testb3_8.cpp   [plain text]

/*
 * Copyright (C) 2015-2019 Apple Inc. All rights reserved.
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions
 * are met:
 * 1. Redistributions of source code must retain the above copyright
 *    notice, this list of conditions and the following disclaimer.
 * 2. Redistributions in binary form must reproduce the above copyright
 *    notice, this list of conditions and the following disclaimer in the
 *    documentation and/or other materials provided with the distribution.
 *
 * THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
 * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
 * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL APPLE INC. OR
 * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
 * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
 * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
 * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
 * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
 * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
 */

#include "config.h"
#include "testb3.h"

#include <wtf/UniqueArray.h>

#if ENABLE(B3_JIT)

template<typename T>
void testAtomicWeakCAS()
{
    constexpr Type type = NativeTraits<T>::type;
    constexpr Width width = NativeTraits<T>::width;

    auto checkMyDisassembly = [&] (Compilation& compilation, bool fenced) {
        if (isX86()) {
            checkUsesInstruction(compilation, "lock");
            checkUsesInstruction(compilation, "cmpxchg");
        } else {
            if (fenced) {
                checkUsesInstruction(compilation, "ldax");
                checkUsesInstruction(compilation, "stlx");
            } else {
                checkUsesInstruction(compilation, "ldx");
                checkUsesInstruction(compilation, "stx");
            }
        }
    };

    {
        Procedure proc;
        BasicBlock* root = proc.addBlock();
        BasicBlock* reloop = proc.addBlock();
        BasicBlock* done = proc.addBlock();
    
        Value* ptr = root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0);
        root->appendNew<Value>(proc, Jump, Origin());
        root->setSuccessors(reloop);
    
        reloop->appendNew<Value>(
            proc, Branch, Origin(),
            reloop->appendNew<AtomicValue>(
                proc, AtomicWeakCAS, Origin(), width,
                reloop->appendIntConstant(proc, Origin(), type, 42),
                reloop->appendIntConstant(proc, Origin(), type, 0xbeef),
                ptr));
        reloop->setSuccessors(done, reloop);
    
        done->appendNew<Value>(proc, Return, Origin());
    
        auto code = compileProc(proc);
        T value[2];
        value[0] = 42;
        value[1] = 13;
        invoke<void>(*code, value);
        CHECK_EQ(value[0], static_cast<T>(0xbeef));
        CHECK_EQ(value[1], 13);
        checkMyDisassembly(*code, true);
    }

    {
        Procedure proc;
        BasicBlock* root = proc.addBlock();
        BasicBlock* reloop = proc.addBlock();
        BasicBlock* done = proc.addBlock();
    
        Value* ptr = root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0);
        root->appendNew<Value>(proc, Jump, Origin());
        root->setSuccessors(reloop);
    
        reloop->appendNew<Value>(
            proc, Branch, Origin(),
            reloop->appendNew<AtomicValue>(
                proc, AtomicWeakCAS, Origin(), width,
                reloop->appendIntConstant(proc, Origin(), type, 42),
                reloop->appendIntConstant(proc, Origin(), type, 0xbeef),
                ptr, 0, HeapRange(42), HeapRange()));
        reloop->setSuccessors(done, reloop);
    
        done->appendNew<Value>(proc, Return, Origin());
    
        auto code = compileProc(proc);
        T value[2];
        value[0] = 42;
        value[1] = 13;
        invoke<void>(*code, value);
        CHECK_EQ(value[0], static_cast<T>(0xbeef));
        CHECK_EQ(value[1], 13);
        checkMyDisassembly(*code, false);
    }

    {
        Procedure proc;
        BasicBlock* root = proc.addBlock();
        BasicBlock* succ = proc.addBlock();
        BasicBlock* fail = proc.addBlock();
    
        Value* ptr = root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0);
        root->appendNew<Value>(
            proc, Branch, Origin(),
            root->appendNew<AtomicValue>(
                proc, AtomicWeakCAS, Origin(), width,
                root->appendIntConstant(proc, Origin(), type, 42),
                root->appendIntConstant(proc, Origin(), type, 0xbeef),
                ptr));
        root->setSuccessors(succ, fail);
    
        succ->appendNew<MemoryValue>(
            proc, storeOpcode(GP, width), Origin(),
            succ->appendIntConstant(proc, Origin(), type, 100),
            ptr);
        succ->appendNew<Value>(proc, Return, Origin());
    
        fail->appendNew<Value>(proc, Return, Origin());
    
        auto code = compileProc(proc);
        T value[2];
        value[0] = 42;
        value[1] = 13;
        while (value[0] == 42)
            invoke<void>(*code, value);
        CHECK_EQ(value[0], static_cast<T>(100));
        CHECK_EQ(value[1], 13);
        value[0] = static_cast<T>(300);
        invoke<void>(*code, value);
        CHECK_EQ(value[0], static_cast<T>(300));
        CHECK_EQ(value[1], 13);
        checkMyDisassembly(*code, true);
    }

    {
        Procedure proc;
        BasicBlock* root = proc.addBlock();
        BasicBlock* succ = proc.addBlock();
        BasicBlock* fail = proc.addBlock();
    
        Value* ptr = root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0);
        root->appendNew<Value>(
            proc, Branch, Origin(),
            root->appendNew<Value>(
                proc, Equal, Origin(),
                root->appendNew<AtomicValue>(
                    proc, AtomicWeakCAS, Origin(), width,
                    root->appendIntConstant(proc, Origin(), type, 42),
                    root->appendIntConstant(proc, Origin(), type, 0xbeef),
                    ptr),
                root->appendIntConstant(proc, Origin(), Int32, 0)));
        root->setSuccessors(fail, succ);
    
        succ->appendNew<MemoryValue>(
            proc, storeOpcode(GP, width), Origin(),
            succ->appendIntConstant(proc, Origin(), type, 100),
            ptr);
        succ->appendNew<Value>(proc, Return, Origin());
    
        fail->appendNew<Value>(proc, Return, Origin());
    
        auto code = compileProc(proc);
        T value[2];
        value[0] = 42;
        value[1] = 13;
        while (value[0] == 42)
            invoke<void>(*code, value);
        CHECK_EQ(value[0], static_cast<T>(100));
        CHECK_EQ(value[1], 13);
        value[0] = static_cast<T>(300);
        invoke<void>(*code, value);
        CHECK_EQ(value[0], static_cast<T>(300));
        CHECK_EQ(value[1], 13);
        checkMyDisassembly(*code, true);
    }

    {
        Procedure proc;
        BasicBlock* root = proc.addBlock();
        root->appendNew<Value>(
            proc, Return, Origin(),
            root->appendNew<AtomicValue>(
                proc, AtomicWeakCAS, Origin(), width,
                root->appendIntConstant(proc, Origin(), type, 42),
                root->appendIntConstant(proc, Origin(), type, 0xbeef),
                root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0)));
    
        auto code = compileProc(proc);
        T value[2];
        value[0] = 42;
        value[1] = 13;
        while (!invoke<bool>(*code, value)) { }
        CHECK_EQ(value[0], static_cast<T>(0xbeef));
        CHECK_EQ(value[1], 13);
    
        value[0] = static_cast<T>(300);
        CHECK(!invoke<bool>(*code, value));
        CHECK_EQ(value[0], static_cast<T>(300));
        CHECK_EQ(value[1], 13);
        checkMyDisassembly(*code, true);
    }

    {
        Procedure proc;
        BasicBlock* root = proc.addBlock();
        root->appendNew<Value>(
            proc, Return, Origin(),
            root->appendNew<Value>(
                proc, Equal, Origin(),
                root->appendNew<AtomicValue>(
                    proc, AtomicWeakCAS, Origin(), width,
                    root->appendIntConstant(proc, Origin(), type, 42),
                    root->appendIntConstant(proc, Origin(), type, 0xbeef),
                    root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0)),
                root->appendNew<Const32Value>(proc, Origin(), 0)));
    
        auto code = compileProc(proc);
        T value[2];
        value[0] = 42;
        value[1] = 13;
        while (invoke<bool>(*code, value)) { }
        CHECK_EQ(value[0], static_cast<T>(0xbeef));
        CHECK_EQ(value[1], 13);
    
        value[0] = static_cast<T>(300);
        CHECK(invoke<bool>(*code, value));
        CHECK_EQ(value[0], static_cast<T>(300));
        CHECK_EQ(value[1], 13);
        checkMyDisassembly(*code, true);
    }

    {
        Procedure proc;
        BasicBlock* root = proc.addBlock();
        root->appendNew<Value>(
            proc, Return, Origin(),
            root->appendNew<AtomicValue>(
                proc, AtomicWeakCAS, Origin(), width,
                root->appendIntConstant(proc, Origin(), type, 42),
                root->appendIntConstant(proc, Origin(), type, 0xbeef),
                root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0),
                42));
    
        auto code = compileProc(proc);
        T value[2];
        value[0] = 42;
        value[1] = 13;
        while (!invoke<bool>(*code, bitwise_cast<intptr_t>(value) - 42)) { }
        CHECK_EQ(value[0], static_cast<T>(0xbeef));
        CHECK_EQ(value[1], 13);
    
        value[0] = static_cast<T>(300);
        CHECK(!invoke<bool>(*code, bitwise_cast<intptr_t>(value) - 42));
        CHECK_EQ(value[0], static_cast<T>(300));
        CHECK_EQ(value[1], 13);
        checkMyDisassembly(*code, true);
    }
}

template<typename T>
void testAtomicStrongCAS()
{
    constexpr Type type = NativeTraits<T>::type;
    constexpr Width width = NativeTraits<T>::width;

    auto checkMyDisassembly = [&] (Compilation& compilation, bool fenced) {
        if (isX86()) {
            checkUsesInstruction(compilation, "lock");
            checkUsesInstruction(compilation, "cmpxchg");
        } else {
            if (fenced) {
                checkUsesInstruction(compilation, "ldax");
                checkUsesInstruction(compilation, "stlx");
            } else {
                checkUsesInstruction(compilation, "ldx");
                checkUsesInstruction(compilation, "stx");
            }
        }
    };

    {
        Procedure proc;
        BasicBlock* root = proc.addBlock();
        BasicBlock* succ = proc.addBlock();
        BasicBlock* fail = proc.addBlock();
    
        Value* ptr = root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0);
        root->appendNew<Value>(
            proc, Branch, Origin(),
            root->appendNew<Value>(
                proc, Equal, Origin(),
                root->appendNew<AtomicValue>(
                    proc, AtomicStrongCAS, Origin(), width,
                    root->appendIntConstant(proc, Origin(), type, 42),
                    root->appendIntConstant(proc, Origin(), type, 0xbeef),
                    ptr),
                root->appendIntConstant(proc, Origin(), type, 42)));
        root->setSuccessors(succ, fail);
    
        succ->appendNew<MemoryValue>(
            proc, storeOpcode(GP, width), Origin(),
            succ->appendIntConstant(proc, Origin(), type, 100),
            ptr);
        succ->appendNew<Value>(proc, Return, Origin());
    
        fail->appendNew<Value>(proc, Return, Origin());
    
        auto code = compileProc(proc);
        T value[2];
        value[0] = 42;
        value[1] = 13;
        invoke<void>(*code, value);
        CHECK_EQ(value[0], static_cast<T>(100));
        CHECK_EQ(value[1], 13);
        value[0] = static_cast<T>(300);
        invoke<void>(*code, value);
        CHECK_EQ(value[0], static_cast<T>(300));
        CHECK_EQ(value[1], 13);
        checkMyDisassembly(*code, true);
    }

    {
        Procedure proc;
        BasicBlock* root = proc.addBlock();
        BasicBlock* succ = proc.addBlock();
        BasicBlock* fail = proc.addBlock();
    
        Value* ptr = root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0);
        root->appendNew<Value>(
            proc, Branch, Origin(),
            root->appendNew<Value>(
                proc, Equal, Origin(),
                root->appendNew<AtomicValue>(
                    proc, AtomicStrongCAS, Origin(), width,
                    root->appendIntConstant(proc, Origin(), type, 42),
                    root->appendIntConstant(proc, Origin(), type, 0xbeef),
                    ptr, 0, HeapRange(42), HeapRange()),
                root->appendIntConstant(proc, Origin(), type, 42)));
        root->setSuccessors(succ, fail);
    
        succ->appendNew<MemoryValue>(
            proc, storeOpcode(GP, width), Origin(),
            succ->appendIntConstant(proc, Origin(), type, 100),
            ptr);
        succ->appendNew<Value>(proc, Return, Origin());
    
        fail->appendNew<Value>(proc, Return, Origin());
    
        auto code = compileProc(proc);
        T value[2];
        value[0] = 42;
        value[1] = 13;
        invoke<void>(*code, value);
        CHECK_EQ(value[0], static_cast<T>(100));
        CHECK_EQ(value[1], 13);
        value[0] = static_cast<T>(300);
        invoke<void>(*code, value);
        CHECK_EQ(value[0], static_cast<T>(300));
        CHECK_EQ(value[1], 13);
        checkMyDisassembly(*code, false);
    }

    {
        Procedure proc;
        BasicBlock* root = proc.addBlock();
        BasicBlock* succ = proc.addBlock();
        BasicBlock* fail = proc.addBlock();
    
        Value* ptr = root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0);
        root->appendNew<Value>(
            proc, Branch, Origin(),
            root->appendNew<Value>(
                proc, NotEqual, Origin(),
                root->appendNew<AtomicValue>(
                    proc, AtomicStrongCAS, Origin(), width,
                    root->appendIntConstant(proc, Origin(), type, 42),
                    root->appendIntConstant(proc, Origin(), type, 0xbeef),
                    ptr),
                root->appendIntConstant(proc, Origin(), type, 42)));
        root->setSuccessors(fail, succ);
    
        succ->appendNew<MemoryValue>(
            proc, storeOpcode(GP, width), Origin(),
            succ->appendIntConstant(proc, Origin(), type, 100),
            ptr);
        succ->appendNew<Value>(proc, Return, Origin());
    
        fail->appendNew<Value>(proc, Return, Origin());
    
        auto code = compileProc(proc);
        T value[2];
        value[0] = 42;
        value[1] = 13;
        invoke<void>(*code, value);
        CHECK_EQ(value[0], static_cast<T>(100));
        CHECK_EQ(value[1], 13);
        value[0] = static_cast<T>(300);
        invoke<void>(*code, value);
        CHECK_EQ(value[0], static_cast<T>(300));
        CHECK_EQ(value[1], 13);
        checkMyDisassembly(*code, true);
    }

    {
        Procedure proc;
        BasicBlock* root = proc.addBlock();
        root->appendNew<Value>(
            proc, Return, Origin(),
            root->appendNew<AtomicValue>(
                proc, AtomicStrongCAS, Origin(), width,
                root->appendIntConstant(proc, Origin(), type, 42),
                root->appendIntConstant(proc, Origin(), type, 0xbeef),
                root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0)));
    
        auto code = compileProc(proc);
        T value[2];
        value[0] = 42;
        value[1] = 13;
        CHECK_EQ(invoke<typename NativeTraits<T>::CanonicalType>(*code, value), 42);
        CHECK_EQ(value[0], static_cast<T>(0xbeef));
        CHECK_EQ(value[1], 13);
        value[0] = static_cast<T>(300);
        CHECK_EQ(invoke<typename NativeTraits<T>::CanonicalType>(*code, value), static_cast<typename NativeTraits<T>::CanonicalType>(static_cast<T>(300)));
        CHECK_EQ(value[0], static_cast<T>(300));
        CHECK_EQ(value[1], 13);
        value[0] = static_cast<T>(-1);
        CHECK_EQ(invoke<typename NativeTraits<T>::CanonicalType>(*code, value), static_cast<typename NativeTraits<T>::CanonicalType>(static_cast<T>(-1)));
        CHECK_EQ(value[0], static_cast<T>(-1));
        CHECK_EQ(value[1], 13);
        checkMyDisassembly(*code, true);
    }

    {
        // Test for https://bugs.webkit.org/show_bug.cgi?id=169867.
    
        Procedure proc;
        BasicBlock* root = proc.addBlock();
        root->appendNew<Value>(
            proc, Return, Origin(),
            root->appendNew<Value>(
                proc, BitXor, Origin(),
                root->appendNew<AtomicValue>(
                    proc, AtomicStrongCAS, Origin(), width,
                    root->appendIntConstant(proc, Origin(), type, 42),
                    root->appendIntConstant(proc, Origin(), type, 0xbeef),
                    root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0)),
                root->appendIntConstant(proc, Origin(), type, 1)));
    
        typename NativeTraits<T>::CanonicalType one = 1;
    
        auto code = compileProc(proc);
        T value[2];
        value[0] = 42;
        value[1] = 13;
        CHECK_EQ(invoke<typename NativeTraits<T>::CanonicalType>(*code, value), 42 ^ one);
        CHECK_EQ(value[0], static_cast<T>(0xbeef));
        CHECK_EQ(value[1], 13);
        value[0] = static_cast<T>(300);
        CHECK_EQ(invoke<typename NativeTraits<T>::CanonicalType>(*code, value), static_cast<typename NativeTraits<T>::CanonicalType>(static_cast<T>(300)) ^ one);
        CHECK_EQ(value[0], static_cast<T>(300));
        CHECK_EQ(value[1], 13);
        value[0] = static_cast<T>(-1);
        CHECK_EQ(invoke<typename NativeTraits<T>::CanonicalType>(*code, value), static_cast<typename NativeTraits<T>::CanonicalType>(static_cast<T>(-1)) ^ one);
        CHECK_EQ(value[0], static_cast<T>(-1));
        CHECK_EQ(value[1], 13);
        checkMyDisassembly(*code, true);
    }

    {
        Procedure proc;
        BasicBlock* root = proc.addBlock();
        root->appendNew<Value>(
            proc, Return, Origin(),
            root->appendNew<Value>(
                proc, Equal, Origin(),
                root->appendNew<AtomicValue>(
                    proc, AtomicStrongCAS, Origin(), width,
                    root->appendIntConstant(proc, Origin(), type, 42),
                    root->appendIntConstant(proc, Origin(), type, 0xbeef),
                    root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0)),
                root->appendIntConstant(proc, Origin(), type, 42)));
    
        auto code = compileProc(proc);
        T value[2];
        value[0] = 42;
        value[1] = 13;
        CHECK(invoke<bool>(*code, value));
        CHECK_EQ(value[0], static_cast<T>(0xbeef));
        CHECK_EQ(value[1], 13);
        value[0] = static_cast<T>(300);
        CHECK(!invoke<bool>(*code, value));
        CHECK_EQ(value[0], static_cast<T>(300));
        CHECK_EQ(value[1], 13);
        checkMyDisassembly(*code, true);
    }

    {
        Procedure proc;
        BasicBlock* root = proc.addBlock();
        root->appendNew<Value>(
            proc, Return, Origin(),
            root->appendNew<Value>(
                proc, Equal, Origin(),
                root->appendNew<Value>(
                    proc, NotEqual, Origin(),
                    root->appendNew<AtomicValue>(
                        proc, AtomicStrongCAS, Origin(), width,
                        root->appendIntConstant(proc, Origin(), type, 42),
                        root->appendIntConstant(proc, Origin(), type, 0xbeef),
                        root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0)),
                    root->appendIntConstant(proc, Origin(), type, 42)),
                root->appendNew<Const32Value>(proc, Origin(), 0)));
        
        auto code = compileProc(proc);
        T value[2];
        value[0] = 42;
        value[1] = 13;
        CHECK(invoke<bool>(*code, value));
        CHECK_EQ(value[0], static_cast<T>(0xbeef));
        CHECK_EQ(value[1], 13);
        value[0] = static_cast<T>(300);
        CHECK(!invoke<bool>(*code, &value));
        CHECK_EQ(value[0], static_cast<T>(300));
        CHECK_EQ(value[1], 13);
        checkMyDisassembly(*code, true);
    }
}

template<typename T>
void testAtomicXchg(B3::Opcode opcode)
{
    constexpr Type type = NativeTraits<T>::type;
    constexpr Width width = NativeTraits<T>::width;

    auto doTheMath = [&] (T& memory, T operand) -> T {
        T oldValue = memory;
        switch (opcode) {
        case AtomicXchgAdd:
            memory += operand;
            break;
        case AtomicXchgAnd:
            memory &= operand;
            break;
        case AtomicXchgOr:
            memory |= operand;
            break;
        case AtomicXchgSub:
            memory -= operand;
            break;
        case AtomicXchgXor:
            memory ^= operand;
            break;
        case AtomicXchg:
            memory = operand;
            break;
        default:
            RELEASE_ASSERT_NOT_REACHED();
        }
        return oldValue;
    };

    auto oldValue = [&] (T memory, T operand) -> T {
        return doTheMath(memory, operand);
    };

    auto newValue = [&] (T memory, T operand) -> T {
        doTheMath(memory, operand);
        return memory;
    };

    auto checkMyDisassembly = [&] (Compilation& compilation, bool fenced) {
        if (isX86()) {
            // AtomicXchg can be lowered to "xchg" without "lock", and this is OK since "lock" signal is asserted for "xchg" by default.
            if (AtomicXchg != opcode)
                checkUsesInstruction(compilation, "lock");
        } else {
            if (fenced) {
                checkUsesInstruction(compilation, "ldax");
                checkUsesInstruction(compilation, "stlx");
            } else {
                checkUsesInstruction(compilation, "ldx");
                checkUsesInstruction(compilation, "stx");
            }
        }
    };

    {
        Procedure proc;
        BasicBlock* root = proc.addBlock();
        root->appendNew<Value>(
            proc, Return, Origin(),
            root->appendNew<AtomicValue>(
                proc, opcode, Origin(), width,
                root->appendIntConstant(proc, Origin(), type, 1),
                root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0)));

        auto code = compileProc(proc);
        T value[2];
        value[0] = 5;
        value[1] = 100;
        CHECK_EQ(invoke<T>(*code, value), oldValue(5, 1));
        CHECK_EQ(value[0], newValue(5, 1));
        CHECK_EQ(value[1], 100);
        checkMyDisassembly(*code, true);
    }

    {
        Procedure proc;
        BasicBlock* root = proc.addBlock();
        root->appendNew<Value>(
            proc, Return, Origin(),
            root->appendNew<AtomicValue>(
                proc, opcode, Origin(), width,
                root->appendIntConstant(proc, Origin(), type, 42),
                root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0)));

        auto code = compileProc(proc);
        T value[2];
        value[0] = 5;
        value[1] = 100;
        CHECK_EQ(invoke<T>(*code, value), oldValue(5, 42));
        CHECK_EQ(value[0], newValue(5, 42));
        CHECK_EQ(value[1], 100);
        checkMyDisassembly(*code, true);
    }

    {
        Procedure proc;
        BasicBlock* root = proc.addBlock();
        root->appendNew<AtomicValue>(
            proc, opcode, Origin(), width,
            root->appendIntConstant(proc, Origin(), type, 42),
            root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0));
        root->appendNew<Value>(proc, Return, Origin());

        auto code = compileProc(proc);
        T value[2];
        value[0] = 5;
        value[1] = 100;
        invoke<T>(*code, value);
        CHECK_EQ(value[0], newValue(5, 42));
        CHECK_EQ(value[1], 100);
        checkMyDisassembly(*code, true);
    }

    {
        Procedure proc;
        BasicBlock* root = proc.addBlock();
        root->appendNew<AtomicValue>(
            proc, opcode, Origin(), width,
            root->appendIntConstant(proc, Origin(), type, 42),
            root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0),
            0, HeapRange(42), HeapRange());
        root->appendNew<Value>(proc, Return, Origin());

        auto code = compileProc(proc);
        T value[2];
        value[0] = 5;
        value[1] = 100;
        invoke<T>(*code, value);
        CHECK_EQ(value[0], newValue(5, 42));
        CHECK_EQ(value[1], 100);
        checkMyDisassembly(*code, false);
    }
}

void addAtomicTests(const char* filter, Deque<RefPtr<SharedTask<void()>>>& tasks)
{
    RUN(testAtomicWeakCAS<int8_t>());
    RUN(testAtomicWeakCAS<int16_t>());
    RUN(testAtomicWeakCAS<int32_t>());
    RUN(testAtomicWeakCAS<int64_t>());
    RUN(testAtomicStrongCAS<int8_t>());
    RUN(testAtomicStrongCAS<int16_t>());
    RUN(testAtomicStrongCAS<int32_t>());
    RUN(testAtomicStrongCAS<int64_t>());
    RUN(testAtomicXchg<int8_t>(AtomicXchgAdd));
    RUN(testAtomicXchg<int16_t>(AtomicXchgAdd));
    RUN(testAtomicXchg<int32_t>(AtomicXchgAdd));
    RUN(testAtomicXchg<int64_t>(AtomicXchgAdd));
    RUN(testAtomicXchg<int8_t>(AtomicXchgAnd));
    RUN(testAtomicXchg<int16_t>(AtomicXchgAnd));
    RUN(testAtomicXchg<int32_t>(AtomicXchgAnd));
    RUN(testAtomicXchg<int64_t>(AtomicXchgAnd));
    RUN(testAtomicXchg<int8_t>(AtomicXchgOr));
    RUN(testAtomicXchg<int16_t>(AtomicXchgOr));
    RUN(testAtomicXchg<int32_t>(AtomicXchgOr));
    RUN(testAtomicXchg<int64_t>(AtomicXchgOr));
    RUN(testAtomicXchg<int8_t>(AtomicXchgSub));
    RUN(testAtomicXchg<int16_t>(AtomicXchgSub));
    RUN(testAtomicXchg<int32_t>(AtomicXchgSub));
    RUN(testAtomicXchg<int64_t>(AtomicXchgSub));
    RUN(testAtomicXchg<int8_t>(AtomicXchgXor));
    RUN(testAtomicXchg<int16_t>(AtomicXchgXor));
    RUN(testAtomicXchg<int32_t>(AtomicXchgXor));
    RUN(testAtomicXchg<int64_t>(AtomicXchgXor));
    RUN(testAtomicXchg<int8_t>(AtomicXchg));
    RUN(testAtomicXchg<int16_t>(AtomicXchg));
    RUN(testAtomicXchg<int32_t>(AtomicXchg));
    RUN(testAtomicXchg<int64_t>(AtomicXchg));
}

template<typename CType, typename InputType>
void testLoad(B3::Type type, B3::Opcode opcode, InputType value)
{
    // Simple load from an absolute address.
    {
        Procedure proc;
        BasicBlock* root = proc.addBlock();

        root->appendNewControlValue(
            proc, Return, Origin(),
            root->appendNew<MemoryValue>(
                proc, opcode, type, Origin(),
                root->appendNew<ConstPtrValue>(proc, Origin(), &value)));

        CHECK(isIdentical(compileAndRun<CType>(proc), modelLoad<CType>(value)));
    }

    // Simple load from an address in a register.
    {
        Procedure proc;
        BasicBlock* root = proc.addBlock();

        root->appendNewControlValue(
            proc, Return, Origin(),
            root->appendNew<MemoryValue>(
                proc, opcode, type, Origin(),
                root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0)));

        CHECK(isIdentical(compileAndRun<CType>(proc, &value), modelLoad<CType>(value)));
    }

    // Simple load from an address in a register, at an offset.
    {
        Procedure proc;
        BasicBlock* root = proc.addBlock();

        root->appendNewControlValue(
            proc, Return, Origin(),
            root->appendNew<MemoryValue>(
                proc, opcode, type, Origin(),
                root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0),
                static_cast<int32_t>(sizeof(InputType))));

        CHECK(isIdentical(compileAndRun<CType>(proc, &value - 1), modelLoad<CType>(value)));
    }

    // Load from a simple base-index with various scales.
    for (unsigned logScale = 0; logScale <= 3; ++logScale) {
        Procedure proc;
        BasicBlock* root = proc.addBlock();

        root->appendNewControlValue(
            proc, Return, Origin(),
            root->appendNew<MemoryValue>(
                proc, opcode, type, Origin(),
                root->appendNew<Value>(
                    proc, Add, Origin(),
                    root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0),
                    root->appendNew<Value>(
                        proc, Shl, Origin(),
                        root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR1),
                        root->appendNew<Const32Value>(proc, Origin(), logScale)))));

        CHECK(isIdentical(compileAndRun<CType>(proc, &value - 2, (sizeof(InputType) * 2) >> logScale), modelLoad<CType>(value)));
    }

    // Load from a simple base-index with various scales, but commuted.
    for (unsigned logScale = 0; logScale <= 3; ++logScale) {
        Procedure proc;
        BasicBlock* root = proc.addBlock();

        root->appendNewControlValue(
            proc, Return, Origin(),
            root->appendNew<MemoryValue>(
                proc, opcode, type, Origin(),
                root->appendNew<Value>(
                    proc, Add, Origin(),
                    root->appendNew<Value>(
                        proc, Shl, Origin(),
                        root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR1),
                        root->appendNew<Const32Value>(proc, Origin(), logScale)),
                    root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0))));

        CHECK(isIdentical(compileAndRun<CType>(proc, &value - 2, (sizeof(InputType) * 2) >> logScale), modelLoad<CType>(value)));
    }
}

template<typename T>
void testLoad(B3::Opcode opcode, int32_t value)
{
    return testLoad<T>(B3::Int32, opcode, value);
}

template<typename T>
void testLoad(B3::Type type, T value)
{
    return testLoad<T>(type, Load, value);
}

void addLoadTests(const char* filter, Deque<RefPtr<SharedTask<void()>>>& tasks)
{
    RUN(testLoad(Int32, 60));
    RUN(testLoad(Int32, -60));
    RUN(testLoad(Int32, 1000));
    RUN(testLoad(Int32, -1000));
    RUN(testLoad(Int32, 1000000));
    RUN(testLoad(Int32, -1000000));
    RUN(testLoad(Int32, 1000000000));
    RUN(testLoad(Int32, -1000000000));
    RUN_BINARY(testLoad, { MAKE_OPERAND(Int64) }, int64Operands());
    RUN_BINARY(testLoad, { MAKE_OPERAND(Float) }, floatingPointOperands<float>());
    RUN_BINARY(testLoad, { MAKE_OPERAND(Double) }, floatingPointOperands<double>());

    RUN(testLoad<int8_t>(Load8S, 60));
    RUN(testLoad<int8_t>(Load8S, -60));
    RUN(testLoad<int8_t>(Load8S, 1000));
    RUN(testLoad<int8_t>(Load8S, -1000));
    RUN(testLoad<int8_t>(Load8S, 1000000));
    RUN(testLoad<int8_t>(Load8S, -1000000));
    RUN(testLoad<int8_t>(Load8S, 1000000000));
    RUN(testLoad<int8_t>(Load8S, -1000000000));
    
    RUN(testLoad<uint8_t>(Load8Z, 60));
    RUN(testLoad<uint8_t>(Load8Z, -60));
    RUN(testLoad<uint8_t>(Load8Z, 1000));
    RUN(testLoad<uint8_t>(Load8Z, -1000));
    RUN(testLoad<uint8_t>(Load8Z, 1000000));
    RUN(testLoad<uint8_t>(Load8Z, -1000000));
    RUN(testLoad<uint8_t>(Load8Z, 1000000000));
    RUN(testLoad<uint8_t>(Load8Z, -1000000000));
    
    RUN(testLoad<int16_t>(Load16S, 60));
    RUN(testLoad<int16_t>(Load16S, -60));
    RUN(testLoad<int16_t>(Load16S, 1000));
    RUN(testLoad<int16_t>(Load16S, -1000));
    RUN(testLoad<int16_t>(Load16S, 1000000));
    RUN(testLoad<int16_t>(Load16S, -1000000));
    RUN(testLoad<int16_t>(Load16S, 1000000000));
    RUN(testLoad<int16_t>(Load16S, -1000000000));
    
    RUN(testLoad<uint16_t>(Load16Z, 60));
    RUN(testLoad<uint16_t>(Load16Z, -60));
    RUN(testLoad<uint16_t>(Load16Z, 1000));
    RUN(testLoad<uint16_t>(Load16Z, -1000));
    RUN(testLoad<uint16_t>(Load16Z, 1000000));
    RUN(testLoad<uint16_t>(Load16Z, -1000000));
    RUN(testLoad<uint16_t>(Load16Z, 1000000000));
    RUN(testLoad<uint16_t>(Load16Z, -1000000000));
}

void testFastForwardCopy32()
{
#if CPU(X86_64)
    for (const bool aligned : { true, false }) {
        for (const bool overlap : { false, true }) {
            for (size_t arrsize : { 1, 4, 5, 6, 8, 10, 12, 16, 20, 40, 100, 1000}) {
                size_t overlapAmount = 5;

                UniqueArray<uint32_t> array1, array2;
                uint32_t* arr1, *arr2;

                if (overlap) {
                    array1 = makeUniqueArray<uint32_t>(arrsize * 2);
                    arr1 = &array1[0];
                    arr2 = arr1 + (arrsize - overlapAmount);
                } else {
                    array1 = makeUniqueArray<uint32_t>(arrsize);
                    array2 = makeUniqueArray<uint32_t>(arrsize);
                    arr1 = &array1[0];
                    arr2 = &array2[0];
                }

                if (!aligned && arrsize < 3)
                    continue;
                if (overlap && arrsize <= overlapAmount + 3)
                    continue;

                if (!aligned) {
                    ++arr1;
                    ++arr2;
                    arrsize -= 1;
                    overlapAmount -= 1;
                }

                for (size_t i = 0; i < arrsize; ++i)
                    arr1[i] = i;

                fastForwardCopy32(arr2, arr1, arrsize);

                if (overlap) {
                    for (size_t i = 0; i < arrsize - overlapAmount; ++i)
                        CHECK(arr2[i] == i);
                    for (size_t i = arrsize - overlapAmount; i < arrsize; ++i)
                        CHECK(arr2[i] == i - (arrsize - overlapAmount));
                } else {
                    for (size_t i = 0; i < arrsize; ++i)
                        CHECK(arr2[i] == i);
                }

                if (!aligned) {
                    --arr1;
                    --arr2;
                }
            }
        }
    }
#endif
}

void testByteCopyLoop()
{
    Procedure proc;
    BasicBlock* root = proc.addBlock();
    BasicBlock* head = proc.addBlock();
    BasicBlock* update = proc.addBlock();
    BasicBlock* continuation = proc.addBlock();

    auto* arraySrc = root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0);
    auto* arrayDst = root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR1);
    auto* arraySize = root->appendNew<Value>(proc, Trunc, Origin(), root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR2));
    auto* one = root->appendNew<Const32Value>(proc, Origin(), 1);
    auto* two = root->appendNew<Const32Value>(proc, Origin(), 2);
    UpsilonValue* startingIndex = root->appendNew<UpsilonValue>(proc, Origin(), root->appendNew<Const32Value>(proc, Origin(), 0));
    root->appendNew<Value>(proc, Jump, Origin());
    root->setSuccessors(FrequentedBlock(head));

    auto* index = head->appendNew<Value>(proc, Phi, Int32, Origin());
    startingIndex->setPhi(index);
    auto* loadIndex = head->appendNew<Value>(proc, Add, Origin(), arraySrc,
        head->appendNew<Value>(proc, ZExt32, Origin(), head->appendNew<Value>(proc, Shl, Origin(), index, two)));
    auto* storeIndex = head->appendNew<Value>(proc, Add, Origin(), arrayDst,
        head->appendNew<Value>(proc, ZExt32, Origin(), head->appendNew<Value>(proc, Shl, Origin(), index, two)));
    head->appendNew<MemoryValue>(proc, Store, Origin(), head->appendNew<MemoryValue>(proc, Load, Int32, Origin(), loadIndex), storeIndex);
    auto* newIndex = head->appendNew<Value>(proc, Add, Origin(), index, one);
    auto* cmpValue = head->appendNew<Value>(proc, GreaterThan, Origin(), newIndex, arraySize);
    head->appendNew<Value>(proc, Branch, Origin(), cmpValue);
    head->setSuccessors(FrequentedBlock(continuation), FrequentedBlock(update));

    UpsilonValue* updateIndex = update->appendNew<UpsilonValue>(proc, Origin(), newIndex);
    updateIndex->setPhi(index);
    update->appendNew<Value>(proc, Jump, Origin());
    update->setSuccessors(FrequentedBlock(head));

    continuation->appendNewControlValue(proc, Return, Origin());

    int* arr1 = new int[3];
    int* arr2 = new int[3];

    arr1[0] = 0;
    arr1[1] = 0;
    arr1[2] = 0;
    arr2[0] = 1;
    arr2[1] = 2;
    arr2[2] = 3;

    compileAndRun<void>(proc, arr2, arr1, 3);

    CHECK_EQ(arr1[0], 1);
    CHECK_EQ(arr1[1], 2);
    CHECK_EQ(arr1[2], 3);

    delete[] arr1;
    delete [] arr2;
}

void testByteCopyLoopStartIsLoopDependent()
{
    Procedure proc;
    BasicBlock* root = proc.addBlock();
    BasicBlock* head = proc.addBlock();
    BasicBlock* update = proc.addBlock();
    BasicBlock* continuation = proc.addBlock();

    auto* arraySrc = root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0);
    auto* arrayDst = root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR1);
    auto* arraySize = root->appendNew<Value>(proc, Trunc, Origin(), root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR2));
    auto* one = root->appendNew<Const32Value>(proc, Origin(), 1);
    auto* two = root->appendNew<Const32Value>(proc, Origin(), 2);
    root->appendNew<Value>(proc, Jump, Origin());
    root->setSuccessors(FrequentedBlock(head));

    UpsilonValue* startingIndex = head->appendNew<UpsilonValue>(proc, Origin(), head->appendNew<Const32Value>(proc, Origin(), 0));
    auto* index = head->appendNew<Value>(proc, Phi, Int32, Origin());
    startingIndex->setPhi(index);
    auto* loadIndex = head->appendNew<Value>(proc, Add, Origin(), arraySrc,
        head->appendNew<Value>(proc, ZExt32, Origin(), head->appendNew<Value>(proc, Shl, Origin(), index, two)));
    auto* storeIndex = head->appendNew<Value>(proc, Add, Origin(), arrayDst,
        head->appendNew<Value>(proc, ZExt32, Origin(), head->appendNew<Value>(proc, Shl, Origin(), index, two)));
    head->appendNew<MemoryValue>(proc, Store, Origin(), head->appendNew<MemoryValue>(proc, Load, Int32, Origin(), loadIndex), storeIndex);
    auto* newIndex = head->appendNew<Value>(proc, Add, Origin(), index, one);
    auto* cmpValue = head->appendNew<Value>(proc, GreaterThan, Origin(), newIndex, arraySize);
    head->appendNew<Value>(proc, Branch, Origin(), cmpValue);
    head->setSuccessors(FrequentedBlock(continuation), FrequentedBlock(update));

    UpsilonValue* updateIndex = update->appendNew<UpsilonValue>(proc, Origin(), newIndex);
    updateIndex->setPhi(index);
    update->appendNew<Value>(proc, Jump, Origin());
    update->setSuccessors(FrequentedBlock(head));

    continuation->appendNewControlValue(proc, Return, Origin());

    int* arr1 = new int[3];
    int* arr2 = new int[3];

    arr1[0] = 0;
    arr1[1] = 0;
    arr1[2] = 0;
    arr2[0] = 1;
    arr2[1] = 2;
    arr2[2] = 3;

    compileAndRun<void>(proc, arr2, arr1, 0);

    CHECK_EQ(arr1[0], 1);
    CHECK_EQ(arr1[1], 0);
    CHECK_EQ(arr1[2], 0);

    delete[] arr1;
    delete [] arr2;
}

void testByteCopyLoopBoundIsLoopDependent()
{
    Procedure proc;
    BasicBlock* root = proc.addBlock();
    BasicBlock* head = proc.addBlock();
    BasicBlock* update = proc.addBlock();
    BasicBlock* continuation = proc.addBlock();

    auto* arraySrc = root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR0);
    auto* arrayDst = root->appendNew<ArgumentRegValue>(proc, Origin(), GPRInfo::argumentGPR1);
    auto* one = root->appendNew<Const32Value>(proc, Origin(), 1);
    auto* two = root->appendNew<Const32Value>(proc, Origin(), 2);
    UpsilonValue* startingIndex = root->appendNew<UpsilonValue>(proc, Origin(), root->appendNew<Const32Value>(proc, Origin(), 0));
    root->appendNew<Value>(proc, Jump, Origin());
    root->setSuccessors(FrequentedBlock(head));

    auto* index = head->appendNew<Value>(proc, Phi, Int32, Origin());
    startingIndex->setPhi(index);
    auto* loadIndex = head->appendNew<Value>(proc, Add, Origin(), arraySrc,
        head->appendNew<Value>(proc, ZExt32, Origin(), head->appendNew<Value>(proc, Shl, Origin(), index, two)));
    auto* storeIndex = head->appendNew<Value>(proc, Add, Origin(), arrayDst,
        head->appendNew<Value>(proc, ZExt32, Origin(), head->appendNew<Value>(proc, Shl, Origin(), index, two)));
    head->appendNew<MemoryValue>(proc, Store, Origin(), head->appendNew<MemoryValue>(proc, Load, Int32, Origin(), loadIndex), storeIndex);
    auto* newIndex = head->appendNew<Value>(proc, Add, Origin(), index, one);
    auto* cmpValue = head->appendNew<Value>(proc, GreaterThan, Origin(), newIndex, index);
    head->appendNew<Value>(proc, Branch, Origin(), cmpValue);
    head->setSuccessors(FrequentedBlock(continuation), FrequentedBlock(update));

    UpsilonValue* updateIndex = update->appendNew<UpsilonValue>(proc, Origin(), newIndex);
    updateIndex->setPhi(index);
    update->appendNew<Value>(proc, Jump, Origin());
    update->setSuccessors(FrequentedBlock(head));

    continuation->appendNewControlValue(proc, Return, Origin());

    int* arr1 = new int[3];
    int* arr2 = new int[3];

    arr1[0] = 0;
    arr1[1] = 0;
    arr1[2] = 0;
    arr2[0] = 1;
    arr2[1] = 2;
    arr2[2] = 3;

    compileAndRun<void>(proc, arr2, arr1, 3);

    CHECK_EQ(arr1[0], 1);
    CHECK_EQ(arr1[1], 0);
    CHECK_EQ(arr1[2], 0);

    delete[] arr1;
    delete [] arr2;
}

void addCopyTests(const char* filter, Deque<RefPtr<SharedTask<void()>>>& tasks)
{
    RUN(testFastForwardCopy32());
    RUN(testByteCopyLoop());
    RUN(testByteCopyLoopStartIsLoopDependent());
    RUN(testByteCopyLoopBoundIsLoopDependent());
}

#endif // ENABLE(B3_JIT)