| // Copyright 2014 the V8 project authors. All rights reserved. |
| // Use of this source code is governed by a BSD-style license that can be |
| // found in the LICENSE file. |
| |
| // 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;) { |
| // v8::internal::EmbeddedVector<char, 256> buffer; |
| // byte* prev_pc = pc; |
| // pc += d.InstructionDecode(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 <stdarg.h> |
| #include <stdio.h> |
| #include <string.h> |
| |
| #if V8_TARGET_ARCH_S390 |
| |
| #include "src/base/platform/platform.h" |
| #include "src/codegen/macro-assembler.h" |
| #include "src/codegen/register-configuration.h" |
| #include "src/codegen/s390/constants-s390.h" |
| #include "src/diagnostics/disasm.h" |
| |
| namespace v8 { |
| namespace 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, 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 PrintDRegister(int reg); |
| void PrintSoftwareInterrupt(SoftwareInterruptCodes svc); |
| |
| // Handle formatting of instructions and their options. |
| int FormatRegister(Instruction* instr, const char* option); |
| int FormatFloatingRegister(Instruction* instr, const char* option); |
| int FormatMask(Instruction* instr, const char* option); |
| int FormatDisplacement(Instruction* instr, const char* option); |
| int FormatImmediate(Instruction* instr, const char* option); |
| int FormatOption(Instruction* instr, const char* option); |
| void Format(Instruction* instr, const char* format); |
| void Unknown(Instruction* instr); |
| void UnknownFormat(Instruction* instr, const char* opcname); |
| |
| bool DecodeSpecial(Instruction* instr); |
| bool DecodeGeneric(Instruction* instr); |
| |
| const disasm::NameConverter& converter_; |
| 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)); |
| } |
| |
| // Print the double FP register name according to the active name converter. |
| void Decoder::PrintDRegister(int reg) { |
| Print(RegisterName(DoubleRegister::from_code(reg))); |
| } |
| |
| // Print SoftwareInterrupt codes. Factoring this out reduces the complexity of |
| // the FormatOption method. |
| void Decoder::PrintSoftwareInterrupt(SoftwareInterruptCodes svc) { |
| switch (svc) { |
| case kCallRtRedirected: |
| Print("call rt redirected"); |
| return; |
| case kBreakpoint: |
| Print("breakpoint"); |
| return; |
| default: |
| if (svc >= kStopCode) { |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "%d - 0x%x", |
| svc & kStopCodeMask, svc & kStopCodeMask); |
| } else { |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "%d", svc); |
| } |
| return; |
| } |
| } |
| |
| // Handle all register based formatting in this function to reduce the |
| // complexity of FormatOption. |
| int Decoder::FormatRegister(Instruction* instr, const char* format) { |
| DCHECK_EQ(format[0], 'r'); |
| |
| if (format[1] == '1') { // 'r1: register resides in bit 8-11 |
| int reg = instr->Bits<SixByteInstr, int>(39, 36); |
| PrintRegister(reg); |
| return 2; |
| } else if (format[1] == '2') { // 'r2: register resides in bit 12-15 |
| int reg = instr->Bits<SixByteInstr, int>(35, 32); |
| // indicating it is a r0 for displacement, in which case the offset |
| // should be 0. |
| if (format[2] == 'd') { |
| if (reg == 0) return 4; |
| PrintRegister(reg); |
| return 3; |
| } else { |
| PrintRegister(reg); |
| return 2; |
| } |
| } else if (format[1] == '3') { // 'r3: register resides in bit 16-19 |
| int reg = instr->Bits<SixByteInstr, int>(31, 28); |
| PrintRegister(reg); |
| return 2; |
| } else if (format[1] == '4') { // 'r4: register resides in bit 20-23 |
| int reg = instr->Bits<SixByteInstr, int>(27, 24); |
| PrintRegister(reg); |
| return 2; |
| } else if (format[1] == '5') { // 'r5: register resides in bit 24-27 |
| int reg = instr->Bits<SixByteInstr, int>(23, 20); |
| PrintRegister(reg); |
| return 2; |
| } else if (format[1] == '6') { // 'r6: register resides in bit 28-31 |
| int reg = instr->Bits<SixByteInstr, int>(19, 16); |
| PrintRegister(reg); |
| return 2; |
| } else if (format[1] == '7') { // 'r6: register resides in bit 32-35 |
| int reg = instr->Bits<SixByteInstr, int>(15, 12); |
| PrintRegister(reg); |
| return 2; |
| } |
| |
| UNREACHABLE(); |
| } |
| |
| int Decoder::FormatFloatingRegister(Instruction* instr, const char* format) { |
| DCHECK_EQ(format[0], 'f'); |
| |
| // reuse 1, 5 and 6 because it is coresponding |
| if (format[1] == '1') { // 'r1: register resides in bit 8-11 |
| RRInstruction* rrinstr = reinterpret_cast<RRInstruction*>(instr); |
| int reg = rrinstr->R1Value(); |
| PrintDRegister(reg); |
| return 2; |
| } else if (format[1] == '2') { // 'f2: register resides in bit 12-15 |
| RRInstruction* rrinstr = reinterpret_cast<RRInstruction*>(instr); |
| int reg = rrinstr->R2Value(); |
| PrintDRegister(reg); |
| return 2; |
| } else if (format[1] == '3') { // 'f3: register resides in bit 16-19 |
| RRDInstruction* rrdinstr = reinterpret_cast<RRDInstruction*>(instr); |
| int reg = rrdinstr->R1Value(); |
| PrintDRegister(reg); |
| return 2; |
| } else if (format[1] == '5') { // 'f5: register resides in bit 24-28 |
| RREInstruction* rreinstr = reinterpret_cast<RREInstruction*>(instr); |
| int reg = rreinstr->R1Value(); |
| PrintDRegister(reg); |
| return 2; |
| } else if (format[1] == '6') { // 'f6: register resides in bit 29-32 |
| RREInstruction* rreinstr = reinterpret_cast<RREInstruction*>(instr); |
| int reg = rreinstr->R2Value(); |
| PrintDRegister(reg); |
| return 2; |
| } else if (format[1] == '4') { |
| VRR_E_Instruction* vrreinstr = reinterpret_cast<VRR_E_Instruction*>(instr); |
| int reg = vrreinstr->R4Value(); |
| PrintDRegister(reg); |
| return 2; |
| } |
| UNREACHABLE(); |
| } |
| |
| // 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 'o': { |
| if (instr->Bit(10) == 1) { |
| Print("o"); |
| } |
| return 1; |
| } |
| case '.': { |
| if (instr->Bit(0) == 1) { |
| Print("."); |
| } else { |
| Print(" "); // ensure consistent spacing |
| } |
| return 1; |
| } |
| case 'r': { |
| return FormatRegister(instr, format); |
| } |
| case 'f': { |
| return FormatFloatingRegister(instr, format); |
| } |
| case 'i': { // int16 |
| return FormatImmediate(instr, format); |
| } |
| case 'u': { // uint16 |
| int32_t value = instr->Bits(15, 0); |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "%d", value); |
| return 6; |
| } |
| case 'l': { |
| // Link (LK) Bit 0 |
| if (instr->Bit(0) == 1) { |
| Print("l"); |
| } |
| return 1; |
| } |
| case 'a': { |
| // Absolute Address Bit 1 |
| if (instr->Bit(1) == 1) { |
| Print("a"); |
| } |
| return 1; |
| } |
| case 't': { // 'target: target of branch instructions |
| // target26 or target16 |
| DCHECK(STRING_STARTS_WITH(format, "target")); |
| if ((format[6] == '2') && (format[7] == '6')) { |
| int off = ((instr->Bits(25, 2)) << 8) >> 6; |
| out_buffer_pos_ += SNPrintF( |
| out_buffer_ + out_buffer_pos_, "%+d -> %s", off, |
| converter_.NameOfAddress(reinterpret_cast<byte*>(instr) + off)); |
| return 8; |
| } else if ((format[6] == '1') && (format[7] == '6')) { |
| int off = ((instr->Bits(15, 2)) << 18) >> 16; |
| out_buffer_pos_ += SNPrintF( |
| out_buffer_ + out_buffer_pos_, "%+d -> %s", off, |
| converter_.NameOfAddress(reinterpret_cast<byte*>(instr) + off)); |
| return 8; |
| } |
| break; |
| case 'm': { |
| return FormatMask(instr, format); |
| } |
| } |
| case 'd': { // ds value for offset |
| return FormatDisplacement(instr, format); |
| } |
| default: { |
| UNREACHABLE(); |
| } |
| } |
| |
| UNREACHABLE(); |
| } |
| |
| int Decoder::FormatMask(Instruction* instr, const char* format) { |
| DCHECK_EQ(format[0], 'm'); |
| int32_t value = 0; |
| if ((format[1] == '1')) { // prints the mask format in bits 8-12 |
| value = reinterpret_cast<RRInstruction*>(instr)->R1Value(); |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "0x%x", value); |
| return 2; |
| } else if (format[1] == '2') { // mask format in bits 16-19 |
| value = reinterpret_cast<RXInstruction*>(instr)->B2Value(); |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "0x%x", value); |
| return 2; |
| } else if (format[1] == '3') { // mask format in bits 20-23 |
| value = reinterpret_cast<RRFInstruction*>(instr)->M4Value(); |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "0x%x", value); |
| return 2; |
| } else if (format[1] == '4') { // mask format in bits 32-35 |
| value = reinterpret_cast<VRR_C_Instruction*>(instr)->M4Value(); |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "0x%x", value); |
| return 2; |
| } else if (format[1] == '5') { // mask format in bits 28-31 |
| value = reinterpret_cast<VRR_C_Instruction*>(instr)->M5Value(); |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "0x%x", value); |
| return 2; |
| } else if (format[1] == '6') { // mask format in bits 24-27 |
| value = reinterpret_cast<VRR_C_Instruction*>(instr)->M6Value(); |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "0x%x", value); |
| return 2; |
| } |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "%d", value); |
| return 2; |
| } |
| |
| int Decoder::FormatDisplacement(Instruction* instr, const char* format) { |
| DCHECK_EQ(format[0], 'd'); |
| |
| if (format[1] == '1') { // displacement in 20-31 |
| RSInstruction* rsinstr = reinterpret_cast<RSInstruction*>(instr); |
| uint16_t value = rsinstr->D2Value(); |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "%d", value); |
| |
| return 2; |
| } else if (format[1] == '2') { // displacement in 20-39 |
| RXYInstruction* rxyinstr = reinterpret_cast<RXYInstruction*>(instr); |
| int32_t value = rxyinstr->D2Value(); |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "%d", value); |
| return 2; |
| } else if (format[1] == '4') { // SS displacement 2 36-47 |
| SSInstruction* ssInstr = reinterpret_cast<SSInstruction*>(instr); |
| uint16_t value = ssInstr->D2Value(); |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "%d", value); |
| return 2; |
| } else if (format[1] == '3') { // SS displacement 1 20 - 32 |
| SSInstruction* ssInstr = reinterpret_cast<SSInstruction*>(instr); |
| uint16_t value = ssInstr->D1Value(); |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "%d", value); |
| return 2; |
| } else { // s390 specific |
| int32_t value = SIGN_EXT_IMM16(instr->Bits(15, 0) & ~3); |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "%d", value); |
| return 1; |
| } |
| } |
| |
| int Decoder::FormatImmediate(Instruction* instr, const char* format) { |
| DCHECK_EQ(format[0], 'i'); |
| |
| if (format[1] == '1') { // immediate in 16-31 |
| RIInstruction* riinstr = reinterpret_cast<RIInstruction*>(instr); |
| int16_t value = riinstr->I2Value(); |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "%d", value); |
| return 2; |
| } else if (format[1] == '2') { // immediate in 16-48 |
| RILInstruction* rilinstr = reinterpret_cast<RILInstruction*>(instr); |
| int32_t value = rilinstr->I2Value(); |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "%d", value); |
| return 2; |
| } else if (format[1] == '3') { // immediate in I format |
| IInstruction* iinstr = reinterpret_cast<IInstruction*>(instr); |
| int8_t value = iinstr->IValue(); |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "%d", value); |
| return 2; |
| } else if (format[1] == '4') { // immediate in 16-31, but outputs as offset |
| RIInstruction* riinstr = reinterpret_cast<RIInstruction*>(instr); |
| int16_t value = riinstr->I2Value() * 2; |
| if (value >= 0) |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "*+"); |
| else |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "*"); |
| |
| out_buffer_pos_ += SNPrintF( |
| out_buffer_ + out_buffer_pos_, "%d -> %s", value, |
| converter_.NameOfAddress(reinterpret_cast<byte*>(instr) + value)); |
| return 2; |
| } else if (format[1] == '5') { // immediate in 16-31, but outputs as offset |
| RILInstruction* rilinstr = reinterpret_cast<RILInstruction*>(instr); |
| int32_t value = rilinstr->I2Value() * 2; |
| if (value >= 0) |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "*+"); |
| else |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "*"); |
| |
| out_buffer_pos_ += SNPrintF( |
| out_buffer_ + out_buffer_pos_, "%d -> %s", value, |
| converter_.NameOfAddress(reinterpret_cast<byte*>(instr) + value)); |
| return 2; |
| } else if (format[1] == '6') { // unsigned immediate in 16-31 |
| RIInstruction* riinstr = reinterpret_cast<RIInstruction*>(instr); |
| uint16_t value = riinstr->I2UnsignedValue(); |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "%d", value); |
| return 2; |
| } else if (format[1] == '7') { // unsigned immediate in 16-47 |
| RILInstruction* rilinstr = reinterpret_cast<RILInstruction*>(instr); |
| uint32_t value = rilinstr->I2UnsignedValue(); |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "%d", value); |
| return 2; |
| } else if (format[1] == '8') { // unsigned immediate in 8-15 |
| SSInstruction* ssinstr = reinterpret_cast<SSInstruction*>(instr); |
| uint8_t value = ssinstr->Length(); |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "%d", value); |
| return 2; |
| } else if (format[1] == '9') { // unsigned immediate in 16-23 |
| RIEInstruction* rie_instr = reinterpret_cast<RIEInstruction*>(instr); |
| uint8_t value = rie_instr->I3Value(); |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "%d", value); |
| return 2; |
| } else if (format[1] == 'a') { // unsigned immediate in 24-31 |
| RIEInstruction* rie_instr = reinterpret_cast<RIEInstruction*>(instr); |
| uint8_t value = rie_instr->I4Value(); |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "%d", value); |
| return 2; |
| } else if (format[1] == 'b') { // unsigned immediate in 32-39 |
| RIEInstruction* rie_instr = reinterpret_cast<RIEInstruction*>(instr); |
| uint8_t value = rie_instr->I5Value(); |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "%d", value); |
| return 2; |
| } else if (format[1] == 'c') { // signed immediate in 8-15 |
| SSInstruction* ssinstr = reinterpret_cast<SSInstruction*>(instr); |
| int8_t value = ssinstr->Length(); |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "%d", value); |
| return 2; |
| } else if (format[1] == 'd') { // signed immediate in 32-47 |
| SILInstruction* silinstr = reinterpret_cast<SILInstruction*>(instr); |
| int16_t value = silinstr->I2Value(); |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "%d", value); |
| return 2; |
| } else if (format[1] == 'e') { // immediate in 16-47, but outputs as offset |
| RILInstruction* rilinstr = reinterpret_cast<RILInstruction*>(instr); |
| int32_t value = rilinstr->I2Value() * 2; |
| if (value >= 0) |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "*+"); |
| else |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "*"); |
| |
| out_buffer_pos_ += SNPrintF( |
| out_buffer_ + out_buffer_pos_, "%d -> %s", value, |
| converter_.NameOfAddress(reinterpret_cast<byte*>(instr) + value)); |
| return 2; |
| } |
| |
| UNREACHABLE(); |
| } |
| |
| // 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'; |
| } |
| |
| // The disassembler may end up decoding data inlined in the code. We do not want |
| // it to crash if the data does not resemble any known instruction. |
| #define VERIFY(condition) \ |
| if (!(condition)) { \ |
| Unknown(instr); \ |
| return; \ |
| } |
| |
| // 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"); } |
| |
| // For currently unimplemented decodings the disassembler calls |
| // UnknownFormat(instr) which will just print opcode name of the |
| // instruction bits. |
| void Decoder::UnknownFormat(Instruction* instr, const char* name) { |
| char buffer[100]; |
| snprintf(buffer, sizeof(buffer), "%s (unknown-format)", name); |
| Format(instr, buffer); |
| } |
| |
| #undef VERIFY |
| #undef STRING_STARTS_WITH |
| |
| // Handles special cases of instructions; |
| // @return true if successfully decoded |
| bool Decoder::DecodeSpecial(Instruction* instr) { |
| Opcode opcode = instr->S390OpcodeValue(); |
| switch (opcode) { |
| case BKPT: |
| Format(instr, "bkpt"); |
| break; |
| case DUMY: |
| Format(instr, "dumy\t'r1, 'd2 ( 'r2d, 'r3 )"); |
| break; |
| /* RR format */ |
| case LDR: |
| Format(instr, "ldr\t'f1,'f2"); |
| break; |
| case BCR: |
| Format(instr, "bcr\t'm1,'r2"); |
| break; |
| case OR: |
| Format(instr, "or\t'r1,'r2"); |
| break; |
| case CR: |
| Format(instr, "cr\t'r1,'r2"); |
| break; |
| case MR: |
| Format(instr, "mr\t'r1,'r2"); |
| break; |
| case HER_Z: |
| Format(instr, "her\t'r1,'r2"); |
| break; |
| /* RI-b format */ |
| case BRAS: |
| Format(instr, "bras\t'r1,'i1"); |
| break; |
| /* RRE format */ |
| case MDBR: |
| Format(instr, "mdbr\t'f5,'f6"); |
| break; |
| case SDBR: |
| Format(instr, "sdbr\t'f5,'f6"); |
| break; |
| case ADBR: |
| Format(instr, "adbr\t'f5,'f6"); |
| break; |
| case CDBR: |
| Format(instr, "cdbr\t'f5,'f6"); |
| break; |
| case MEEBR: |
| Format(instr, "meebr\t'f5,'f6"); |
| break; |
| case SQDBR: |
| Format(instr, "sqdbr\t'f5,'f6"); |
| break; |
| case SQEBR: |
| Format(instr, "sqebr\t'f5,'f6"); |
| break; |
| case LCDBR: |
| Format(instr, "lcdbr\t'f5,'f6"); |
| break; |
| case LCEBR: |
| Format(instr, "lcebr\t'f5,'f6"); |
| break; |
| case LTEBR: |
| Format(instr, "ltebr\t'f5,'f6"); |
| break; |
| case LDEBR: |
| Format(instr, "ldebr\t'f5,'f6"); |
| break; |
| case CEBR: |
| Format(instr, "cebr\t'f5,'f6"); |
| break; |
| case AEBR: |
| Format(instr, "aebr\t'f5,'f6"); |
| break; |
| case SEBR: |
| Format(instr, "sebr\t'f5,'f6"); |
| break; |
| case DEBR: |
| Format(instr, "debr\t'f5,'f6"); |
| break; |
| case LTDBR: |
| Format(instr, "ltdbr\t'f5,'f6"); |
| break; |
| case LDGR: |
| Format(instr, "ldgr\t'f5,'f6"); |
| break; |
| case DDBR: |
| Format(instr, "ddbr\t'f5,'f6"); |
| break; |
| case LZDR: |
| Format(instr, "lzdr\t'f5"); |
| break; |
| /* RRF-e format */ |
| case FIEBRA: |
| Format(instr, "fiebra\t'f5,'m2,'f6,'m3"); |
| break; |
| case FIDBRA: |
| Format(instr, "fidbra\t'f5,'m2,'f6,'m3"); |
| break; |
| /* RX-a format */ |
| case IC_z: |
| Format(instr, "ic\t'r1,'d1('r2d,'r3)"); |
| break; |
| case AL: |
| Format(instr, "al\t'r1,'d1('r2d,'r3)"); |
| break; |
| case LE: |
| Format(instr, "le\t'f1,'d1('r2d,'r3)"); |
| break; |
| case LD: |
| Format(instr, "ld\t'f1,'d1('r2d,'r3)"); |
| break; |
| case STE: |
| Format(instr, "ste\t'f1,'d1('r2d,'r3)"); |
| break; |
| case STD: |
| Format(instr, "std\t'f1,'d1('r2d,'r3)"); |
| break; |
| /* S format */ |
| // TRAP4 is used in calling to native function. it will not be generated |
| // in native code. |
| case TRAP4: |
| Format(instr, "trap4"); |
| break; |
| /* RIL-a format */ |
| case CFI: |
| Format(instr, "cfi\t'r1,'i2"); |
| break; |
| case CGFI: |
| Format(instr, "cgfi\t'r1,'i2"); |
| break; |
| case AFI: |
| Format(instr, "afi\t'r1,'i2"); |
| break; |
| case AGFI: |
| Format(instr, "agfi\t'r1,'i2"); |
| break; |
| case MSFI: |
| Format(instr, "msfi\t'r1,'i2"); |
| break; |
| case MSGFI: |
| Format(instr, "msgfi\t'r1,'i2"); |
| break; |
| case ALSIH: |
| Format(instr, "alsih\t'r1,'i2"); |
| break; |
| case ALSIHN: |
| Format(instr, "alsihn\t'r1,'i2"); |
| break; |
| case CIH: |
| Format(instr, "cih\t'r1,'i2"); |
| break; |
| case AIH: |
| Format(instr, "aih\t'r1,'i2"); |
| break; |
| case LGFI: |
| Format(instr, "lgfi\t'r1,'i2"); |
| break; |
| /* SIY format */ |
| case ASI: |
| Format(instr, "asi\t'd2('r3),'ic"); |
| break; |
| case AGSI: |
| Format(instr, "agsi\t'd2('r3),'ic"); |
| break; |
| /* RXY-a format */ |
| case LT: |
| Format(instr, "lt\t'r1,'d2('r2d,'r3)"); |
| break; |
| case LDY: |
| Format(instr, "ldy\t'f1,'d2('r2d,'r3)"); |
| break; |
| case LEY: |
| Format(instr, "ley\t'f1,'d2('r2d,'r3)"); |
| break; |
| case STDY: |
| Format(instr, "stdy\t'f1,'d2('r2d,'r3)"); |
| break; |
| case STEY: |
| Format(instr, "stey\t'f1,'d2('r2d,'r3)"); |
| break; |
| /* RXE format */ |
| case LDEB: |
| Format(instr, "ldeb\t'f1,'d2('r2d,'r3)"); |
| break; |
| default: |
| return false; |
| } |
| return true; |
| } |
| |
| // Handles common cases of instructions; |
| // @return true if successfully decoded |
| bool Decoder::DecodeGeneric(Instruction* instr) { |
| Opcode opcode = instr->S390OpcodeValue(); |
| switch (opcode) { |
| /* 2 bytes */ |
| #define DECODE_RR_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'r1,'r2"); \ |
| break; |
| S390_RR_OPCODE_LIST(DECODE_RR_INSTRUCTIONS) |
| #undef DECODE_RR_INSTRUCTIONS |
| |
| /* 4 bytes */ |
| #define DECODE_RS_A_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'r1,'r2,'d1('r3)"); \ |
| break; |
| S390_RS_A_OPCODE_LIST(DECODE_RS_A_INSTRUCTIONS) |
| #undef DECODE_RS_A_INSTRUCTIONS |
| |
| #define DECODE_RSI_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'r1,'r2,'i4"); \ |
| break; |
| S390_RSI_OPCODE_LIST(DECODE_RSI_INSTRUCTIONS) |
| #undef DECODE_RSI_INSTRUCTIONS |
| |
| #define DECODE_RI_A_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'r1,'i1"); \ |
| break; |
| S390_RI_A_OPCODE_LIST(DECODE_RI_A_INSTRUCTIONS) |
| #undef DECODE_RI_A_INSTRUCTIONS |
| |
| #define DECODE_RI_B_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'r1,'i4"); \ |
| break; |
| S390_RI_B_OPCODE_LIST(DECODE_RI_B_INSTRUCTIONS) |
| #undef DECODE_RI_B_INSTRUCTIONS |
| |
| #define DECODE_RI_C_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'm1,'i4"); \ |
| break; |
| S390_RI_C_OPCODE_LIST(DECODE_RI_C_INSTRUCTIONS) |
| #undef DECODE_RI_C_INSTRUCTIONS |
| |
| #define DECODE_RRE_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'r5,'r6"); \ |
| break; |
| S390_RRE_OPCODE_LIST(DECODE_RRE_INSTRUCTIONS) |
| #undef DECODE_RRE_INSTRUCTIONS |
| |
| #define DECODE_RRF_A_INSTRUCTIONS(name, opcode_name, opcode_val) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'r5,'r6,'r3"); \ |
| break; |
| S390_RRF_A_OPCODE_LIST(DECODE_RRF_A_INSTRUCTIONS) |
| #undef DECODE_RRF_A_INSTRUCTIONS |
| |
| #define DECODE_RRF_C_INSTRUCTIONS(name, opcode_name, opcode_val) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'r5,'r6,'m2"); \ |
| break; |
| S390_RRF_C_OPCODE_LIST(DECODE_RRF_C_INSTRUCTIONS) |
| #undef DECODE_RRF_C_INSTRUCTIONS |
| |
| #define DECODE_RRF_E_INSTRUCTIONS(name, opcode_name, opcode_val) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'r5,'m2,'f6"); \ |
| break; |
| S390_RRF_E_OPCODE_LIST(DECODE_RRF_E_INSTRUCTIONS) |
| #undef DECODE_RRF_E_INSTRUCTIONS |
| |
| #define DECODE_RX_A_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'r1,'d1('r2d,'r3)"); \ |
| break; |
| S390_RX_A_OPCODE_LIST(DECODE_RX_A_INSTRUCTIONS) |
| #undef DECODE_RX_A_INSTRUCTIONS |
| |
| #define DECODE_RX_B_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'm1,'d1('r2d,'r3)"); \ |
| break; |
| S390_RX_B_OPCODE_LIST(DECODE_RX_B_INSTRUCTIONS) |
| #undef DECODE_RX_B_INSTRUCTIONS |
| |
| #define DECODE_RRD_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'f3,'f5,'f6"); \ |
| break; |
| S390_RRD_OPCODE_LIST(DECODE_RRD_INSTRUCTIONS) |
| #undef DECODE_RRD_INSTRUCTIONS |
| |
| #define DECODE_SI_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'd1('r3),'i8"); \ |
| break; |
| S390_SI_OPCODE_LIST(DECODE_SI_INSTRUCTIONS) |
| #undef DECODE_SI_INSTRUCTIONS |
| |
| /* 6 bytes */ |
| #define DECODE_VRR_A_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'f1,'f2,'m4,'m5,'m6"); \ |
| break; |
| S390_VRR_A_OPCODE_LIST(DECODE_VRR_A_INSTRUCTIONS) |
| #undef DECODE_VRR_A_INSTRUCTIONS |
| |
| #define DECODE_VRR_B_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'f1,'f2,'f3,'m4,'m6"); \ |
| break; |
| S390_VRR_B_OPCODE_LIST(DECODE_VRR_B_INSTRUCTIONS) |
| #undef DECODE_VRR_B_INSTRUCTIONS |
| |
| #define DECODE_VRR_C_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'f1,'f2,'f3,'m4"); \ |
| break; |
| S390_VRR_C_OPCODE_LIST(DECODE_VRR_C_INSTRUCTIONS) |
| #undef DECODE_VRR_C_INSTRUCTIONS |
| |
| #define DECODE_VRR_E_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'f1,'f2,'f3,'f4,'m5,'m3"); \ |
| break; |
| S390_VRR_E_OPCODE_LIST(DECODE_VRR_E_INSTRUCTIONS) |
| #undef DECODE_VRR_E_INSTRUCTIONS |
| |
| #define DECODE_VRR_F_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'f1,'r1,'r2"); \ |
| break; |
| S390_VRR_F_OPCODE_LIST(DECODE_VRR_F_INSTRUCTIONS) |
| #undef DECODE_VRR_F_INSTRUCTIONS |
| |
| #define DECODE_VRX_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'f1,'d1('r2d,'r3),'m4"); \ |
| break; |
| S390_VRX_OPCODE_LIST(DECODE_VRX_INSTRUCTIONS) |
| #undef DECODE_VRX_INSTRUCTIONS |
| |
| #define DECODE_VRS_A_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'f1,'f2,'d1('r3),'m4"); \ |
| break; |
| S390_VRS_A_OPCODE_LIST(DECODE_VRS_A_INSTRUCTIONS) |
| #undef DECODE_VRS_A_INSTRUCTIONS |
| |
| #define DECODE_VRS_B_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'f1,'r2,'d1('r3),'m4"); \ |
| break; |
| S390_VRS_B_OPCODE_LIST(DECODE_VRS_B_INSTRUCTIONS) |
| #undef DECODE_VRS_B_INSTRUCTIONS |
| |
| #define DECODE_VRS_C_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'r1,'f2,'d1('r3),'m4"); \ |
| break; |
| S390_VRS_C_OPCODE_LIST(DECODE_VRS_C_INSTRUCTIONS) |
| #undef DECODE_VRS_C_INSTRUCTIONS |
| |
| #define DECODE_VRI_A_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'f1,'i1,'m4"); \ |
| break; |
| S390_VRI_A_OPCODE_LIST(DECODE_VRI_A_INSTRUCTIONS) |
| #undef DECODE_VRI_A_INSTRUCTIONS |
| |
| #define DECODE_VRI_C_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'f1,'f2,'i1,'m4"); \ |
| break; |
| S390_VRI_C_OPCODE_LIST(DECODE_VRI_C_INSTRUCTIONS) |
| #undef DECODE_VRI_C_INSTRUCTIONS |
| |
| #define DECODE_RIL_A_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'r1,'i7"); \ |
| break; |
| S390_RIL_A_OPCODE_LIST(DECODE_RIL_A_INSTRUCTIONS) |
| #undef DECODE_RIL_A_INSTRUCTIONS |
| |
| #define DECODE_RIL_B_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'r1,'ie"); \ |
| break; |
| S390_RIL_B_OPCODE_LIST(DECODE_RIL_B_INSTRUCTIONS) |
| #undef DECODE_RIL_B_INSTRUCTIONS |
| |
| #define DECODE_RIL_C_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'm1,'ie"); \ |
| break; |
| S390_RIL_C_OPCODE_LIST(DECODE_RIL_C_INSTRUCTIONS) |
| #undef DECODE_RIL_C_INSTRUCTIONS |
| |
| #define DECODE_SIY_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'd2('r3),'i8"); \ |
| break; |
| S390_SIY_OPCODE_LIST(DECODE_SIY_INSTRUCTIONS) |
| #undef DECODE_SIY_INSTRUCTIONS |
| |
| #define DECODE_RIE_D_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'r1,'r2,'i1"); \ |
| break; |
| S390_RIE_D_OPCODE_LIST(DECODE_RIE_D_INSTRUCTIONS) |
| #undef DECODE_RIE_D_INSTRUCTIONS |
| |
| #define DECODE_RIE_E_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'r1,'r2,'i4"); \ |
| break; |
| S390_RIE_E_OPCODE_LIST(DECODE_RIE_E_INSTRUCTIONS) |
| #undef DECODE_RIE_E_INSTRUCTIONS |
| |
| #define DECODE_RIE_F_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'r1,'r2,'i9,'ia,'ib"); \ |
| break; |
| S390_RIE_F_OPCODE_LIST(DECODE_RIE_F_INSTRUCTIONS) |
| #undef DECODE_RIE_F_INSTRUCTIONS |
| |
| #define DECODE_RSY_A_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'r1,'r2,'d2('r3)"); \ |
| break; |
| S390_RSY_A_OPCODE_LIST(DECODE_RSY_A_INSTRUCTIONS) |
| #undef DECODE_RSY_A_INSTRUCTIONS |
| |
| #define DECODE_RSY_B_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'm2,'r1,'d2('r3)"); \ |
| break; |
| S390_RSY_B_OPCODE_LIST(DECODE_RSY_B_INSTRUCTIONS) |
| #undef DECODE_RSY_B_INSTRUCTIONS |
| |
| #define DECODE_RXY_A_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'r1,'d2('r2d,'r3)"); \ |
| break; |
| S390_RXY_A_OPCODE_LIST(DECODE_RXY_A_INSTRUCTIONS) |
| #undef DECODE_RXY_A_INSTRUCTIONS |
| |
| #define DECODE_RXY_B_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'm1,'d2('r2d,'r3)"); \ |
| break; |
| S390_RXY_B_OPCODE_LIST(DECODE_RXY_B_INSTRUCTIONS) |
| #undef DECODE_RXY_B_INSTRUCTIONS |
| |
| #define DECODE_RXE_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'f1,'d1('r2d, 'r3)"); \ |
| break; |
| S390_RXE_OPCODE_LIST(DECODE_RXE_INSTRUCTIONS) |
| #undef DECODE_RXE_INSTRUCTIONS |
| |
| #define DECODE_SIL_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'd3('r3),'id"); \ |
| break; |
| S390_SIL_OPCODE_LIST(DECODE_SIL_INSTRUCTIONS) |
| #undef DECODE_SIL_INSTRUCTIONS |
| |
| #define DECODE_SS_A_INSTRUCTIONS(name, opcode_name, opcode_value) \ |
| case opcode_name: \ |
| Format(instr, #name "\t'd3('i8,'r3),'d4('r7)"); \ |
| break; |
| S390_SS_A_OPCODE_LIST(DECODE_SS_A_INSTRUCTIONS) |
| #undef DECODE_SS_A_INSTRUCTIONS |
| |
| default: |
| return false; |
| } |
| return true; |
| } |
| |
| // Disassemble the instruction at *instr_ptr into the output buffer. |
| int Decoder::InstructionDecode(byte* instr_ptr) { |
| Instruction* instr = Instruction::At(instr_ptr); |
| int instrLength = instr->InstructionLength(); |
| |
| // Print the Instruction bits. |
| if (instrLength == 2) { |
| out_buffer_pos_ += |
| SNPrintF(out_buffer_ + out_buffer_pos_, "%04x ", |
| instr->InstructionBits<TwoByteInstr>()); |
| } else if (instrLength == 4) { |
| out_buffer_pos_ += SNPrintF(out_buffer_ + out_buffer_pos_, "%08x ", |
| instr->InstructionBits<FourByteInstr>()); |
| } else { |
| out_buffer_pos_ += |
| SNPrintF(out_buffer_ + out_buffer_pos_, "%012" PRIx64 " ", |
| instr->InstructionBits<SixByteInstr>()); |
| } |
| |
| bool decoded = DecodeSpecial(instr); |
| if (!decoded) decoded = DecodeGeneric(instr); |
| if (!decoded) Unknown(instr); |
| return instrLength; |
| } |
| |
| } // namespace internal |
| } // namespace v8 |
| |
| //------------------------------------------------------------------------------ |
| |
| namespace disasm { |
| |
| const char* NameConverter::NameOfAddress(byte* addr) const { |
| v8::internal::SNPrintF(tmp_buffer_, "%p", static_cast<void*>(addr)); |
| return tmp_buffer_.begin(); |
| } |
| |
| const char* NameConverter::NameOfConstant(byte* addr) const { |
| return NameOfAddress(addr); |
| } |
| |
| const char* NameConverter::NameOfCPURegister(int reg) const { |
| return RegisterName(i::Register::from_code(reg)); |
| } |
| |
| const char* NameConverter::NameOfByteCPURegister(int reg) const { |
| UNREACHABLE(); // S390 does not have the concept of a byte register |
| } |
| |
| const char* NameConverter::NameOfXMMRegister(int reg) const { |
| // S390 does not have XMM register |
| // TODO(joransiu): Consider update this for Vector Regs |
| UNREACHABLE(); |
| } |
| |
| 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 ""; |
| } |
| |
| //------------------------------------------------------------------------------ |
| |
| int Disassembler::InstructionDecode(v8::internal::Vector<char> buffer, |
| byte* instruction) { |
| v8::internal::Decoder d(converter_, buffer); |
| return d.InstructionDecode(instruction); |
| } |
| |
| // The S390 assembler does not currently use constant pools. |
| int Disassembler::ConstantPoolSizeAt(byte* instruction) { return -1; } |
| |
| void Disassembler::Disassemble(FILE* f, byte* begin, byte* end, |
| UnimplementedOpcodeAction unimplemented_action) { |
| NameConverter converter; |
| Disassembler d(converter, unimplemented_action); |
| for (byte* pc = begin; pc < end;) { |
| v8::internal::EmbeddedVector<char, 128> buffer; |
| buffer[0] = '\0'; |
| byte* prev_pc = pc; |
| pc += d.InstructionDecode(buffer, pc); |
| v8::internal::PrintF(f, "%p %08x %s\n", static_cast<void*>(prev_pc), |
| *reinterpret_cast<int32_t*>(prev_pc), buffer.begin()); |
| } |
| } |
| |
| } // namespace disasm |
| |
| #endif // V8_TARGET_ARCH_S390 |