// Copyright (c) 1994-2006 Sun Microsystems 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: // // - Redistributions of source code must retain the above copyright notice, // this list of conditions and the following disclaimer. // // - Redistribution 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. // // - Neither the name of Sun Microsystems or the names of contributors may // be used to endorse or promote products derived from this software without // specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS // "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 THE // COPYRIGHT OWNER 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. // The original source code covered by the above license above has been modified // significantly by Google Inc. // Copyright 2012 the V8 project authors. All rights reserved. #include "src/x87/assembler-x87.h" #if V8_TARGET_ARCH_X87 #include "src/base/bits.h" #include "src/base/cpu.h" #include "src/disassembler.h" #include "src/macro-assembler.h" #include "src/v8.h" namespace v8 { namespace internal { // ----------------------------------------------------------------------------- // Implementation of CpuFeatures void CpuFeatures::ProbeImpl(bool cross_compile) { base::CPU cpu; // Only use statically determined features for cross compile (snapshot). if (cross_compile) return; } void CpuFeatures::PrintTarget() { } void CpuFeatures::PrintFeatures() { } // ----------------------------------------------------------------------------- // Implementation of Displacement void Displacement::init(Label* L, Type type) { DCHECK(!L->is_bound()); int next = 0; if (L->is_linked()) { next = L->pos(); DCHECK(next > 0); // Displacements must be at positions > 0 } // Ensure that we _never_ overflow the next field. DCHECK(NextField::is_valid(Assembler::kMaximalBufferSize)); data_ = NextField::encode(next) | TypeField::encode(type); } // ----------------------------------------------------------------------------- // Implementation of RelocInfo const int RelocInfo::kApplyMask = RelocInfo::kCodeTargetMask | 1 << RelocInfo::RUNTIME_ENTRY | 1 << RelocInfo::INTERNAL_REFERENCE | 1 << RelocInfo::CODE_AGE_SEQUENCE | RelocInfo::kDebugBreakSlotMask; bool RelocInfo::IsCodedSpecially() { // The deserializer needs to know whether a pointer is specially coded. Being // specially coded on IA32 means that it is a relative address, as used by // branch instructions. These are also the ones that need changing when a // code object moves. return (1 << rmode_) & kApplyMask; } bool RelocInfo::IsInConstantPool() { return false; } Address RelocInfo::wasm_memory_reference() { DCHECK(IsWasmMemoryReference(rmode_)); return Memory::Address_at(pc_); } Address RelocInfo::wasm_global_reference() { DCHECK(IsWasmGlobalReference(rmode_)); return Memory::Address_at(pc_); } uint32_t RelocInfo::wasm_memory_size_reference() { DCHECK(IsWasmMemorySizeReference(rmode_)); return Memory::uint32_at(pc_); } uint32_t RelocInfo::wasm_function_table_size_reference() { DCHECK(IsWasmFunctionTableSizeReference(rmode_)); return Memory::uint32_at(pc_); } void RelocInfo::unchecked_update_wasm_memory_reference( Isolate* isolate, Address address, ICacheFlushMode icache_flush_mode) { Memory::Address_at(pc_) = address; if (icache_flush_mode != SKIP_ICACHE_FLUSH) { Assembler::FlushICache(isolate, pc_, sizeof(Address)); } } void RelocInfo::unchecked_update_wasm_size(Isolate* isolate, uint32_t size, ICacheFlushMode icache_flush_mode) { Memory::uint32_at(pc_) = size; if (icache_flush_mode != SKIP_ICACHE_FLUSH) { Assembler::FlushICache(isolate, pc_, sizeof(uint32_t)); } } // ----------------------------------------------------------------------------- // Implementation of Operand Operand::Operand(Register base, int32_t disp, RelocInfo::Mode rmode) { // [base + disp/r] if (disp == 0 && RelocInfo::IsNone(rmode) && !base.is(ebp)) { // [base] set_modrm(0, base); if (base.is(esp)) set_sib(times_1, esp, base); } else if (is_int8(disp) && RelocInfo::IsNone(rmode)) { // [base + disp8] set_modrm(1, base); if (base.is(esp)) set_sib(times_1, esp, base); set_disp8(disp); } else { // [base + disp/r] set_modrm(2, base); if (base.is(esp)) set_sib(times_1, esp, base); set_dispr(disp, rmode); } } Operand::Operand(Register base, Register index, ScaleFactor scale, int32_t disp, RelocInfo::Mode rmode) { DCHECK(!index.is(esp)); // illegal addressing mode // [base + index*scale + disp/r] if (disp == 0 && RelocInfo::IsNone(rmode) && !base.is(ebp)) { // [base + index*scale] set_modrm(0, esp); set_sib(scale, index, base); } else if (is_int8(disp) && RelocInfo::IsNone(rmode)) { // [base + index*scale + disp8] set_modrm(1, esp); set_sib(scale, index, base); set_disp8(disp); } else { // [base + index*scale + disp/r] set_modrm(2, esp); set_sib(scale, index, base); set_dispr(disp, rmode); } } Operand::Operand(Register index, ScaleFactor scale, int32_t disp, RelocInfo::Mode rmode) { DCHECK(!index.is(esp)); // illegal addressing mode // [index*scale + disp/r] set_modrm(0, esp); set_sib(scale, index, ebp); set_dispr(disp, rmode); } bool Operand::is_reg(Register reg) const { return ((buf_[0] & 0xF8) == 0xC0) // addressing mode is register only. && ((buf_[0] & 0x07) == reg.code()); // register codes match. } bool Operand::is_reg_only() const { return (buf_[0] & 0xF8) == 0xC0; // Addressing mode is register only. } Register Operand::reg() const { DCHECK(is_reg_only()); return Register::from_code(buf_[0] & 0x07); } // ----------------------------------------------------------------------------- // Implementation of Assembler. // Emit a single byte. Must always be inlined. #define EMIT(x) \ *pc_++ = (x) Assembler::Assembler(IsolateData isolate_data, void* buffer, int buffer_size) : AssemblerBase(isolate_data, buffer, buffer_size) { // Clear the buffer in debug mode unless it was provided by the // caller in which case we can't be sure it's okay to overwrite // existing code in it; see CodePatcher::CodePatcher(...). #ifdef DEBUG if (own_buffer_) { memset(buffer_, 0xCC, buffer_size_); // int3 } #endif reloc_info_writer.Reposition(buffer_ + buffer_size_, pc_); } void Assembler::GetCode(CodeDesc* desc) { // Finalize code (at this point overflow() may be true, but the gap ensures // that we are still not overlapping instructions and relocation info). DCHECK(pc_ <= reloc_info_writer.pos()); // No overlap. // Set up code descriptor. desc->buffer = buffer_; desc->buffer_size = buffer_size_; desc->instr_size = pc_offset(); desc->reloc_size = (buffer_ + buffer_size_) - reloc_info_writer.pos(); desc->origin = this; desc->constant_pool_size = 0; desc->unwinding_info_size = 0; desc->unwinding_info = nullptr; } void Assembler::Align(int m) { DCHECK(base::bits::IsPowerOfTwo32(m)); int mask = m - 1; int addr = pc_offset(); Nop((m - (addr & mask)) & mask); } bool Assembler::IsNop(Address addr) { Address a = addr; while (*a == 0x66) a++; if (*a == 0x90) return true; if (a[0] == 0xf && a[1] == 0x1f) return true; return false; } void Assembler::Nop(int bytes) { EnsureSpace ensure_space(this); // Older CPUs that do not support SSE2 may not support multibyte NOP // instructions. for (; bytes > 0; bytes--) { EMIT(0x90); } return; } void Assembler::CodeTargetAlign() { Align(16); // Preferred alignment of jump targets on ia32. } void Assembler::cpuid() { EnsureSpace ensure_space(this); EMIT(0x0F); EMIT(0xA2); } void Assembler::pushad() { EnsureSpace ensure_space(this); EMIT(0x60); } void Assembler::popad() { EnsureSpace ensure_space(this); EMIT(0x61); } void Assembler::pushfd() { EnsureSpace ensure_space(this); EMIT(0x9C); } void Assembler::popfd() { EnsureSpace ensure_space(this); EMIT(0x9D); } void Assembler::push(const Immediate& x) { EnsureSpace ensure_space(this); if (x.is_int8()) { EMIT(0x6a); EMIT(x.x_); } else { EMIT(0x68); emit(x); } } void Assembler::push_imm32(int32_t imm32) { EnsureSpace ensure_space(this); EMIT(0x68); emit(imm32); } void Assembler::push(Register src) { EnsureSpace ensure_space(this); EMIT(0x50 | src.code()); } void Assembler::push(const Operand& src) { EnsureSpace ensure_space(this); EMIT(0xFF); emit_operand(esi, src); } void Assembler::pop(Register dst) { DCHECK(reloc_info_writer.last_pc() != NULL); EnsureSpace ensure_space(this); EMIT(0x58 | dst.code()); } void Assembler::pop(const Operand& dst) { EnsureSpace ensure_space(this); EMIT(0x8F); emit_operand(eax, dst); } void Assembler::enter(const Immediate& size) { EnsureSpace ensure_space(this); EMIT(0xC8); emit_w(size); EMIT(0); } void Assembler::leave() { EnsureSpace ensure_space(this); EMIT(0xC9); } void Assembler::mov_b(Register dst, const Operand& src) { CHECK(dst.is_byte_register()); EnsureSpace ensure_space(this); EMIT(0x8A); emit_operand(dst, src); } void Assembler::mov_b(const Operand& dst, const Immediate& src) { EnsureSpace ensure_space(this); EMIT(0xC6); emit_operand(eax, dst); EMIT(static_cast(src.x_)); } void Assembler::mov_b(const Operand& dst, int8_t imm8) { EnsureSpace ensure_space(this); EMIT(0xC6); emit_operand(eax, dst); EMIT(imm8); } void Assembler::mov_b(const Operand& dst, Register src) { CHECK(src.is_byte_register()); EnsureSpace ensure_space(this); EMIT(0x88); emit_operand(src, dst); } void Assembler::mov_w(Register dst, const Operand& src) { EnsureSpace ensure_space(this); EMIT(0x66); EMIT(0x8B); emit_operand(dst, src); } void Assembler::mov_w(const Operand& dst, Register src) { EnsureSpace ensure_space(this); EMIT(0x66); EMIT(0x89); emit_operand(src, dst); } void Assembler::mov_w(const Operand& dst, int16_t imm16) { EnsureSpace ensure_space(this); EMIT(0x66); EMIT(0xC7); emit_operand(eax, dst); EMIT(static_cast(imm16 & 0xff)); EMIT(static_cast(imm16 >> 8)); } void Assembler::mov_w(const Operand& dst, const Immediate& src) { EnsureSpace ensure_space(this); EMIT(0x66); EMIT(0xC7); emit_operand(eax, dst); EMIT(static_cast(src.x_ & 0xff)); EMIT(static_cast(src.x_ >> 8)); } void Assembler::mov(Register dst, int32_t imm32) { EnsureSpace ensure_space(this); EMIT(0xB8 | dst.code()); emit(imm32); } void Assembler::mov(Register dst, const Immediate& x) { EnsureSpace ensure_space(this); EMIT(0xB8 | dst.code()); emit(x); } void Assembler::mov(Register dst, Handle handle) { EnsureSpace ensure_space(this); EMIT(0xB8 | dst.code()); emit(handle); } void Assembler::mov(Register dst, const Operand& src) { EnsureSpace ensure_space(this); EMIT(0x8B); emit_operand(dst, src); } void Assembler::mov(Register dst, Register src) { EnsureSpace ensure_space(this); EMIT(0x89); EMIT(0xC0 | src.code() << 3 | dst.code()); } void Assembler::mov(const Operand& dst, const Immediate& x) { EnsureSpace ensure_space(this); EMIT(0xC7); emit_operand(eax, dst); emit(x); } void Assembler::mov(const Operand& dst, Handle handle) { EnsureSpace ensure_space(this); EMIT(0xC7); emit_operand(eax, dst); emit(handle); } void Assembler::mov(const Operand& dst, Register src) { EnsureSpace ensure_space(this); EMIT(0x89); emit_operand(src, dst); } void Assembler::movsx_b(Register dst, const Operand& src) { EnsureSpace ensure_space(this); EMIT(0x0F); EMIT(0xBE); emit_operand(dst, src); } void Assembler::movsx_w(Register dst, const Operand& src) { EnsureSpace ensure_space(this); EMIT(0x0F); EMIT(0xBF); emit_operand(dst, src); } void Assembler::movzx_b(Register dst, const Operand& src) { EnsureSpace ensure_space(this); EMIT(0x0F); EMIT(0xB6); emit_operand(dst, src); } void Assembler::movzx_w(Register dst, const Operand& src) { EnsureSpace ensure_space(this); EMIT(0x0F); EMIT(0xB7); emit_operand(dst, src); } void Assembler::cld() { EnsureSpace ensure_space(this); EMIT(0xFC); } void Assembler::rep_movs() { EnsureSpace ensure_space(this); EMIT(0xF3); EMIT(0xA5); } void Assembler::rep_stos() { EnsureSpace ensure_space(this); EMIT(0xF3); EMIT(0xAB); } void Assembler::stos() { EnsureSpace ensure_space(this); EMIT(0xAB); } void Assembler::xchg(Register dst, Register src) { EnsureSpace ensure_space(this); if (src.is(eax) || dst.is(eax)) { // Single-byte encoding. EMIT(0x90 | (src.is(eax) ? dst.code() : src.code())); } else { EMIT(0x87); EMIT(0xC0 | src.code() << 3 | dst.code()); } } void Assembler::xchg(Register dst, const Operand& src) { EnsureSpace ensure_space(this); EMIT(0x87); emit_operand(dst, src); } void Assembler::xchg_b(Register reg, const Operand& op) { EnsureSpace ensure_space(this); EMIT(0x86); emit_operand(reg, op); } void Assembler::xchg_w(Register reg, const Operand& op) { EnsureSpace ensure_space(this); EMIT(0x66); EMIT(0x87); emit_operand(reg, op); } void Assembler::lock() { EnsureSpace ensure_space(this); EMIT(0xF0); } void Assembler::cmpxchg(const Operand& dst, Register src) { EnsureSpace ensure_space(this); EMIT(0x0F); EMIT(0xB1); emit_operand(src, dst); } void Assembler::cmpxchg_b(const Operand& dst, Register src) { EnsureSpace ensure_space(this); EMIT(0x0F); EMIT(0xB0); emit_operand(src, dst); } void Assembler::cmpxchg_w(const Operand& dst, Register src) { EnsureSpace ensure_space(this); EMIT(0x66); EMIT(0x0F); EMIT(0xB1); emit_operand(src, dst); } void Assembler::adc(Register dst, int32_t imm32) { EnsureSpace ensure_space(this); emit_arith(2, Operand(dst), Immediate(imm32)); } void Assembler::adc(Register dst, const Operand& src) { EnsureSpace ensure_space(this); EMIT(0x13); emit_operand(dst, src); } void Assembler::add(Register dst, const Operand& src) { EnsureSpace ensure_space(this); EMIT(0x03); emit_operand(dst, src); } void Assembler::add(const Operand& dst, Register src) { EnsureSpace ensure_space(this); EMIT(0x01); emit_operand(src, dst); } void Assembler::add(const Operand& dst, const Immediate& x) { DCHECK(reloc_info_writer.last_pc() != NULL); EnsureSpace ensure_space(this); emit_arith(0, dst, x); } void Assembler::and_(Register dst, int32_t imm32) { and_(dst, Immediate(imm32)); } void Assembler::and_(Register dst, const Immediate& x) { EnsureSpace ensure_space(this); emit_arith(4, Operand(dst), x); } void Assembler::and_(Register dst, const Operand& src) { EnsureSpace ensure_space(this); EMIT(0x23); emit_operand(dst, src); } void Assembler::and_(const Operand& dst, const Immediate& x) { EnsureSpace ensure_space(this); emit_arith(4, dst, x); } void Assembler::and_(const Operand& dst, Register src) { EnsureSpace ensure_space(this); EMIT(0x21); emit_operand(src, dst); } void Assembler::cmpb(const Operand& op, Immediate imm8) { DCHECK(imm8.is_int8() || imm8.is_uint8()); EnsureSpace ensure_space(this); if (op.is_reg(eax)) { EMIT(0x3C); } else { EMIT(0x80); emit_operand(edi, op); // edi == 7 } emit_b(imm8); } void Assembler::cmpb(const Operand& op, Register reg) { CHECK(reg.is_byte_register()); EnsureSpace ensure_space(this); EMIT(0x38); emit_operand(reg, op); } void Assembler::cmpb(Register reg, const Operand& op) { CHECK(reg.is_byte_register()); EnsureSpace ensure_space(this); EMIT(0x3A); emit_operand(reg, op); } void Assembler::cmpw(const Operand& op, Immediate imm16) { DCHECK(imm16.is_int16()); EnsureSpace ensure_space(this); EMIT(0x66); EMIT(0x81); emit_operand(edi, op); emit_w(imm16); } void Assembler::cmpw(Register reg, const Operand& op) { EnsureSpace ensure_space(this); EMIT(0x66); EMIT(0x3B); emit_operand(reg, op); } void Assembler::cmpw(const Operand& op, Register reg) { EnsureSpace ensure_space(this); EMIT(0x66); EMIT(0x39); emit_operand(reg, op); } void Assembler::cmp(Register reg, int32_t imm32) { EnsureSpace ensure_space(this); emit_arith(7, Operand(reg), Immediate(imm32)); } void Assembler::cmp(Register reg, Handle handle) { EnsureSpace ensure_space(this); emit_arith(7, Operand(reg), Immediate(handle)); } void Assembler::cmp(Register reg, const Operand& op) { EnsureSpace ensure_space(this); EMIT(0x3B); emit_operand(reg, op); } void Assembler::cmp(const Operand& op, Register reg) { EnsureSpace ensure_space(this); EMIT(0x39); emit_operand(reg, op); } void Assembler::cmp(const Operand& op, const Immediate& imm) { EnsureSpace ensure_space(this); emit_arith(7, op, imm); } void Assembler::cmp(const Operand& op, Handle handle) { EnsureSpace ensure_space(this); emit_arith(7, op, Immediate(handle)); } void Assembler::cmpb_al(const Operand& op) { EnsureSpace ensure_space(this); EMIT(0x38); // CMP r/m8, r8 emit_operand(eax, op); // eax has same code as register al. } void Assembler::cmpw_ax(const Operand& op) { EnsureSpace ensure_space(this); EMIT(0x66); EMIT(0x39); // CMP r/m16, r16 emit_operand(eax, op); // eax has same code as register ax. } void Assembler::dec_b(Register dst) { CHECK(dst.is_byte_register()); EnsureSpace ensure_space(this); EMIT(0xFE); EMIT(0xC8 | dst.code()); } void Assembler::dec_b(const Operand& dst) { EnsureSpace ensure_space(this); EMIT(0xFE); emit_operand(ecx, dst); } void Assembler::dec(Register dst) { EnsureSpace ensure_space(this); EMIT(0x48 | dst.code()); } void Assembler::dec(const Operand& dst) { EnsureSpace ensure_space(this); EMIT(0xFF); emit_operand(ecx, dst); } void Assembler::cdq() { EnsureSpace ensure_space(this); EMIT(0x99); } void Assembler::idiv(const Operand& src) { EnsureSpace ensure_space(this); EMIT(0xF7); emit_operand(edi, src); } void Assembler::div(const Operand& src) { EnsureSpace ensure_space(this); EMIT(0xF7); emit_operand(esi, src); } void Assembler::imul(Register reg) { EnsureSpace ensure_space(this); EMIT(0xF7); EMIT(0xE8 | reg.code()); } void Assembler::imul(Register dst, const Operand& src) { EnsureSpace ensure_space(this); EMIT(0x0F); EMIT(0xAF); emit_operand(dst, src); } void Assembler::imul(Register dst, Register src, int32_t imm32) { imul(dst, Operand(src), imm32); } void Assembler::imul(Register dst, const Operand& src, int32_t imm32) { EnsureSpace ensure_space(this); if (is_int8(imm32)) { EMIT(0x6B); emit_operand(dst, src); EMIT(imm32); } else { EMIT(0x69); emit_operand(dst, src); emit(imm32); } } void Assembler::inc(Register dst) { EnsureSpace ensure_space(this); EMIT(0x40 | dst.code()); } void Assembler::inc(const Operand& dst) { EnsureSpace ensure_space(this); EMIT(0xFF); emit_operand(eax, dst); } void Assembler::lea(Register dst, const Operand& src) { EnsureSpace ensure_space(this); EMIT(0x8D); emit_operand(dst, src); } void Assembler::mul(Register src) { EnsureSpace ensure_space(this); EMIT(0xF7); EMIT(0xE0 | src.code()); } void Assembler::neg(Register dst) { EnsureSpace ensure_space(this); EMIT(0xF7); EMIT(0xD8 | dst.code()); } void Assembler::neg(const Operand& dst) { EnsureSpace ensure_space(this); EMIT(0xF7); emit_operand(ebx, dst); } void Assembler::not_(Register dst) { EnsureSpace ensure_space(this); EMIT(0xF7); EMIT(0xD0 | dst.code()); } void Assembler::not_(const Operand& dst) { EnsureSpace ensure_space(this); EMIT(0xF7); emit_operand(edx, dst); } void Assembler::or_(Register dst, int32_t imm32) { EnsureSpace ensure_space(this); emit_arith(1, Operand(dst), Immediate(imm32)); } void Assembler::or_(Register dst, const Operand& src) { EnsureSpace ensure_space(this); EMIT(0x0B); emit_operand(dst, src); } void Assembler::or_(const Operand& dst, const Immediate& x) { EnsureSpace ensure_space(this); emit_arith(1, dst, x); } void Assembler::or_(const Operand& dst, Register src) { EnsureSpace ensure_space(this); EMIT(0x09); emit_operand(src, dst); } void Assembler::rcl(Register dst, uint8_t imm8) { EnsureSpace ensure_space(this); DCHECK(is_uint5(imm8)); // illegal shift count if (imm8 == 1) { EMIT(0xD1); EMIT(0xD0 | dst.code()); } else { EMIT(0xC1); EMIT(0xD0 | dst.code()); EMIT(imm8); } } void Assembler::rcr(Register dst, uint8_t imm8) { EnsureSpace ensure_space(this); DCHECK(is_uint5(imm8)); // illegal shift count if (imm8 == 1) { EMIT(0xD1); EMIT(0xD8 | dst.code()); } else { EMIT(0xC1); EMIT(0xD8 | dst.code()); EMIT(imm8); } } void Assembler::ror(const Operand& dst, uint8_t imm8) { EnsureSpace ensure_space(this); DCHECK(is_uint5(imm8)); // illegal shift count if (imm8 == 1) { EMIT(0xD1); emit_operand(ecx, dst); } else { EMIT(0xC1); emit_operand(ecx, dst); EMIT(imm8); } } void Assembler::ror_cl(const Operand& dst) { EnsureSpace ensure_space(this); EMIT(0xD3); emit_operand(ecx, dst); } void Assembler::sar(const Operand& dst, uint8_t imm8) { EnsureSpace ensure_space(this); DCHECK(is_uint5(imm8)); // illegal shift count if (imm8 == 1) { EMIT(0xD1); emit_operand(edi, dst); } else { EMIT(0xC1); emit_operand(edi, dst); EMIT(imm8); } } void Assembler::sar_cl(const Operand& dst) { EnsureSpace ensure_space(this); EMIT(0xD3); emit_operand(edi, dst); } void Assembler::sbb(Register dst, const Operand& src) { EnsureSpace ensure_space(this); EMIT(0x1B); emit_operand(dst, src); } void Assembler::shld(Register dst, Register src, uint8_t shift) { DCHECK(is_uint5(shift)); EnsureSpace ensure_space(this); EMIT(0x0F); EMIT(0xA4); emit_operand(src, Operand(dst)); EMIT(shift); } void Assembler::shld_cl(Register dst, Register src) { EnsureSpace ensure_space(this); EMIT(0x0F); EMIT(0xA5); emit_operand(src, Operand(dst)); } void Assembler::shl(const Operand& dst, uint8_t imm8) { EnsureSpace ensure_space(this); DCHECK(is_uint5(imm8)); // illegal shift count if (imm8 == 1) { EMIT(0xD1); emit_operand(esp, dst); } else { EMIT(0xC1); emit_operand(esp, dst); EMIT(imm8); } } void Assembler::shl_cl(const Operand& dst) { EnsureSpace ensure_space(this); EMIT(0xD3); emit_operand(esp, dst); } void Assembler::shr(const Operand& dst, uint8_t imm8) { EnsureSpace ensure_space(this); DCHECK(is_uint5(imm8)); // illegal shift count if (imm8 == 1) { EMIT(0xD1); emit_operand(ebp, dst); } else { EMIT(0xC1); emit_operand(ebp, dst); EMIT(imm8); } } void Assembler::shr_cl(const Operand& dst) { EnsureSpace ensure_space(this); EMIT(0xD3); emit_operand(ebp, dst); } void Assembler::shrd(Register dst, Register src, uint8_t shift) { DCHECK(is_uint5(shift)); EnsureSpace ensure_space(this); EMIT(0x0F); EMIT(0xAC); emit_operand(dst, Operand(src)); EMIT(shift); } void Assembler::shrd_cl(const Operand& dst, Register src) { EnsureSpace ensure_space(this); EMIT(0x0F); EMIT(0xAD); emit_operand(src, dst); } void Assembler::sub(const Operand& dst, const Immediate& x) { EnsureSpace ensure_space(this); emit_arith(5, dst, x); } void Assembler::sub(Register dst, const Operand& src) { EnsureSpace ensure_space(this); EMIT(0x2B); emit_operand(dst, src); } void Assembler::sub(const Operand& dst, Register src) { EnsureSpace ensure_space(this); EMIT(0x29); emit_operand(src, dst); } void Assembler::test(Register reg, const Immediate& imm) { if (imm.is_uint8()) { test_b(reg, imm); return; } EnsureSpace ensure_space(this); // This is not using emit_arith because test doesn't support // sign-extension of 8-bit operands. if (reg.is(eax)) { EMIT(0xA9); } else { EMIT(0xF7); EMIT(0xC0 | reg.code()); } emit(imm); } void Assembler::test(Register reg, const Operand& op) { EnsureSpace ensure_space(this); EMIT(0x85); emit_operand(reg, op); } void Assembler::test_b(Register reg, const Operand& op) { CHECK(reg.is_byte_register()); EnsureSpace ensure_space(this); EMIT(0x84); emit_operand(reg, op); } void Assembler::test(const Operand& op, const Immediate& imm) { if (op.is_reg_only()) { test(op.reg(), imm); return; } if (imm.is_uint8()) { return test_b(op, imm); } EnsureSpace ensure_space(this); EMIT(0xF7); emit_operand(eax, op); emit(imm); } void Assembler::test_b(Register reg, Immediate imm8) { DCHECK(imm8.is_uint8()); EnsureSpace ensure_space(this); // Only use test against byte for registers that have a byte // variant: eax, ebx, ecx, and edx. if (reg.is(eax)) { EMIT(0xA8); emit_b(imm8); } else if (reg.is_byte_register()) { emit_arith_b(0xF6, 0xC0, reg, static_cast(imm8.x_)); } else { EMIT(0x66); EMIT(0xF7); EMIT(0xC0 | reg.code()); emit_w(imm8); } } void Assembler::test_b(const Operand& op, Immediate imm8) { if (op.is_reg_only()) { test_b(op.reg(), imm8); return; } EnsureSpace ensure_space(this); EMIT(0xF6); emit_operand(eax, op); emit_b(imm8); } void Assembler::test_w(Register reg, Immediate imm16) { DCHECK(imm16.is_int16() || imm16.is_uint16()); EnsureSpace ensure_space(this); if (reg.is(eax)) { EMIT(0xA9); emit_w(imm16); } else { EMIT(0x66); EMIT(0xF7); EMIT(0xc0 | reg.code()); emit_w(imm16); } } void Assembler::test_w(Register reg, const Operand& op) { EnsureSpace ensure_space(this); EMIT(0x66); EMIT(0x85); emit_operand(reg, op); } void Assembler::test_w(const Operand& op, Immediate imm16) { DCHECK(imm16.is_int16() || imm16.is_uint16()); if (op.is_reg_only()) { test_w(op.reg(), imm16); return; } EnsureSpace ensure_space(this); EMIT(0x66); EMIT(0xF7); emit_operand(eax, op); emit_w(imm16); } void Assembler::xor_(Register dst, int32_t imm32) { EnsureSpace ensure_space(this); emit_arith(6, Operand(dst), Immediate(imm32)); } void Assembler::xor_(Register dst, const Operand& src) { EnsureSpace ensure_space(this); EMIT(0x33); emit_operand(dst, src); } void Assembler::xor_(const Operand& dst, Register src) { EnsureSpace ensure_space(this); EMIT(0x31); emit_operand(src, dst); } void Assembler::xor_(const Operand& dst, const Immediate& x) { EnsureSpace ensure_space(this); emit_arith(6, dst, x); } void Assembler::bt(const Operand& dst, Register src) { EnsureSpace ensure_space(this); EMIT(0x0F); EMIT(0xA3); emit_operand(src, dst); } void Assembler::bts(const Operand& dst, Register src) { EnsureSpace ensure_space(this); EMIT(0x0F); EMIT(0xAB); emit_operand(src, dst); } void Assembler::bsr(Register dst, const Operand& src) { EnsureSpace ensure_space(this); EMIT(0x0F); EMIT(0xBD); emit_operand(dst, src); } void Assembler::bsf(Register dst, const Operand& src) { EnsureSpace ensure_space(this); EMIT(0x0F); EMIT(0xBC); emit_operand(dst, src); } void Assembler::hlt() { EnsureSpace ensure_space(this); EMIT(0xF4); } void Assembler::int3() { EnsureSpace ensure_space(this); EMIT(0xCC); } void Assembler::nop() { EnsureSpace ensure_space(this); EMIT(0x90); } void Assembler::ret(int imm16) { EnsureSpace ensure_space(this); DCHECK(is_uint16(imm16)); if (imm16 == 0) { EMIT(0xC3); } else { EMIT(0xC2); EMIT(imm16 & 0xFF); EMIT((imm16 >> 8) & 0xFF); } } void Assembler::ud2() { EnsureSpace ensure_space(this); EMIT(0x0F); EMIT(0x0B); } // Labels refer to positions in the (to be) generated code. // There are bound, linked, and unused labels. // // Bound labels refer to known positions in the already // generated code. pos() is the position the label refers to. // // Linked labels refer to unknown positions in the code // to be generated; pos() is the position of the 32bit // Displacement of the last instruction using the label. void Assembler::print(Label* L) { if (L->is_unused()) { PrintF("unused label\n"); } else if (L->is_bound()) { PrintF("bound label to %d\n", L->pos()); } else if (L->is_linked()) { Label l = *L; PrintF("unbound label"); while (l.is_linked()) { Displacement disp = disp_at(&l); PrintF("@ %d ", l.pos()); disp.print(); PrintF("\n"); disp.next(&l); } } else { PrintF("label in inconsistent state (pos = %d)\n", L->pos_); } } void Assembler::bind_to(Label* L, int pos) { EnsureSpace ensure_space(this); DCHECK(0 <= pos && pos <= pc_offset()); // must have a valid binding position while (L->is_linked()) { Displacement disp = disp_at(L); int fixup_pos = L->pos(); if (disp.type() == Displacement::CODE_ABSOLUTE) { long_at_put(fixup_pos, reinterpret_cast(buffer_ + pos)); internal_reference_positions_.push_back(fixup_pos); } else if (disp.type() == Displacement::CODE_RELATIVE) { // Relative to Code* heap object pointer. long_at_put(fixup_pos, pos + Code::kHeaderSize - kHeapObjectTag); } else { if (disp.type() == Displacement::UNCONDITIONAL_JUMP) { DCHECK(byte_at(fixup_pos - 1) == 0xE9); // jmp expected } // Relative address, relative to point after address. int imm32 = pos - (fixup_pos + sizeof(int32_t)); long_at_put(fixup_pos, imm32); } disp.next(L); } while (L->is_near_linked()) { int fixup_pos = L->near_link_pos(); int offset_to_next = static_cast(*reinterpret_cast(addr_at(fixup_pos))); DCHECK(offset_to_next <= 0); // Relative address, relative to point after address. int disp = pos - fixup_pos - sizeof(int8_t); CHECK(0 <= disp && disp <= 127); set_byte_at(fixup_pos, disp); if (offset_to_next < 0) { L->link_to(fixup_pos + offset_to_next, Label::kNear); } else { L->UnuseNear(); } } L->bind_to(pos); } void Assembler::bind(Label* L) { EnsureSpace ensure_space(this); DCHECK(!L->is_bound()); // label can only be bound once bind_to(L, pc_offset()); } void Assembler::call(Label* L) { EnsureSpace ensure_space(this); if (L->is_bound()) { const int long_size = 5; int offs = L->pos() - pc_offset(); DCHECK(offs <= 0); // 1110 1000 #32-bit disp. EMIT(0xE8); emit(offs - long_size); } else { // 1110 1000 #32-bit disp. EMIT(0xE8); emit_disp(L, Displacement::OTHER); } } void Assembler::call(byte* entry, RelocInfo::Mode rmode) { EnsureSpace ensure_space(this); DCHECK(!RelocInfo::IsCodeTarget(rmode)); EMIT(0xE8); if (RelocInfo::IsRuntimeEntry(rmode)) { emit(reinterpret_cast(entry), rmode); } else { emit(entry - (pc_ + sizeof(int32_t)), rmode); } } int Assembler::CallSize(const Operand& adr) { // Call size is 1 (opcode) + adr.len_ (operand). return 1 + adr.len_; } void Assembler::call(const Operand& adr) { EnsureSpace ensure_space(this); EMIT(0xFF); emit_operand(edx, adr); } int Assembler::CallSize(Handle code, RelocInfo::Mode rmode) { return 1 /* EMIT */ + sizeof(uint32_t) /* emit */; } void Assembler::call(Handle code, RelocInfo::Mode rmode, TypeFeedbackId ast_id) { EnsureSpace ensure_space(this); DCHECK(RelocInfo::IsCodeTarget(rmode) || rmode == RelocInfo::CODE_AGE_SEQUENCE); EMIT(0xE8); emit(code, rmode, ast_id); } void Assembler::jmp(Label* L, Label::Distance distance) { EnsureSpace ensure_space(this); if (L->is_bound()) { const int short_size = 2; const int long_size = 5; int offs = L->pos() - pc_offset(); DCHECK(offs <= 0); if (is_int8(offs - short_size)) { // 1110 1011 #8-bit disp. EMIT(0xEB); EMIT((offs - short_size) & 0xFF); } else { // 1110 1001 #32-bit disp. EMIT(0xE9); emit(offs - long_size); } } else if (distance == Label::kNear) { EMIT(0xEB); emit_near_disp(L); } else { // 1110 1001 #32-bit disp. EMIT(0xE9); emit_disp(L, Displacement::UNCONDITIONAL_JUMP); } } void Assembler::jmp(byte* entry, RelocInfo::Mode rmode) { EnsureSpace ensure_space(this); DCHECK(!RelocInfo::IsCodeTarget(rmode)); EMIT(0xE9); if (RelocInfo::IsRuntimeEntry(rmode)) { emit(reinterpret_cast(entry), rmode); } else { emit(entry - (pc_ + sizeof(int32_t)), rmode); } } void Assembler::jmp(const Operand& adr) { EnsureSpace ensure_space(this); EMIT(0xFF); emit_operand(esp, adr); } void Assembler::jmp(Handle code, RelocInfo::Mode rmode) { EnsureSpace ensure_space(this); DCHECK(RelocInfo::IsCodeTarget(rmode)); EMIT(0xE9); emit(code, rmode); } void Assembler::j(Condition cc, Label* L, Label::Distance distance) { EnsureSpace ensure_space(this); DCHECK(0 <= cc && static_cast(cc) < 16); if (L->is_bound()) { const int short_size = 2; const int long_size = 6; int offs = L->pos() - pc_offset(); DCHECK(offs <= 0); if (is_int8(offs - short_size)) { // 0111 tttn #8-bit disp EMIT(0x70 | cc); EMIT((offs - short_size) & 0xFF); } else { // 0000 1111 1000 tttn #32-bit disp EMIT(0x0F); EMIT(0x80 | cc); emit(offs - long_size); } } else if (distance == Label::kNear) { EMIT(0x70 | cc); emit_near_disp(L); } else { // 0000 1111 1000 tttn #32-bit disp // Note: could eliminate cond. jumps to this jump if condition // is the same however, seems to be rather unlikely case. EMIT(0x0F); EMIT(0x80 | cc); emit_disp(L, Displacement::OTHER); } } void Assembler::j(Condition cc, byte* entry, RelocInfo::Mode rmode) { EnsureSpace ensure_space(this); DCHECK((0 <= cc) && (static_cast(cc) < 16)); // 0000 1111 1000 tttn #32-bit disp. EMIT(0x0F); EMIT(0x80 | cc); if (RelocInfo::IsRuntimeEntry(rmode)) { emit(reinterpret_cast(entry), rmode); } else { emit(entry - (pc_ + sizeof(int32_t)), rmode); } } void Assembler::j(Condition cc, Handle code, RelocInfo::Mode rmode) { EnsureSpace ensure_space(this); // 0000 1111 1000 tttn #32-bit disp EMIT(0x0F); EMIT(0x80 | cc); emit(code, rmode); } // FPU instructions. void Assembler::fld(int i) { EnsureSpace ensure_space(this); emit_farith(0xD9, 0xC0, i); } void Assembler::fstp(int i) { EnsureSpace ensure_space(this); emit_farith(0xDD, 0xD8, i); } void Assembler::fld1() { EnsureSpace ensure_space(this); EMIT(0xD9); EMIT(0xE8); } void Assembler::fldpi() { EnsureSpace ensure_space(this); EMIT(0xD9); EMIT(0xEB); } void Assembler::fldz() { EnsureSpace ensure_space(this); EMIT(0xD9); EMIT(0xEE); } void Assembler::fldln2() { EnsureSpace ensure_space(this); EMIT(0xD9); EMIT(0xED); } void Assembler::fld_s(const Operand& adr) { EnsureSpace ensure_space(this); EMIT(0xD9); emit_operand(eax, adr); } void Assembler::fld_d(const Operand& adr) { EnsureSpace ensure_space(this); EMIT(0xDD); emit_operand(eax, adr); } void Assembler::fstp_s(const Operand& adr) { EnsureSpace ensure_space(this); EMIT(0xD9); emit_operand(ebx, adr); } void Assembler::fst_s(const Operand& adr) { EnsureSpace ensure_space(this); EMIT(0xD9); emit_operand(edx, adr); } void Assembler::fldcw(const Operand& adr) { EnsureSpace ensure_space(this); EMIT(0xD9); emit_operand(ebp, adr); } void Assembler::fnstcw(const Operand& adr) { EnsureSpace ensure_space(this); EMIT(0xD9); emit_operand(edi, adr); } void Assembler::fstp_d(const Operand& adr) { EnsureSpace ensure_space(this); EMIT(0xDD); emit_operand(ebx, adr); } void Assembler::fst_d(const Operand& adr) { EnsureSpace ensure_space(this); EMIT(0xDD); emit_operand(edx, adr); } void Assembler::fild_s(const Operand& adr) { EnsureSpace ensure_space(this); EMIT(0xDB); emit_operand(eax, adr); } void Assembler::fild_d(const Operand& adr) { EnsureSpace ensure_space(this); EMIT(0xDF); emit_operand(ebp, adr); } void Assembler::fistp_s(const Operand& adr) { EnsureSpace ensure_space(this); EMIT(0xDB); emit_operand(ebx, adr); } void Assembler::fisttp_s(const Operand& adr) { DCHECK(IsEnabled(SSE3)); EnsureSpace ensure_space(this); EMIT(0xDB); emit_operand(ecx, adr); } void Assembler::fisttp_d(const Operand& adr) { DCHECK(IsEnabled(SSE3)); EnsureSpace ensure_space(this); EMIT(0xDD); emit_operand(ecx, adr); } void Assembler::fist_s(const Operand& adr) { EnsureSpace ensure_space(this); EMIT(0xDB); emit_operand(edx, adr); } void Assembler::fistp_d(const Operand& adr) { EnsureSpace ensure_space(this); EMIT(0xDF); emit_operand(edi, adr); } void Assembler::fabs() { EnsureSpace ensure_space(this); EMIT(0xD9); EMIT(0xE1); } void Assembler::fchs() { EnsureSpace ensure_space(this); EMIT(0xD9); EMIT(0xE0); } void Assembler::fsqrt() { EnsureSpace ensure_space(this); EMIT(0xD9); EMIT(0xFA); } void Assembler::fcos() { EnsureSpace ensure_space(this); EMIT(0xD9); EMIT(0xFF); } void Assembler::fsin() { EnsureSpace ensure_space(this); EMIT(0xD9); EMIT(0xFE); } void Assembler::fptan() { EnsureSpace ensure_space(this); EMIT(0xD9); EMIT(0xF2); } void Assembler::fyl2x() { EnsureSpace ensure_space(this); EMIT(0xD9); EMIT(0xF1); } void Assembler::f2xm1() { EnsureSpace ensure_space(this); EMIT(0xD9); EMIT(0xF0); } void Assembler::fscale() { EnsureSpace ensure_space(this); EMIT(0xD9); EMIT(0xFD); } void Assembler::fninit() { EnsureSpace ensure_space(this); EMIT(0xDB); EMIT(0xE3); } void Assembler::fadd(int i) { EnsureSpace ensure_space(this); emit_farith(0xDC, 0xC0, i); } void Assembler::fadd_i(int i) { EnsureSpace ensure_space(this); emit_farith(0xD8, 0xC0, i); } void Assembler::fadd_d(const Operand& adr) { EnsureSpace ensure_space(this); EMIT(0xDC); emit_operand(eax, adr); } void Assembler::fsub(int i) { EnsureSpace ensure_space(this); emit_farith(0xDC, 0xE8, i); } void Assembler::fsub_i(int i) { EnsureSpace ensure_space(this); emit_farith(0xD8, 0xE0, i); } void Assembler::fsubr_d(const Operand& adr) { EnsureSpace ensure_space(this); EMIT(0xDC); emit_operand(ebp, adr); } void Assembler::fsub_d(const Operand& adr) { EnsureSpace ensure_space(this); EMIT(0xDC); emit_operand(esp, adr); } void Assembler::fisub_s(const Operand& adr) { EnsureSpace ensure_space(this); EMIT(0xDA); emit_operand(esp, adr); } void Assembler::fmul_i(int i) { EnsureSpace ensure_space(this); emit_farith(0xD8, 0xC8, i); } void Assembler::fmul(int i) { EnsureSpace ensure_space(this); emit_farith(0xDC, 0xC8, i); } void Assembler::fmul_d(const Operand& adr) { EnsureSpace ensure_space(this); EMIT(0xDC); emit_operand(ecx, adr); } void Assembler::fdiv(int i) { EnsureSpace ensure_space(this); emit_farith(0xDC, 0xF8, i); } void Assembler::fdiv_d(const Operand& adr) { EnsureSpace ensure_space(this); EMIT(0xDC); emit_operand(esi, adr); } void Assembler::fdivr_d(const Operand& adr) { EnsureSpace ensure_space(this); EMIT(0xDC); emit_operand(edi, adr); } void Assembler::fdiv_i(int i) { EnsureSpace ensure_space(this); emit_farith(0xD8, 0xF0, i); } void Assembler::faddp(int i) { EnsureSpace ensure_space(this); emit_farith(0xDE, 0xC0, i); } void Assembler::fsubp(int i) { EnsureSpace ensure_space(this); emit_farith(0xDE, 0xE8, i); } void Assembler::fsubrp(int i) { EnsureSpace ensure_space(this); emit_farith(0xDE, 0xE0, i); } void Assembler::fmulp(int i) { EnsureSpace ensure_space(this); emit_farith(0xDE, 0xC8, i); } void Assembler::fdivp(int i) { EnsureSpace ensure_space(this); emit_farith(0xDE, 0xF8, i); } void Assembler::fprem() { EnsureSpace ensure_space(this); EMIT(0xD9); EMIT(0xF8); } void Assembler::fprem1() { EnsureSpace ensure_space(this); EMIT(0xD9); EMIT(0xF5); } void Assembler::fxch(int i) { EnsureSpace ensure_space(this); emit_farith(0xD9, 0xC8, i); } void Assembler::fincstp() { EnsureSpace ensure_space(this); EMIT(0xD9); EMIT(0xF7); } void Assembler::ffree(int i) { EnsureSpace ensure_space(this); emit_farith(0xDD, 0xC0, i); } void Assembler::ftst() { EnsureSpace ensure_space(this); EMIT(0xD9); EMIT(0xE4); } void Assembler::fxam() { EnsureSpace ensure_space(this); EMIT(0xD9); EMIT(0xE5); } void Assembler::fucomp(int i) { EnsureSpace ensure_space(this); emit_farith(0xDD, 0xE8, i); } void Assembler::fucompp() { EnsureSpace ensure_space(this); EMIT(0xDA); EMIT(0xE9); } void Assembler::fucomi(int i) { EnsureSpace ensure_space(this); EMIT(0xDB); EMIT(0xE8 + i); } void Assembler::fucomip() { EnsureSpace ensure_space(this); EMIT(0xDF); EMIT(0xE9); } void Assembler::fcompp() { EnsureSpace ensure_space(this); EMIT(0xDE); EMIT(0xD9); } void Assembler::fnstsw_ax() { EnsureSpace ensure_space(this); EMIT(0xDF); EMIT(0xE0); } void Assembler::fwait() { EnsureSpace ensure_space(this); EMIT(0x9B); } void Assembler::frndint() { EnsureSpace ensure_space(this); EMIT(0xD9); EMIT(0xFC); } void Assembler::fnclex() { EnsureSpace ensure_space(this); EMIT(0xDB); EMIT(0xE2); } void Assembler::fnsave(const Operand& adr) { EnsureSpace ensure_space(this); EMIT(0xDD); emit_operand(esi, adr); } void Assembler::frstor(const Operand& adr) { EnsureSpace ensure_space(this); EMIT(0xDD); emit_operand(esp, adr); } void Assembler::sahf() { EnsureSpace ensure_space(this); EMIT(0x9E); } void Assembler::setcc(Condition cc, Register reg) { DCHECK(reg.is_byte_register()); EnsureSpace ensure_space(this); EMIT(0x0F); EMIT(0x90 | cc); EMIT(0xC0 | reg.code()); } void Assembler::GrowBuffer() { DCHECK(buffer_overflow()); if (!own_buffer_) FATAL("external code buffer is too small"); // Compute new buffer size. CodeDesc desc; // the new buffer desc.buffer_size = 2 * buffer_size_; // Some internal data structures overflow for very large buffers, // they must ensure that kMaximalBufferSize is not too large. if (desc.buffer_size > kMaximalBufferSize || static_cast(desc.buffer_size) > isolate()->heap()->MaxOldGenerationSize()) { V8::FatalProcessOutOfMemory("Assembler::GrowBuffer"); } // Set up new buffer. desc.buffer = NewArray(desc.buffer_size); desc.origin = this; desc.instr_size = pc_offset(); desc.reloc_size = (buffer_ + buffer_size_) - (reloc_info_writer.pos()); // Clear the buffer in debug mode. Use 'int3' instructions to make // sure to get into problems if we ever run uninitialized code. #ifdef DEBUG memset(desc.buffer, 0xCC, desc.buffer_size); #endif // Copy the data. int pc_delta = desc.buffer - buffer_; int rc_delta = (desc.buffer + desc.buffer_size) - (buffer_ + buffer_size_); MemMove(desc.buffer, buffer_, desc.instr_size); MemMove(rc_delta + reloc_info_writer.pos(), reloc_info_writer.pos(), desc.reloc_size); DeleteArray(buffer_); buffer_ = desc.buffer; buffer_size_ = desc.buffer_size; pc_ += pc_delta; reloc_info_writer.Reposition(reloc_info_writer.pos() + rc_delta, reloc_info_writer.last_pc() + pc_delta); // Relocate internal references. for (auto pos : internal_reference_positions_) { int32_t* p = reinterpret_cast(buffer_ + pos); *p += pc_delta; } DCHECK(!buffer_overflow()); } void Assembler::emit_arith_b(int op1, int op2, Register dst, int imm8) { DCHECK(is_uint8(op1) && is_uint8(op2)); // wrong opcode DCHECK(is_uint8(imm8)); DCHECK((op1 & 0x01) == 0); // should be 8bit operation EMIT(op1); EMIT(op2 | dst.code()); EMIT(imm8); } void Assembler::emit_arith(int sel, Operand dst, const Immediate& x) { DCHECK((0 <= sel) && (sel <= 7)); Register ireg = { sel }; if (x.is_int8()) { EMIT(0x83); // using a sign-extended 8-bit immediate. emit_operand(ireg, dst); EMIT(x.x_ & 0xFF); } else if (dst.is_reg(eax)) { EMIT((sel << 3) | 0x05); // short form if the destination is eax. emit(x); } else { EMIT(0x81); // using a literal 32-bit immediate. emit_operand(ireg, dst); emit(x); } } void Assembler::emit_operand(Register reg, const Operand& adr) { const unsigned length = adr.len_; DCHECK(length > 0); // Emit updated ModRM byte containing the given register. pc_[0] = (adr.buf_[0] & ~0x38) | (reg.code() << 3); // Emit the rest of the encoded operand. for (unsigned i = 1; i < length; i++) pc_[i] = adr.buf_[i]; pc_ += length; // Emit relocation information if necessary. if (length >= sizeof(int32_t) && !RelocInfo::IsNone(adr.rmode_)) { pc_ -= sizeof(int32_t); // pc_ must be *at* disp32 RecordRelocInfo(adr.rmode_); if (adr.rmode_ == RelocInfo::INTERNAL_REFERENCE) { // Fixup for labels emit_label(*reinterpret_cast(pc_)); } else { pc_ += sizeof(int32_t); } } } void Assembler::emit_label(Label* label) { if (label->is_bound()) { internal_reference_positions_.push_back(pc_offset()); emit(reinterpret_cast(buffer_ + label->pos())); } else { emit_disp(label, Displacement::CODE_ABSOLUTE); } } void Assembler::emit_farith(int b1, int b2, int i) { DCHECK(is_uint8(b1) && is_uint8(b2)); // wrong opcode DCHECK(0 <= i && i < 8); // illegal stack offset EMIT(b1); EMIT(b2 + i); } void Assembler::db(uint8_t data) { EnsureSpace ensure_space(this); EMIT(data); } void Assembler::dd(uint32_t data) { EnsureSpace ensure_space(this); emit(data); } void Assembler::dq(uint64_t data) { EnsureSpace ensure_space(this); emit_q(data); } void Assembler::dd(Label* label) { EnsureSpace ensure_space(this); RecordRelocInfo(RelocInfo::INTERNAL_REFERENCE); emit_label(label); } void Assembler::RecordRelocInfo(RelocInfo::Mode rmode, intptr_t data) { DCHECK(!RelocInfo::IsNone(rmode)); // Don't record external references unless the heap will be serialized. if (rmode == RelocInfo::EXTERNAL_REFERENCE && !serializer_enabled() && !emit_debug_code()) { return; } RelocInfo rinfo(isolate(), pc_, rmode, data, NULL); reloc_info_writer.Write(&rinfo); } } // namespace internal } // namespace v8 #endif // V8_TARGET_ARCH_X87