diff options
author | Jędrzej Nowacki <jedrzej.nowacki@digia.com> | 2013-01-29 14:20:50 +0100 |
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committer | Lars Knoll <lars.knoll@digia.com> | 2013-01-30 13:20:40 +0100 |
commit | 74fba4d8069c946c1ba12b9ac4d4026aaf14118b (patch) | |
tree | 138cc204ec33ef0c838c98355ea84846e11ca1a7 /src/3rdparty/masm/assembler/AbstractMacroAssembler.h | |
parent | 0781ecb087b027cccc1c44de1a1c7520cc89e2d2 (diff) |
Say hello to QtV4 module.
Change-Id: I507cd5707b7d7223a0d901cf939896fb2649b684
Reviewed-by: Lars Knoll <lars.knoll@digia.com>
Diffstat (limited to 'src/3rdparty/masm/assembler/AbstractMacroAssembler.h')
-rw-r--r-- | src/3rdparty/masm/assembler/AbstractMacroAssembler.h | 792 |
1 files changed, 792 insertions, 0 deletions
diff --git a/src/3rdparty/masm/assembler/AbstractMacroAssembler.h b/src/3rdparty/masm/assembler/AbstractMacroAssembler.h new file mode 100644 index 0000000000..ee78ef84eb --- /dev/null +++ b/src/3rdparty/masm/assembler/AbstractMacroAssembler.h @@ -0,0 +1,792 @@ +/* + * Copyright (C) 2008, 2012 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. + */ + +#ifndef AbstractMacroAssembler_h +#define AbstractMacroAssembler_h + +#include "AssemblerBuffer.h" +#include "CodeLocation.h" +#include "MacroAssemblerCodeRef.h" +#include <wtf/CryptographicallyRandomNumber.h> +#include <wtf/Noncopyable.h> +#include <wtf/UnusedParam.h> + +#if ENABLE(ASSEMBLER) + + +#if PLATFORM(QT) +#define ENABLE_JIT_CONSTANT_BLINDING 0 +#endif + +#ifndef ENABLE_JIT_CONSTANT_BLINDING +#define ENABLE_JIT_CONSTANT_BLINDING 1 +#endif + +namespace JSC { + +class JumpReplacementWatchpoint; +class LinkBuffer; +class RepatchBuffer; +class Watchpoint; +namespace DFG { +struct OSRExit; +} + +template <class AssemblerType> +class AbstractMacroAssembler { +public: + friend class JITWriteBarrierBase; + typedef AssemblerType AssemblerType_T; + + typedef MacroAssemblerCodePtr CodePtr; + typedef MacroAssemblerCodeRef CodeRef; + + class Jump; + + typedef typename AssemblerType::RegisterID RegisterID; + + // Section 1: MacroAssembler operand types + // + // The following types are used as operands to MacroAssembler operations, + // describing immediate and memory operands to the instructions to be planted. + + enum Scale { + TimesOne, + TimesTwo, + TimesFour, + TimesEight, + }; + + // Address: + // + // Describes a simple base-offset address. + struct Address { + explicit Address(RegisterID base, int32_t offset = 0) + : base(base) + , offset(offset) + { + } + + RegisterID base; + int32_t offset; + }; + + struct ExtendedAddress { + explicit ExtendedAddress(RegisterID base, intptr_t offset = 0) + : base(base) + , offset(offset) + { + } + + RegisterID base; + intptr_t offset; + }; + + // ImplicitAddress: + // + // This class is used for explicit 'load' and 'store' operations + // (as opposed to situations in which a memory operand is provided + // to a generic operation, such as an integer arithmetic instruction). + // + // In the case of a load (or store) operation we want to permit + // addresses to be implicitly constructed, e.g. the two calls: + // + // load32(Address(addrReg), destReg); + // load32(addrReg, destReg); + // + // Are equivalent, and the explicit wrapping of the Address in the former + // is unnecessary. + struct ImplicitAddress { + ImplicitAddress(RegisterID base) + : base(base) + , offset(0) + { + } + + ImplicitAddress(Address address) + : base(address.base) + , offset(address.offset) + { + } + + RegisterID base; + int32_t offset; + }; + + // BaseIndex: + // + // Describes a complex addressing mode. + struct BaseIndex { + BaseIndex(RegisterID base, RegisterID index, Scale scale, int32_t offset = 0) + : base(base) + , index(index) + , scale(scale) + , offset(offset) + { + } + + RegisterID base; + RegisterID index; + Scale scale; + int32_t offset; + }; + + // AbsoluteAddress: + // + // Describes an memory operand given by a pointer. For regular load & store + // operations an unwrapped void* will be used, rather than using this. + struct AbsoluteAddress { + explicit AbsoluteAddress(const void* ptr) + : m_ptr(ptr) + { + } + + const void* m_ptr; + }; + + // TrustedImmPtr: + // + // A pointer sized immediate operand to an instruction - this is wrapped + // in a class requiring explicit construction in order to differentiate + // from pointers used as absolute addresses to memory operations + struct TrustedImmPtr { + TrustedImmPtr() { } + + explicit TrustedImmPtr(const void* value) + : m_value(value) + { + } + + // This is only here so that TrustedImmPtr(0) does not confuse the C++ + // overload handling rules. + explicit TrustedImmPtr(int value) + : m_value(0) + { + ASSERT_UNUSED(value, !value); + } + + explicit TrustedImmPtr(size_t value) + : m_value(reinterpret_cast<void*>(value)) + { + } + + intptr_t asIntptr() + { + return reinterpret_cast<intptr_t>(m_value); + } + + const void* m_value; + }; + + struct ImmPtr : +#if ENABLE(JIT_CONSTANT_BLINDING) + private TrustedImmPtr +#else + public TrustedImmPtr +#endif + { + explicit ImmPtr(const void* value) + : TrustedImmPtr(value) + { + } + + TrustedImmPtr asTrustedImmPtr() { return *this; } + }; + + // TrustedImm32: + // + // A 32bit immediate operand to an instruction - this is wrapped in a + // class requiring explicit construction in order to prevent RegisterIDs + // (which are implemented as an enum) from accidentally being passed as + // immediate values. + struct TrustedImm32 { + TrustedImm32() { } + + explicit TrustedImm32(int32_t value) + : m_value(value) + { + } + +#if !CPU(X86_64) + explicit TrustedImm32(TrustedImmPtr ptr) + : m_value(ptr.asIntptr()) + { + } +#endif + + int32_t m_value; + }; + + + struct Imm32 : +#if ENABLE(JIT_CONSTANT_BLINDING) + private TrustedImm32 +#else + public TrustedImm32 +#endif + { + explicit Imm32(int32_t value) + : TrustedImm32(value) + { + } +#if !CPU(X86_64) + explicit Imm32(TrustedImmPtr ptr) + : TrustedImm32(ptr) + { + } +#endif + const TrustedImm32& asTrustedImm32() const { return *this; } + + }; + + // TrustedImm64: + // + // A 64bit immediate operand to an instruction - this is wrapped in a + // class requiring explicit construction in order to prevent RegisterIDs + // (which are implemented as an enum) from accidentally being passed as + // immediate values. + struct TrustedImm64 { + TrustedImm64() { } + + explicit TrustedImm64(int64_t value) + : m_value(value) + { + } + +#if CPU(X86_64) + explicit TrustedImm64(TrustedImmPtr ptr) + : m_value(ptr.asIntptr()) + { + } +#endif + + int64_t m_value; + }; + + struct Imm64 : +#if ENABLE(JIT_CONSTANT_BLINDING) + private TrustedImm64 +#else + public TrustedImm64 +#endif + { + explicit Imm64(int64_t value) + : TrustedImm64(value) + { + } +#if CPU(X86_64) + explicit Imm64(TrustedImmPtr ptr) + : TrustedImm64(ptr) + { + } +#endif + const TrustedImm64& asTrustedImm64() const { return *this; } + }; + + // Section 2: MacroAssembler code buffer handles + // + // The following types are used to reference items in the code buffer + // during JIT code generation. For example, the type Jump is used to + // track the location of a jump instruction so that it may later be + // linked to a label marking its destination. + + + // Label: + // + // A Label records a point in the generated instruction stream, typically such that + // it may be used as a destination for a jump. + class Label { + template<class TemplateAssemblerType> + friend class AbstractMacroAssembler; + friend struct DFG::OSRExit; + friend class Jump; + friend class JumpReplacementWatchpoint; + friend class MacroAssemblerCodeRef; + friend class LinkBuffer; + friend class Watchpoint; + + public: + Label() + { + } + + Label(AbstractMacroAssembler<AssemblerType>* masm) + : m_label(masm->m_assembler.label()) + { + } + + bool isSet() const { return m_label.isSet(); } + private: + AssemblerLabel m_label; + }; + + // ConvertibleLoadLabel: + // + // A ConvertibleLoadLabel records a loadPtr instruction that can be patched to an addPtr + // so that: + // + // loadPtr(Address(a, i), b) + // + // becomes: + // + // addPtr(TrustedImmPtr(i), a, b) + class ConvertibleLoadLabel { + template<class TemplateAssemblerType> + friend class AbstractMacroAssembler; + friend class LinkBuffer; + + public: + ConvertibleLoadLabel() + { + } + + ConvertibleLoadLabel(AbstractMacroAssembler<AssemblerType>* masm) + : m_label(masm->m_assembler.labelIgnoringWatchpoints()) + { + } + + bool isSet() const { return m_label.isSet(); } + private: + AssemblerLabel m_label; + }; + + // DataLabelPtr: + // + // A DataLabelPtr is used to refer to a location in the code containing a pointer to be + // patched after the code has been generated. + class DataLabelPtr { + template<class TemplateAssemblerType> + friend class AbstractMacroAssembler; + friend class LinkBuffer; + public: + DataLabelPtr() + { + } + + DataLabelPtr(AbstractMacroAssembler<AssemblerType>* masm) + : m_label(masm->m_assembler.label()) + { + } + + bool isSet() const { return m_label.isSet(); } + + private: + AssemblerLabel m_label; + }; + + // DataLabel32: + // + // A DataLabelPtr is used to refer to a location in the code containing a pointer to be + // patched after the code has been generated. + class DataLabel32 { + template<class TemplateAssemblerType> + friend class AbstractMacroAssembler; + friend class LinkBuffer; + public: + DataLabel32() + { + } + + DataLabel32(AbstractMacroAssembler<AssemblerType>* masm) + : m_label(masm->m_assembler.label()) + { + } + + AssemblerLabel label() const { return m_label; } + + private: + AssemblerLabel m_label; + }; + + // DataLabelCompact: + // + // A DataLabelCompact is used to refer to a location in the code containing a + // compact immediate to be patched after the code has been generated. + class DataLabelCompact { + template<class TemplateAssemblerType> + friend class AbstractMacroAssembler; + friend class LinkBuffer; + public: + DataLabelCompact() + { + } + + DataLabelCompact(AbstractMacroAssembler<AssemblerType>* masm) + : m_label(masm->m_assembler.label()) + { + } + + DataLabelCompact(AssemblerLabel label) + : m_label(label) + { + } + + private: + AssemblerLabel m_label; + }; + + // Call: + // + // A Call object is a reference to a call instruction that has been planted + // into the code buffer - it is typically used to link the call, setting the + // relative offset such that when executed it will call to the desired + // destination. + class Call { + template<class TemplateAssemblerType> + friend class AbstractMacroAssembler; + + public: + enum Flags { + None = 0x0, + Linkable = 0x1, + Near = 0x2, + LinkableNear = 0x3, + }; + + Call() + : m_flags(None) + { + } + + Call(AssemblerLabel jmp, Flags flags) + : m_label(jmp) + , m_flags(flags) + { + } + + bool isFlagSet(Flags flag) + { + return m_flags & flag; + } + + static Call fromTailJump(Jump jump) + { + return Call(jump.m_label, Linkable); + } + + AssemblerLabel m_label; + private: + Flags m_flags; + }; + + // Jump: + // + // A jump object is a reference to a jump instruction that has been planted + // into the code buffer - it is typically used to link the jump, setting the + // relative offset such that when executed it will jump to the desired + // destination. + class Jump { + template<class TemplateAssemblerType> + friend class AbstractMacroAssembler; + friend class Call; + friend struct DFG::OSRExit; + friend class LinkBuffer; + public: + Jump() + { + } + +#if CPU(ARM_THUMB2) + // Fixme: this information should be stored in the instruction stream, not in the Jump object. + Jump(AssemblerLabel jmp, ARMv7Assembler::JumpType type, ARMv7Assembler::Condition condition = ARMv7Assembler::ConditionInvalid) + : m_label(jmp) + , m_type(type) + , m_condition(condition) + { + } +#elif CPU(SH4) + Jump(AssemblerLabel jmp, SH4Assembler::JumpType type = SH4Assembler::JumpFar) + : m_label(jmp) + , m_type(type) + { + } +#else + Jump(AssemblerLabel jmp) + : m_label(jmp) + { + } +#endif + + Label label() const + { + Label result; + result.m_label = m_label; + return result; + } + + void link(AbstractMacroAssembler<AssemblerType>* masm) const + { +#if CPU(ARM_THUMB2) + masm->m_assembler.linkJump(m_label, masm->m_assembler.label(), m_type, m_condition); +#elif CPU(SH4) + masm->m_assembler.linkJump(m_label, masm->m_assembler.label(), m_type); +#else + masm->m_assembler.linkJump(m_label, masm->m_assembler.label()); +#endif + } + + void linkTo(Label label, AbstractMacroAssembler<AssemblerType>* masm) const + { +#if CPU(ARM_THUMB2) + masm->m_assembler.linkJump(m_label, label.m_label, m_type, m_condition); +#else + masm->m_assembler.linkJump(m_label, label.m_label); +#endif + } + + bool isSet() const { return m_label.isSet(); } + + private: + AssemblerLabel m_label; +#if CPU(ARM_THUMB2) + ARMv7Assembler::JumpType m_type; + ARMv7Assembler::Condition m_condition; +#endif +#if CPU(SH4) + SH4Assembler::JumpType m_type; +#endif + }; + + struct PatchableJump { + PatchableJump() + { + } + + explicit PatchableJump(Jump jump) + : m_jump(jump) + { + } + + operator Jump&() { return m_jump; } + + Jump m_jump; + }; + + // JumpList: + // + // A JumpList is a set of Jump objects. + // All jumps in the set will be linked to the same destination. + class JumpList { + friend class LinkBuffer; + + public: + typedef Vector<Jump, 16> JumpVector; + + JumpList() { } + + JumpList(Jump jump) + { + append(jump); + } + + void link(AbstractMacroAssembler<AssemblerType>* masm) + { + size_t size = m_jumps.size(); + for (size_t i = 0; i < size; ++i) + m_jumps[i].link(masm); + m_jumps.clear(); + } + + void linkTo(Label label, AbstractMacroAssembler<AssemblerType>* masm) + { + size_t size = m_jumps.size(); + for (size_t i = 0; i < size; ++i) + m_jumps[i].linkTo(label, masm); + m_jumps.clear(); + } + + void append(Jump jump) + { + m_jumps.append(jump); + } + + void append(const JumpList& other) + { + m_jumps.append(other.m_jumps.begin(), other.m_jumps.size()); + } + + bool empty() + { + return !m_jumps.size(); + } + + void clear() + { + m_jumps.clear(); + } + + const JumpVector& jumps() const { return m_jumps; } + + private: + JumpVector m_jumps; + }; + + + // Section 3: Misc admin methods +#if ENABLE(DFG_JIT) + Label labelIgnoringWatchpoints() + { + Label result; + result.m_label = m_assembler.labelIgnoringWatchpoints(); + return result; + } +#else + Label labelIgnoringWatchpoints() + { + return label(); + } +#endif + + Label label() + { + return Label(this); + } + + void padBeforePatch() + { + // Rely on the fact that asking for a label already does the padding. + (void)label(); + } + + Label watchpointLabel() + { + Label result; + result.m_label = m_assembler.labelForWatchpoint(); + return result; + } + + Label align() + { + m_assembler.align(16); + return Label(this); + } + + template<typename T, typename U> + static ptrdiff_t differenceBetween(T from, U to) + { + return AssemblerType::getDifferenceBetweenLabels(from.m_label, to.m_label); + } + + static ptrdiff_t differenceBetweenCodePtr(const MacroAssemblerCodePtr& a, const MacroAssemblerCodePtr& b) + { + return reinterpret_cast<ptrdiff_t>(b.executableAddress()) - reinterpret_cast<ptrdiff_t>(a.executableAddress()); + } + + unsigned debugOffset() { return m_assembler.debugOffset(); } + + ALWAYS_INLINE static void cacheFlush(void* code, size_t size) + { + AssemblerType::cacheFlush(code, size); + } +protected: + AbstractMacroAssembler() + : m_randomSource(cryptographicallyRandomNumber()) + { + } + + AssemblerType m_assembler; + + uint32_t random() + { + return m_randomSource.getUint32(); + } + + WeakRandom m_randomSource; + +#if ENABLE(JIT_CONSTANT_BLINDING) + static bool scratchRegisterForBlinding() { return false; } + static bool shouldBlindForSpecificArch(uint32_t) { return true; } + static bool shouldBlindForSpecificArch(uint64_t) { return true; } +#endif + + friend class LinkBuffer; + friend class RepatchBuffer; + + static void linkJump(void* code, Jump jump, CodeLocationLabel target) + { + AssemblerType::linkJump(code, jump.m_label, target.dataLocation()); + } + + static void linkPointer(void* code, AssemblerLabel label, void* value) + { + AssemblerType::linkPointer(code, label, value); + } + + static void* getLinkerAddress(void* code, AssemblerLabel label) + { + return AssemblerType::getRelocatedAddress(code, label); + } + + static unsigned getLinkerCallReturnOffset(Call call) + { + return AssemblerType::getCallReturnOffset(call.m_label); + } + + static void repatchJump(CodeLocationJump jump, CodeLocationLabel destination) + { + AssemblerType::relinkJump(jump.dataLocation(), destination.dataLocation()); + } + + static void repatchNearCall(CodeLocationNearCall nearCall, CodeLocationLabel destination) + { + AssemblerType::relinkCall(nearCall.dataLocation(), destination.executableAddress()); + } + + static void repatchCompact(CodeLocationDataLabelCompact dataLabelCompact, int32_t value) + { + AssemblerType::repatchCompact(dataLabelCompact.dataLocation(), value); + } + + static void repatchInt32(CodeLocationDataLabel32 dataLabel32, int32_t value) + { + AssemblerType::repatchInt32(dataLabel32.dataLocation(), value); + } + + static void repatchPointer(CodeLocationDataLabelPtr dataLabelPtr, void* value) + { + AssemblerType::repatchPointer(dataLabelPtr.dataLocation(), value); + } + + static void* readPointer(CodeLocationDataLabelPtr dataLabelPtr) + { + return AssemblerType::readPointer(dataLabelPtr.dataLocation()); + } + + static void replaceWithLoad(CodeLocationConvertibleLoad label) + { + AssemblerType::replaceWithLoad(label.dataLocation()); + } + + static void replaceWithAddressComputation(CodeLocationConvertibleLoad label) + { + AssemblerType::replaceWithAddressComputation(label.dataLocation()); + } +}; + +} // namespace JSC + +#endif // ENABLE(ASSEMBLER) + +#endif // AbstractMacroAssembler_h |