == NULL || !(packet->m_flags & M_PKTHDR)) {
		return FALSE;
	}

	return packet->m_pkthdr.pkt_flags & PKTF_KEEPALIVE;
}

u_int32_t
necp_socket_get_content_filter_control_unit(struct socket *so)
{
	struct inpcb *inp = sotoinpcb(so);

	if (inp == NULL) {
		return 0;
	}
	return inp->inp_policyresult.results.filter_control_unit;
}

bool
necp_socket_should_use_flow_divert(struct inpcb *inp)
{
	if (inp == NULL) {
		return FALSE;
	}

	return inp->inp_policyresult.results.result == NECP_KERNEL_POLICY_RESULT_SOCKET_DIVERT;
}

u_int32_t
necp_socket_get_flow_divert_control_unit(struct inpcb *inp)
{
	if (inp == NULL) {
		return 0;
	}

	if (inp->inp_policyresult.results.result == NECP_KERNEL_POLICY_RESULT_SOCKET_DIVERT) {
		return inp->inp_policyresult.results.result_parameter.flow_divert_control_unit;
	}

	return 0;
}

bool
necp_socket_should_rescope(struct inpcb *inp)
{
	if (inp == NULL) {
		return FALSE;
	}

	return inp->inp_policyresult.results.result == NECP_KERNEL_POLICY_RESULT_SOCKET_SCOPED ||
	       inp->inp_policyresult.results.result == NECP_KERNEL_POLICY_RESULT_SCOPED_DIRECT;
}

u_int
necp_socket_get_rescope_if_index(struct inpcb *inp)
{
	if (inp == NULL) {
		return 0;
	}

	if (inp->inp_policyresult.results.result == NECP_KERNEL_POLICY_RESULT_SOCKET_SCOPED) {
		return inp->inp_policyresult.results.result_parameter.scoped_interface_index;
	} else if (inp->inp_policyresult.results.result == NECP_KERNEL_POLICY_RESULT_SCOPED_DIRECT) {
		return necp_get_primary_direct_interface_index();
	}

	return 0;
}

u_int32_t
necp_socket_get_effective_mtu(struct inpcb *inp, u_int32_t current_mtu)
{
	if (inp == NULL) {
		return current_mtu;
	}

	if (inp->inp_policyresult.results.result == NECP_KERNEL_POLICY_RESULT_IP_TUNNEL &&
	    (inp->inp_flags & INP_BOUND_IF) &&
	    inp->inp_boundifp) {
		u_int bound_interface_index = inp->inp_boundifp->if_index;
		u_int tunnel_interface_index = inp->inp_policyresult.results.result_parameter.tunnel_interface_index;

		// The result is IP Tunnel, and is rescoping from one interface to another. Recalculate MTU.
		if (bound_interface_index != tunnel_interface_index) {
			ifnet_t tunnel_interface = NULL;

			ifnet_head_lock_shared();
			tunnel_interface = ifindex2ifnet[tunnel_interface_index];
			ifnet_head_done();

			if (tunnel_interface != NULL) {
				u_int32_t direct_tunnel_mtu = tunnel_interface->if_mtu;
				u_int32_t delegate_tunnel_mtu = (tunnel_interface->if_delegated.ifp != NULL) ? tunnel_interface->if_delegated.ifp->if_mtu : 0;
				if (delegate_tunnel_mtu != 0 &&
				    strncmp(tunnel_interface->if_name, "ipsec", strlen("ipsec")) == 0) {
					// For ipsec interfaces, calculate the overhead from the delegate interface
					u_int32_t tunnel_overhead = (u_int32_t)(esp_hdrsiz(NULL) + sizeof(struct ip6_hdr));
					if (delegate_tunnel_mtu > tunnel_overhead) {
						delegate_tunnel_mtu -= tunnel_overhead;
					}

					if (delegate_tunnel_mtu < direct_tunnel_mtu) {
						// If the (delegate - overhead) < direct, return (delegate - overhead)
						return delegate_tunnel_mtu;
					} else {
						// Otherwise return direct
						return direct_tunnel_mtu;
					}
				} else {
					// For non-ipsec interfaces, just return the tunnel MTU
					return direct_tunnel_mtu;
				}
			}
		}
	}

	// By default, just return the MTU passed in
	return current_mtu;
}

ifnet_t
necp_get_ifnet_from_result_parameter(necp_kernel_policy_result_parameter *result_parameter)
{
	if (result_parameter == NULL) {
		return NULL;
	}

	return ifindex2ifnet[result_parameter->tunnel_interface_index];
}

bool
necp_packet_can_rebind_to_ifnet(struct mbuf *packet, struct ifnet *interface, struct route *new_route, int family)
{
	bool found_match = FALSE;
	errno_t result = 0;
	ifaddr_t *addresses = NULL;
	union necp_sockaddr_union address_storage;
	int i;

	if (packet == NULL || interface == NULL || new_route == NULL || (family != AF_INET && family != AF_INET6)) {
		return FALSE;
	}

	result = ifnet_get_address_list_family(interface, &addresses, family);
	if (result != 0) {
		NECPLOG(LOG_ERR, "Failed to get address list for %s%d", ifnet_name(interface), ifnet_unit(interface));
		return FALSE;
	}

	for (i = 0; addresses[i] != NULL; i++) {
		ROUTE_RELEASE(new_route);
		if (ifaddr_address(addresses[i], &address_storage.sa, sizeof(address_storage)) == 0) {
			if (family == AF_INET) {
				struct ip *ip = mtod(packet, struct ip *);
				if (memcmp(&address_storage.sin.sin_addr, &ip->ip_src, sizeof(ip->ip_src)) == 0) {
					struct sockaddr_in *dst4 = (struct sockaddr_in *)(void *)&new_route->ro_dst;
					dst4->sin_family = AF_INET;
					dst4->sin_len = sizeof(struct sockaddr_in);
					dst4->sin_addr = ip->ip_dst;
					rtalloc_scoped(new_route, interface->if_index);
					if (!ROUTE_UNUSABLE(new_route)) {
						found_match = TRUE;
						goto done;
					}
				}
			} else if (family == AF_INET6) {
				struct ip6_hdr *ip6 = mtod(packet, struct ip6_hdr *);
				if (memcmp(&address_storage.sin6.sin6_addr, &ip6->ip6_src, sizeof(ip6->ip6_src)) == 0) {
					struct sockaddr_in6 *dst6 = (struct sockaddr_in6 *)(void *)&new_route->ro_dst;
					dst6->sin6_family = AF_INET6;
					dst6->sin6_len = sizeof(struct sockaddr_in6);
					dst6->sin6_addr = ip6->ip6_dst;
					rtalloc_scoped(new_route, interface->if_index);
					if (!ROUTE_UNUSABLE(new_route)) {
						found_match = TRUE;
						goto done;
					}
				}
			}
		}
	}

done:
	ifnet_free_address_list(addresses);
	addresses = NULL;
	return found_match;
}

static bool
necp_addr_is_loopback(struct sockaddr *address)
{
	if (address == NULL) {
		return FALSE;
	}

	if (address->sa_family == AF_INET) {
		return ntohl(((struct sockaddr_in *)(void *)address)->sin_addr.s_addr) == INADDR_LOOPBACK;
	} else if (address->sa_family == AF_INET6) {
		return IN6_IS_ADDR_LOOPBACK(&((struct sockaddr_in6 *)(void *)address)->sin6_addr);
	}

	return FALSE;
}

static bool
necp_is_loopback(struct sockaddr *local_addr, struct sockaddr *remote_addr, struct inpcb *inp, struct mbuf *packet, u_int32_t bound_interface_index)
{
	// Note: This function only checks for the loopback addresses.
	// In the future, we may want to expand to also allow any traffic
	// going through the loopback interface, but until then, this
	// check is cheaper.

	if (local_addr != NULL && necp_addr_is_loopback(local_addr)) {
		return TRUE;
	}

	if (remote_addr != NULL && necp_addr_is_loopback(remote_addr)) {
		return TRUE;
	}

	if (inp != NULL) {
		if ((inp->inp_flags & INP_BOUND_IF) && inp->inp_boundifp && (inp->inp_boundifp->if_flags & IFF_LOOPBACK)) {
			return TRUE;
		}
		if (inp->inp_vflag & INP_IPV4) {
			if (ntohl(inp->inp_laddr.s_addr) == INADDR_LOOPBACK ||
			    ntohl(inp->inp_faddr.s_addr) == INADDR_LOOPBACK) {
				return TRUE;
			}
		} else if (inp->inp_vflag & INP_IPV6) {
			if (IN6_IS_ADDR_LOOPBACK(&inp->in6p_laddr) ||
			    IN6_IS_ADDR_LOOPBACK(&inp->in6p_faddr)) {
				return TRUE;
			}
		}
	} else if (bound_interface_index != IFSCOPE_NONE && lo_ifp->if_index == bound_interface_index) {
		return TRUE;
	}

	if (packet != NULL) {
		struct ip *ip = mtod(packet, struct ip *);
		if (ip->ip_v == 4) {
			if (ntohl(ip->ip_src.s_addr) == INADDR_LOOPBACK) {
				return TRUE;
			}
			if (ntohl(ip->ip_dst.s_addr) == INADDR_LOOPBACK) {
				return TRUE;
			}
		} else if (ip->ip_v == 6) {
			struct ip6_hdr *ip6 = mtod(packet, struct ip6_hdr *);
			if (IN6_IS_ADDR_LOOPBACK(&ip6->ip6_src)) {
				return TRUE;
			}
			if (IN6_IS_ADDR_LOOPBACK(&ip6->ip6_dst)) {
				return TRUE;
			}
		}
	}

	return FALSE;
}

static bool
necp_is_intcoproc(struct inpcb *inp, struct mbuf *packet)
{
	if (inp != NULL) {
		if (!(inp->inp_vflag & INP_IPV6)) {
			return false;
		}
		if (INP_INTCOPROC_ALLOWED(inp)) {
			return true;
		}
		if ((inp->inp_flags & INP_BOUND_IF) &&
		    IFNET_IS_INTCOPROC(inp->inp_boundifp)) {
			return true;
		}
		return false;
	}
	if (packet != NULL) {
		struct ip6_hdr *ip6 = mtod(packet, struct ip6_hdr *);
		if ((ip6->ip6_vfc & IPV6_VERSION_MASK) == IPV6_VERSION &&
		    IN6_IS_ADDR_LINKLOCAL(&ip6->ip6_dst) &&
		    ip6->ip6_dst.s6_addr32[2] == ntohl(0xaede48ff) &&
		    ip6->ip6_dst.s6_addr32[3] == ntohl(0xfe334455)) {
			return true;
		}
	}

	return false;
}

static bool
necp_address_matches_drop_dest_policy(union necp_sockaddr_union *sau, u_int32_t session_order)
{
	char dest_str[MAX_IPv6_STR_LEN];

	if (necp_drop_dest_debug > 0) {
		if (sau->sa.sa_family == AF_INET) {
			(void) inet_ntop(AF_INET, &sau->sin.sin_addr, dest_str, sizeof(dest_str));
		} else if (sau->sa.sa_family == AF_INET6) {
			(void) inet_ntop(AF_INET6, &sau->sin6.sin6_addr, dest_str, sizeof(dest_str));
		} else {
			dest_str[0] = 0;
		}
	}
	for (u_int32_t i = 0; i < necp_drop_dest_policy.entry_count; i++) {
		struct necp_drop_dest_entry *necp_drop_dest_entry = &necp_drop_dest_policy.entries[i];
		struct necp_policy_condition_addr *npca = &necp_drop_dest_entry->cond_addr;

		if (session_order >= necp_drop_dest_entry->order && necp_is_addr_in_subnet(&sau->sa, &npca->address.sa, npca->prefix)) {
			if (necp_drop_dest_debug > 0) {
				char subnet_str[MAX_IPv6_STR_LEN];
				struct proc *p = current_proc();
				pid_t pid = proc_pid(p);

				if (sau->sa.sa_family == AF_INET) {
					(void) inet_ntop(AF_INET, &npca->address.sin, subnet_str, sizeof(subnet_str));
					os_log(OS_LOG_DEFAULT, "%s (process %s:%u) %s matches %s/%u", __func__, proc_best_name(p), pid, dest_str, subnet_str, npca->prefix);
				} else if (sau->sa.sa_family == AF_INET6) {
					(void) inet_ntop(AF_INET6, &npca->address.sin6, subnet_str, sizeof(subnet_str));
					os_log(OS_LOG_DEFAULT, "%s (process %s:%u) %s matches %s/%u", __func__, proc_best_name(p), pid, dest_str, subnet_str, npca->prefix);
				}
			}
			return true;
		}
	}
	if (necp_drop_dest_debug > 1) {
		struct proc *p = current_proc();
		pid_t pid = proc_pid(p);

		os_log(OS_LOG_DEFAULT, "%s (process %s:%u) %s no match", __func__, proc_best_name(p), pid, dest_str);
	}
	return false;
}

static int
sysctl_handle_necp_drop_dest_level SYSCTL_HANDLER_ARGS
{
#pragma unused(arg1, arg2, oidp)
	int changed = 0;
	int error = 0;
	struct necp_drop_dest_policy tmp_drop_dest_policy;
	struct proc *p = current_proc();
	pid_t pid = proc_pid(p);

	if (req->newptr != USER_ADDR_NULL && proc_suser(current_proc()) != 0 &&
	    priv_check_cred(kauth_cred_get(), PRIV_NET_PRIVILEGED_NECP_POLICIES, 0) != 0) {
		NECPLOG(LOG_ERR, "%s (process %s:%u) not permitted", __func__, proc_best_name(p), pid);
		return EPERM;
	}
	if (req->newptr != USER_ADDR_NULL && req->newlen != sizeof(struct necp_drop_dest_policy)) {
		NECPLOG(LOG_ERR, "%s (process %s:%u) bad newlen %lu", __func__, proc_best_name(p), pid, req->newlen);
		return EINVAL;
	}

	memcpy(&tmp_drop_dest_policy, &necp_drop_dest_policy, sizeof(struct necp_drop_dest_policy));
	error = sysctl_io_opaque(req, &tmp_drop_dest_policy, sizeof(struct necp_drop_dest_policy), &changed);
	if (error != 0) {
		NECPLOG(LOG_ERR, "%s (process %s:%u) sysctl_io_opaque() error %d", __func__, proc_best_name(p), pid, error);
		return error;
	}
	if (changed == 0 || req->newptr == USER_ADDR_NULL) {
		return error;
	}

	//
	// Validate the passed parameters
	//
	if (tmp_drop_dest_policy.entry_count >= MAX_NECP_DROP_DEST_LEVEL_ADDRS) {
		NECPLOG(LOG_ERR, "%s (process %s:%u) bad entry_count %u", __func__, proc_best_name(p), pid, tmp_drop_dest_policy.entry_count);
		return EINVAL;
	}
	for (u_int32_t i = 0; i < tmp_drop_dest_policy.entry_count; i++) {
		struct necp_drop_dest_entry *tmp_drop_dest_entry = &tmp_drop_dest_policy.entries[i];
		struct necp_policy_condition_addr *npca = &tmp_drop_dest_entry->cond_addr;

		switch (tmp_drop_dest_entry->level) {
		case NECP_SESSION_PRIORITY_UNKNOWN:
			if (tmp_drop_dest_policy.entry_count != 0) {
				NECPLOG(LOG_ERR, "%s (process %s:%u) NECP_SESSION_PRIORITY_UNKNOWN bad entry_count %u", __func__, proc_best_name(p), pid, tmp_drop_dest_policy.entry_count);
				return EINVAL;
			}
			break;
		case NECP_SESSION_PRIORITY_CONTROL:
		case NECP_SESSION_PRIORITY_PRIVILEGED_TUNNEL:
		case NECP_SESSION_PRIORITY_HIGH:
		case NECP_SESSION_PRIORITY_DEFAULT:
		case NECP_SESSION_PRIORITY_LOW:
			if (tmp_drop_dest_policy.entry_count == 0) {
				NECPLOG(LOG_ERR, "%s (process %s:%u) priority %u entry_count 0", __func__, proc_best_name(p), pid, tmp_drop_dest_entry->level);
				return EINVAL;
			}
			break;
		default: {
			NECPLOG(LOG_ERR, "%s (process %s:%u) bad level %u", __func__, proc_best_name(p), pid, tmp_drop_dest_entry->level);
			return EINVAL;
		}
		}

		switch (npca->address.sa.sa_family) {
		case AF_INET: {
			if (npca->prefix > 32) {
				NECPLOG(LOG_ERR, "%s (process %s:%u) AF_INET bad prefix %u", __func__, proc_best_name(p), pid, npca->prefix);
				return EINVAL;
			}
			if (npca->address.sin.sin_len != sizeof(struct sockaddr_in)) {
				NECPLOG(LOG_ERR, "%s (process %s:%u) AF_INET bad sin_len %u", __func__, proc_best_name(p), pid, npca->address.sin.sin_len);
				return EINVAL;
			}
			if (npca->address.sin.sin_port != 0) {
				NECPLOG(LOG_ERR, "%s (process %s:%u) AF_INET bad sin_port %u, not zero", __func__, proc_best_name(p), pid, npca->address.sin.sin_port);
				return EINVAL;
			}
			break;
		}
		case AF_INET6: {
			if (npca->prefix > 128) {
				NECPLOG(LOG_ERR, "%s (process %s:%u) AF_INET6 bad prefix %u", __func__, proc_best_name(p), pid, npca->prefix);
				return EINVAL;
			}
			if (npca->address.sin6.sin6_len != sizeof(struct sockaddr_in6)) {
				NECPLOG(LOG_ERR, "%s (process %s:%u) AF_INET6 bad sin6_len %u", __func__, proc_best_name(p), pid, npca->address.sin6.sin6_len);
				return EINVAL;
			}
			if (npca->address.sin6.sin6_port != 0) {
				NECPLOG(LOG_ERR, "%s (process %s:%u) AF_INET6 bad sin6_port %u, not zero", __func__, proc_best_name(p), pid, npca->address.sin6.sin6_port);
				return EINVAL;
			}
			if (npca->address.sin6.sin6_flowinfo != 0) {
				NECPLOG(LOG_ERR, "%s (process %s:%u) AF_INET6 bad sin6_flowinfo %u, not zero", __func__, proc_best_name(p), pid, npca->address.sin6.sin6_flowinfo);
				return EINVAL;
			}
			if (npca->address.sin6.sin6_scope_id != 0) {
				NECPLOG(LOG_ERR, "%s (process %s:%u) AF_INET6 bad sin6_scope_id %u, not zero", __func__, proc_best_name(p), pid, npca->address.sin6.sin6_scope_id);
				return EINVAL;
			}
			break;
		}
		default: {
			return EINVAL;
		}
		}
	}

	//
	// Commit the changed policy
	//
	lck_rw_lock_exclusive(&necp_kernel_policy_lock);
	memset(&necp_drop_dest_policy, 0, sizeof(struct necp_drop_dest_policy));

	necp_drop_dest_policy.entry_count = tmp_drop_dest_policy.entry_count;
	for (u_int32_t i = 0; i < tmp_drop_dest_policy.entry_count; i++) {
		struct necp_drop_dest_entry *tmp_drop_dest_entry = &tmp_drop_dest_policy.entries[i];
		struct necp_drop_dest_entry *necp_drop_dest_entry = &necp_drop_dest_policy.entries[i];

		memcpy(necp_drop_dest_entry, tmp_drop_dest_entry, sizeof(struct necp_drop_dest_entry));

		necp_drop_dest_entry->order = necp_get_first_order_for_priority(necp_drop_dest_entry->level);
	}
	lck_rw_done(&necp_kernel_policy_lock);

	return 0;
}