ocspdUtils.cpp   [plain text]


/*
 * Copyright (c) 2002,2000 Apple Computer, Inc. All rights reserved.
 *
 * @APPLE_LICENSE_HEADER_START@
 * 
 * The contents of this file constitute Original Code as defined in and
 * are subject to the Apple Public Source License Version 1.1 (the
 * "License").  You may not use this file except in compliance with the
 * License.  Please obtain a copy of the License at
 * http://www.apple.com/publicsource and read it before using this file.
 * 
 * This 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 OR NON-INFRINGEMENT.  Please see the
 * License for the specific language governing rights and limitations
 * under the License.
 * 
 * @APPLE_LICENSE_HEADER_END@
 */

/* 
 * ocspUtils.cpp - common utilities for OCSPD
 */

#include "ocspdUtils.h"
#include <CoreFoundation/CoreFoundation.h>

/*
 * Compare two CSSM_DATAs, return CSSM_TRUE if identical.
 */
CSSM_BOOL ocspdCompareCssmData(
	const CSSM_DATA *data1,
	const CSSM_DATA *data2)
{	
	if((data1 == NULL) || (data1->Data == NULL) || 
	   (data2 == NULL) || (data2->Data == NULL) ||
	   (data1->Length != data2->Length)) {
		return CSSM_FALSE;
	}
	if(data1->Length != data2->Length) {
		return CSSM_FALSE;
	}
	if(memcmp(data1->Data, data2->Data, data1->Length) == 0) {
		return CSSM_TRUE;
	}
	else {
		return CSSM_FALSE;
	}
}

/*
 * Convert a generalized time string, with a 4-digit year and no trailing
 * fractional seconds or time zone info, to a CFAbsoluteTime. Returns 
 * NULL_TIME (0.0) on error. 
 */
static CFAbsoluteTime parseGenTime(
	const uint8 *str,
	uint32 len)
{
	if((str == NULL) || (len == 0)) {
    	return NULL_TIME;
  	}
	
  	/* tolerate NULL terminated or not */
  	if(str[len - 1] == '\0') {
  		len--;
  	}
	if(len < 4) {
		return NULL_TIME;
	}
	char szTemp[5];
	CFGregorianDate greg;
	memset(&greg, 0, sizeof(greg));
	const uint8 *cp = str;
	
	/* YEAR */
	szTemp[0] = *cp++;
	szTemp[1] = *cp++;
	szTemp[2] = *cp++;
	szTemp[3] = *cp++;
	szTemp[4] = '\0';
	len -= 4;
	greg.year = atoi(szTemp);
	
	/* MONTH - CFGregorianDate ranges 1..12, just like the string */
	if(len < 2) {
		return NULL_TIME;
	}
	szTemp[0] = *cp++;
	szTemp[1] = *cp++;
	szTemp[2] = '\0';
	len -= 2;
	greg.month = atoi( szTemp );

	/* DAY - 1..31 */
	if(len < 2) {
		return NULL_TIME;
	}
	szTemp[0] = *cp++;
	szTemp[1] = *cp++;
	szTemp[2] = '\0';
	greg.day = atoi( szTemp );
	len -= 2;
	
	if(len >= 2) {
		/* HOUR 0..23 */
		szTemp[0] = *cp++;
		szTemp[1] = *cp++;
		szTemp[2] = '\0';
		greg.hour = atoi( szTemp );
		len -= 2;
	}
	if(len >= 2) {
		/* MINUTE 0..59 */
		szTemp[0] = *cp++;
		szTemp[1] = *cp++;
		szTemp[2] = '\0';
		greg.minute = atoi( szTemp );
		len -= 2;
	}
	if(len >= 2) {
		/* SECOND 0..59 */
		szTemp[0] = *cp++;
		szTemp[1] = *cp++;
		szTemp[2] = '\0';
		greg.second = atoi( szTemp );
		len -= 2;
	}
	return CFGregorianDateGetAbsoluteTime(greg, NULL);
}

/*
 * Parse a GeneralizedTime string into a CFAbsoluteTime. Returns NULL on parse error.
 * Fractional parts of a second are discarded. 
 */
CFAbsoluteTime genTimeToCFAbsTime(
	const CSSM_DATA *strData)
{
	if((strData == NULL) || (strData->Data == NULL) || (strData->Length == 0)) {
    	return NULL_TIME;
  	}
	
	uint8 *timeStr = strData->Data;
	size_t timeStrLen = strData->Length;
  	
  	/* tolerate NULL terminated or not */
  	if(timeStr[timeStrLen - 1] == '\0') {
  		timeStrLen--;
  	}
	
	/* start with a fresh editable copy */
	uint8 *str = (uint8 *)malloc(timeStrLen);
	uint32 strLen = 0;
	
	/* 
	 * If there is a decimal point, strip it and all trailing digits off
	 */
	const uint8 *inCp = timeStr;
	uint8 *outCp = str;
	int foundDecimal = 0;
	int minutesOffset = 0;
	int hoursOffset = 0;
	bool minusOffset = false;
	bool isGMT = false;
	size_t toGo = timeStrLen;
	
	do {
		if(*inCp == '.') {
			if(foundDecimal) {
				/* only legal once */ {
					free(str);
					return NULL_TIME;
				}
			}
			foundDecimal++;
			
			/* skip the decimal point... */
			inCp++;
			toGo--;
			if(toGo == 0) {
				/* all done */
				break;
			}
			/* then all subsequent contiguous digits */
			while(isdigit(*inCp) && (toGo != 0)) {
				inCp++;
				toGo--;
			}
		}	/* decimal point processing */
		else if((*inCp == '+') || (*inCp == '-')) {
			/* Time zone offset - handle 2 or 4 chars */
			if((toGo != 2) & (toGo != 4)) {
				free(str);
				return NULL_TIME;
			}
			if(*inCp == '-') {
				minusOffset = true;
			}
			inCp++;
			hoursOffset = (10 * (inCp[0] - '0')) + (inCp[1] - '0');
			toGo -= 2;
			if(toGo) {
				minutesOffset = (10 * (inCp[0] - '0')) + (inCp[1] - '0');
				toGo -= 2;
			}
		}
		else {
			*outCp++ = *inCp++;
			strLen++;
			toGo--;
		}
	} while(toGo != 0);
	
	if(str[strLen - 1] == 'Z') {
		isGMT = true;
		strLen--;
	}
	
	CFAbsoluteTime absTime;
	absTime = parseGenTime(str, strLen);
	free(str);
	if(absTime == NULL_TIME) {
		return NULL_TIME;
	}
	
	/* post processing needed? */
	if(isGMT) {
		/* Nope, string was in GMT */
		return absTime;
	}
	if((minutesOffset != 0) || (hoursOffset != 0)) {
		/* string contained explicit offset from GMT */
		if(minusOffset) {
			absTime -= (minutesOffset * 60);
			absTime -= (hoursOffset * 3600);
		}
		else {
			absTime += (minutesOffset * 60);
			absTime += (hoursOffset * 3600);
		}
	}
	else {
		/* implciit offset = local */
		CFTimeInterval tzDelta;
		CFTimeZoneRef localZone = CFTimeZoneCopySystem();
		tzDelta = CFTimeZoneGetSecondsFromGMT (localZone, CFAbsoluteTimeGetCurrent());
		CFRelease(localZone);
		absTime += tzDelta;
	}
	return absTime;
}

/* 
 * Convert CFAbsoluteTime to generalized time string, GMT format (4 digit year,
 * trailing 'Z'). Caller allocated the output which is GENERAL_TIME_STRLEN+1 bytes.
 */
void cfAbsTimeToGgenTime(
	CFAbsoluteTime		absTime,
	char				*genTime)
{
	/* time zone = GMT */
	CFTimeZoneRef tz = CFTimeZoneCreateWithTimeIntervalFromGMT(NULL, 0.0);
	CFGregorianDate greg = CFAbsoluteTimeGetGregorianDate(absTime, tz);
	int seconds = (int)greg.second;
	sprintf(genTime, "%04d%02d%02d%02d%02d%02dZ",
				(int)greg.year, greg.month, greg.day, greg.hour, 
				greg.minute, seconds);
}
 
void ocspdSha1(
	const void		*data,
	CC_LONG			len,
	unsigned char	*md)		// allocd by caller, CC_SHA1_DIGEST_LENGTH bytes
{
	CC_SHA1_CTX ctx;
	CC_SHA1_Init(&ctx);
	CC_SHA1_Update(&ctx, data, len);
	CC_SHA1_Final(md, &ctx);
}

void ocspdMD5(
	const void		*data,
	CC_LONG			len,
	unsigned char	*md)		// allocd by caller, CC_MD5_DIGEST_LENGTH bytes
{
	CC_MD5_CTX ctx;
	CC_MD5_Init(&ctx);
	CC_MD5_Update(&ctx, data, len);
	CC_MD5_Final(md, &ctx);
}

void ocspdMD4(
	const void		*data,
	CC_LONG			len,
	unsigned char	*md)		// allocd by caller, CC_MD4_DIGEST_LENGTH bytes
{
	CC_MD4_CTX ctx;
	CC_MD4_Init(&ctx);
	CC_MD4_Update(&ctx, data, len);
	CC_MD4_Final(md, &ctx);
}

void ocspdSHA256(
	const void		*data,
	CC_LONG			len,
	unsigned char	*md)		// allocd by caller, CC_SHA256_DIGEST_LENGTH bytes
{
	CC_SHA256_CTX ctx;
	CC_SHA256_Init(&ctx);
	CC_SHA256_Update(&ctx, data, len);
	CC_SHA256_Final(md, &ctx);
}

/*
 * How many items in a NULL-terminated array of pointers?
 */
unsigned ocspdArraySize(
	const void **array)
{
    unsigned count = 0;
    if (array) {
		while (*array++) {
			count++;
		}
    }
    return count;
}