/* Copyright (c) 2008, Avian Contributors Permission to use, copy, modify, and/or distribute this software for any purpose with or without fee is hereby granted, provided that the above copyright notice and this permission notice appear in all copies. There is NO WARRANTY for this software. See license.txt for details. */ #include "assembler.h" #include "vector.h" using namespace vm; namespace { enum { rax = 0, rcx = 1, rdx = 2, rbx = 3, rsp = 4, rbp = 5, rsi = 6, rdi = 7, r8 = 8, r9 = 9, r10 = 10, r11 = 11, r12 = 12, r13 = 13, r14 = 14, r15 = 15, }; const unsigned FrameHeaderSize = 2; inline bool isInt8(intptr_t v) { return v == static_cast(v); } inline bool isInt32(intptr_t v) { return v == static_cast(v); } class Task; class AlignmentPadding; unsigned padding(AlignmentPadding* p, unsigned index, unsigned offset, unsigned limit); class MyBlock: public Assembler::Block { public: MyBlock(unsigned offset): next(0), firstPadding(0), lastPadding(0), offset(offset), start(~0), size(0) { } virtual unsigned resolve(unsigned start, Assembler::Block* next) { this->start = start; this->next = static_cast(next); return start + size + padding(firstPadding, start, offset, ~0); } MyBlock* next; AlignmentPadding* firstPadding; AlignmentPadding* lastPadding; unsigned offset; unsigned start; unsigned size; }; class Context { public: Context(System* s, Allocator* a, Zone* zone): s(s), zone(zone), client(0), code(s, a, 1024), tasks(0), result(0), firstBlock(new (zone->allocate(sizeof(MyBlock))) MyBlock(0)), lastBlock(firstBlock) { } System* s; Zone* zone; Assembler::Client* client; Vector code; Task* tasks; uint8_t* result; MyBlock* firstBlock; MyBlock* lastBlock; }; typedef void (*OperationType)(Context*); typedef void (*UnaryOperationType)(Context*, unsigned, Assembler::Operand*); typedef void (*BinaryOperationType) (Context*, unsigned, Assembler::Operand*, unsigned, Assembler::Operand*); class ArchitectureContext { public: ArchitectureContext(System* s): s(s) { } System* s; OperationType operations[OperationCount]; UnaryOperationType unaryOperations[UnaryOperationCount * OperandTypeCount]; BinaryOperationType binaryOperations [(BinaryOperationCount + TernaryOperationCount) * OperandTypeCount * OperandTypeCount]; }; inline void NO_RETURN abort(Context* c) { abort(c->s); } inline void NO_RETURN abort(ArchitectureContext* c) { abort(c->s); } #ifndef NDEBUG inline void assert(Context* c, bool v) { assert(c->s, v); } inline void assert(ArchitectureContext* c, bool v) { assert(c->s, v); } #endif // not NDEBUG inline void expect(Context* c, bool v) { expect(c->s, v); } ResolvedPromise* resolved(Context* c, int64_t value) { return new (c->zone->allocate(sizeof(ResolvedPromise))) ResolvedPromise(value); } class CodePromise: public Promise { public: CodePromise(Context* c, unsigned offset): c(c), offset(offset) { } virtual int64_t value() { if (resolved()) { return reinterpret_cast(c->result + offset); } abort(c); } virtual bool resolved() { return c->result != 0; } Context* c; unsigned offset; }; CodePromise* codePromise(Context* c, unsigned offset) { return new (c->zone->allocate(sizeof(CodePromise))) CodePromise(c, offset); } class Task { public: Task(Task* next): next(next) { } virtual ~Task() { } virtual void run(Context* c) = 0; Task* next; }; class OffsetTask: public Task { public: OffsetTask(Task* next, Promise* promise, unsigned instructionOffset, unsigned instructionSize): Task(next), promise(promise), instructionOffset(instructionOffset), instructionSize(instructionSize) { } virtual void run(Context* c) { uint8_t* instruction = c->result + instructionOffset; intptr_t v = reinterpret_cast(promise->value()) - instruction - instructionSize; expect(c, isInt32(v)); int32_t v4 = v; memcpy(instruction + instructionSize - 4, &v4, 4); } Promise* promise; unsigned instructionOffset; unsigned instructionSize; }; void appendOffsetTask(Context* c, Promise* promise, int instructionOffset, unsigned instructionSize) { c->tasks = new (c->zone->allocate(sizeof(OffsetTask))) OffsetTask (c->tasks, promise, instructionOffset, instructionSize); } class ImmediateTask: public Task { public: ImmediateTask(Task* next, Promise* promise, unsigned offset): Task(next), promise(promise), offset(offset) { } virtual void run(Context* c) { intptr_t v = promise->value(); memcpy(c->result + offset, &v, BytesPerWord); } Promise* promise; unsigned offset; }; void appendImmediateTask(Context* c, Promise* promise, unsigned offset) { c->tasks = new (c->zone->allocate(sizeof(ImmediateTask))) ImmediateTask (c->tasks, promise, offset); } class AlignmentPadding { public: AlignmentPadding(Context* c): offset(c->code.length()), next(0) { if (c->lastBlock->firstPadding) { c->lastBlock->lastPadding->next = this; } else { c->lastBlock->firstPadding = this; } c->lastBlock->lastPadding = this; } unsigned offset; AlignmentPadding* next; }; unsigned padding(AlignmentPadding* p, unsigned index, unsigned offset, unsigned limit) { unsigned padding = 0; for (; p; p = p->next) { if (p->offset <= limit) { index += p->offset - offset; while ((index + padding + 1) % 4) { ++ padding; } } } return padding; } void encode(Context* c, uint8_t* instruction, unsigned length, int a, int b, int32_t displacement, int index, unsigned scale) { c->code.append(instruction, length); uint8_t width; if (displacement == 0 and b != rbp) { width = 0; } else if (isInt8(displacement)) { width = 0x40; } else { width = 0x80; } if (index == -1) { c->code.append(width | (a << 3) | b); if (b == rsp) { c->code.append(0x24); } } else { assert(c, b != rsp); c->code.append(width | (a << 3) | 4); c->code.append((log(scale) << 6) | (index << 3) | b); } if (displacement == 0 and b != rbp) { // do nothing } else if (isInt8(displacement)) { c->code.append(displacement); } else { c->code.append4(displacement); } } void rex(Context* c, uint8_t mask, int r) { if (BytesPerWord == 8) { c->code.append(mask | ((r & 8) >> 3)); } } void rex(Context* c) { rex(c, 0x48, rax); } void encode(Context* c, uint8_t instruction, int a, Assembler::Memory* b, bool rex) { if (rex) { ::rex(c); } encode(c, &instruction, 1, a, b->base, b->offset, b->index, b->scale); } void encode2(Context* c, uint16_t instruction, int a, Assembler::Memory* b, bool rex) { if (rex) { ::rex(c); } uint8_t i[2] = { instruction >> 8, instruction & 0xff }; encode(c, i, 2, a, b->base, b->offset, b->index, b->scale); } void return_(Context* c) { c->code.append(0xc3); } void unconditional(Context* c, unsigned jump, Assembler::Constant* a) { appendOffsetTask(c, a->value, c->code.length(), 5); c->code.append(jump); c->code.append4(0); } void conditional(Context* c, unsigned condition, Assembler::Constant* a) { appendOffsetTask(c, a->value, c->code.length(), 6); c->code.append(0x0f); c->code.append(condition); c->code.append4(0); } inline unsigned index(UnaryOperation operation, OperandType operand) { return operation + (UnaryOperationCount * operand); } inline unsigned index(BinaryOperation operation, OperandType operand1, OperandType operand2) { return operation + ((BinaryOperationCount + TernaryOperationCount) * operand1) + ((BinaryOperationCount + TernaryOperationCount) * OperandTypeCount * operand2); } inline unsigned index(TernaryOperation operation, OperandType operand1, OperandType operand2) { return operation + ((BinaryOperationCount + TernaryOperationCount) * operand1) + ((BinaryOperationCount + TernaryOperationCount) * OperandTypeCount * operand2); } void jumpR(Context* c, unsigned size UNUSED, Assembler::Register* a) { assert(c, size == BytesPerWord); if (a->low & 8) rex(c, 0x40, a->low); c->code.append(0xff); c->code.append(0xe0 | (a->low & 7)); } void jumpC(Context* c, unsigned size UNUSED, Assembler::Constant* a) { assert(c, size == BytesPerWord); unconditional(c, 0xe9, a); } void moveCR(Context* c, unsigned aSize, Assembler::Constant* a, unsigned bSize, Assembler::Register* b); void longJumpC(Context* c, unsigned size, Assembler::Constant* a) { assert(c, size == BytesPerWord); if (BytesPerWord == 8) { Assembler::Register r(r10); moveCR(c, size, a, size, &r); jumpR(c, size, &r); } else { jumpC(c, size, a); } } void callR(Context* c, unsigned size UNUSED, Assembler::Register* a) { assert(c, size == BytesPerWord); if (a->low & 8) rex(c, 0x40, a->low); c->code.append(0xff); c->code.append(0xd0 | (a->low & 7)); } void callC(Context* c, unsigned size UNUSED, Assembler::Constant* a) { assert(c, size == BytesPerWord); unconditional(c, 0xe8, a); } void alignedCallC(Context* c, unsigned size, Assembler::Constant* a) { new (c->zone->allocate(sizeof(AlignmentPadding))) AlignmentPadding(c); callC(c, size, a); } void longCallC(Context* c, unsigned size, Assembler::Constant* a) { assert(c, size == BytesPerWord); if (BytesPerWord == 8) { Assembler::Register r(r10); moveCR(c, size, a, size, &r); callR(c, size, &r); } else { callC(c, size, a); } } void pushR(Context* c, unsigned size, Assembler::Register* a) { if (BytesPerWord == 4 and size == 8) { Assembler::Register ah(a->high); pushR(c, 4, &ah); pushR(c, 4, a); } else { c->code.append(0x50 | a->low); } } void moveRR(Context* c, unsigned aSize, Assembler::Register* a, unsigned bSize, Assembler::Register* b); void popR(Context* c, unsigned size, Assembler::Register* a) { if (BytesPerWord == 4 and size == 8) { Assembler::Register ah(a->high); popR(c, 4, a); popR(c, 4, &ah); } else { c->code.append(0x58 | a->low); if (BytesPerWord == 8 and size == 4) { moveRR(c, 4, a, 8, a); } } } void moveRR(Context* c, unsigned aSize, Assembler::Register* a, unsigned bSize, Assembler::Register* b) { if (BytesPerWord == 4 and aSize == 8 and bSize == 8) { Assembler::Register ah(a->high); Assembler::Register bh(b->high); moveRR(c, 4, a, 4, b); moveRR(c, 4, &ah, 4, &bh); } else { switch (aSize) { case 1: if (BytesPerWord == 4 and a->low > rbx) { assert(c, b->low <= rbx); moveRR(c, BytesPerWord, a, BytesPerWord, b); moveRR(c, 1, b, BytesPerWord, b); } else { rex(c); c->code.append(0x0f); c->code.append(0xbe); c->code.append(0xc0 | (b->low << 3) | a->low); } break; case 2: rex(c); c->code.append(0x0f); c->code.append(0xbf); c->code.append(0xc0 | (b->low << 3) | a->low); break; case 8: case 4: if (aSize == 4 and bSize == 8) { if (BytesPerWord == 8) { rex(c); c->code.append(0x63); c->code.append(0xc0 | (b->low << 3) | a->low); } else { if (a->low == rax and b->low == rax and b->high == rdx) { c->code.append(0x99); // cdq } else { assert(c, b->low == rax and b->high == rdx); moveRR(c, 4, a, 4, b); moveRR(c, 4, b, 8, b); } } } else { if (a->low != b->low) { rex(c); c->code.append(0x89); c->code.append(0xc0 | (a->low << 3) | b->low); } } break; } } } void moveMR(Context* c, unsigned aSize, Assembler::Memory* a, unsigned bSize, Assembler::Register* b) { switch (aSize) { case 1: encode2(c, 0x0fbe, b->low, a, true); break; case 2: encode2(c, 0x0fbf, b->low, a, true); break; case 4: case 8: if (aSize == 4 and bSize == 8) { if (BytesPerWord == 8) { encode(c, 0x63, b->low, a, true); } else { assert(c, b->low == rax and b->high == rdx); moveMR(c, 4, a, 4, b); moveRR(c, 4, b, 8, b); } } else { if (BytesPerWord == 4 and aSize == 8) { Assembler::Memory ah(a->base, a->offset + 4, a->index, a->scale); Assembler::Register bh(b->high); moveMR(c, 4, a, 4, b); moveMR(c, 4, &ah, 4, &bh); } else if (BytesPerWord == 8 and aSize == 4) { encode(c, 0x63, b->low, a, true); } else { encode(c, 0x8b, b->low, a, true); } } break; default: abort(c); } } void moveRM(Context* c, unsigned aSize, Assembler::Register* a, unsigned bSize UNUSED, Assembler::Memory* b) { assert(c, aSize == bSize); if (BytesPerWord == 4 and aSize == 8) { Assembler::Register ah(a->high); Assembler::Memory bh(b->base, b->offset + 4, b->index, b->scale); moveRM(c, 4, a, 4, b); moveRM(c, 4, &ah, 4, &bh); } else if (BytesPerWord == 8 and aSize == 4) { encode(c, 0x89, a->low, b, false); } else { switch (aSize) { case 1: if (BytesPerWord == 8) { if (a->low > rbx) { encode2(c, 0x4088, a->low, b, false); } else { encode(c, 0x88, a->low, b, false); } } else { assert(c, a->low <= rbx); encode(c, 0x88, a->low, b, false); } break; case 2: encode2(c, 0x6689, a->low, b, false); break; case BytesPerWord: encode(c, 0x89, a->low, b, true); break; default: abort(c); } } } void moveAR(Context* c, unsigned aSize, Assembler::Address* a, unsigned bSize, Assembler::Register* b) { assert(c, BytesPerWord == 8 or (aSize == 4 and bSize == 4)); Assembler::Constant constant(a->address); Assembler::Memory memory(b->low, 0, -1, 0); moveCR(c, aSize, &constant, bSize, b); moveMR(c, bSize, &memory, bSize, b); } void moveAM(Context* c, unsigned aSize, Assembler::Address* a, unsigned bSize, Assembler::Memory* b) { assert(c, BytesPerWord == 8 or (aSize == 4 and bSize == 4)); Assembler::Register tmp(c->client->acquireTemporary()); moveAR(c, aSize, a, aSize, &tmp); moveRM(c, aSize, &tmp, bSize, b); c->client->releaseTemporary(tmp.low); } void moveCR(Context* c, unsigned aSize, Assembler::Constant* a, unsigned bSize UNUSED, Assembler::Register* b) { assert(c, aSize == bSize); if (BytesPerWord == 4 and aSize == 8) { int64_t v = a->value->value(); ResolvedPromise high((v >> 32) & 0xFFFFFFFF); Assembler::Constant ah(&high); ResolvedPromise low(v & 0xFFFFFFFF); Assembler::Constant al(&low); Assembler::Register bh(b->high); moveCR(c, 4, &al, 4, b); moveCR(c, 4, &ah, 4, &bh); } else { rex(c, 0x48, b->low); c->code.append(0xb8 | b->low); if (a->value->resolved()) { c->code.appendAddress(a->value->value()); } else { appendImmediateTask(c, a->value, c->code.length()); c->code.appendAddress(static_cast(0)); } } } void moveCM(Context* c, unsigned aSize UNUSED, Assembler::Constant* a, unsigned bSize, Assembler::Memory* b) { int64_t v = a->value->value(); switch (bSize) { case 1: encode(c, 0xc6, 0, b, false); c->code.append(a->value->value()); break; case 2: encode2(c, 0x66c7, 0, b, false); c->code.append2(a->value->value()); break; case 4: encode(c, 0xc7, 0, b, false); c->code.append4(a->value->value()); break; case 8: { ResolvedPromise high((v >> 32) & 0xFFFFFFFF); Assembler::Constant ah(&high); ResolvedPromise low(v & 0xFFFFFFFF); Assembler::Constant al(&low); Assembler::Memory bh(b->base, b->offset + 4, b->index, b->scale); moveCM(c, 4, &al, 4, b); moveCM(c, 4, &ah, 4, &bh); } break; default: abort(c); } } void addCarryRR(Context* c, unsigned size, Assembler::Register* a, Assembler::Register* b) { assert(c, BytesPerWord == 8 or size == 4); if (size == 8) rex(c); c->code.append(0x11); c->code.append(0xc0 | (a->low << 3) | b->low); } void addRR(Context* c, unsigned aSize, Assembler::Register* a, unsigned bSize UNUSED, Assembler::Register* b) { assert(c, aSize == bSize); if (BytesPerWord == 4 and aSize == 8) { Assembler::Register ah(a->high); Assembler::Register bh(b->high); addRR(c, 4, a, 4, b); addCarryRR(c, 4, &ah, &bh); } else { if (aSize == 8) rex(c); c->code.append(0x01); c->code.append(0xc0 | (a->low << 3) | b->low); } } void addCarryCR(Context* c, unsigned size UNUSED, Assembler::Constant* a, Assembler::Register* b) { assert(c, BytesPerWord == 8 or size == 4); int64_t v = a->value->value(); if (isInt8(v)) { c->code.append(0x83); c->code.append(0xd0 | b->low); c->code.append(v); } else { abort(c); } } void addCR(Context* c, unsigned aSize, Assembler::Constant* a, unsigned bSize, Assembler::Register* b) { assert(c, aSize == bSize); int64_t v = a->value->value(); if (v) { if (BytesPerWord == 4 and aSize == 8) { ResolvedPromise high((v >> 32) & 0xFFFFFFFF); Assembler::Constant ah(&high); ResolvedPromise low(v & 0xFFFFFFFF); Assembler::Constant al(&low); Assembler::Register bh(b->high); addCR(c, 4, &al, 4, b); addCarryCR(c, 4, &ah, &bh); } else { if (aSize == 8) rex(c); if (isInt8(v)) { c->code.append(0x83); c->code.append(0xc0 | b->low); c->code.append(v); } else if (isInt32(v)) { c->code.append(0x81); c->code.append(0xc0 | b->low); c->code.append4(v); } else { Assembler::Register tmp(c->client->acquireTemporary()); moveCR(c, aSize, a, aSize, &tmp); addRR(c, aSize, &tmp, bSize, b); c->client->releaseTemporary(tmp.low); } } } } void subtractBorrowCR(Context* c, unsigned size UNUSED, Assembler::Constant* a, Assembler::Register* b) { assert(c, BytesPerWord == 8 or size == 4); int64_t v = a->value->value(); if (isInt8(v)) { c->code.append(0x83); c->code.append(0xd8 | b->low); c->code.append(v); } else { abort(c); } } void subtractRR(Context* c, unsigned aSize, Assembler::Register* a, unsigned bSize, Assembler::Register* b); void subtractCR(Context* c, unsigned aSize, Assembler::Constant* a, unsigned bSize, Assembler::Register* b) { assert(c, aSize == bSize); int64_t v = a->value->value(); if (v) { if (BytesPerWord == 4 and aSize == 8) { ResolvedPromise high((v >> 32) & 0xFFFFFFFF); Assembler::Constant ah(&high); ResolvedPromise low(v & 0xFFFFFFFF); Assembler::Constant al(&low); Assembler::Register bh(b->high); subtractCR(c, 4, &al, 4, b); subtractBorrowCR(c, 4, &ah, &bh); } else { if (aSize == 8) rex(c); if (isInt8(v)) { c->code.append(0x83); c->code.append(0xe8 | b->low); c->code.append(v); } else if (isInt32(v)) { c->code.append(0x81); c->code.append(0xe8 | b->low); c->code.append4(v); } else { Assembler::Register tmp(c->client->acquireTemporary()); moveCR(c, aSize, a, aSize, &tmp); subtractRR(c, aSize, &tmp, bSize, b); c->client->releaseTemporary(tmp.low); } } } } void subtractBorrowRR(Context* c, unsigned size, Assembler::Register* a, Assembler::Register* b) { assert(c, BytesPerWord == 8 or size == 4); if (size == 8) rex(c); c->code.append(0x19); c->code.append(0xc0 | (a->low << 3) | b->low); } void subtractRR(Context* c, unsigned aSize, Assembler::Register* a, unsigned bSize UNUSED, Assembler::Register* b) { assert(c, aSize == bSize); if (BytesPerWord == 4 and aSize == 8) { Assembler::Register ah(a->high); Assembler::Register bh(b->high); subtractRR(c, 4, a, 4, b); subtractBorrowRR(c, 4, &ah, &bh); } else { if (aSize == 8) rex(c); c->code.append(0x29); c->code.append(0xc0 | (a->low << 3) | b->low); } } void andRR(Context* c, unsigned aSize, Assembler::Register* a, unsigned bSize UNUSED, Assembler::Register* b) { assert(c, aSize == bSize); if (BytesPerWord == 4 and aSize == 8) { Assembler::Register ah(a->high); Assembler::Register bh(b->high); andRR(c, 4, a, 4, b); andRR(c, 4, &ah, 4, &bh); } else { if (aSize == 8) rex(c); c->code.append(0x21); c->code.append(0xc0 | (a->low << 3) | b->low); } } void andCR(Context* c, unsigned aSize, Assembler::Constant* a, unsigned bSize, Assembler::Register* b) { assert(c, aSize == bSize); int64_t v = a->value->value(); if (BytesPerWord == 4 and aSize == 8) { ResolvedPromise high((v >> 32) & 0xFFFFFFFF); Assembler::Constant ah(&high); ResolvedPromise low(v & 0xFFFFFFFF); Assembler::Constant al(&low); Assembler::Register bh(b->high); andCR(c, 4, &al, 4, b); andCR(c, 4, &ah, 4, &bh); } else { if (isInt32(v)) { if (aSize == 8) rex(c); if (isInt8(v)) { c->code.append(0x83); c->code.append(0xe0 | b->low); c->code.append(v); } else { c->code.append(0x81); c->code.append(0xe0 | b->low); c->code.append4(v); } } else { Assembler::Register tmp(c->client->acquireTemporary()); moveCR(c, aSize, a, aSize, &tmp); andRR(c, aSize, &tmp, bSize, b); c->client->releaseTemporary(tmp.low); } } } void populateTables(ArchitectureContext* c) { #define CAST1(x) reinterpret_cast(x) #define CAST2(x) reinterpret_cast(x) const OperandType C = ConstantOperand; const OperandType A = AddressOperand; const OperandType R = RegisterOperand; const OperandType M = MemoryOperand; OperationType* zo = c->operations; UnaryOperationType* uo = c->unaryOperations; BinaryOperationType* bo = c->binaryOperations; zo[Return] = return_; uo[index(Call, C)] = CAST1(callC); uo[index(AlignedCall, C)] = CAST1(alignedCallC); uo[index(LongCall, C)] = CAST1(longCallC); uo[index(Jump, R)] = CAST1(jumpR); uo[index(Jump, C)] = CAST1(jumpC); uo[index(LongJump, C)] = CAST1(longJumpC); bo[index(Move, R, R)] = CAST2(moveRR); bo[index(Move, C, R)] = CAST2(moveCR); bo[index(Move, M, R)] = CAST2(moveMR); bo[index(Move, R, M)] = CAST2(moveRM); bo[index(Move, C, M)] = CAST2(moveCM); bo[index(Move, A, M)] = CAST2(moveAM); bo[index(Add, C, R)] = CAST2(addCR); bo[index(Subtract, C, R)] = CAST2(subtractCR); bo[index(And, C, R)] = CAST2(andCR); } class MyArchitecture: public Assembler::Architecture { public: MyArchitecture(System* system): c(system), referenceCount(0) { populateTables(&c); } virtual unsigned registerCount() { return 8;//BytesPerWord == 4 ? 8 : 16; } virtual int stack() { return rsp; } virtual int thread() { return rbx; } virtual int returnLow() { return rax; } virtual bool condensedAddressing() { return true; } virtual bool reserved(int register_) { switch (register_) { case rbp: case rsp: case rbx: return true; default: return false; } } virtual int returnHigh() { return (BytesPerWord == 4 ? rdx : NoRegister); } virtual unsigned argumentRegisterCount() { return (BytesPerWord == 4 ? 0 : 6); } virtual int argumentRegister(unsigned index) { assert(&c, BytesPerWord == 8); switch (index) { case 0: return rdi; case 1: return rsi; case 2: return rdx; case 3: return rcx; case 4: return r8; case 5: return r9; default: abort(&c); } } virtual void updateCall(void* returnAddress, void* newTarget) { uint8_t* instruction = static_cast(returnAddress) - 5; assert(&c, *instruction == 0xE8); assert(&c, reinterpret_cast(instruction + 1) % 4 == 0); int32_t v = static_cast(newTarget) - static_cast(returnAddress); memcpy(instruction + 1, &v, 4); } virtual unsigned alignFrameSize(unsigned sizeInWords) { const unsigned alignment = 16 / BytesPerWord; return (ceiling(sizeInWords + FrameHeaderSize, alignment) * alignment) - FrameHeaderSize; } virtual void* frameIp(void* stack) { return *static_cast(stack); } virtual unsigned frameHeaderSize() { return FrameHeaderSize; } virtual unsigned frameFooterSize() { return 0; } virtual void nextFrame(void** stack, void** base) { *stack = static_cast(*base) + 1; *base = *static_cast(*base); } virtual void* popReturnAddress(void* stack) { return static_cast(stack) + 1; } virtual void plan (UnaryOperation, unsigned, uint8_t* aTypeMask, uint64_t* aRegisterMask, bool* thunk) { *aTypeMask = (1 << RegisterOperand) | (1 << MemoryOperand); *aRegisterMask = ~static_cast(0); *thunk = false; } virtual void plan (BinaryOperation op, unsigned aSize, uint8_t* aTypeMask, uint64_t* aRegisterMask, unsigned bSize, uint8_t* bTypeMask, uint64_t* bRegisterMask, bool* thunk) { *aTypeMask = ~0; *aRegisterMask = ~static_cast(0); *bTypeMask = (1 << RegisterOperand) | (1 << MemoryOperand); *bRegisterMask = ~static_cast(0); *thunk = false; switch (op) { case Compare: if (BytesPerWord == 8 and aSize != 8) { *aTypeMask = ~(1 << MemoryOperand); *bTypeMask = ~(1 << MemoryOperand); } else { *bTypeMask = ~(1 << ConstantOperand); } break; case Move: if (BytesPerWord == 4) { if (aSize == 4 and bSize == 8) { const uint32_t mask = ~((1 << rax) | (1 << rdx)); *aRegisterMask = (static_cast(mask) << 32) | mask; *bRegisterMask = (static_cast(1) << (rdx + 32)) | (static_cast(1) << rax); } else if (aSize == 1) { const uint32_t mask = (1 << rax) | (1 << rcx) | (1 << rdx) | (1 << rbx); *aRegisterMask = (static_cast(mask) << 32) | mask; *bRegisterMask = (static_cast(mask) << 32) | mask; } } break; default: break; } } virtual void plan (TernaryOperation, unsigned, uint8_t* aTypeMask, uint64_t* aRegisterMask, unsigned, uint8_t* bTypeMask, uint64_t* bRegisterMask, unsigned, uint8_t* cTypeMask, uint64_t* cRegisterMask, bool* thunk) { *aTypeMask = ~0; *aRegisterMask = ~static_cast(0); *bTypeMask = ~0; *bRegisterMask = ~static_cast(0); *cTypeMask = (1 << RegisterOperand) | (1 << MemoryOperand); *cRegisterMask = ~static_cast(0); *thunk = false; } virtual void acquire() { ++ referenceCount; } virtual void release() { if (-- referenceCount == 0) { c.s->free(this); } } ArchitectureContext c; unsigned referenceCount; }; class MyOffset: public Assembler::Offset { public: MyOffset(Context* c, MyBlock* block, unsigned offset): c(c), block(block), offset(offset) { } virtual unsigned resolve(unsigned start) { block->start = start; return value(); } virtual bool resolved() { return block->start != static_cast(~0); } virtual unsigned value() { assert(c, resolved()); return block->start + (offset - block->offset) + padding(block->firstPadding, block->start, block->offset, offset); } Context* c; MyBlock* block; unsigned offset; }; class MyAssembler: public Assembler { public: MyAssembler(System* s, Allocator* a, Zone* zone, MyArchitecture* arch): c(s, a, zone), arch_(arch) { } virtual void setClient(Client* client) { assert(&c, c.client == 0); c.client = client; } virtual Architecture* arch() { return arch_; } virtual void saveFrame(unsigned stackOffset, unsigned baseOffset) { Register stack(rsp); Memory stackDst(rbx, stackOffset); apply(Move, BytesPerWord, RegisterOperand, &stack, BytesPerWord, MemoryOperand, &stackDst); Register base(rbp); Memory baseDst(rbx, baseOffset); apply(Move, BytesPerWord, RegisterOperand, &base, BytesPerWord, MemoryOperand, &baseDst); } virtual void pushFrame(unsigned argumentCount, ...) { struct { unsigned size; OperandType type; Operand* operand; } arguments[argumentCount]; va_list a; va_start(a, argumentCount); unsigned footprint = 0; for (unsigned i = 0; i < argumentCount; ++i) { arguments[i].size = va_arg(a, unsigned); arguments[i].type = static_cast(va_arg(a, int)); arguments[i].operand = va_arg(a, Operand*); footprint += ceiling(arguments[i].size, BytesPerWord); } va_end(a); allocateFrame(arch_->alignFrameSize(footprint)); unsigned offset = 0; for (unsigned i = 0; i < argumentCount; ++i) { Memory dst(rsp, offset * BytesPerWord); apply(Move, arguments[i].size, arguments[i].type, arguments[i].operand, pad(arguments[i].size), MemoryOperand, &dst); offset += ceiling(arguments[i].size, BytesPerWord); } } virtual void allocateFrame(unsigned footprint) { Register base(rbp); pushR(&c, BytesPerWord, &base); Register stack(rsp); apply(Move, BytesPerWord, RegisterOperand, &stack, BytesPerWord, RegisterOperand, &base); Constant footprintConstant(resolved(&c, footprint * BytesPerWord)); apply(Subtract, BytesPerWord, ConstantOperand, &footprintConstant, BytesPerWord, RegisterOperand, &stack, BytesPerWord, RegisterOperand, &stack); } virtual void popFrame() { Register base(rbp); Register stack(rsp); apply(Move, BytesPerWord, RegisterOperand, &base, BytesPerWord, RegisterOperand, &stack); popR(&c, BytesPerWord, &base); } virtual void apply(Operation op) { arch_->c.operations[op](&c); } virtual void apply(UnaryOperation op, unsigned aSize, OperandType aType, Operand* aOperand) { arch_->c.unaryOperations[index(op, aType)](&c, aSize, aOperand); } virtual void apply(BinaryOperation op, unsigned aSize, OperandType aType, Operand* aOperand, unsigned bSize, OperandType bType, Operand* bOperand) { arch_->c.binaryOperations[index(op, aType, bType)] (&c, aSize, aOperand, bSize, bOperand); } virtual void apply(TernaryOperation op, unsigned aSize, OperandType aType, Operand* aOperand, unsigned bSize, OperandType bType, Operand* bOperand, unsigned cSize, OperandType cType, Operand* cOperand) { assert(&c, bSize == cSize); assert(&c, bType == cType); assert(&c, bOperand == cOperand); arch_->c.binaryOperations[index(op, aType, bType)] (&c, aSize, aOperand, bSize, bOperand); } virtual void writeTo(uint8_t* dst) { c.result = dst; for (MyBlock* b = c.firstBlock; b; b = b->next) { memcpy(dst + b->start, c.code.data + b->offset, b->size); } for (Task* t = c.tasks; t; t = t->next) { t->run(&c); } } virtual Offset* offset() { return new (c.zone->allocate(sizeof(MyOffset))) MyOffset(&c, c.lastBlock, c.code.length()); } virtual Block* endBlock() { MyBlock* b = c.lastBlock; b->size = c.code.length() - b->offset; c.lastBlock = new (c.zone->allocate(sizeof(MyBlock))) MyBlock(c.code.length()); return b; } virtual unsigned length() { return c.code.length(); } virtual void dispose() { c.code.dispose(); } Context c; MyArchitecture* arch_; }; } // namespace namespace vm { Assembler::Architecture* makeArchitecture(System* system) { return new (allocate(system, sizeof(MyArchitecture))) MyArchitecture(system); } Assembler* makeAssembler(System* system, Allocator* allocator, Zone* zone, Assembler::Architecture* architecture) { return new (zone->allocate(sizeof(MyAssembler))) MyAssembler(system, allocator, zone, static_cast(architecture)); } } // namespace vm