src/mips/disasm-mips.cc - fp2-dev/platform/external/chromium_org/v8 - Gitiles

 // Copyright 2010 the V8 project authors. 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.
 //     * 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.
 //     * Neither the name of Google Inc. nor the names of its
 //       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.

 // A Disassembler object is used to disassemble a block of code instruction by
 // instruction. The default implementation of the NameConverter object can be
 // overriden to modify register names or to do symbol lookup on addresses.
 //
 // The example below will disassemble a block of code and print it to stdout.
 //
 //   NameConverter converter;
 //   Disassembler d(converter);
 //   for (byte_* pc = begin; pc < end;) {
 //     char buffer[128];
 //     buffer[0] = '\0';
 //     byte_* prev_pc = pc;
 //     pc += d.InstructionDecode(buffer, sizeof buffer, pc);
 //     printf("%p    %08x      %s\n",
 //            prev_pc, *reinterpret_cast<int32_t*>(prev_pc), buffer);
 //   }
 //
 // The Disassembler class also has a convenience method to disassemble a block
 // of code into a FILE*, meaning that the above functionality could also be
 // achieved by just calling Disassembler::Disassemble(stdout, begin, end);


 #include <assert.h>
 #include <stdio.h>
 #include <stdarg.h>
 #include <string.h>
 #ifndef WIN32
 #include <stdint.h>
 #endif

 #include "v8.h"

 #if defined(V8_TARGET_ARCH_MIPS)

 #include "constants-mips.h"
 #include "disasm.h"
 #include "macro-assembler.h"
 #include "platform.h"

 namespace assembler {
 namespace mips {


 namespace v8i = v8::internal;


 //------------------------------------------------------------------------------

 // Decoder decodes and disassembles instructions into an output buffer.
 // It uses the converter to convert register names and call destinations into
 // more informative description.
 class Decoder {
  public:
   Decoder(const disasm::NameConverter& converter,
           v8::internal::Vector<char> out_buffer)
     : converter_(converter),
       out_buffer_(out_buffer),
       out_buffer_pos_(0) {
     out_buffer_[out_buffer_pos_] = '\0';
   }

   ~Decoder() {}

   // Writes one disassembled instruction into 'buffer' (0-terminated).
   // Returns the length of the disassembled machine instruction in bytes.
   int InstructionDecode(byte_* instruction);

  private:
   // Bottleneck functions to print into the out_buffer.
   void PrintChar(const char ch);
   void Print(const char* str);

   // Printing of common values.
   void PrintRegister(int reg);
   void PrintCRegister(int creg);
   void PrintRs(Instruction* instr);
   void PrintRt(Instruction* instr);
   void PrintRd(Instruction* instr);
   void PrintFs(Instruction* instr);
   void PrintFt(Instruction* instr);
   void PrintFd(Instruction* instr);
   void PrintSa(Instruction* instr);
   void PrintFunction(Instruction* instr);
   void PrintSecondaryField(Instruction* instr);
   void PrintUImm16(Instruction* instr);
   void PrintSImm16(Instruction* instr);
   void PrintXImm16(Instruction* instr);
   void PrintImm26(Instruction* instr);
   void PrintCode(Instruction* instr);   // For break and trap instructions.
   // Printing of instruction name.
   void PrintInstructionName(Instruction* instr);

   // Handle formatting of instructions and their options.
   int FormatRegister(Instruction* instr, const char* option);
   int FormatCRegister(Instruction* instr, const char* option);
   int FormatOption(Instruction* instr, const char* option);
   void Format(Instruction* instr, const char* format);
   void Unknown(Instruction* instr);

   // Each of these functions decodes one particular instruction type.
   void DecodeTypeRegister(Instruction* instr);
   void DecodeTypeImmediate(Instruction* instr);
   void DecodeTypeJump(Instruction* instr);

   const disasm::NameConverter& converter_;
   v8::internal::Vector<char> out_buffer_;
   int out_buffer_pos_;

   DISALLOW_COPY_AND_ASSIGN(Decoder);
 };


 // Support for assertions in the Decoder formatting functions.
 #define STRING_STARTS_WITH(string, compare_string) \
   (strncmp(string, compare_string, strlen(compare_string)) == 0)


 // Append the ch to the output buffer.
 void Decoder::PrintChar(const char ch) {
   out_buffer_[out_buffer_pos_++] = ch;
 }


 // Append the str to the output buffer.
 void Decoder::Print(const char* str) {
   char cur = *str++;
   while (cur != '\0' && (out_buffer_pos_ < (out_buffer_.length() - 1))) {
     PrintChar(cur);
     cur = *str++;
   }
   out_buffer_[out_buffer_pos_] = 0;
 }


 // Print the register name according to the active name converter.
 void Decoder::PrintRegister(int reg) {
   Print(converter_.NameOfCPURegister(reg));
 }


 void Decoder::PrintRs(Instruction* instr) {
   int reg = instr->RsField();
   PrintRegister(reg);
 }


 void Decoder::PrintRt(Instruction* instr) {
   int reg = instr->RtField();
   PrintRegister(reg);
 }


 void Decoder::PrintRd(Instruction* instr) {
   int reg = instr->RdField();
   PrintRegister(reg);
 }


 // Print the Cregister name according to the active name converter.
 void Decoder::PrintCRegister(int creg) {
   Print(converter_.NameOfXMMRegister(creg));
 }


 void Decoder::PrintFs(Instruction* instr) {
   int creg = instr->RsField();
   PrintCRegister(creg);
 }


 void Decoder::PrintFt(Instruction* instr) {
   int creg = instr->RtField();
   PrintCRegister(creg);
 }


 void Decoder::PrintFd(Instruction* instr) {
   int creg = instr->RdField();
   PrintCRegister(creg);
 }


 // Print the integer value of the sa field.
 void Decoder::PrintSa(Instruction* instr) {
   int sa = instr->SaField();
   out_buffer_pos_ += v8i::OS::SNPrintF(out_buffer_ + out_buffer_pos_,
                                        "%d", sa);
 }


 // Print 16-bit unsigned immediate value.
 void Decoder::PrintUImm16(Instruction* instr) {
   int32_t imm = instr->Imm16Field();
   out_buffer_pos_ += v8i::OS::SNPrintF(out_buffer_ + out_buffer_pos_,
                                        "%u", imm);
 }


 // Print 16-bit signed immediate value.
 void Decoder::PrintSImm16(Instruction* instr) {
   int32_t imm = ((instr->Imm16Field())<<16)>>16;
   out_buffer_pos_ += v8i::OS::SNPrintF(out_buffer_ + out_buffer_pos_,
                                        "%d", imm);
 }


 // Print 16-bit hexa immediate value.
 void Decoder::PrintXImm16(Instruction* instr) {
   int32_t imm = instr->Imm16Field();
   out_buffer_pos_ += v8i::OS::SNPrintF(out_buffer_ + out_buffer_pos_,
                                        "0x%x", imm);
 }


 // Print 26-bit immediate value.
 void Decoder::PrintImm26(Instruction* instr) {
   int32_t imm = instr->Imm26Field();
   out_buffer_pos_ += v8i::OS::SNPrintF(out_buffer_ + out_buffer_pos_,
                                        "%d", imm);
 }


 // Print 26-bit immediate value.
 void Decoder::PrintCode(Instruction* instr) {
   if (instr->OpcodeFieldRaw() != SPECIAL)
     return;  // Not a break or trap instruction.
   switch (instr->FunctionFieldRaw()) {
     case BREAK: {
       int32_t code = instr->Bits(25, 6);
       out_buffer_pos_ +=
           v8i::OS::SNPrintF(out_buffer_ + out_buffer_pos_, "0x%05x", code);
       break;
                 }
     case TGE:
     case TGEU:
     case TLT:
     case TLTU:
     case TEQ:
     case TNE: {
       int32_t code = instr->Bits(15, 6);
       out_buffer_pos_ +=
           v8i::OS::SNPrintF(out_buffer_ + out_buffer_pos_, "0x%03x", code);
       break;
     }
     default:  // Not a break or trap instruction.
     break;
   };
 }


 // Printing of instruction name.
 void Decoder::PrintInstructionName(Instruction* instr) {
 }


 // Handle all register based formatting in this function to reduce the
 // complexity of FormatOption.
 int Decoder::FormatRegister(Instruction* instr, const char* format) {
   ASSERT(format[0] == 'r');
   if (format[1] == 's') {  // 'rs: Rs register
     int reg = instr->RsField();
     PrintRegister(reg);
     return 2;
   } else if (format[1] == 't') {  // 'rt: rt register
     int reg = instr->RtField();
     PrintRegister(reg);
     return 2;
   } else if (format[1] == 'd') {  // 'rd: rd register
     int reg = instr->RdField();
     PrintRegister(reg);
     return 2;
   }
   UNREACHABLE();
   return -1;
 }


 // Handle all Cregister based formatting in this function to reduce the
 // complexity of FormatOption.
 int Decoder::FormatCRegister(Instruction* instr, const char* format) {
   ASSERT(format[0] == 'f');
   if (format[1] == 's') {  // 'fs: fs register
     int reg = instr->RsField();
     PrintCRegister(reg);
     return 2;
   } else if (format[1] == 't') {  // 'ft: ft register
     int reg = instr->RtField();
     PrintCRegister(reg);
     return 2;
   } else if (format[1] == 'd') {  // 'fd: fd register
     int reg = instr->RdField();
     PrintCRegister(reg);
     return 2;
   }
   UNREACHABLE();
   return -1;
 }


 // FormatOption takes a formatting string and interprets it based on
 // the current instructions. The format string points to the first
 // character of the option string (the option escape has already been
 // consumed by the caller.)  FormatOption returns the number of
 // characters that were consumed from the formatting string.
 int Decoder::FormatOption(Instruction* instr, const char* format) {
   switch (format[0]) {
     case 'c': {   // 'code for break or trap instructions
       ASSERT(STRING_STARTS_WITH(format, "code"));
       PrintCode(instr);
       return 4;
     }
     case 'i': {   // 'imm16u or 'imm26
       if (format[3] == '1') {
         ASSERT(STRING_STARTS_WITH(format, "imm16"));
         if (format[5] == 's') {
           ASSERT(STRING_STARTS_WITH(format, "imm16s"));
           PrintSImm16(instr);
         } else if (format[5] == 'u') {
           ASSERT(STRING_STARTS_WITH(format, "imm16u"));
           PrintSImm16(instr);
         } else {
           ASSERT(STRING_STARTS_WITH(format, "imm16x"));
           PrintXImm16(instr);
         }
         return 6;
       } else {
         ASSERT(STRING_STARTS_WITH(format, "imm26"));
         PrintImm26(instr);
         return 5;
       }
     }
     case 'r': {   // 'r: registers
       return FormatRegister(instr, format);
     }
     case 'f': {   // 'f: Cregisters
       return FormatCRegister(instr, format);
     }
     case 's': {   // 'sa
       ASSERT(STRING_STARTS_WITH(format, "sa"));
       PrintSa(instr);
       return 2;
     }
   };
   UNREACHABLE();
   return -1;
 }


 // Format takes a formatting string for a whole instruction and prints it into
 // the output buffer. All escaped options are handed to FormatOption to be
 // parsed further.
 void Decoder::Format(Instruction* instr, const char* format) {
   char cur = *format++;
   while ((cur != 0) && (out_buffer_pos_ < (out_buffer_.length() - 1))) {
     if (cur == '\'') {  // Single quote is used as the formatting escape.
       format += FormatOption(instr, format);
     } else {
       out_buffer_[out_buffer_pos_++] = cur;
     }
     cur = *format++;
   }
   out_buffer_[out_buffer_pos_]  = '\0';
 }


 // For currently unimplemented decodings the disassembler calls Unknown(instr)
 // which will just print "unknown" of the instruction bits.
 void Decoder::Unknown(Instruction* instr) {
   Format(instr, "unknown");
 }


 void Decoder::DecodeTypeRegister(Instruction* instr) {
   switch (instr->OpcodeFieldRaw()) {
     case COP1:    // Coprocessor instructions
       switch (instr->RsFieldRaw()) {
         case BC1:   // branch on coprocessor condition
           UNREACHABLE();
           break;
         case MFC1:
           Format(instr, "mfc1 'rt, 'fs");
           break;
         case MFHC1:
           Format(instr, "mfhc1  rt, 'fs");
           break;
         case MTC1:
           Format(instr, "mtc1 'rt, 'fs");
           break;
         case MTHC1:
           Format(instr, "mthc1  rt, 'fs");
           break;
         case S:
         case D:
           UNIMPLEMENTED_MIPS();
           break;
         case W:
           switch (instr->FunctionFieldRaw()) {
             case CVT_S_W:
               UNIMPLEMENTED_MIPS();
               break;
             case CVT_D_W:   // Convert word to double.
               Format(instr, "cvt.d.w  'fd, 'fs");
               break;
             default:
               UNREACHABLE();
           };
           break;
         case L:
         case PS:
           UNIMPLEMENTED_MIPS();
           break;
           break;
         default:
           UNREACHABLE();
       };
       break;
     case SPECIAL:
       switch (instr->FunctionFieldRaw()) {
         case JR:
           Format(instr, "jr   'rs");
           break;
         case JALR:
           Format(instr, "jalr 'rs");
           break;
         case SLL:
           if ( 0x0 == static_cast<int>(instr->InstructionBits()))
             Format(instr, "nop");
           else
             Format(instr, "sll  'rd, 'rt, 'sa");
           break;
         case SRL:
           Format(instr, "srl  'rd, 'rt, 'sa");
           break;
         case SRA:
           Format(instr, "sra  'rd, 'rt, 'sa");
           break;
         case SLLV:
           Format(instr, "sllv 'rd, 'rt, 'rs");
           break;
         case SRLV:
           Format(instr, "srlv 'rd, 'rt, 'rs");
           break;
         case SRAV:
           Format(instr, "srav 'rd, 'rt, 'rs");
           break;
         case MFHI:
           Format(instr, "mfhi 'rd");
           break;
         case MFLO:
           Format(instr, "mflo 'rd");
           break;
         case MULT:
           Format(instr, "mult 'rs, 'rt");
           break;
         case MULTU:
           Format(instr, "multu  'rs, 'rt");
           break;
         case DIV:
           Format(instr, "div  'rs, 'rt");
           break;
         case DIVU:
           Format(instr, "divu 'rs, 'rt");
           break;
         case ADD:
           Format(instr, "add  'rd, 'rs, 'rt");
           break;
         case ADDU:
           Format(instr, "addu 'rd, 'rs, 'rt");
           break;
         case SUB:
           Format(instr, "sub  'rd, 'rs, 'rt");
           break;
         case SUBU:
           Format(instr, "sub  'rd, 'rs, 'rt");
           break;
         case AND:
           Format(instr, "and  'rd, 'rs, 'rt");
           break;
         case OR:
           if (0 == instr->RsField()) {
             Format(instr, "mov  'rd, 'rt");
           } else if (0 == instr->RtField()) {
             Format(instr, "mov  'rd, 'rs");
           } else {
             Format(instr, "or   'rd, 'rs, 'rt");
           }
           break;
         case XOR:
           Format(instr, "xor  'rd, 'rs, 'rt");
           break;
         case NOR:
           Format(instr, "nor  'rd, 'rs, 'rt");
           break;
         case SLT:
           Format(instr, "slt  'rd, 'rs, 'rt");
           break;
         case SLTU:
           Format(instr, "sltu 'rd, 'rs, 'rt");
           break;
         case BREAK:
           Format(instr, "break, code: 'code");
           break;
         case TGE:
           Format(instr, "tge  'rs, 'rt, code: 'code");
           break;
         case TGEU:
           Format(instr, "tgeu 'rs, 'rt, code: 'code");
           break;
         case TLT:
           Format(instr, "tlt  'rs, 'rt, code: 'code");
           break;
         case TLTU:
           Format(instr, "tltu 'rs, 'rt, code: 'code");
           break;
         case TEQ:
           Format(instr, "teq  'rs, 'rt, code: 'code");
           break;
         case TNE:
           Format(instr, "tne  'rs, 'rt, code: 'code");
           break;
         default:
           UNREACHABLE();
       };
       break;
     case SPECIAL2:
       switch (instr->FunctionFieldRaw()) {
         case MUL:
           break;
         default:
           UNREACHABLE();
       };
       break;
     default:
       UNREACHABLE();
   };
 }


 void Decoder::DecodeTypeImmediate(Instruction* instr) {
   switch (instr->OpcodeFieldRaw()) {
     // ------------- REGIMM class.
     case REGIMM:
       switch (instr->RtFieldRaw()) {
         case BLTZ:
           Format(instr, "bltz 'rs, 'imm16u");
           break;
         case BLTZAL:
           Format(instr, "bltzal 'rs, 'imm16u");
           break;
         case BGEZ:
           Format(instr, "bgez 'rs, 'imm16u");
           break;
         case BGEZAL:
           Format(instr, "bgezal 'rs, 'imm16u");
           break;
         default:
           UNREACHABLE();
       };
     break;  // case REGIMM
     // ------------- Branch instructions.
     case BEQ:
       Format(instr, "beq  'rs, 'rt, 'imm16u");
       break;
     case BNE:
       Format(instr, "bne  'rs, 'rt, 'imm16u");
       break;
     case BLEZ:
       Format(instr, "blez 'rs, 'imm16u");
       break;
     case BGTZ:
       Format(instr, "bgtz 'rs, 'imm16u");
       break;
     // ------------- Arithmetic instructions.
     case ADDI:
       Format(instr, "addi   'rt, 'rs, 'imm16s");
       break;
     case ADDIU:
       Format(instr, "addiu  'rt, 'rs, 'imm16s");
       break;
     case SLTI:
       Format(instr, "slti   'rt, 'rs, 'imm16s");
       break;
     case SLTIU:
       Format(instr, "sltiu  'rt, 'rs, 'imm16u");
       break;
     case ANDI:
       Format(instr, "andi   'rt, 'rs, 'imm16x");
       break;
     case ORI:
       Format(instr, "ori    'rt, 'rs, 'imm16x");
       break;
     case XORI:
       Format(instr, "xori   'rt, 'rs, 'imm16x");
       break;
     case LUI:
       Format(instr, "lui    'rt, 'imm16x");
       break;
     // ------------- Memory instructions.
     case LB:
       Format(instr, "lb     'rt, 'imm16s('rs)");
       break;
     case LW:
       Format(instr, "lw     'rt, 'imm16s('rs)");
       break;
     case LBU:
       Format(instr, "lbu    'rt, 'imm16s('rs)");
       break;
     case SB:
       Format(instr, "sb     'rt, 'imm16s('rs)");
       break;
     case SW:
       Format(instr, "sw     'rt, 'imm16s('rs)");
       break;
     case LWC1:
       Format(instr, "lwc1   'ft, 'imm16s('rs)");
       break;
     case LDC1:
       Format(instr, "ldc1   'ft, 'imm16s('rs)");
       break;
     case SWC1:
       Format(instr, "swc1   'rt, 'imm16s('fs)");
       break;
     case SDC1:
       Format(instr, "sdc1   'rt, 'imm16s('fs)");
       break;
     default:
       UNREACHABLE();
       break;
   };
 }


 void Decoder::DecodeTypeJump(Instruction* instr) {
   switch (instr->OpcodeFieldRaw()) {
     case J:
       Format(instr, "j    'imm26");
       break;
     case JAL:
       Format(instr, "jal  'imm26");
       break;
     default:
       UNREACHABLE();
   }
 }


 // Disassemble the instruction at *instr_ptr into the output buffer.
 int Decoder::InstructionDecode(byte_* instr_ptr) {
   Instruction* instr = Instruction::At(instr_ptr);
   // Print raw instruction bytes.
   out_buffer_pos_ += v8i::OS::SNPrintF(out_buffer_ + out_buffer_pos_,
                                        "%08x       ",
                                        instr->InstructionBits());
   switch (instr->InstructionType()) {
     case Instruction::kRegisterType: {
       DecodeTypeRegister(instr);
       break;
     }
     case Instruction::kImmediateType: {
       DecodeTypeImmediate(instr);
       break;
     }
     case Instruction::kJumpType: {
       DecodeTypeJump(instr);
       break;
     }
     default: {
       UNSUPPORTED_MIPS();
     }
   }
   return Instruction::kInstructionSize;
 }


 } }  // namespace assembler::mips


 //------------------------------------------------------------------------------

 namespace disasm {

 namespace v8i = v8::internal;


 const char* NameConverter::NameOfAddress(byte_* addr) const {
   static v8::internal::EmbeddedVector<char, 32> tmp_buffer;
   v8::internal::OS::SNPrintF(tmp_buffer, "%p", addr);
   return tmp_buffer.start();
 }


 const char* NameConverter::NameOfConstant(byte_* addr) const {
   return NameOfAddress(addr);
 }


 const char* NameConverter::NameOfCPURegister(int reg) const {
   return assembler::mips::Registers::Name(reg);
 }


 const char* NameConverter::NameOfXMMRegister(int reg) const {
   return assembler::mips::FPURegister::Name(reg);
 }


 const char* NameConverter::NameOfByteCPURegister(int reg) const {
   UNREACHABLE();  // MIPS does not have the concept of a byte register
   return "nobytereg";
 }


 const char* NameConverter::NameInCode(byte_* addr) const {
   // The default name converter is called for unknown code. So we will not try
   // to access any memory.
   return "";
 }


 //------------------------------------------------------------------------------

 Disassembler::Disassembler(const NameConverter& converter)
     : converter_(converter) {}


 Disassembler::~Disassembler() {}


 int Disassembler::InstructionDecode(v8::internal::Vector<char> buffer,
                                     byte_* instruction) {
   assembler::mips::Decoder d(converter_, buffer);
   return d.InstructionDecode(instruction);
 }


 int Disassembler::ConstantPoolSizeAt(byte_* instruction) {
   UNIMPLEMENTED_MIPS();
   return -1;
 }


 void Disassembler::Disassemble(FILE* f, byte_* begin, byte_* end) {
   NameConverter converter;
   Disassembler d(converter);
   for (byte_* pc = begin; pc < end;) {
     v8::internal::EmbeddedVector<char, 128> buffer;
     buffer[0] = '\0';
     byte_* prev_pc = pc;
     pc += d.InstructionDecode(buffer, pc);
     fprintf(f, "%p    %08x      %s\n",
             prev_pc, *reinterpret_cast<int32_t*>(prev_pc), buffer.start());
   }
 }

 #undef UNSUPPORTED

 }  // namespace disasm

 #endif  // V8_TARGET_ARCH_MIPS
	// Copyright 2010 the V8 project authors. 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.
	// * 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.
	// * Neither the name of Google Inc. nor the names of its
	// 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.

	// A Disassembler object is used to disassemble a block of code instruction by
	// instruction. The default implementation of the NameConverter object can be
	// overriden to modify register names or to do symbol lookup on addresses.
	//
	// The example below will disassemble a block of code and print it to stdout.
	//
	// NameConverter converter;
	// Disassembler d(converter);
	// for (byte_* pc = begin; pc < end;) {
	// char buffer[128];
	// buffer[0] = '\0';
	// byte_* prev_pc = pc;
	// pc += d.InstructionDecode(buffer, sizeof buffer, pc);
	// printf("%p %08x %s\n",
	// prev_pc, reinterpret_cast<int32_t>(prev_pc), buffer);
	// }
	//
	// The Disassembler class also has a convenience method to disassemble a block
	// of code into a FILE*, meaning that the above functionality could also be
	// achieved by just calling Disassembler::Disassemble(stdout, begin, end);


	#include <assert.h>
	#include <stdio.h>
	#include <stdarg.h>
	#include <string.h>
	#ifndef WIN32
	#include <stdint.h>
	#endif

	#include "v8.h"

	#if defined(V8_TARGET_ARCH_MIPS)

	#include "constants-mips.h"
	#include "disasm.h"
	#include "macro-assembler.h"
	#include "platform.h"

	namespace assembler {
	namespace mips {


	namespace v8i = v8::internal;


	//------------------------------------------------------------------------------

	// Decoder decodes and disassembles instructions into an output buffer.
	// It uses the converter to convert register names and call destinations into
	// more informative description.
	class Decoder {
	public:
	Decoder(const disasm::NameConverter& converter,
	v8::internal::Vector<char> out_buffer)
	: converter_(converter),
	out_buffer_(out_buffer),
	out_buffer_pos_(0) {
	out_buffer_[out_buffer_pos_] = '\0';
	}

	~Decoder() {}

	// Writes one disassembled instruction into 'buffer' (0-terminated).
	// Returns the length of the disassembled machine instruction in bytes.
	int InstructionDecode(byte_* instruction);

	private:
	// Bottleneck functions to print into the out_buffer.
	void PrintChar(const char ch);
	void Print(const char* str);

	// Printing of common values.
	void PrintRegister(int reg);
	void PrintCRegister(int creg);
	void PrintRs(Instruction* instr);
	void PrintRt(Instruction* instr);
	void PrintRd(Instruction* instr);
	void PrintFs(Instruction* instr);
	void PrintFt(Instruction* instr);
	void PrintFd(Instruction* instr);
	void PrintSa(Instruction* instr);
	void PrintFunction(Instruction* instr);
	void PrintSecondaryField(Instruction* instr);
	void PrintUImm16(Instruction* instr);
	void PrintSImm16(Instruction* instr);
	void PrintXImm16(Instruction* instr);
	void PrintImm26(Instruction* instr);
	void PrintCode(Instruction* instr); // For break and trap instructions.
	// Printing of instruction name.
	void PrintInstructionName(Instruction* instr);

	// Handle formatting of instructions and their options.
	int FormatRegister(Instruction* instr, const char* option);
	int FormatCRegister(Instruction* instr, const char* option);
	int FormatOption(Instruction* instr, const char* option);
	void Format(Instruction* instr, const char* format);
	void Unknown(Instruction* instr);

	// Each of these functions decodes one particular instruction type.
	void DecodeTypeRegister(Instruction* instr);
	void DecodeTypeImmediate(Instruction* instr);
	void DecodeTypeJump(Instruction* instr);

	const disasm::NameConverter& converter_;
	v8::internal::Vector<char> out_buffer_;
	int out_buffer_pos_;

	DISALLOW_COPY_AND_ASSIGN(Decoder);
	};


	// Support for assertions in the Decoder formatting functions.
	#define STRING_STARTS_WITH(string, compare_string) \
	(strncmp(string, compare_string, strlen(compare_string)) == 0)


	// Append the ch to the output buffer.
	void Decoder::PrintChar(const char ch) {
	out_buffer_[out_buffer_pos_++] = ch;
	}


	// Append the str to the output buffer.
	void Decoder::Print(const char* str) {
	char cur = *str++;
	while (cur != '\0' && (out_buffer_pos_ < (out_buffer_.length() - 1))) {
	PrintChar(cur);
	cur = *str++;
	}
	out_buffer_[out_buffer_pos_] = 0;
	}


	// Print the register name according to the active name converter.
	void Decoder::PrintRegister(int reg) {
	Print(converter_.NameOfCPURegister(reg));
	}


	void Decoder::PrintRs(Instruction* instr) {
	int reg = instr->RsField();
	PrintRegister(reg);
	}


	void Decoder::PrintRt(Instruction* instr) {
	int reg = instr->RtField();
	PrintRegister(reg);
	}


	void Decoder::PrintRd(Instruction* instr) {
	int reg = instr->RdField();
	PrintRegister(reg);
	}


	// Print the Cregister name according to the active name converter.
	void Decoder::PrintCRegister(int creg) {
	Print(converter_.NameOfXMMRegister(creg));
	}


	void Decoder::PrintFs(Instruction* instr) {
	int creg = instr->RsField();
	PrintCRegister(creg);
	}


	void Decoder::PrintFt(Instruction* instr) {
	int creg = instr->RtField();
	PrintCRegister(creg);
	}


	void Decoder::PrintFd(Instruction* instr) {
	int creg = instr->RdField();
	PrintCRegister(creg);
	}


	// Print the integer value of the sa field.
	void Decoder::PrintSa(Instruction* instr) {
	int sa = instr->SaField();
	out_buffer_pos_ += v8i::OS::SNPrintF(out_buffer_ + out_buffer_pos_,
	"%d", sa);
	}


	// Print 16-bit unsigned immediate value.
	void Decoder::PrintUImm16(Instruction* instr) {
	int32_t imm = instr->Imm16Field();
	out_buffer_pos_ += v8i::OS::SNPrintF(out_buffer_ + out_buffer_pos_,
	"%u", imm);
	}


	// Print 16-bit signed immediate value.
	void Decoder::PrintSImm16(Instruction* instr) {
	int32_t imm = ((instr->Imm16Field())<<16)>>16;
	out_buffer_pos_ += v8i::OS::SNPrintF(out_buffer_ + out_buffer_pos_,
	"%d", imm);
	}


	// Print 16-bit hexa immediate value.
	void Decoder::PrintXImm16(Instruction* instr) {
	int32_t imm = instr->Imm16Field();
	out_buffer_pos_ += v8i::OS::SNPrintF(out_buffer_ + out_buffer_pos_,
	"0x%x", imm);
	}


	// Print 26-bit immediate value.
	void Decoder::PrintImm26(Instruction* instr) {
	int32_t imm = instr->Imm26Field();
	out_buffer_pos_ += v8i::OS::SNPrintF(out_buffer_ + out_buffer_pos_,
	"%d", imm);
	}


	// Print 26-bit immediate value.
	void Decoder::PrintCode(Instruction* instr) {
	if (instr->OpcodeFieldRaw() != SPECIAL)
	return; // Not a break or trap instruction.
	switch (instr->FunctionFieldRaw()) {
	case BREAK: {
	int32_t code = instr->Bits(25, 6);
	out_buffer_pos_ +=
	v8i::OS::SNPrintF(out_buffer_ + out_buffer_pos_, "0x%05x", code);
	break;
	}
	case TGE:
	case TGEU:
	case TLT:
	case TLTU:
	case TEQ:
	case TNE: {
	int32_t code = instr->Bits(15, 6);
	out_buffer_pos_ +=
	v8i::OS::SNPrintF(out_buffer_ + out_buffer_pos_, "0x%03x", code);
	break;
	}
	default: // Not a break or trap instruction.
	break;
	};
	}


	// Printing of instruction name.
	void Decoder::PrintInstructionName(Instruction* instr) {
	}


	// Handle all register based formatting in this function to reduce the
	// complexity of FormatOption.
	int Decoder::FormatRegister(Instruction* instr, const char* format) {
	ASSERT(format[0] == 'r');
	if (format[1] == 's') { // 'rs: Rs register
	int reg = instr->RsField();
	PrintRegister(reg);
	return 2;
	} else if (format[1] == 't') { // 'rt: rt register
	int reg = instr->RtField();
	PrintRegister(reg);
	return 2;
	} else if (format[1] == 'd') { // 'rd: rd register
	int reg = instr->RdField();
	PrintRegister(reg);
	return 2;
	}
	UNREACHABLE();
	return -1;
	}


	// Handle all Cregister based formatting in this function to reduce the
	// complexity of FormatOption.
	int Decoder::FormatCRegister(Instruction* instr, const char* format) {
	ASSERT(format[0] == 'f');
	if (format[1] == 's') { // 'fs: fs register
	int reg = instr->RsField();
	PrintCRegister(reg);
	return 2;
	} else if (format[1] == 't') { // 'ft: ft register
	int reg = instr->RtField();
	PrintCRegister(reg);
	return 2;
	} else if (format[1] == 'd') { // 'fd: fd register
	int reg = instr->RdField();
	PrintCRegister(reg);
	return 2;
	}
	UNREACHABLE();
	return -1;
	}


	// FormatOption takes a formatting string and interprets it based on
	// the current instructions. The format string points to the first
	// character of the option string (the option escape has already been
	// consumed by the caller.) FormatOption returns the number of
	// characters that were consumed from the formatting string.
	int Decoder::FormatOption(Instruction* instr, const char* format) {
	switch (format[0]) {
	case 'c': { // 'code for break or trap instructions
	ASSERT(STRING_STARTS_WITH(format, "code"));
	PrintCode(instr);
	return 4;
	}
	case 'i': { // 'imm16u or 'imm26
	if (format[3] == '1') {
	ASSERT(STRING_STARTS_WITH(format, "imm16"));
	if (format[5] == 's') {
	ASSERT(STRING_STARTS_WITH(format, "imm16s"));
	PrintSImm16(instr);
	} else if (format[5] == 'u') {
	ASSERT(STRING_STARTS_WITH(format, "imm16u"));
	PrintSImm16(instr);
	} else {
	ASSERT(STRING_STARTS_WITH(format, "imm16x"));
	PrintXImm16(instr);
	}
	return 6;
	} else {
	ASSERT(STRING_STARTS_WITH(format, "imm26"));
	PrintImm26(instr);
	return 5;
	}
	}
	case 'r': { // 'r: registers
	return FormatRegister(instr, format);
	}
	case 'f': { // 'f: Cregisters
	return FormatCRegister(instr, format);
	}
	case 's': { // 'sa
	ASSERT(STRING_STARTS_WITH(format, "sa"));
	PrintSa(instr);
	return 2;
	}
	};
	UNREACHABLE();
	return -1;
	}


	// Format takes a formatting string for a whole instruction and prints it into
	// the output buffer. All escaped options are handed to FormatOption to be
	// parsed further.
	void Decoder::Format(Instruction* instr, const char* format) {
	char cur = *format++;
	while ((cur != 0) && (out_buffer_pos_ < (out_buffer_.length() - 1))) {
	if (cur == '\'') { // Single quote is used as the formatting escape.
	format += FormatOption(instr, format);
	} else {
	out_buffer_[out_buffer_pos_++] = cur;
	}
	cur = *format++;
	}
	out_buffer_[out_buffer_pos_] = '\0';
	}


	// For currently unimplemented decodings the disassembler calls Unknown(instr)
	// which will just print "unknown" of the instruction bits.
	void Decoder::Unknown(Instruction* instr) {
	Format(instr, "unknown");
	}


	void Decoder::DecodeTypeRegister(Instruction* instr) {
	switch (instr->OpcodeFieldRaw()) {
	case COP1: // Coprocessor instructions
	switch (instr->RsFieldRaw()) {
	case BC1: // branch on coprocessor condition
	UNREACHABLE();
	break;
	case MFC1:
	Format(instr, "mfc1 'rt, 'fs");
	break;
	case MFHC1:
	Format(instr, "mfhc1 rt, 'fs");
	break;
	case MTC1:
	Format(instr, "mtc1 'rt, 'fs");
	break;
	case MTHC1:
	Format(instr, "mthc1 rt, 'fs");
	break;
	case S:
	case D:
	UNIMPLEMENTED_MIPS();
	break;
	case W:
	switch (instr->FunctionFieldRaw()) {
	case CVT_S_W:
	UNIMPLEMENTED_MIPS();
	break;
	case CVT_D_W: // Convert word to double.
	Format(instr, "cvt.d.w 'fd, 'fs");
	break;
	default:
	UNREACHABLE();
	};
	break;
	case L:
	case PS:
	UNIMPLEMENTED_MIPS();
	break;
	break;
	default:
	UNREACHABLE();
	};
	break;
	case SPECIAL:
	switch (instr->FunctionFieldRaw()) {
	case JR:
	Format(instr, "jr 'rs");
	break;
	case JALR:
	Format(instr, "jalr 'rs");
	break;
	case SLL:
	if ( 0x0 == static_cast<int>(instr->InstructionBits()))
	Format(instr, "nop");
	else
	Format(instr, "sll 'rd, 'rt, 'sa");
	break;
	case SRL:
	Format(instr, "srl 'rd, 'rt, 'sa");
	break;
	case SRA:
	Format(instr, "sra 'rd, 'rt, 'sa");
	break;
	case SLLV:
	Format(instr, "sllv 'rd, 'rt, 'rs");
	break;
	case SRLV:
	Format(instr, "srlv 'rd, 'rt, 'rs");
	break;
	case SRAV:
	Format(instr, "srav 'rd, 'rt, 'rs");
	break;
	case MFHI:
	Format(instr, "mfhi 'rd");
	break;
	case MFLO:
	Format(instr, "mflo 'rd");
	break;
	case MULT:
	Format(instr, "mult 'rs, 'rt");
	break;
	case MULTU:
	Format(instr, "multu 'rs, 'rt");
	break;
	case DIV:
	Format(instr, "div 'rs, 'rt");
	break;
	case DIVU:
	Format(instr, "divu 'rs, 'rt");
	break;
	case ADD:
	Format(instr, "add 'rd, 'rs, 'rt");
	break;
	case ADDU:
	Format(instr, "addu 'rd, 'rs, 'rt");
	break;
	case SUB:
	Format(instr, "sub 'rd, 'rs, 'rt");
	break;
	case SUBU:
	Format(instr, "sub 'rd, 'rs, 'rt");
	break;
	case AND:
	Format(instr, "and 'rd, 'rs, 'rt");
	break;
	case OR:
	if (0 == instr->RsField()) {
	Format(instr, "mov 'rd, 'rt");
	} else if (0 == instr->RtField()) {
	Format(instr, "mov 'rd, 'rs");
	} else {
	Format(instr, "or 'rd, 'rs, 'rt");
	}
	break;
	case XOR:
	Format(instr, "xor 'rd, 'rs, 'rt");
	break;
	case NOR:
	Format(instr, "nor 'rd, 'rs, 'rt");
	break;
	case SLT:
	Format(instr, "slt 'rd, 'rs, 'rt");
	break;
	case SLTU:
	Format(instr, "sltu 'rd, 'rs, 'rt");
	break;
	case BREAK:
	Format(instr, "break, code: 'code");
	break;
	case TGE:
	Format(instr, "tge 'rs, 'rt, code: 'code");
	break;
	case TGEU:
	Format(instr, "tgeu 'rs, 'rt, code: 'code");
	break;
	case TLT:
	Format(instr, "tlt 'rs, 'rt, code: 'code");
	break;
	case TLTU:
	Format(instr, "tltu 'rs, 'rt, code: 'code");
	break;
	case TEQ:
	Format(instr, "teq 'rs, 'rt, code: 'code");
	break;
	case TNE:
	Format(instr, "tne 'rs, 'rt, code: 'code");
	break;
	default:
	UNREACHABLE();
	};
	break;
	case SPECIAL2:
	switch (instr->FunctionFieldRaw()) {
	case MUL:
	break;
	default:
	UNREACHABLE();
	};
	break;
	default:
	UNREACHABLE();
	};
	}


	void Decoder::DecodeTypeImmediate(Instruction* instr) {
	switch (instr->OpcodeFieldRaw()) {
	// ------------- REGIMM class.
	case REGIMM:
	switch (instr->RtFieldRaw()) {
	case BLTZ:
	Format(instr, "bltz 'rs, 'imm16u");
	break;
	case BLTZAL:
	Format(instr, "bltzal 'rs, 'imm16u");
	break;
	case BGEZ:
	Format(instr, "bgez 'rs, 'imm16u");
	break;
	case BGEZAL:
	Format(instr, "bgezal 'rs, 'imm16u");
	break;
	default:
	UNREACHABLE();
	};
	break; // case REGIMM
	// ------------- Branch instructions.
	case BEQ:
	Format(instr, "beq 'rs, 'rt, 'imm16u");
	break;
	case BNE:
	Format(instr, "bne 'rs, 'rt, 'imm16u");
	break;
	case BLEZ:
	Format(instr, "blez 'rs, 'imm16u");
	break;
	case BGTZ:
	Format(instr, "bgtz 'rs, 'imm16u");
	break;
	// ------------- Arithmetic instructions.
	case ADDI:
	Format(instr, "addi 'rt, 'rs, 'imm16s");
	break;
	case ADDIU:
	Format(instr, "addiu 'rt, 'rs, 'imm16s");
	break;
	case SLTI:
	Format(instr, "slti 'rt, 'rs, 'imm16s");
	break;
	case SLTIU:
	Format(instr, "sltiu 'rt, 'rs, 'imm16u");
	break;
	case ANDI:
	Format(instr, "andi 'rt, 'rs, 'imm16x");
	break;
	case ORI:
	Format(instr, "ori 'rt, 'rs, 'imm16x");
	break;
	case XORI:
	Format(instr, "xori 'rt, 'rs, 'imm16x");
	break;
	case LUI:
	Format(instr, "lui 'rt, 'imm16x");
	break;
	// ------------- Memory instructions.
	case LB:
	Format(instr, "lb 'rt, 'imm16s('rs)");
	break;
	case LW:
	Format(instr, "lw 'rt, 'imm16s('rs)");
	break;
	case LBU:
	Format(instr, "lbu 'rt, 'imm16s('rs)");
	break;
	case SB:
	Format(instr, "sb 'rt, 'imm16s('rs)");
	break;
	case SW:
	Format(instr, "sw 'rt, 'imm16s('rs)");
	break;
	case LWC1:
	Format(instr, "lwc1 'ft, 'imm16s('rs)");
	break;
	case LDC1:
	Format(instr, "ldc1 'ft, 'imm16s('rs)");
	break;
	case SWC1:
	Format(instr, "swc1 'rt, 'imm16s('fs)");
	break;
	case SDC1:
	Format(instr, "sdc1 'rt, 'imm16s('fs)");
	break;
	default:
	UNREACHABLE();
	break;
	};
	}


	void Decoder::DecodeTypeJump(Instruction* instr) {
	switch (instr->OpcodeFieldRaw()) {
	case J:
	Format(instr, "j 'imm26");
	break;
	case JAL:
	Format(instr, "jal 'imm26");
	break;
	default:
	UNREACHABLE();
	}
	}


	// Disassemble the instruction at *instr_ptr into the output buffer.
	int Decoder::InstructionDecode(byte_* instr_ptr) {
	Instruction* instr = Instruction::At(instr_ptr);
	// Print raw instruction bytes.
	out_buffer_pos_ += v8i::OS::SNPrintF(out_buffer_ + out_buffer_pos_,
	"%08x ",
	instr->InstructionBits());
	switch (instr->InstructionType()) {
	case Instruction::kRegisterType: {
	DecodeTypeRegister(instr);
	break;
	}
	case Instruction::kImmediateType: {
	DecodeTypeImmediate(instr);
	break;
	}
	case Instruction::kJumpType: {
	DecodeTypeJump(instr);
	break;
	}
	default: {
	UNSUPPORTED_MIPS();
	}
	}
	return Instruction::kInstructionSize;
	}


	} } // namespace assembler::mips



	//------------------------------------------------------------------------------

	namespace disasm {

	namespace v8i = v8::internal;


	const char* NameConverter::NameOfAddress(byte_* addr) const {
	static v8::internal::EmbeddedVector<char, 32> tmp_buffer;
	v8::internal::OS::SNPrintF(tmp_buffer, "%p", addr);
	return tmp_buffer.start();
	}


	const char* NameConverter::NameOfConstant(byte_* addr) const {
	return NameOfAddress(addr);
	}


	const char* NameConverter::NameOfCPURegister(int reg) const {
	return assembler::mips::Registers::Name(reg);
	}


	const char* NameConverter::NameOfXMMRegister(int reg) const {
	return assembler::mips::FPURegister::Name(reg);
	}


	const char* NameConverter::NameOfByteCPURegister(int reg) const {
	UNREACHABLE(); // MIPS does not have the concept of a byte register
	return "nobytereg";
	}


	const char* NameConverter::NameInCode(byte_* addr) const {
	// The default name converter is called for unknown code. So we will not try
	// to access any memory.
	return "";
	}


	//------------------------------------------------------------------------------

	Disassembler::Disassembler(const NameConverter& converter)
	: converter_(converter) {}


	Disassembler::~Disassembler() {}


	int Disassembler::InstructionDecode(v8::internal::Vector<char> buffer,
	byte_* instruction) {
	assembler::mips::Decoder d(converter_, buffer);
	return d.InstructionDecode(instruction);
	}


	int Disassembler::ConstantPoolSizeAt(byte_* instruction) {
	UNIMPLEMENTED_MIPS();
	return -1;
	}


	void Disassembler::Disassemble(FILE* f, byte_* begin, byte_* end) {
	NameConverter converter;
	Disassembler d(converter);
	for (byte_* pc = begin; pc < end;) {
	v8::internal::EmbeddedVector<char, 128> buffer;
	buffer[0] = '\0';
	byte_* prev_pc = pc;
	pc += d.InstructionDecode(buffer, pc);
	fprintf(f, "%p %08x %s\n",
	prev_pc, reinterpret_cast<int32_t>(prev_pc), buffer.start());
	}
	}

	#undef UNSUPPORTED

	} // namespace disasm

	#endif // V8_TARGET_ARCH_MIPS