| Index: src/a64/simulator-a64.cc
|
| diff --git a/src/a64/simulator-a64.cc b/src/a64/simulator-a64.cc
|
| deleted file mode 100644
|
| index 51650cf08192adf88b74b1bd48ee951157a6a464..0000000000000000000000000000000000000000
|
| --- a/src/a64/simulator-a64.cc
|
| +++ /dev/null
|
| @@ -1,3646 +0,0 @@
|
| -// Copyright 2013 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.
|
| -
|
| -#include <stdlib.h>
|
| -#include <cmath>
|
| -#include <cstdarg>
|
| -#include "v8.h"
|
| -
|
| -#if V8_TARGET_ARCH_A64
|
| -
|
| -#include "disasm.h"
|
| -#include "assembler.h"
|
| -#include "a64/decoder-a64-inl.h"
|
| -#include "a64/simulator-a64.h"
|
| -#include "macro-assembler.h"
|
| -
|
| -namespace v8 {
|
| -namespace internal {
|
| -
|
| -#if defined(USE_SIMULATOR)
|
| -
|
| -
|
| -// This macro provides a platform independent use of sscanf. The reason for
|
| -// SScanF not being implemented in a platform independent way through
|
| -// ::v8::internal::OS in the same way as SNPrintF is that the
|
| -// Windows C Run-Time Library does not provide vsscanf.
|
| -#define SScanF sscanf // NOLINT
|
| -
|
| -
|
| -// Helpers for colors.
|
| -// Depending on your terminal configuration, the colour names may not match the
|
| -// observed colours.
|
| -#define COLOUR(colour_code) "\033[" colour_code "m"
|
| -#define BOLD(colour_code) "1;" colour_code
|
| -#define NORMAL ""
|
| -#define GREY "30"
|
| -#define GREEN "32"
|
| -#define ORANGE "33"
|
| -#define BLUE "34"
|
| -#define PURPLE "35"
|
| -#define INDIGO "36"
|
| -#define WHITE "37"
|
| -typedef char const * const TEXT_COLOUR;
|
| -TEXT_COLOUR clr_normal = FLAG_log_colour ? COLOUR(NORMAL) : "";
|
| -TEXT_COLOUR clr_flag_name = FLAG_log_colour ? COLOUR(BOLD(GREY)) : "";
|
| -TEXT_COLOUR clr_flag_value = FLAG_log_colour ? COLOUR(BOLD(WHITE)) : "";
|
| -TEXT_COLOUR clr_reg_name = FLAG_log_colour ? COLOUR(BOLD(BLUE)) : "";
|
| -TEXT_COLOUR clr_reg_value = FLAG_log_colour ? COLOUR(BOLD(INDIGO)) : "";
|
| -TEXT_COLOUR clr_fpreg_name = FLAG_log_colour ? COLOUR(BOLD(ORANGE)) : "";
|
| -TEXT_COLOUR clr_fpreg_value = FLAG_log_colour ? COLOUR(BOLD(PURPLE)) : "";
|
| -TEXT_COLOUR clr_memory_value = FLAG_log_colour ? COLOUR(BOLD(GREEN)) : "";
|
| -TEXT_COLOUR clr_memory_address = FLAG_log_colour ? COLOUR(GREEN) : "";
|
| -TEXT_COLOUR clr_debug_number = FLAG_log_colour ? COLOUR(BOLD(ORANGE)) : "";
|
| -TEXT_COLOUR clr_debug_message = FLAG_log_colour ? COLOUR(ORANGE) : "";
|
| -TEXT_COLOUR clr_printf = FLAG_log_colour ? COLOUR(GREEN) : "";
|
| -
|
| -
|
| -// This is basically the same as PrintF, with a guard for FLAG_trace_sim.
|
| -void PRINTF_CHECKING TraceSim(const char* format, ...) {
|
| - if (FLAG_trace_sim) {
|
| - va_list arguments;
|
| - va_start(arguments, format);
|
| - OS::VPrint(format, arguments);
|
| - va_end(arguments);
|
| - }
|
| -}
|
| -
|
| -
|
| -const Instruction* Simulator::kEndOfSimAddress = NULL;
|
| -
|
| -
|
| -void SimSystemRegister::SetBits(int msb, int lsb, uint32_t bits) {
|
| - int width = msb - lsb + 1;
|
| - ASSERT(is_uintn(bits, width) || is_intn(bits, width));
|
| -
|
| - bits <<= lsb;
|
| - uint32_t mask = ((1 << width) - 1) << lsb;
|
| - ASSERT((mask & write_ignore_mask_) == 0);
|
| -
|
| - value_ = (value_ & ~mask) | (bits & mask);
|
| -}
|
| -
|
| -
|
| -SimSystemRegister SimSystemRegister::DefaultValueFor(SystemRegister id) {
|
| - switch (id) {
|
| - case NZCV:
|
| - return SimSystemRegister(0x00000000, NZCVWriteIgnoreMask);
|
| - case FPCR:
|
| - return SimSystemRegister(0x00000000, FPCRWriteIgnoreMask);
|
| - default:
|
| - UNREACHABLE();
|
| - return SimSystemRegister();
|
| - }
|
| -}
|
| -
|
| -
|
| -void Simulator::Initialize(Isolate* isolate) {
|
| - if (isolate->simulator_initialized()) return;
|
| - isolate->set_simulator_initialized(true);
|
| - ExternalReference::set_redirector(isolate, &RedirectExternalReference);
|
| -}
|
| -
|
| -
|
| -// Get the active Simulator for the current thread.
|
| -Simulator* Simulator::current(Isolate* isolate) {
|
| - Isolate::PerIsolateThreadData* isolate_data =
|
| - isolate->FindOrAllocatePerThreadDataForThisThread();
|
| - ASSERT(isolate_data != NULL);
|
| -
|
| - Simulator* sim = isolate_data->simulator();
|
| - if (sim == NULL) {
|
| - if (FLAG_trace_sim || FLAG_log_instruction_stats || FLAG_debug_sim) {
|
| - sim = new Simulator(new Decoder<DispatchingDecoderVisitor>(), isolate);
|
| - } else {
|
| - sim = new Decoder<Simulator>();
|
| - sim->isolate_ = isolate;
|
| - }
|
| - isolate_data->set_simulator(sim);
|
| - }
|
| - return sim;
|
| -}
|
| -
|
| -
|
| -void Simulator::CallVoid(byte* entry, CallArgument* args) {
|
| - int index_x = 0;
|
| - int index_d = 0;
|
| -
|
| - std::vector<int64_t> stack_args(0);
|
| - for (int i = 0; !args[i].IsEnd(); i++) {
|
| - CallArgument arg = args[i];
|
| - if (arg.IsX() && (index_x < 8)) {
|
| - set_xreg(index_x++, arg.bits());
|
| - } else if (arg.IsD() && (index_d < 8)) {
|
| - set_dreg_bits(index_d++, arg.bits());
|
| - } else {
|
| - ASSERT(arg.IsD() || arg.IsX());
|
| - stack_args.push_back(arg.bits());
|
| - }
|
| - }
|
| -
|
| - // Process stack arguments, and make sure the stack is suitably aligned.
|
| - uintptr_t original_stack = sp();
|
| - uintptr_t entry_stack = original_stack -
|
| - stack_args.size() * sizeof(stack_args[0]);
|
| - if (OS::ActivationFrameAlignment() != 0) {
|
| - entry_stack &= -OS::ActivationFrameAlignment();
|
| - }
|
| - char * stack = reinterpret_cast<char*>(entry_stack);
|
| - std::vector<int64_t>::const_iterator it;
|
| - for (it = stack_args.begin(); it != stack_args.end(); it++) {
|
| - memcpy(stack, &(*it), sizeof(*it));
|
| - stack += sizeof(*it);
|
| - }
|
| -
|
| - ASSERT(reinterpret_cast<uintptr_t>(stack) <= original_stack);
|
| - set_sp(entry_stack);
|
| -
|
| - // Call the generated code.
|
| - set_pc(entry);
|
| - set_lr(kEndOfSimAddress);
|
| - CheckPCSComplianceAndRun();
|
| -
|
| - set_sp(original_stack);
|
| -}
|
| -
|
| -
|
| -int64_t Simulator::CallInt64(byte* entry, CallArgument* args) {
|
| - CallVoid(entry, args);
|
| - return xreg(0);
|
| -}
|
| -
|
| -
|
| -double Simulator::CallDouble(byte* entry, CallArgument* args) {
|
| - CallVoid(entry, args);
|
| - return dreg(0);
|
| -}
|
| -
|
| -
|
| -int64_t Simulator::CallJS(byte* entry,
|
| - byte* function_entry,
|
| - JSFunction* func,
|
| - Object* revc,
|
| - int64_t argc,
|
| - Object*** argv) {
|
| - CallArgument args[] = {
|
| - CallArgument(function_entry),
|
| - CallArgument(func),
|
| - CallArgument(revc),
|
| - CallArgument(argc),
|
| - CallArgument(argv),
|
| - CallArgument::End()
|
| - };
|
| - return CallInt64(entry, args);
|
| -}
|
| -
|
| -int64_t Simulator::CallRegExp(byte* entry,
|
| - String* input,
|
| - int64_t start_offset,
|
| - const byte* input_start,
|
| - const byte* input_end,
|
| - int* output,
|
| - int64_t output_size,
|
| - Address stack_base,
|
| - int64_t direct_call,
|
| - void* return_address,
|
| - Isolate* isolate) {
|
| - CallArgument args[] = {
|
| - CallArgument(input),
|
| - CallArgument(start_offset),
|
| - CallArgument(input_start),
|
| - CallArgument(input_end),
|
| - CallArgument(output),
|
| - CallArgument(output_size),
|
| - CallArgument(stack_base),
|
| - CallArgument(direct_call),
|
| - CallArgument(return_address),
|
| - CallArgument(isolate),
|
| - CallArgument::End()
|
| - };
|
| - return CallInt64(entry, args);
|
| -}
|
| -
|
| -
|
| -void Simulator::CheckPCSComplianceAndRun() {
|
| -#ifdef DEBUG
|
| - CHECK_EQ(kNumberOfCalleeSavedRegisters, kCalleeSaved.Count());
|
| - CHECK_EQ(kNumberOfCalleeSavedFPRegisters, kCalleeSavedFP.Count());
|
| -
|
| - int64_t saved_registers[kNumberOfCalleeSavedRegisters];
|
| - uint64_t saved_fpregisters[kNumberOfCalleeSavedFPRegisters];
|
| -
|
| - CPURegList register_list = kCalleeSaved;
|
| - CPURegList fpregister_list = kCalleeSavedFP;
|
| -
|
| - for (int i = 0; i < kNumberOfCalleeSavedRegisters; i++) {
|
| - // x31 is not a caller saved register, so no need to specify if we want
|
| - // the stack or zero.
|
| - saved_registers[i] = xreg(register_list.PopLowestIndex().code());
|
| - }
|
| - for (int i = 0; i < kNumberOfCalleeSavedFPRegisters; i++) {
|
| - saved_fpregisters[i] =
|
| - dreg_bits(fpregister_list.PopLowestIndex().code());
|
| - }
|
| - int64_t original_stack = sp();
|
| -#endif
|
| - // Start the simulation!
|
| - Run();
|
| -#ifdef DEBUG
|
| - CHECK_EQ(original_stack, sp());
|
| - // Check that callee-saved registers have been preserved.
|
| - register_list = kCalleeSaved;
|
| - fpregister_list = kCalleeSavedFP;
|
| - for (int i = 0; i < kNumberOfCalleeSavedRegisters; i++) {
|
| - CHECK_EQ(saved_registers[i], xreg(register_list.PopLowestIndex().code()));
|
| - }
|
| - for (int i = 0; i < kNumberOfCalleeSavedFPRegisters; i++) {
|
| - ASSERT(saved_fpregisters[i] ==
|
| - dreg_bits(fpregister_list.PopLowestIndex().code()));
|
| - }
|
| -
|
| - // Corrupt caller saved register minus the return regiters.
|
| -
|
| - // In theory x0 to x7 can be used for return values, but V8 only uses x0, x1
|
| - // for now .
|
| - register_list = kCallerSaved;
|
| - register_list.Remove(x0);
|
| - register_list.Remove(x1);
|
| -
|
| - // In theory d0 to d7 can be used for return values, but V8 only uses d0
|
| - // for now .
|
| - fpregister_list = kCallerSavedFP;
|
| - fpregister_list.Remove(d0);
|
| -
|
| - CorruptRegisters(®ister_list, kCallerSavedRegisterCorruptionValue);
|
| - CorruptRegisters(&fpregister_list, kCallerSavedFPRegisterCorruptionValue);
|
| -#endif
|
| -}
|
| -
|
| -
|
| -#ifdef DEBUG
|
| -// The least significant byte of the curruption value holds the corresponding
|
| -// register's code.
|
| -void Simulator::CorruptRegisters(CPURegList* list, uint64_t value) {
|
| - if (list->type() == CPURegister::kRegister) {
|
| - while (!list->IsEmpty()) {
|
| - unsigned code = list->PopLowestIndex().code();
|
| - set_xreg(code, value | code);
|
| - }
|
| - } else {
|
| - ASSERT(list->type() == CPURegister::kFPRegister);
|
| - while (!list->IsEmpty()) {
|
| - unsigned code = list->PopLowestIndex().code();
|
| - set_dreg_bits(code, value | code);
|
| - }
|
| - }
|
| -}
|
| -
|
| -
|
| -void Simulator::CorruptAllCallerSavedCPURegisters() {
|
| - // Corrupt alters its parameter so copy them first.
|
| - CPURegList register_list = kCallerSaved;
|
| - CPURegList fpregister_list = kCallerSavedFP;
|
| -
|
| - CorruptRegisters(®ister_list, kCallerSavedRegisterCorruptionValue);
|
| - CorruptRegisters(&fpregister_list, kCallerSavedFPRegisterCorruptionValue);
|
| -}
|
| -#endif
|
| -
|
| -
|
| -// Extending the stack by 2 * 64 bits is required for stack alignment purposes.
|
| -uintptr_t Simulator::PushAddress(uintptr_t address) {
|
| - ASSERT(sizeof(uintptr_t) < 2 * kXRegSize);
|
| - intptr_t new_sp = sp() - 2 * kXRegSize;
|
| - uintptr_t* alignment_slot =
|
| - reinterpret_cast<uintptr_t*>(new_sp + kXRegSize);
|
| - memcpy(alignment_slot, &kSlotsZapValue, kPointerSize);
|
| - uintptr_t* stack_slot = reinterpret_cast<uintptr_t*>(new_sp);
|
| - memcpy(stack_slot, &address, kPointerSize);
|
| - set_sp(new_sp);
|
| - return new_sp;
|
| -}
|
| -
|
| -
|
| -uintptr_t Simulator::PopAddress() {
|
| - intptr_t current_sp = sp();
|
| - uintptr_t* stack_slot = reinterpret_cast<uintptr_t*>(current_sp);
|
| - uintptr_t address = *stack_slot;
|
| - ASSERT(sizeof(uintptr_t) < 2 * kXRegSize);
|
| - set_sp(current_sp + 2 * kXRegSize);
|
| - return address;
|
| -}
|
| -
|
| -
|
| -// Returns the limit of the stack area to enable checking for stack overflows.
|
| -uintptr_t Simulator::StackLimit() const {
|
| - // Leave a safety margin of 1024 bytes to prevent overrunning the stack when
|
| - // pushing values.
|
| - return reinterpret_cast<uintptr_t>(stack_limit_) + 1024;
|
| -}
|
| -
|
| -
|
| -Simulator::Simulator(Decoder<DispatchingDecoderVisitor>* decoder,
|
| - Isolate* isolate, FILE* stream)
|
| - : decoder_(decoder),
|
| - last_debugger_input_(NULL),
|
| - log_parameters_(NO_PARAM),
|
| - isolate_(isolate) {
|
| - // Setup the decoder.
|
| - decoder_->AppendVisitor(this);
|
| -
|
| - Init(stream);
|
| -
|
| - if (FLAG_trace_sim) {
|
| - decoder_->InsertVisitorBefore(print_disasm_, this);
|
| - log_parameters_ = LOG_ALL;
|
| - }
|
| -
|
| - if (FLAG_log_instruction_stats) {
|
| - instrument_ = new Instrument(FLAG_log_instruction_file,
|
| - FLAG_log_instruction_period);
|
| - decoder_->AppendVisitor(instrument_);
|
| - }
|
| -}
|
| -
|
| -
|
| -Simulator::Simulator()
|
| - : decoder_(NULL),
|
| - last_debugger_input_(NULL),
|
| - log_parameters_(NO_PARAM),
|
| - isolate_(NULL) {
|
| - Init(NULL);
|
| - CHECK(!FLAG_trace_sim && !FLAG_log_instruction_stats);
|
| -}
|
| -
|
| -
|
| -void Simulator::Init(FILE* stream) {
|
| - ResetState();
|
| -
|
| - // Allocate and setup the simulator stack.
|
| - stack_size_ = (FLAG_sim_stack_size * KB) + (2 * stack_protection_size_);
|
| - stack_ = new byte[stack_size_];
|
| - stack_limit_ = stack_ + stack_protection_size_;
|
| - byte* tos = stack_ + stack_size_ - stack_protection_size_;
|
| - // The stack pointer must be 16 bytes aligned.
|
| - set_sp(reinterpret_cast<int64_t>(tos) & ~0xfUL);
|
| -
|
| - stream_ = stream;
|
| - print_disasm_ = new PrintDisassembler(stream_);
|
| -
|
| - // The debugger needs to disassemble code without the simulator executing an
|
| - // instruction, so we create a dedicated decoder.
|
| - disassembler_decoder_ = new Decoder<DispatchingDecoderVisitor>();
|
| - disassembler_decoder_->AppendVisitor(print_disasm_);
|
| -}
|
| -
|
| -
|
| -void Simulator::ResetState() {
|
| - // Reset the system registers.
|
| - nzcv_ = SimSystemRegister::DefaultValueFor(NZCV);
|
| - fpcr_ = SimSystemRegister::DefaultValueFor(FPCR);
|
| -
|
| - // Reset registers to 0.
|
| - pc_ = NULL;
|
| - for (unsigned i = 0; i < kNumberOfRegisters; i++) {
|
| - set_xreg(i, 0xbadbeef);
|
| - }
|
| - for (unsigned i = 0; i < kNumberOfFPRegisters; i++) {
|
| - // Set FP registers to a value that is NaN in both 32-bit and 64-bit FP.
|
| - set_dreg_bits(i, 0x7ff000007f800001UL);
|
| - }
|
| - // Returning to address 0 exits the Simulator.
|
| - set_lr(kEndOfSimAddress);
|
| -
|
| - // Reset debug helpers.
|
| - breakpoints_.empty();
|
| - break_on_next_= false;
|
| -}
|
| -
|
| -
|
| -Simulator::~Simulator() {
|
| - delete[] stack_;
|
| - if (FLAG_log_instruction_stats) {
|
| - delete instrument_;
|
| - }
|
| - delete disassembler_decoder_;
|
| - delete print_disasm_;
|
| - DeleteArray(last_debugger_input_);
|
| - delete decoder_;
|
| -}
|
| -
|
| -
|
| -void Simulator::Run() {
|
| - pc_modified_ = false;
|
| - while (pc_ != kEndOfSimAddress) {
|
| - ExecuteInstruction();
|
| - }
|
| -}
|
| -
|
| -
|
| -void Simulator::RunFrom(Instruction* start) {
|
| - set_pc(start);
|
| - Run();
|
| -}
|
| -
|
| -
|
| -// When the generated code calls an external reference we need to catch that in
|
| -// the simulator. The external reference will be a function compiled for the
|
| -// host architecture. We need to call that function instead of trying to
|
| -// execute it with the simulator. We do that by redirecting the external
|
| -// reference to a svc (Supervisor Call) instruction that is handled by
|
| -// the simulator. We write the original destination of the jump just at a known
|
| -// offset from the svc instruction so the simulator knows what to call.
|
| -class Redirection {
|
| - public:
|
| - Redirection(void* external_function, ExternalReference::Type type)
|
| - : external_function_(external_function),
|
| - type_(type),
|
| - next_(NULL) {
|
| - redirect_call_.SetInstructionBits(
|
| - HLT | Assembler::ImmException(kImmExceptionIsRedirectedCall));
|
| - Isolate* isolate = Isolate::Current();
|
| - next_ = isolate->simulator_redirection();
|
| - // TODO(all): Simulator flush I cache
|
| - isolate->set_simulator_redirection(this);
|
| - }
|
| -
|
| - void* address_of_redirect_call() {
|
| - return reinterpret_cast<void*>(&redirect_call_);
|
| - }
|
| -
|
| - template <typename T>
|
| - T external_function() { return reinterpret_cast<T>(external_function_); }
|
| -
|
| - ExternalReference::Type type() { return type_; }
|
| -
|
| - static Redirection* Get(void* external_function,
|
| - ExternalReference::Type type) {
|
| - Isolate* isolate = Isolate::Current();
|
| - Redirection* current = isolate->simulator_redirection();
|
| - for (; current != NULL; current = current->next_) {
|
| - if (current->external_function_ == external_function) {
|
| - ASSERT_EQ(current->type(), type);
|
| - return current;
|
| - }
|
| - }
|
| - return new Redirection(external_function, type);
|
| - }
|
| -
|
| - static Redirection* FromHltInstruction(Instruction* redirect_call) {
|
| - char* addr_of_hlt = reinterpret_cast<char*>(redirect_call);
|
| - char* addr_of_redirection =
|
| - addr_of_hlt - OFFSET_OF(Redirection, redirect_call_);
|
| - return reinterpret_cast<Redirection*>(addr_of_redirection);
|
| - }
|
| -
|
| - static void* ReverseRedirection(int64_t reg) {
|
| - Redirection* redirection =
|
| - FromHltInstruction(reinterpret_cast<Instruction*>(reg));
|
| - return redirection->external_function<void*>();
|
| - }
|
| -
|
| - private:
|
| - void* external_function_;
|
| - Instruction redirect_call_;
|
| - ExternalReference::Type type_;
|
| - Redirection* next_;
|
| -};
|
| -
|
| -
|
| -// Calls into the V8 runtime are based on this very simple interface.
|
| -// Note: To be able to return two values from some calls the code in runtime.cc
|
| -// uses the ObjectPair structure.
|
| -// The simulator assumes all runtime calls return two 64-bits values. If they
|
| -// don't, register x1 is clobbered. This is fine because x1 is caller-saved.
|
| -struct ObjectPair {
|
| - int64_t res0;
|
| - int64_t res1;
|
| -};
|
| -
|
| -
|
| -typedef ObjectPair (*SimulatorRuntimeCall)(int64_t arg0,
|
| - int64_t arg1,
|
| - int64_t arg2,
|
| - int64_t arg3,
|
| - int64_t arg4,
|
| - int64_t arg5,
|
| - int64_t arg6,
|
| - int64_t arg7);
|
| -
|
| -typedef int64_t (*SimulatorRuntimeCompareCall)(double arg1, double arg2);
|
| -typedef double (*SimulatorRuntimeFPFPCall)(double arg1, double arg2);
|
| -typedef double (*SimulatorRuntimeFPCall)(double arg1);
|
| -typedef double (*SimulatorRuntimeFPIntCall)(double arg1, int32_t arg2);
|
| -
|
| -// This signature supports direct call in to API function native callback
|
| -// (refer to InvocationCallback in v8.h).
|
| -typedef void (*SimulatorRuntimeDirectApiCall)(int64_t arg0);
|
| -typedef void (*SimulatorRuntimeProfilingApiCall)(int64_t arg0, void* arg1);
|
| -
|
| -// This signature supports direct call to accessor getter callback.
|
| -typedef void (*SimulatorRuntimeDirectGetterCall)(int64_t arg0, int64_t arg1);
|
| -typedef void (*SimulatorRuntimeProfilingGetterCall)(int64_t arg0, int64_t arg1,
|
| - void* arg2);
|
| -
|
| -void Simulator::DoRuntimeCall(Instruction* instr) {
|
| - Redirection* redirection = Redirection::FromHltInstruction(instr);
|
| -
|
| - // The called C code might itself call simulated code, so any
|
| - // caller-saved registers (including lr) could still be clobbered by a
|
| - // redirected call.
|
| - Instruction* return_address = lr();
|
| -
|
| - int64_t external = redirection->external_function<int64_t>();
|
| -
|
| - TraceSim("Call to host function at %p\n",
|
| - redirection->external_function<void*>());
|
| -
|
| - // SP must be 16-byte-aligned at the call interface.
|
| - bool stack_alignment_exception = ((sp() & 0xf) != 0);
|
| - if (stack_alignment_exception) {
|
| - TraceSim(" with unaligned stack 0x%016" PRIx64 ".\n", sp());
|
| - FATAL("ALIGNMENT EXCEPTION");
|
| - }
|
| -
|
| - switch (redirection->type()) {
|
| - default:
|
| - TraceSim("Type: Unknown.\n");
|
| - UNREACHABLE();
|
| - break;
|
| -
|
| - case ExternalReference::BUILTIN_CALL: {
|
| - // MaybeObject* f(v8::internal::Arguments).
|
| - TraceSim("Type: BUILTIN_CALL\n");
|
| - SimulatorRuntimeCall target =
|
| - reinterpret_cast<SimulatorRuntimeCall>(external);
|
| -
|
| - // We don't know how many arguments are being passed, but we can
|
| - // pass 8 without touching the stack. They will be ignored by the
|
| - // host function if they aren't used.
|
| - TraceSim("Arguments: "
|
| - "0x%016" PRIx64 ", 0x%016" PRIx64 ", "
|
| - "0x%016" PRIx64 ", 0x%016" PRIx64 ", "
|
| - "0x%016" PRIx64 ", 0x%016" PRIx64 ", "
|
| - "0x%016" PRIx64 ", 0x%016" PRIx64,
|
| - xreg(0), xreg(1), xreg(2), xreg(3),
|
| - xreg(4), xreg(5), xreg(6), xreg(7));
|
| - ObjectPair result = target(xreg(0), xreg(1), xreg(2), xreg(3),
|
| - xreg(4), xreg(5), xreg(6), xreg(7));
|
| - TraceSim("Returned: {0x%" PRIx64 ", 0x%" PRIx64 "}\n",
|
| - result.res0, result.res1);
|
| -#ifdef DEBUG
|
| - CorruptAllCallerSavedCPURegisters();
|
| -#endif
|
| - set_xreg(0, result.res0);
|
| - set_xreg(1, result.res1);
|
| - break;
|
| - }
|
| -
|
| - case ExternalReference::DIRECT_API_CALL: {
|
| - // void f(v8::FunctionCallbackInfo&)
|
| - TraceSim("Type: DIRECT_API_CALL\n");
|
| - SimulatorRuntimeDirectApiCall target =
|
| - reinterpret_cast<SimulatorRuntimeDirectApiCall>(external);
|
| - TraceSim("Arguments: 0x%016" PRIx64 "\n", xreg(0));
|
| - target(xreg(0));
|
| - TraceSim("No return value.");
|
| -#ifdef DEBUG
|
| - CorruptAllCallerSavedCPURegisters();
|
| -#endif
|
| - break;
|
| - }
|
| -
|
| - case ExternalReference::BUILTIN_COMPARE_CALL: {
|
| - // int f(double, double)
|
| - TraceSim("Type: BUILTIN_COMPARE_CALL\n");
|
| - SimulatorRuntimeCompareCall target =
|
| - reinterpret_cast<SimulatorRuntimeCompareCall>(external);
|
| - TraceSim("Arguments: %f, %f\n", dreg(0), dreg(1));
|
| - int64_t result = target(dreg(0), dreg(1));
|
| - TraceSim("Returned: %" PRId64 "\n", result);
|
| -#ifdef DEBUG
|
| - CorruptAllCallerSavedCPURegisters();
|
| -#endif
|
| - set_xreg(0, result);
|
| - break;
|
| - }
|
| -
|
| - case ExternalReference::BUILTIN_FP_CALL: {
|
| - // double f(double)
|
| - TraceSim("Type: BUILTIN_FP_CALL\n");
|
| - SimulatorRuntimeFPCall target =
|
| - reinterpret_cast<SimulatorRuntimeFPCall>(external);
|
| - TraceSim("Argument: %f\n", dreg(0));
|
| - double result = target(dreg(0));
|
| - TraceSim("Returned: %f\n", result);
|
| -#ifdef DEBUG
|
| - CorruptAllCallerSavedCPURegisters();
|
| -#endif
|
| - set_dreg(0, result);
|
| - break;
|
| - }
|
| -
|
| - case ExternalReference::BUILTIN_FP_FP_CALL: {
|
| - // double f(double, double)
|
| - TraceSim("Type: BUILTIN_FP_FP_CALL\n");
|
| - SimulatorRuntimeFPFPCall target =
|
| - reinterpret_cast<SimulatorRuntimeFPFPCall>(external);
|
| - TraceSim("Arguments: %f, %f\n", dreg(0), dreg(1));
|
| - double result = target(dreg(0), dreg(1));
|
| - TraceSim("Returned: %f\n", result);
|
| -#ifdef DEBUG
|
| - CorruptAllCallerSavedCPURegisters();
|
| -#endif
|
| - set_dreg(0, result);
|
| - break;
|
| - }
|
| -
|
| - case ExternalReference::BUILTIN_FP_INT_CALL: {
|
| - // double f(double, int)
|
| - TraceSim("Type: BUILTIN_FP_INT_CALL\n");
|
| - SimulatorRuntimeFPIntCall target =
|
| - reinterpret_cast<SimulatorRuntimeFPIntCall>(external);
|
| - TraceSim("Arguments: %f, %d\n", dreg(0), wreg(0));
|
| - double result = target(dreg(0), wreg(0));
|
| - TraceSim("Returned: %f\n", result);
|
| -#ifdef DEBUG
|
| - CorruptAllCallerSavedCPURegisters();
|
| -#endif
|
| - set_dreg(0, result);
|
| - break;
|
| - }
|
| -
|
| - case ExternalReference::DIRECT_GETTER_CALL: {
|
| - // void f(Local<String> property, PropertyCallbackInfo& info)
|
| - TraceSim("Type: DIRECT_GETTER_CALL\n");
|
| - SimulatorRuntimeDirectGetterCall target =
|
| - reinterpret_cast<SimulatorRuntimeDirectGetterCall>(external);
|
| - TraceSim("Arguments: 0x%016" PRIx64 ", 0x%016" PRIx64 "\n",
|
| - xreg(0), xreg(1));
|
| - target(xreg(0), xreg(1));
|
| - TraceSim("No return value.");
|
| -#ifdef DEBUG
|
| - CorruptAllCallerSavedCPURegisters();
|
| -#endif
|
| - break;
|
| - }
|
| -
|
| - case ExternalReference::PROFILING_API_CALL: {
|
| - // void f(v8::FunctionCallbackInfo&, v8::FunctionCallback)
|
| - TraceSim("Type: PROFILING_API_CALL\n");
|
| - SimulatorRuntimeProfilingApiCall target =
|
| - reinterpret_cast<SimulatorRuntimeProfilingApiCall>(external);
|
| - void* arg1 = Redirection::ReverseRedirection(xreg(1));
|
| - TraceSim("Arguments: 0x%016" PRIx64 ", %p\n", xreg(0), arg1);
|
| - target(xreg(0), arg1);
|
| - TraceSim("No return value.");
|
| -#ifdef DEBUG
|
| - CorruptAllCallerSavedCPURegisters();
|
| -#endif
|
| - break;
|
| - }
|
| -
|
| - case ExternalReference::PROFILING_GETTER_CALL: {
|
| - // void f(Local<String> property, PropertyCallbackInfo& info,
|
| - // AccessorGetterCallback callback)
|
| - TraceSim("Type: PROFILING_GETTER_CALL\n");
|
| - SimulatorRuntimeProfilingGetterCall target =
|
| - reinterpret_cast<SimulatorRuntimeProfilingGetterCall>(
|
| - external);
|
| - void* arg2 = Redirection::ReverseRedirection(xreg(2));
|
| - TraceSim("Arguments: 0x%016" PRIx64 ", 0x%016" PRIx64 ", %p\n",
|
| - xreg(0), xreg(1), arg2);
|
| - target(xreg(0), xreg(1), arg2);
|
| - TraceSim("No return value.");
|
| -#ifdef DEBUG
|
| - CorruptAllCallerSavedCPURegisters();
|
| -#endif
|
| - break;
|
| - }
|
| - }
|
| -
|
| - set_lr(return_address);
|
| - set_pc(return_address);
|
| -}
|
| -
|
| -
|
| -void* Simulator::RedirectExternalReference(void* external_function,
|
| - ExternalReference::Type type) {
|
| - Redirection* redirection = Redirection::Get(external_function, type);
|
| - return redirection->address_of_redirect_call();
|
| -}
|
| -
|
| -
|
| -const char* Simulator::xreg_names[] = {
|
| -"x0", "x1", "x2", "x3", "x4", "x5", "x6", "x7",
|
| -"x8", "x9", "x10", "x11", "x12", "x13", "x14", "x15",
|
| -"ip0", "ip1", "x18", "x19", "x20", "x21", "x22", "x23",
|
| -"x24", "x25", "x26", "cp", "jssp", "fp", "lr", "xzr", "csp"};
|
| -
|
| -const char* Simulator::wreg_names[] = {
|
| -"w0", "w1", "w2", "w3", "w4", "w5", "w6", "w7",
|
| -"w8", "w9", "w10", "w11", "w12", "w13", "w14", "w15",
|
| -"w16", "w17", "w18", "w19", "w20", "w21", "w22", "w23",
|
| -"w24", "w25", "w26", "wcp", "wjssp", "wfp", "wlr", "wzr", "wcsp"};
|
| -
|
| -const char* Simulator::sreg_names[] = {
|
| -"s0", "s1", "s2", "s3", "s4", "s5", "s6", "s7",
|
| -"s8", "s9", "s10", "s11", "s12", "s13", "s14", "s15",
|
| -"s16", "s17", "s18", "s19", "s20", "s21", "s22", "s23",
|
| -"s24", "s25", "s26", "s27", "s28", "s29", "s30", "s31"};
|
| -
|
| -const char* Simulator::dreg_names[] = {
|
| -"d0", "d1", "d2", "d3", "d4", "d5", "d6", "d7",
|
| -"d8", "d9", "d10", "d11", "d12", "d13", "d14", "d15",
|
| -"d16", "d17", "d18", "d19", "d20", "d21", "d22", "d23",
|
| -"d24", "d25", "d26", "d27", "d28", "d29", "d30", "d31"};
|
| -
|
| -const char* Simulator::vreg_names[] = {
|
| -"v0", "v1", "v2", "v3", "v4", "v5", "v6", "v7",
|
| -"v8", "v9", "v10", "v11", "v12", "v13", "v14", "v15",
|
| -"v16", "v17", "v18", "v19", "v20", "v21", "v22", "v23",
|
| -"v24", "v25", "v26", "v27", "v28", "v29", "v30", "v31"};
|
| -
|
| -
|
| -const char* Simulator::WRegNameForCode(unsigned code, Reg31Mode mode) {
|
| - ASSERT(code < kNumberOfRegisters);
|
| - // If the code represents the stack pointer, index the name after zr.
|
| - if ((code == kZeroRegCode) && (mode == Reg31IsStackPointer)) {
|
| - code = kZeroRegCode + 1;
|
| - }
|
| - return wreg_names[code];
|
| -}
|
| -
|
| -
|
| -const char* Simulator::XRegNameForCode(unsigned code, Reg31Mode mode) {
|
| - ASSERT(code < kNumberOfRegisters);
|
| - // If the code represents the stack pointer, index the name after zr.
|
| - if ((code == kZeroRegCode) && (mode == Reg31IsStackPointer)) {
|
| - code = kZeroRegCode + 1;
|
| - }
|
| - return xreg_names[code];
|
| -}
|
| -
|
| -
|
| -const char* Simulator::SRegNameForCode(unsigned code) {
|
| - ASSERT(code < kNumberOfFPRegisters);
|
| - return sreg_names[code];
|
| -}
|
| -
|
| -
|
| -const char* Simulator::DRegNameForCode(unsigned code) {
|
| - ASSERT(code < kNumberOfFPRegisters);
|
| - return dreg_names[code];
|
| -}
|
| -
|
| -
|
| -const char* Simulator::VRegNameForCode(unsigned code) {
|
| - ASSERT(code < kNumberOfFPRegisters);
|
| - return vreg_names[code];
|
| -}
|
| -
|
| -
|
| -int Simulator::CodeFromName(const char* name) {
|
| - for (unsigned i = 0; i < kNumberOfRegisters; i++) {
|
| - if ((strcmp(xreg_names[i], name) == 0) ||
|
| - (strcmp(wreg_names[i], name) == 0)) {
|
| - return i;
|
| - }
|
| - }
|
| - for (unsigned i = 0; i < kNumberOfFPRegisters; i++) {
|
| - if ((strcmp(vreg_names[i], name) == 0) ||
|
| - (strcmp(dreg_names[i], name) == 0) ||
|
| - (strcmp(sreg_names[i], name) == 0)) {
|
| - return i;
|
| - }
|
| - }
|
| - if ((strcmp("csp", name) == 0) || (strcmp("wcsp", name) == 0)) {
|
| - return kSPRegInternalCode;
|
| - }
|
| - return -1;
|
| -}
|
| -
|
| -
|
| -// Helpers ---------------------------------------------------------------------
|
| -int64_t Simulator::AddWithCarry(unsigned reg_size,
|
| - bool set_flags,
|
| - int64_t src1,
|
| - int64_t src2,
|
| - int64_t carry_in) {
|
| - ASSERT((carry_in == 0) || (carry_in == 1));
|
| - ASSERT((reg_size == kXRegSizeInBits) || (reg_size == kWRegSizeInBits));
|
| -
|
| - uint64_t u1, u2;
|
| - int64_t result;
|
| - int64_t signed_sum = src1 + src2 + carry_in;
|
| -
|
| - bool N, Z, C, V;
|
| -
|
| - if (reg_size == kWRegSizeInBits) {
|
| - u1 = static_cast<uint64_t>(src1) & kWRegMask;
|
| - u2 = static_cast<uint64_t>(src2) & kWRegMask;
|
| -
|
| - result = signed_sum & kWRegMask;
|
| - // Compute the C flag by comparing the sum to the max unsigned integer.
|
| - C = ((kWMaxUInt - u1) < (u2 + carry_in)) ||
|
| - ((kWMaxUInt - u1 - carry_in) < u2);
|
| - // Overflow iff the sign bit is the same for the two inputs and different
|
| - // for the result.
|
| - int64_t s_src1 = src1 << (kXRegSizeInBits - kWRegSizeInBits);
|
| - int64_t s_src2 = src2 << (kXRegSizeInBits - kWRegSizeInBits);
|
| - int64_t s_result = result << (kXRegSizeInBits - kWRegSizeInBits);
|
| - V = ((s_src1 ^ s_src2) >= 0) && ((s_src1 ^ s_result) < 0);
|
| -
|
| - } else {
|
| - u1 = static_cast<uint64_t>(src1);
|
| - u2 = static_cast<uint64_t>(src2);
|
| -
|
| - result = signed_sum;
|
| - // Compute the C flag by comparing the sum to the max unsigned integer.
|
| - C = ((kXMaxUInt - u1) < (u2 + carry_in)) ||
|
| - ((kXMaxUInt - u1 - carry_in) < u2);
|
| - // Overflow iff the sign bit is the same for the two inputs and different
|
| - // for the result.
|
| - V = ((src1 ^ src2) >= 0) && ((src1 ^ result) < 0);
|
| - }
|
| -
|
| - N = CalcNFlag(result, reg_size);
|
| - Z = CalcZFlag(result);
|
| -
|
| - if (set_flags) {
|
| - nzcv().SetN(N);
|
| - nzcv().SetZ(Z);
|
| - nzcv().SetC(C);
|
| - nzcv().SetV(V);
|
| - }
|
| - return result;
|
| -}
|
| -
|
| -
|
| -int64_t Simulator::ShiftOperand(unsigned reg_size,
|
| - int64_t value,
|
| - Shift shift_type,
|
| - unsigned amount) {
|
| - if (amount == 0) {
|
| - return value;
|
| - }
|
| - int64_t mask = reg_size == kXRegSizeInBits ? kXRegMask : kWRegMask;
|
| - switch (shift_type) {
|
| - case LSL:
|
| - return (value << amount) & mask;
|
| - case LSR:
|
| - return static_cast<uint64_t>(value) >> amount;
|
| - case ASR: {
|
| - // Shift used to restore the sign.
|
| - unsigned s_shift = kXRegSizeInBits - reg_size;
|
| - // Value with its sign restored.
|
| - int64_t s_value = (value << s_shift) >> s_shift;
|
| - return (s_value >> amount) & mask;
|
| - }
|
| - case ROR: {
|
| - if (reg_size == kWRegSizeInBits) {
|
| - value &= kWRegMask;
|
| - }
|
| - return (static_cast<uint64_t>(value) >> amount) |
|
| - ((value & ((1L << amount) - 1L)) << (reg_size - amount));
|
| - }
|
| - default:
|
| - UNIMPLEMENTED();
|
| - return 0;
|
| - }
|
| -}
|
| -
|
| -
|
| -int64_t Simulator::ExtendValue(unsigned reg_size,
|
| - int64_t value,
|
| - Extend extend_type,
|
| - unsigned left_shift) {
|
| - switch (extend_type) {
|
| - case UXTB:
|
| - value &= kByteMask;
|
| - break;
|
| - case UXTH:
|
| - value &= kHalfWordMask;
|
| - break;
|
| - case UXTW:
|
| - value &= kWordMask;
|
| - break;
|
| - case SXTB:
|
| - value = (value << 56) >> 56;
|
| - break;
|
| - case SXTH:
|
| - value = (value << 48) >> 48;
|
| - break;
|
| - case SXTW:
|
| - value = (value << 32) >> 32;
|
| - break;
|
| - case UXTX:
|
| - case SXTX:
|
| - break;
|
| - default:
|
| - UNREACHABLE();
|
| - }
|
| - int64_t mask = (reg_size == kXRegSizeInBits) ? kXRegMask : kWRegMask;
|
| - return (value << left_shift) & mask;
|
| -}
|
| -
|
| -
|
| -template<> double Simulator::FPDefaultNaN<double>() const {
|
| - return kFP64DefaultNaN;
|
| -}
|
| -
|
| -
|
| -template<> float Simulator::FPDefaultNaN<float>() const {
|
| - return kFP32DefaultNaN;
|
| -}
|
| -
|
| -
|
| -void Simulator::FPCompare(double val0, double val1) {
|
| - AssertSupportedFPCR();
|
| -
|
| - // TODO(jbramley): This assumes that the C++ implementation handles
|
| - // comparisons in the way that we expect (as per AssertSupportedFPCR()).
|
| - if ((std::isnan(val0) != 0) || (std::isnan(val1) != 0)) {
|
| - nzcv().SetRawValue(FPUnorderedFlag);
|
| - } else if (val0 < val1) {
|
| - nzcv().SetRawValue(FPLessThanFlag);
|
| - } else if (val0 > val1) {
|
| - nzcv().SetRawValue(FPGreaterThanFlag);
|
| - } else if (val0 == val1) {
|
| - nzcv().SetRawValue(FPEqualFlag);
|
| - } else {
|
| - UNREACHABLE();
|
| - }
|
| -}
|
| -
|
| -
|
| -void Simulator::SetBreakpoint(Instruction* location) {
|
| - for (unsigned i = 0; i < breakpoints_.size(); i++) {
|
| - if (breakpoints_.at(i).location == location) {
|
| - PrintF("Existing breakpoint at %p was %s\n",
|
| - reinterpret_cast<void*>(location),
|
| - breakpoints_.at(i).enabled ? "disabled" : "enabled");
|
| - breakpoints_.at(i).enabled = !breakpoints_.at(i).enabled;
|
| - return;
|
| - }
|
| - }
|
| - Breakpoint new_breakpoint = {location, true};
|
| - breakpoints_.push_back(new_breakpoint);
|
| - PrintF("Set a breakpoint at %p\n", reinterpret_cast<void*>(location));
|
| -}
|
| -
|
| -
|
| -void Simulator::ListBreakpoints() {
|
| - PrintF("Breakpoints:\n");
|
| - for (unsigned i = 0; i < breakpoints_.size(); i++) {
|
| - PrintF("%p : %s\n",
|
| - reinterpret_cast<void*>(breakpoints_.at(i).location),
|
| - breakpoints_.at(i).enabled ? "enabled" : "disabled");
|
| - }
|
| -}
|
| -
|
| -
|
| -void Simulator::CheckBreakpoints() {
|
| - bool hit_a_breakpoint = false;
|
| - for (unsigned i = 0; i < breakpoints_.size(); i++) {
|
| - if ((breakpoints_.at(i).location == pc_) &&
|
| - breakpoints_.at(i).enabled) {
|
| - hit_a_breakpoint = true;
|
| - // Disable this breakpoint.
|
| - breakpoints_.at(i).enabled = false;
|
| - }
|
| - }
|
| - if (hit_a_breakpoint) {
|
| - PrintF("Hit and disabled a breakpoint at %p.\n",
|
| - reinterpret_cast<void*>(pc_));
|
| - Debug();
|
| - }
|
| -}
|
| -
|
| -
|
| -void Simulator::CheckBreakNext() {
|
| - // If the current instruction is a BL, insert a breakpoint just after it.
|
| - if (break_on_next_ && pc_->IsBranchAndLinkToRegister()) {
|
| - SetBreakpoint(pc_->following());
|
| - break_on_next_ = false;
|
| - }
|
| -}
|
| -
|
| -
|
| -void Simulator::PrintInstructionsAt(Instruction* start, uint64_t count) {
|
| - Instruction* end = start->InstructionAtOffset(count * kInstructionSize);
|
| - for (Instruction* pc = start; pc < end; pc = pc->following()) {
|
| - disassembler_decoder_->Decode(pc);
|
| - }
|
| -}
|
| -
|
| -
|
| -void Simulator::PrintSystemRegisters(bool print_all) {
|
| - static bool first_run = true;
|
| -
|
| - static SimSystemRegister last_nzcv;
|
| - if (print_all || first_run || (last_nzcv.RawValue() != nzcv().RawValue())) {
|
| - fprintf(stream_, "# %sFLAGS: %sN:%d Z:%d C:%d V:%d%s\n",
|
| - clr_flag_name,
|
| - clr_flag_value,
|
| - nzcv().N(), nzcv().Z(), nzcv().C(), nzcv().V(),
|
| - clr_normal);
|
| - }
|
| - last_nzcv = nzcv();
|
| -
|
| - static SimSystemRegister last_fpcr;
|
| - if (print_all || first_run || (last_fpcr.RawValue() != fpcr().RawValue())) {
|
| - static const char * rmode[] = {
|
| - "0b00 (Round to Nearest)",
|
| - "0b01 (Round towards Plus Infinity)",
|
| - "0b10 (Round towards Minus Infinity)",
|
| - "0b11 (Round towards Zero)"
|
| - };
|
| - ASSERT(fpcr().RMode() <= (sizeof(rmode) / sizeof(rmode[0])));
|
| - fprintf(stream_, "# %sFPCR: %sAHP:%d DN:%d FZ:%d RMode:%s%s\n",
|
| - clr_flag_name,
|
| - clr_flag_value,
|
| - fpcr().AHP(), fpcr().DN(), fpcr().FZ(), rmode[fpcr().RMode()],
|
| - clr_normal);
|
| - }
|
| - last_fpcr = fpcr();
|
| -
|
| - first_run = false;
|
| -}
|
| -
|
| -
|
| -void Simulator::PrintRegisters(bool print_all_regs) {
|
| - static bool first_run = true;
|
| - static int64_t last_regs[kNumberOfRegisters];
|
| -
|
| - for (unsigned i = 0; i < kNumberOfRegisters; i++) {
|
| - if (print_all_regs || first_run ||
|
| - (last_regs[i] != xreg(i, Reg31IsStackPointer))) {
|
| - fprintf(stream_,
|
| - "# %s%4s:%s 0x%016" PRIx64 "%s\n",
|
| - clr_reg_name,
|
| - XRegNameForCode(i, Reg31IsStackPointer),
|
| - clr_reg_value,
|
| - xreg(i, Reg31IsStackPointer),
|
| - clr_normal);
|
| - }
|
| - // Cache the new register value so the next run can detect any changes.
|
| - last_regs[i] = xreg(i, Reg31IsStackPointer);
|
| - }
|
| - first_run = false;
|
| -}
|
| -
|
| -
|
| -void Simulator::PrintFPRegisters(bool print_all_regs) {
|
| - static bool first_run = true;
|
| - static uint64_t last_regs[kNumberOfFPRegisters];
|
| -
|
| - // Print as many rows of registers as necessary, keeping each individual
|
| - // register in the same column each time (to make it easy to visually scan
|
| - // for changes).
|
| - for (unsigned i = 0; i < kNumberOfFPRegisters; i++) {
|
| - if (print_all_regs || first_run || (last_regs[i] != dreg_bits(i))) {
|
| - fprintf(stream_,
|
| - "# %s %4s:%s 0x%016" PRIx64 "%s (%s%s:%s %g%s %s:%s %g%s)\n",
|
| - clr_fpreg_name,
|
| - VRegNameForCode(i),
|
| - clr_fpreg_value,
|
| - dreg_bits(i),
|
| - clr_normal,
|
| - clr_fpreg_name,
|
| - DRegNameForCode(i),
|
| - clr_fpreg_value,
|
| - dreg(i),
|
| - clr_fpreg_name,
|
| - SRegNameForCode(i),
|
| - clr_fpreg_value,
|
| - sreg(i),
|
| - clr_normal);
|
| - }
|
| - // Cache the new register value so the next run can detect any changes.
|
| - last_regs[i] = dreg_bits(i);
|
| - }
|
| - first_run = false;
|
| -}
|
| -
|
| -
|
| -void Simulator::PrintProcessorState() {
|
| - PrintSystemRegisters();
|
| - PrintRegisters();
|
| - PrintFPRegisters();
|
| -}
|
| -
|
| -
|
| -void Simulator::PrintWrite(uint8_t* address,
|
| - uint64_t value,
|
| - unsigned num_bytes) {
|
| - // The template is "# value -> address". The template is not directly used
|
| - // in the printf since compilers tend to struggle with the parametrized
|
| - // width (%0*).
|
| - const char* format = "# %s0x%0*" PRIx64 "%s -> %s0x%016" PRIx64 "%s\n";
|
| - fprintf(stream_,
|
| - format,
|
| - clr_memory_value,
|
| - num_bytes * 2, // The width in hexa characters.
|
| - value,
|
| - clr_normal,
|
| - clr_memory_address,
|
| - address,
|
| - clr_normal);
|
| -}
|
| -
|
| -
|
| -// Visitors---------------------------------------------------------------------
|
| -
|
| -void Simulator::VisitUnimplemented(Instruction* instr) {
|
| - fprintf(stream_, "Unimplemented instruction at %p: 0x%08" PRIx32 "\n",
|
| - reinterpret_cast<void*>(instr), instr->InstructionBits());
|
| - UNIMPLEMENTED();
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitUnallocated(Instruction* instr) {
|
| - fprintf(stream_, "Unallocated instruction at %p: 0x%08" PRIx32 "\n",
|
| - reinterpret_cast<void*>(instr), instr->InstructionBits());
|
| - UNIMPLEMENTED();
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitPCRelAddressing(Instruction* instr) {
|
| - switch (instr->Mask(PCRelAddressingMask)) {
|
| - case ADR:
|
| - set_reg(instr->Rd(), instr->ImmPCOffsetTarget());
|
| - break;
|
| - case ADRP: // Not implemented in the assembler.
|
| - UNIMPLEMENTED();
|
| - break;
|
| - default:
|
| - UNREACHABLE();
|
| - break;
|
| - }
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitUnconditionalBranch(Instruction* instr) {
|
| - switch (instr->Mask(UnconditionalBranchMask)) {
|
| - case BL:
|
| - set_lr(instr->following());
|
| - // Fall through.
|
| - case B:
|
| - set_pc(instr->ImmPCOffsetTarget());
|
| - break;
|
| - default:
|
| - UNREACHABLE();
|
| - }
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitConditionalBranch(Instruction* instr) {
|
| - ASSERT(instr->Mask(ConditionalBranchMask) == B_cond);
|
| - if (ConditionPassed(static_cast<Condition>(instr->ConditionBranch()))) {
|
| - set_pc(instr->ImmPCOffsetTarget());
|
| - }
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitUnconditionalBranchToRegister(Instruction* instr) {
|
| - Instruction* target = reg<Instruction*>(instr->Rn());
|
| - switch (instr->Mask(UnconditionalBranchToRegisterMask)) {
|
| - case BLR: {
|
| - set_lr(instr->following());
|
| - if (instr->Rn() == 31) {
|
| - // BLR XZR is used as a guard for the constant pool. We should never hit
|
| - // this, but if we do trap to allow debugging.
|
| - Debug();
|
| - }
|
| - // Fall through.
|
| - }
|
| - case BR:
|
| - case RET: set_pc(target); break;
|
| - default: UNIMPLEMENTED();
|
| - }
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitTestBranch(Instruction* instr) {
|
| - unsigned bit_pos = (instr->ImmTestBranchBit5() << 5) |
|
| - instr->ImmTestBranchBit40();
|
| - bool take_branch = ((xreg(instr->Rt()) & (1UL << bit_pos)) == 0);
|
| - switch (instr->Mask(TestBranchMask)) {
|
| - case TBZ: break;
|
| - case TBNZ: take_branch = !take_branch; break;
|
| - default: UNIMPLEMENTED();
|
| - }
|
| - if (take_branch) {
|
| - set_pc(instr->ImmPCOffsetTarget());
|
| - }
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitCompareBranch(Instruction* instr) {
|
| - unsigned rt = instr->Rt();
|
| - bool take_branch = false;
|
| - switch (instr->Mask(CompareBranchMask)) {
|
| - case CBZ_w: take_branch = (wreg(rt) == 0); break;
|
| - case CBZ_x: take_branch = (xreg(rt) == 0); break;
|
| - case CBNZ_w: take_branch = (wreg(rt) != 0); break;
|
| - case CBNZ_x: take_branch = (xreg(rt) != 0); break;
|
| - default: UNIMPLEMENTED();
|
| - }
|
| - if (take_branch) {
|
| - set_pc(instr->ImmPCOffsetTarget());
|
| - }
|
| -}
|
| -
|
| -
|
| -void Simulator::AddSubHelper(Instruction* instr, int64_t op2) {
|
| - unsigned reg_size = instr->SixtyFourBits() ? kXRegSizeInBits
|
| - : kWRegSizeInBits;
|
| - bool set_flags = instr->FlagsUpdate();
|
| - int64_t new_val = 0;
|
| - Instr operation = instr->Mask(AddSubOpMask);
|
| -
|
| - switch (operation) {
|
| - case ADD:
|
| - case ADDS: {
|
| - new_val = AddWithCarry(reg_size,
|
| - set_flags,
|
| - reg(reg_size, instr->Rn(), instr->RnMode()),
|
| - op2);
|
| - break;
|
| - }
|
| - case SUB:
|
| - case SUBS: {
|
| - new_val = AddWithCarry(reg_size,
|
| - set_flags,
|
| - reg(reg_size, instr->Rn(), instr->RnMode()),
|
| - ~op2,
|
| - 1);
|
| - break;
|
| - }
|
| - default: UNREACHABLE();
|
| - }
|
| -
|
| - set_reg(reg_size, instr->Rd(), new_val, instr->RdMode());
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitAddSubShifted(Instruction* instr) {
|
| - unsigned reg_size = instr->SixtyFourBits() ? kXRegSizeInBits
|
| - : kWRegSizeInBits;
|
| - int64_t op2 = ShiftOperand(reg_size,
|
| - reg(reg_size, instr->Rm()),
|
| - static_cast<Shift>(instr->ShiftDP()),
|
| - instr->ImmDPShift());
|
| - AddSubHelper(instr, op2);
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitAddSubImmediate(Instruction* instr) {
|
| - int64_t op2 = instr->ImmAddSub() << ((instr->ShiftAddSub() == 1) ? 12 : 0);
|
| - AddSubHelper(instr, op2);
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitAddSubExtended(Instruction* instr) {
|
| - unsigned reg_size = instr->SixtyFourBits() ? kXRegSizeInBits
|
| - : kWRegSizeInBits;
|
| - int64_t op2 = ExtendValue(reg_size,
|
| - reg(reg_size, instr->Rm()),
|
| - static_cast<Extend>(instr->ExtendMode()),
|
| - instr->ImmExtendShift());
|
| - AddSubHelper(instr, op2);
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitAddSubWithCarry(Instruction* instr) {
|
| - unsigned reg_size = instr->SixtyFourBits() ? kXRegSizeInBits
|
| - : kWRegSizeInBits;
|
| - int64_t op2 = reg(reg_size, instr->Rm());
|
| - int64_t new_val;
|
| -
|
| - if ((instr->Mask(AddSubOpMask) == SUB) || instr->Mask(AddSubOpMask) == SUBS) {
|
| - op2 = ~op2;
|
| - }
|
| -
|
| - new_val = AddWithCarry(reg_size,
|
| - instr->FlagsUpdate(),
|
| - reg(reg_size, instr->Rn()),
|
| - op2,
|
| - nzcv().C());
|
| -
|
| - set_reg(reg_size, instr->Rd(), new_val);
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitLogicalShifted(Instruction* instr) {
|
| - unsigned reg_size = instr->SixtyFourBits() ? kXRegSizeInBits
|
| - : kWRegSizeInBits;
|
| - Shift shift_type = static_cast<Shift>(instr->ShiftDP());
|
| - unsigned shift_amount = instr->ImmDPShift();
|
| - int64_t op2 = ShiftOperand(reg_size, reg(reg_size, instr->Rm()), shift_type,
|
| - shift_amount);
|
| - if (instr->Mask(NOT) == NOT) {
|
| - op2 = ~op2;
|
| - }
|
| - LogicalHelper(instr, op2);
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitLogicalImmediate(Instruction* instr) {
|
| - LogicalHelper(instr, instr->ImmLogical());
|
| -}
|
| -
|
| -
|
| -void Simulator::LogicalHelper(Instruction* instr, int64_t op2) {
|
| - unsigned reg_size = instr->SixtyFourBits() ? kXRegSizeInBits
|
| - : kWRegSizeInBits;
|
| - int64_t op1 = reg(reg_size, instr->Rn());
|
| - int64_t result = 0;
|
| - bool update_flags = false;
|
| -
|
| - // Switch on the logical operation, stripping out the NOT bit, as it has a
|
| - // different meaning for logical immediate instructions.
|
| - switch (instr->Mask(LogicalOpMask & ~NOT)) {
|
| - case ANDS: update_flags = true; // Fall through.
|
| - case AND: result = op1 & op2; break;
|
| - case ORR: result = op1 | op2; break;
|
| - case EOR: result = op1 ^ op2; break;
|
| - default:
|
| - UNIMPLEMENTED();
|
| - }
|
| -
|
| - if (update_flags) {
|
| - nzcv().SetN(CalcNFlag(result, reg_size));
|
| - nzcv().SetZ(CalcZFlag(result));
|
| - nzcv().SetC(0);
|
| - nzcv().SetV(0);
|
| - }
|
| -
|
| - set_reg(reg_size, instr->Rd(), result, instr->RdMode());
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitConditionalCompareRegister(Instruction* instr) {
|
| - unsigned reg_size = instr->SixtyFourBits() ? kXRegSizeInBits
|
| - : kWRegSizeInBits;
|
| - ConditionalCompareHelper(instr, reg(reg_size, instr->Rm()));
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitConditionalCompareImmediate(Instruction* instr) {
|
| - ConditionalCompareHelper(instr, instr->ImmCondCmp());
|
| -}
|
| -
|
| -
|
| -void Simulator::ConditionalCompareHelper(Instruction* instr, int64_t op2) {
|
| - unsigned reg_size = instr->SixtyFourBits() ? kXRegSizeInBits
|
| - : kWRegSizeInBits;
|
| - int64_t op1 = reg(reg_size, instr->Rn());
|
| -
|
| - if (ConditionPassed(static_cast<Condition>(instr->Condition()))) {
|
| - // If the condition passes, set the status flags to the result of comparing
|
| - // the operands.
|
| - if (instr->Mask(ConditionalCompareMask) == CCMP) {
|
| - AddWithCarry(reg_size, true, op1, ~op2, 1);
|
| - } else {
|
| - ASSERT(instr->Mask(ConditionalCompareMask) == CCMN);
|
| - AddWithCarry(reg_size, true, op1, op2, 0);
|
| - }
|
| - } else {
|
| - // If the condition fails, set the status flags to the nzcv immediate.
|
| - nzcv().SetFlags(instr->Nzcv());
|
| - }
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitLoadStoreUnsignedOffset(Instruction* instr) {
|
| - int offset = instr->ImmLSUnsigned() << instr->SizeLS();
|
| - LoadStoreHelper(instr, offset, Offset);
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitLoadStoreUnscaledOffset(Instruction* instr) {
|
| - LoadStoreHelper(instr, instr->ImmLS(), Offset);
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitLoadStorePreIndex(Instruction* instr) {
|
| - LoadStoreHelper(instr, instr->ImmLS(), PreIndex);
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitLoadStorePostIndex(Instruction* instr) {
|
| - LoadStoreHelper(instr, instr->ImmLS(), PostIndex);
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitLoadStoreRegisterOffset(Instruction* instr) {
|
| - Extend ext = static_cast<Extend>(instr->ExtendMode());
|
| - ASSERT((ext == UXTW) || (ext == UXTX) || (ext == SXTW) || (ext == SXTX));
|
| - unsigned shift_amount = instr->ImmShiftLS() * instr->SizeLS();
|
| -
|
| - int64_t offset = ExtendValue(kXRegSizeInBits, xreg(instr->Rm()), ext,
|
| - shift_amount);
|
| - LoadStoreHelper(instr, offset, Offset);
|
| -}
|
| -
|
| -
|
| -void Simulator::LoadStoreHelper(Instruction* instr,
|
| - int64_t offset,
|
| - AddrMode addrmode) {
|
| - unsigned srcdst = instr->Rt();
|
| - unsigned addr_reg = instr->Rn();
|
| - uint8_t* address = LoadStoreAddress(addr_reg, offset, addrmode);
|
| - int num_bytes = 1 << instr->SizeLS();
|
| - uint8_t* stack = NULL;
|
| -
|
| - // Handle the writeback for stores before the store. On a CPU the writeback
|
| - // and the store are atomic, but when running on the simulator it is possible
|
| - // to be interrupted in between. The simulator is not thread safe and V8 does
|
| - // not require it to be to run JavaScript therefore the profiler may sample
|
| - // the "simulated" CPU in the middle of load/store with writeback. The code
|
| - // below ensures that push operations are safe even when interrupted: the
|
| - // stack pointer will be decremented before adding an element to the stack.
|
| - if (instr->IsStore()) {
|
| - LoadStoreWriteBack(addr_reg, offset, addrmode);
|
| -
|
| - // For store the address post writeback is used to check access below the
|
| - // stack.
|
| - stack = reinterpret_cast<uint8_t*>(sp());
|
| - }
|
| -
|
| - LoadStoreOp op = static_cast<LoadStoreOp>(instr->Mask(LoadStoreOpMask));
|
| - switch (op) {
|
| - case LDRB_w:
|
| - case LDRH_w:
|
| - case LDR_w:
|
| - case LDR_x: set_xreg(srcdst, MemoryRead(address, num_bytes)); break;
|
| - case STRB_w:
|
| - case STRH_w:
|
| - case STR_w:
|
| - case STR_x: MemoryWrite(address, xreg(srcdst), num_bytes); break;
|
| - case LDRSB_w: {
|
| - set_wreg(srcdst,
|
| - ExtendValue(kWRegSizeInBits, MemoryRead8(address), SXTB));
|
| - break;
|
| - }
|
| - case LDRSB_x: {
|
| - set_xreg(srcdst,
|
| - ExtendValue(kXRegSizeInBits, MemoryRead8(address), SXTB));
|
| - break;
|
| - }
|
| - case LDRSH_w: {
|
| - set_wreg(srcdst,
|
| - ExtendValue(kWRegSizeInBits, MemoryRead16(address), SXTH));
|
| - break;
|
| - }
|
| - case LDRSH_x: {
|
| - set_xreg(srcdst,
|
| - ExtendValue(kXRegSizeInBits, MemoryRead16(address), SXTH));
|
| - break;
|
| - }
|
| - case LDRSW_x: {
|
| - set_xreg(srcdst,
|
| - ExtendValue(kXRegSizeInBits, MemoryRead32(address), SXTW));
|
| - break;
|
| - }
|
| - case LDR_s: set_sreg(srcdst, MemoryReadFP32(address)); break;
|
| - case LDR_d: set_dreg(srcdst, MemoryReadFP64(address)); break;
|
| - case STR_s: MemoryWriteFP32(address, sreg(srcdst)); break;
|
| - case STR_d: MemoryWriteFP64(address, dreg(srcdst)); break;
|
| - default: UNIMPLEMENTED();
|
| - }
|
| -
|
| - // Handle the writeback for loads after the load to ensure safe pop
|
| - // operation even when interrupted in the middle of it. The stack pointer
|
| - // is only updated after the load so pop(fp) will never break the invariant
|
| - // sp <= fp expected while walking the stack in the sampler.
|
| - if (instr->IsLoad()) {
|
| - // For loads the address pre writeback is used to check access below the
|
| - // stack.
|
| - stack = reinterpret_cast<uint8_t*>(sp());
|
| -
|
| - LoadStoreWriteBack(addr_reg, offset, addrmode);
|
| - }
|
| -
|
| - // Accesses below the stack pointer (but above the platform stack limit) are
|
| - // not allowed in the ABI.
|
| - CheckMemoryAccess(address, stack);
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitLoadStorePairOffset(Instruction* instr) {
|
| - LoadStorePairHelper(instr, Offset);
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitLoadStorePairPreIndex(Instruction* instr) {
|
| - LoadStorePairHelper(instr, PreIndex);
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitLoadStorePairPostIndex(Instruction* instr) {
|
| - LoadStorePairHelper(instr, PostIndex);
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitLoadStorePairNonTemporal(Instruction* instr) {
|
| - LoadStorePairHelper(instr, Offset);
|
| -}
|
| -
|
| -
|
| -void Simulator::LoadStorePairHelper(Instruction* instr,
|
| - AddrMode addrmode) {
|
| - unsigned rt = instr->Rt();
|
| - unsigned rt2 = instr->Rt2();
|
| - unsigned addr_reg = instr->Rn();
|
| - int offset = instr->ImmLSPair() << instr->SizeLSPair();
|
| - uint8_t* address = LoadStoreAddress(addr_reg, offset, addrmode);
|
| - uint8_t* stack = NULL;
|
| -
|
| - // Handle the writeback for stores before the store. On a CPU the writeback
|
| - // and the store are atomic, but when running on the simulator it is possible
|
| - // to be interrupted in between. The simulator is not thread safe and V8 does
|
| - // not require it to be to run JavaScript therefore the profiler may sample
|
| - // the "simulated" CPU in the middle of load/store with writeback. The code
|
| - // below ensures that push operations are safe even when interrupted: the
|
| - // stack pointer will be decremented before adding an element to the stack.
|
| - if (instr->IsStore()) {
|
| - LoadStoreWriteBack(addr_reg, offset, addrmode);
|
| -
|
| - // For store the address post writeback is used to check access below the
|
| - // stack.
|
| - stack = reinterpret_cast<uint8_t*>(sp());
|
| - }
|
| -
|
| - LoadStorePairOp op =
|
| - static_cast<LoadStorePairOp>(instr->Mask(LoadStorePairMask));
|
| -
|
| - // 'rt' and 'rt2' can only be aliased for stores.
|
| - ASSERT(((op & LoadStorePairLBit) == 0) || (rt != rt2));
|
| -
|
| - switch (op) {
|
| - case LDP_w: {
|
| - set_wreg(rt, MemoryRead32(address));
|
| - set_wreg(rt2, MemoryRead32(address + kWRegSize));
|
| - break;
|
| - }
|
| - case LDP_s: {
|
| - set_sreg(rt, MemoryReadFP32(address));
|
| - set_sreg(rt2, MemoryReadFP32(address + kSRegSize));
|
| - break;
|
| - }
|
| - case LDP_x: {
|
| - set_xreg(rt, MemoryRead64(address));
|
| - set_xreg(rt2, MemoryRead64(address + kXRegSize));
|
| - break;
|
| - }
|
| - case LDP_d: {
|
| - set_dreg(rt, MemoryReadFP64(address));
|
| - set_dreg(rt2, MemoryReadFP64(address + kDRegSize));
|
| - break;
|
| - }
|
| - case LDPSW_x: {
|
| - set_xreg(rt, ExtendValue(kXRegSizeInBits, MemoryRead32(address), SXTW));
|
| - set_xreg(rt2, ExtendValue(kXRegSizeInBits,
|
| - MemoryRead32(address + kWRegSize), SXTW));
|
| - break;
|
| - }
|
| - case STP_w: {
|
| - MemoryWrite32(address, wreg(rt));
|
| - MemoryWrite32(address + kWRegSize, wreg(rt2));
|
| - break;
|
| - }
|
| - case STP_s: {
|
| - MemoryWriteFP32(address, sreg(rt));
|
| - MemoryWriteFP32(address + kSRegSize, sreg(rt2));
|
| - break;
|
| - }
|
| - case STP_x: {
|
| - MemoryWrite64(address, xreg(rt));
|
| - MemoryWrite64(address + kXRegSize, xreg(rt2));
|
| - break;
|
| - }
|
| - case STP_d: {
|
| - MemoryWriteFP64(address, dreg(rt));
|
| - MemoryWriteFP64(address + kDRegSize, dreg(rt2));
|
| - break;
|
| - }
|
| - default: UNREACHABLE();
|
| - }
|
| -
|
| - // Handle the writeback for loads after the load to ensure safe pop
|
| - // operation even when interrupted in the middle of it. The stack pointer
|
| - // is only updated after the load so pop(fp) will never break the invariant
|
| - // sp <= fp expected while walking the stack in the sampler.
|
| - if (instr->IsLoad()) {
|
| - // For loads the address pre writeback is used to check access below the
|
| - // stack.
|
| - stack = reinterpret_cast<uint8_t*>(sp());
|
| -
|
| - LoadStoreWriteBack(addr_reg, offset, addrmode);
|
| - }
|
| -
|
| - // Accesses below the stack pointer (but above the platform stack limit) are
|
| - // not allowed in the ABI.
|
| - CheckMemoryAccess(address, stack);
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitLoadLiteral(Instruction* instr) {
|
| - uint8_t* address = instr->LiteralAddress();
|
| - unsigned rt = instr->Rt();
|
| -
|
| - switch (instr->Mask(LoadLiteralMask)) {
|
| - case LDR_w_lit: set_wreg(rt, MemoryRead32(address)); break;
|
| - case LDR_x_lit: set_xreg(rt, MemoryRead64(address)); break;
|
| - case LDR_s_lit: set_sreg(rt, MemoryReadFP32(address)); break;
|
| - case LDR_d_lit: set_dreg(rt, MemoryReadFP64(address)); break;
|
| - default: UNREACHABLE();
|
| - }
|
| -}
|
| -
|
| -
|
| -uint8_t* Simulator::LoadStoreAddress(unsigned addr_reg,
|
| - int64_t offset,
|
| - AddrMode addrmode) {
|
| - const unsigned kSPRegCode = kSPRegInternalCode & kRegCodeMask;
|
| - int64_t address = xreg(addr_reg, Reg31IsStackPointer);
|
| - if ((addr_reg == kSPRegCode) && ((address % 16) != 0)) {
|
| - // When the base register is SP the stack pointer is required to be
|
| - // quadword aligned prior to the address calculation and write-backs.
|
| - // Misalignment will cause a stack alignment fault.
|
| - FATAL("ALIGNMENT EXCEPTION");
|
| - }
|
| -
|
| - if ((addrmode == Offset) || (addrmode == PreIndex)) {
|
| - address += offset;
|
| - }
|
| -
|
| - return reinterpret_cast<uint8_t*>(address);
|
| -}
|
| -
|
| -
|
| -void Simulator::LoadStoreWriteBack(unsigned addr_reg,
|
| - int64_t offset,
|
| - AddrMode addrmode) {
|
| - if ((addrmode == PreIndex) || (addrmode == PostIndex)) {
|
| - ASSERT(offset != 0);
|
| - uint64_t address = xreg(addr_reg, Reg31IsStackPointer);
|
| - set_reg(addr_reg, address + offset, Reg31IsStackPointer);
|
| - }
|
| -}
|
| -
|
| -
|
| -void Simulator::CheckMemoryAccess(uint8_t* address, uint8_t* stack) {
|
| - if ((address >= stack_limit_) && (address < stack)) {
|
| - fprintf(stream_, "ACCESS BELOW STACK POINTER:\n");
|
| - fprintf(stream_, " sp is here: 0x%16p\n", stack);
|
| - fprintf(stream_, " access was here: 0x%16p\n", address);
|
| - fprintf(stream_, " stack limit is here: 0x%16p\n", stack_limit_);
|
| - fprintf(stream_, "\n");
|
| - FATAL("ACCESS BELOW STACK POINTER");
|
| - }
|
| -}
|
| -
|
| -
|
| -uint64_t Simulator::MemoryRead(uint8_t* address, unsigned num_bytes) {
|
| - ASSERT(address != NULL);
|
| - ASSERT((num_bytes > 0) && (num_bytes <= sizeof(uint64_t)));
|
| - uint64_t read = 0;
|
| - memcpy(&read, address, num_bytes);
|
| - return read;
|
| -}
|
| -
|
| -
|
| -uint8_t Simulator::MemoryRead8(uint8_t* address) {
|
| - return MemoryRead(address, sizeof(uint8_t));
|
| -}
|
| -
|
| -
|
| -uint16_t Simulator::MemoryRead16(uint8_t* address) {
|
| - return MemoryRead(address, sizeof(uint16_t));
|
| -}
|
| -
|
| -
|
| -uint32_t Simulator::MemoryRead32(uint8_t* address) {
|
| - return MemoryRead(address, sizeof(uint32_t));
|
| -}
|
| -
|
| -
|
| -float Simulator::MemoryReadFP32(uint8_t* address) {
|
| - return rawbits_to_float(MemoryRead32(address));
|
| -}
|
| -
|
| -
|
| -uint64_t Simulator::MemoryRead64(uint8_t* address) {
|
| - return MemoryRead(address, sizeof(uint64_t));
|
| -}
|
| -
|
| -
|
| -double Simulator::MemoryReadFP64(uint8_t* address) {
|
| - return rawbits_to_double(MemoryRead64(address));
|
| -}
|
| -
|
| -
|
| -void Simulator::MemoryWrite(uint8_t* address,
|
| - uint64_t value,
|
| - unsigned num_bytes) {
|
| - ASSERT(address != NULL);
|
| - ASSERT((num_bytes > 0) && (num_bytes <= sizeof(uint64_t)));
|
| -
|
| - LogWrite(address, value, num_bytes);
|
| - memcpy(address, &value, num_bytes);
|
| -}
|
| -
|
| -
|
| -void Simulator::MemoryWrite32(uint8_t* address, uint32_t value) {
|
| - MemoryWrite(address, value, sizeof(uint32_t));
|
| -}
|
| -
|
| -
|
| -void Simulator::MemoryWriteFP32(uint8_t* address, float value) {
|
| - MemoryWrite32(address, float_to_rawbits(value));
|
| -}
|
| -
|
| -
|
| -void Simulator::MemoryWrite64(uint8_t* address, uint64_t value) {
|
| - MemoryWrite(address, value, sizeof(uint64_t));
|
| -}
|
| -
|
| -
|
| -void Simulator::MemoryWriteFP64(uint8_t* address, double value) {
|
| - MemoryWrite64(address, double_to_rawbits(value));
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitMoveWideImmediate(Instruction* instr) {
|
| - MoveWideImmediateOp mov_op =
|
| - static_cast<MoveWideImmediateOp>(instr->Mask(MoveWideImmediateMask));
|
| - int64_t new_xn_val = 0;
|
| -
|
| - bool is_64_bits = instr->SixtyFourBits() == 1;
|
| - // Shift is limited for W operations.
|
| - ASSERT(is_64_bits || (instr->ShiftMoveWide() < 2));
|
| -
|
| - // Get the shifted immediate.
|
| - int64_t shift = instr->ShiftMoveWide() * 16;
|
| - int64_t shifted_imm16 = instr->ImmMoveWide() << shift;
|
| -
|
| - // Compute the new value.
|
| - switch (mov_op) {
|
| - case MOVN_w:
|
| - case MOVN_x: {
|
| - new_xn_val = ~shifted_imm16;
|
| - if (!is_64_bits) new_xn_val &= kWRegMask;
|
| - break;
|
| - }
|
| - case MOVK_w:
|
| - case MOVK_x: {
|
| - unsigned reg_code = instr->Rd();
|
| - int64_t prev_xn_val = is_64_bits ? xreg(reg_code)
|
| - : wreg(reg_code);
|
| - new_xn_val = (prev_xn_val & ~(0xffffL << shift)) | shifted_imm16;
|
| - break;
|
| - }
|
| - case MOVZ_w:
|
| - case MOVZ_x: {
|
| - new_xn_val = shifted_imm16;
|
| - break;
|
| - }
|
| - default:
|
| - UNREACHABLE();
|
| - }
|
| -
|
| - // Update the destination register.
|
| - set_xreg(instr->Rd(), new_xn_val);
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitConditionalSelect(Instruction* instr) {
|
| - uint64_t new_val = xreg(instr->Rn());
|
| -
|
| - if (ConditionFailed(static_cast<Condition>(instr->Condition()))) {
|
| - new_val = xreg(instr->Rm());
|
| - switch (instr->Mask(ConditionalSelectMask)) {
|
| - case CSEL_w:
|
| - case CSEL_x: break;
|
| - case CSINC_w:
|
| - case CSINC_x: new_val++; break;
|
| - case CSINV_w:
|
| - case CSINV_x: new_val = ~new_val; break;
|
| - case CSNEG_w:
|
| - case CSNEG_x: new_val = -new_val; break;
|
| - default: UNIMPLEMENTED();
|
| - }
|
| - }
|
| - unsigned reg_size = instr->SixtyFourBits() ? kXRegSizeInBits
|
| - : kWRegSizeInBits;
|
| - set_reg(reg_size, instr->Rd(), new_val);
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitDataProcessing1Source(Instruction* instr) {
|
| - unsigned dst = instr->Rd();
|
| - unsigned src = instr->Rn();
|
| -
|
| - switch (instr->Mask(DataProcessing1SourceMask)) {
|
| - case RBIT_w: set_wreg(dst, ReverseBits(wreg(src), kWRegSizeInBits)); break;
|
| - case RBIT_x: set_xreg(dst, ReverseBits(xreg(src), kXRegSizeInBits)); break;
|
| - case REV16_w: set_wreg(dst, ReverseBytes(wreg(src), Reverse16)); break;
|
| - case REV16_x: set_xreg(dst, ReverseBytes(xreg(src), Reverse16)); break;
|
| - case REV_w: set_wreg(dst, ReverseBytes(wreg(src), Reverse32)); break;
|
| - case REV32_x: set_xreg(dst, ReverseBytes(xreg(src), Reverse32)); break;
|
| - case REV_x: set_xreg(dst, ReverseBytes(xreg(src), Reverse64)); break;
|
| - case CLZ_w: set_wreg(dst, CountLeadingZeros(wreg(src), kWRegSizeInBits));
|
| - break;
|
| - case CLZ_x: set_xreg(dst, CountLeadingZeros(xreg(src), kXRegSizeInBits));
|
| - break;
|
| - case CLS_w: {
|
| - set_wreg(dst, CountLeadingSignBits(wreg(src), kWRegSizeInBits));
|
| - break;
|
| - }
|
| - case CLS_x: {
|
| - set_xreg(dst, CountLeadingSignBits(xreg(src), kXRegSizeInBits));
|
| - break;
|
| - }
|
| - default: UNIMPLEMENTED();
|
| - }
|
| -}
|
| -
|
| -
|
| -uint64_t Simulator::ReverseBits(uint64_t value, unsigned num_bits) {
|
| - ASSERT((num_bits == kWRegSizeInBits) || (num_bits == kXRegSizeInBits));
|
| - uint64_t result = 0;
|
| - for (unsigned i = 0; i < num_bits; i++) {
|
| - result = (result << 1) | (value & 1);
|
| - value >>= 1;
|
| - }
|
| - return result;
|
| -}
|
| -
|
| -
|
| -uint64_t Simulator::ReverseBytes(uint64_t value, ReverseByteMode mode) {
|
| - // Split the 64-bit value into an 8-bit array, where b[0] is the least
|
| - // significant byte, and b[7] is the most significant.
|
| - uint8_t bytes[8];
|
| - uint64_t mask = 0xff00000000000000UL;
|
| - for (int i = 7; i >= 0; i--) {
|
| - bytes[i] = (value & mask) >> (i * 8);
|
| - mask >>= 8;
|
| - }
|
| -
|
| - // Permutation tables for REV instructions.
|
| - // permute_table[Reverse16] is used by REV16_x, REV16_w
|
| - // permute_table[Reverse32] is used by REV32_x, REV_w
|
| - // permute_table[Reverse64] is used by REV_x
|
| - ASSERT((Reverse16 == 0) && (Reverse32 == 1) && (Reverse64 == 2));
|
| - static const uint8_t permute_table[3][8] = { {6, 7, 4, 5, 2, 3, 0, 1},
|
| - {4, 5, 6, 7, 0, 1, 2, 3},
|
| - {0, 1, 2, 3, 4, 5, 6, 7} };
|
| - uint64_t result = 0;
|
| - for (int i = 0; i < 8; i++) {
|
| - result <<= 8;
|
| - result |= bytes[permute_table[mode][i]];
|
| - }
|
| - return result;
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitDataProcessing2Source(Instruction* instr) {
|
| - Shift shift_op = NO_SHIFT;
|
| - int64_t result = 0;
|
| - switch (instr->Mask(DataProcessing2SourceMask)) {
|
| - case SDIV_w: {
|
| - int32_t rn = wreg(instr->Rn());
|
| - int32_t rm = wreg(instr->Rm());
|
| - if ((rn == kWMinInt) && (rm == -1)) {
|
| - result = kWMinInt;
|
| - } else if (rm == 0) {
|
| - // Division by zero can be trapped, but not on A-class processors.
|
| - result = 0;
|
| - } else {
|
| - result = rn / rm;
|
| - }
|
| - break;
|
| - }
|
| - case SDIV_x: {
|
| - int64_t rn = xreg(instr->Rn());
|
| - int64_t rm = xreg(instr->Rm());
|
| - if ((rn == kXMinInt) && (rm == -1)) {
|
| - result = kXMinInt;
|
| - } else if (rm == 0) {
|
| - // Division by zero can be trapped, but not on A-class processors.
|
| - result = 0;
|
| - } else {
|
| - result = rn / rm;
|
| - }
|
| - break;
|
| - }
|
| - case UDIV_w: {
|
| - uint32_t rn = static_cast<uint32_t>(wreg(instr->Rn()));
|
| - uint32_t rm = static_cast<uint32_t>(wreg(instr->Rm()));
|
| - if (rm == 0) {
|
| - // Division by zero can be trapped, but not on A-class processors.
|
| - result = 0;
|
| - } else {
|
| - result = rn / rm;
|
| - }
|
| - break;
|
| - }
|
| - case UDIV_x: {
|
| - uint64_t rn = static_cast<uint64_t>(xreg(instr->Rn()));
|
| - uint64_t rm = static_cast<uint64_t>(xreg(instr->Rm()));
|
| - if (rm == 0) {
|
| - // Division by zero can be trapped, but not on A-class processors.
|
| - result = 0;
|
| - } else {
|
| - result = rn / rm;
|
| - }
|
| - break;
|
| - }
|
| - case LSLV_w:
|
| - case LSLV_x: shift_op = LSL; break;
|
| - case LSRV_w:
|
| - case LSRV_x: shift_op = LSR; break;
|
| - case ASRV_w:
|
| - case ASRV_x: shift_op = ASR; break;
|
| - case RORV_w:
|
| - case RORV_x: shift_op = ROR; break;
|
| - default: UNIMPLEMENTED();
|
| - }
|
| -
|
| - unsigned reg_size = instr->SixtyFourBits() ? kXRegSizeInBits
|
| - : kWRegSizeInBits;
|
| - if (shift_op != NO_SHIFT) {
|
| - // Shift distance encoded in the least-significant five/six bits of the
|
| - // register.
|
| - int mask = (instr->SixtyFourBits() == 1) ? 0x3f : 0x1f;
|
| - unsigned shift = wreg(instr->Rm()) & mask;
|
| - result = ShiftOperand(reg_size, reg(reg_size, instr->Rn()), shift_op,
|
| - shift);
|
| - }
|
| - set_reg(reg_size, instr->Rd(), result);
|
| -}
|
| -
|
| -
|
| -// The algorithm used is described in section 8.2 of
|
| -// Hacker's Delight, by Henry S. Warren, Jr.
|
| -// It assumes that a right shift on a signed integer is an arithmetic shift.
|
| -static int64_t MultiplyHighSigned(int64_t u, int64_t v) {
|
| - uint64_t u0, v0, w0;
|
| - int64_t u1, v1, w1, w2, t;
|
| -
|
| - u0 = u & 0xffffffffL;
|
| - u1 = u >> 32;
|
| - v0 = v & 0xffffffffL;
|
| - v1 = v >> 32;
|
| -
|
| - w0 = u0 * v0;
|
| - t = u1 * v0 + (w0 >> 32);
|
| - w1 = t & 0xffffffffL;
|
| - w2 = t >> 32;
|
| - w1 = u0 * v1 + w1;
|
| -
|
| - return u1 * v1 + w2 + (w1 >> 32);
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitDataProcessing3Source(Instruction* instr) {
|
| - unsigned reg_size = instr->SixtyFourBits() ? kXRegSizeInBits
|
| - : kWRegSizeInBits;
|
| -
|
| - int64_t result = 0;
|
| - // Extract and sign- or zero-extend 32-bit arguments for widening operations.
|
| - uint64_t rn_u32 = reg<uint32_t>(instr->Rn());
|
| - uint64_t rm_u32 = reg<uint32_t>(instr->Rm());
|
| - int64_t rn_s32 = reg<int32_t>(instr->Rn());
|
| - int64_t rm_s32 = reg<int32_t>(instr->Rm());
|
| - switch (instr->Mask(DataProcessing3SourceMask)) {
|
| - case MADD_w:
|
| - case MADD_x:
|
| - result = xreg(instr->Ra()) + (xreg(instr->Rn()) * xreg(instr->Rm()));
|
| - break;
|
| - case MSUB_w:
|
| - case MSUB_x:
|
| - result = xreg(instr->Ra()) - (xreg(instr->Rn()) * xreg(instr->Rm()));
|
| - break;
|
| - case SMADDL_x: result = xreg(instr->Ra()) + (rn_s32 * rm_s32); break;
|
| - case SMSUBL_x: result = xreg(instr->Ra()) - (rn_s32 * rm_s32); break;
|
| - case UMADDL_x: result = xreg(instr->Ra()) + (rn_u32 * rm_u32); break;
|
| - case UMSUBL_x: result = xreg(instr->Ra()) - (rn_u32 * rm_u32); break;
|
| - case SMULH_x:
|
| - ASSERT(instr->Ra() == kZeroRegCode);
|
| - result = MultiplyHighSigned(xreg(instr->Rn()), xreg(instr->Rm()));
|
| - break;
|
| - default: UNIMPLEMENTED();
|
| - }
|
| - set_reg(reg_size, instr->Rd(), result);
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitBitfield(Instruction* instr) {
|
| - unsigned reg_size = instr->SixtyFourBits() ? kXRegSizeInBits
|
| - : kWRegSizeInBits;
|
| - int64_t reg_mask = instr->SixtyFourBits() ? kXRegMask : kWRegMask;
|
| - int64_t R = instr->ImmR();
|
| - int64_t S = instr->ImmS();
|
| - int64_t diff = S - R;
|
| - int64_t mask;
|
| - if (diff >= 0) {
|
| - mask = diff < reg_size - 1 ? (1L << (diff + 1)) - 1
|
| - : reg_mask;
|
| - } else {
|
| - mask = ((1L << (S + 1)) - 1);
|
| - mask = (static_cast<uint64_t>(mask) >> R) | (mask << (reg_size - R));
|
| - diff += reg_size;
|
| - }
|
| -
|
| - // inzero indicates if the extracted bitfield is inserted into the
|
| - // destination register value or in zero.
|
| - // If extend is true, extend the sign of the extracted bitfield.
|
| - bool inzero = false;
|
| - bool extend = false;
|
| - switch (instr->Mask(BitfieldMask)) {
|
| - case BFM_x:
|
| - case BFM_w:
|
| - break;
|
| - case SBFM_x:
|
| - case SBFM_w:
|
| - inzero = true;
|
| - extend = true;
|
| - break;
|
| - case UBFM_x:
|
| - case UBFM_w:
|
| - inzero = true;
|
| - break;
|
| - default:
|
| - UNIMPLEMENTED();
|
| - }
|
| -
|
| - int64_t dst = inzero ? 0 : reg(reg_size, instr->Rd());
|
| - int64_t src = reg(reg_size, instr->Rn());
|
| - // Rotate source bitfield into place.
|
| - int64_t result = (static_cast<uint64_t>(src) >> R) | (src << (reg_size - R));
|
| - // Determine the sign extension.
|
| - int64_t topbits = ((1L << (reg_size - diff - 1)) - 1) << (diff + 1);
|
| - int64_t signbits = extend && ((src >> S) & 1) ? topbits : 0;
|
| -
|
| - // Merge sign extension, dest/zero and bitfield.
|
| - result = signbits | (result & mask) | (dst & ~mask);
|
| -
|
| - set_reg(reg_size, instr->Rd(), result);
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitExtract(Instruction* instr) {
|
| - unsigned lsb = instr->ImmS();
|
| - unsigned reg_size = (instr->SixtyFourBits() == 1) ? kXRegSizeInBits
|
| - : kWRegSizeInBits;
|
| - set_reg(reg_size,
|
| - instr->Rd(),
|
| - (static_cast<uint64_t>(reg(reg_size, instr->Rm())) >> lsb) |
|
| - (reg(reg_size, instr->Rn()) << (reg_size - lsb)));
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitFPImmediate(Instruction* instr) {
|
| - AssertSupportedFPCR();
|
| -
|
| - unsigned dest = instr->Rd();
|
| - switch (instr->Mask(FPImmediateMask)) {
|
| - case FMOV_s_imm: set_sreg(dest, instr->ImmFP32()); break;
|
| - case FMOV_d_imm: set_dreg(dest, instr->ImmFP64()); break;
|
| - default: UNREACHABLE();
|
| - }
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitFPIntegerConvert(Instruction* instr) {
|
| - AssertSupportedFPCR();
|
| -
|
| - unsigned dst = instr->Rd();
|
| - unsigned src = instr->Rn();
|
| -
|
| - FPRounding round = fpcr().RMode();
|
| -
|
| - switch (instr->Mask(FPIntegerConvertMask)) {
|
| - case FCVTAS_ws: set_wreg(dst, FPToInt32(sreg(src), FPTieAway)); break;
|
| - case FCVTAS_xs: set_xreg(dst, FPToInt64(sreg(src), FPTieAway)); break;
|
| - case FCVTAS_wd: set_wreg(dst, FPToInt32(dreg(src), FPTieAway)); break;
|
| - case FCVTAS_xd: set_xreg(dst, FPToInt64(dreg(src), FPTieAway)); break;
|
| - case FCVTAU_ws: set_wreg(dst, FPToUInt32(sreg(src), FPTieAway)); break;
|
| - case FCVTAU_xs: set_xreg(dst, FPToUInt64(sreg(src), FPTieAway)); break;
|
| - case FCVTAU_wd: set_wreg(dst, FPToUInt32(dreg(src), FPTieAway)); break;
|
| - case FCVTAU_xd: set_xreg(dst, FPToUInt64(dreg(src), FPTieAway)); break;
|
| - case FCVTMS_ws:
|
| - set_wreg(dst, FPToInt32(sreg(src), FPNegativeInfinity));
|
| - break;
|
| - case FCVTMS_xs:
|
| - set_xreg(dst, FPToInt64(sreg(src), FPNegativeInfinity));
|
| - break;
|
| - case FCVTMS_wd:
|
| - set_wreg(dst, FPToInt32(dreg(src), FPNegativeInfinity));
|
| - break;
|
| - case FCVTMS_xd:
|
| - set_xreg(dst, FPToInt64(dreg(src), FPNegativeInfinity));
|
| - break;
|
| - case FCVTMU_ws:
|
| - set_wreg(dst, FPToUInt32(sreg(src), FPNegativeInfinity));
|
| - break;
|
| - case FCVTMU_xs:
|
| - set_xreg(dst, FPToUInt64(sreg(src), FPNegativeInfinity));
|
| - break;
|
| - case FCVTMU_wd:
|
| - set_wreg(dst, FPToUInt32(dreg(src), FPNegativeInfinity));
|
| - break;
|
| - case FCVTMU_xd:
|
| - set_xreg(dst, FPToUInt64(dreg(src), FPNegativeInfinity));
|
| - break;
|
| - case FCVTNS_ws: set_wreg(dst, FPToInt32(sreg(src), FPTieEven)); break;
|
| - case FCVTNS_xs: set_xreg(dst, FPToInt64(sreg(src), FPTieEven)); break;
|
| - case FCVTNS_wd: set_wreg(dst, FPToInt32(dreg(src), FPTieEven)); break;
|
| - case FCVTNS_xd: set_xreg(dst, FPToInt64(dreg(src), FPTieEven)); break;
|
| - case FCVTNU_ws: set_wreg(dst, FPToUInt32(sreg(src), FPTieEven)); break;
|
| - case FCVTNU_xs: set_xreg(dst, FPToUInt64(sreg(src), FPTieEven)); break;
|
| - case FCVTNU_wd: set_wreg(dst, FPToUInt32(dreg(src), FPTieEven)); break;
|
| - case FCVTNU_xd: set_xreg(dst, FPToUInt64(dreg(src), FPTieEven)); break;
|
| - case FCVTZS_ws: set_wreg(dst, FPToInt32(sreg(src), FPZero)); break;
|
| - case FCVTZS_xs: set_xreg(dst, FPToInt64(sreg(src), FPZero)); break;
|
| - case FCVTZS_wd: set_wreg(dst, FPToInt32(dreg(src), FPZero)); break;
|
| - case FCVTZS_xd: set_xreg(dst, FPToInt64(dreg(src), FPZero)); break;
|
| - case FCVTZU_ws: set_wreg(dst, FPToUInt32(sreg(src), FPZero)); break;
|
| - case FCVTZU_xs: set_xreg(dst, FPToUInt64(sreg(src), FPZero)); break;
|
| - case FCVTZU_wd: set_wreg(dst, FPToUInt32(dreg(src), FPZero)); break;
|
| - case FCVTZU_xd: set_xreg(dst, FPToUInt64(dreg(src), FPZero)); break;
|
| - case FMOV_ws: set_wreg(dst, sreg_bits(src)); break;
|
| - case FMOV_xd: set_xreg(dst, dreg_bits(src)); break;
|
| - case FMOV_sw: set_sreg_bits(dst, wreg(src)); break;
|
| - case FMOV_dx: set_dreg_bits(dst, xreg(src)); break;
|
| -
|
| - // A 32-bit input can be handled in the same way as a 64-bit input, since
|
| - // the sign- or zero-extension will not affect the conversion.
|
| - case SCVTF_dx: set_dreg(dst, FixedToDouble(xreg(src), 0, round)); break;
|
| - case SCVTF_dw: set_dreg(dst, FixedToDouble(wreg(src), 0, round)); break;
|
| - case UCVTF_dx: set_dreg(dst, UFixedToDouble(xreg(src), 0, round)); break;
|
| - case UCVTF_dw: {
|
| - set_dreg(dst, UFixedToDouble(reg<uint32_t>(src), 0, round));
|
| - break;
|
| - }
|
| - case SCVTF_sx: set_sreg(dst, FixedToFloat(xreg(src), 0, round)); break;
|
| - case SCVTF_sw: set_sreg(dst, FixedToFloat(wreg(src), 0, round)); break;
|
| - case UCVTF_sx: set_sreg(dst, UFixedToFloat(xreg(src), 0, round)); break;
|
| - case UCVTF_sw: {
|
| - set_sreg(dst, UFixedToFloat(reg<uint32_t>(src), 0, round));
|
| - break;
|
| - }
|
| -
|
| - default: UNREACHABLE();
|
| - }
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitFPFixedPointConvert(Instruction* instr) {
|
| - AssertSupportedFPCR();
|
| -
|
| - unsigned dst = instr->Rd();
|
| - unsigned src = instr->Rn();
|
| - int fbits = 64 - instr->FPScale();
|
| -
|
| - FPRounding round = fpcr().RMode();
|
| -
|
| - switch (instr->Mask(FPFixedPointConvertMask)) {
|
| - // A 32-bit input can be handled in the same way as a 64-bit input, since
|
| - // the sign- or zero-extension will not affect the conversion.
|
| - case SCVTF_dx_fixed:
|
| - set_dreg(dst, FixedToDouble(xreg(src), fbits, round));
|
| - break;
|
| - case SCVTF_dw_fixed:
|
| - set_dreg(dst, FixedToDouble(wreg(src), fbits, round));
|
| - break;
|
| - case UCVTF_dx_fixed:
|
| - set_dreg(dst, UFixedToDouble(xreg(src), fbits, round));
|
| - break;
|
| - case UCVTF_dw_fixed: {
|
| - set_dreg(dst,
|
| - UFixedToDouble(reg<uint32_t>(src), fbits, round));
|
| - break;
|
| - }
|
| - case SCVTF_sx_fixed:
|
| - set_sreg(dst, FixedToFloat(xreg(src), fbits, round));
|
| - break;
|
| - case SCVTF_sw_fixed:
|
| - set_sreg(dst, FixedToFloat(wreg(src), fbits, round));
|
| - break;
|
| - case UCVTF_sx_fixed:
|
| - set_sreg(dst, UFixedToFloat(xreg(src), fbits, round));
|
| - break;
|
| - case UCVTF_sw_fixed: {
|
| - set_sreg(dst,
|
| - UFixedToFloat(reg<uint32_t>(src), fbits, round));
|
| - break;
|
| - }
|
| - default: UNREACHABLE();
|
| - }
|
| -}
|
| -
|
| -
|
| -int32_t Simulator::FPToInt32(double value, FPRounding rmode) {
|
| - value = FPRoundInt(value, rmode);
|
| - if (value >= kWMaxInt) {
|
| - return kWMaxInt;
|
| - } else if (value < kWMinInt) {
|
| - return kWMinInt;
|
| - }
|
| - return std::isnan(value) ? 0 : static_cast<int32_t>(value);
|
| -}
|
| -
|
| -
|
| -int64_t Simulator::FPToInt64(double value, FPRounding rmode) {
|
| - value = FPRoundInt(value, rmode);
|
| - if (value >= kXMaxInt) {
|
| - return kXMaxInt;
|
| - } else if (value < kXMinInt) {
|
| - return kXMinInt;
|
| - }
|
| - return std::isnan(value) ? 0 : static_cast<int64_t>(value);
|
| -}
|
| -
|
| -
|
| -uint32_t Simulator::FPToUInt32(double value, FPRounding rmode) {
|
| - value = FPRoundInt(value, rmode);
|
| - if (value >= kWMaxUInt) {
|
| - return kWMaxUInt;
|
| - } else if (value < 0.0) {
|
| - return 0;
|
| - }
|
| - return std::isnan(value) ? 0 : static_cast<uint32_t>(value);
|
| -}
|
| -
|
| -
|
| -uint64_t Simulator::FPToUInt64(double value, FPRounding rmode) {
|
| - value = FPRoundInt(value, rmode);
|
| - if (value >= kXMaxUInt) {
|
| - return kXMaxUInt;
|
| - } else if (value < 0.0) {
|
| - return 0;
|
| - }
|
| - return std::isnan(value) ? 0 : static_cast<uint64_t>(value);
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitFPCompare(Instruction* instr) {
|
| - AssertSupportedFPCR();
|
| -
|
| - unsigned reg_size = (instr->Mask(FP64) == FP64) ? kDRegSizeInBits
|
| - : kSRegSizeInBits;
|
| - double fn_val = fpreg(reg_size, instr->Rn());
|
| -
|
| - switch (instr->Mask(FPCompareMask)) {
|
| - case FCMP_s:
|
| - case FCMP_d: FPCompare(fn_val, fpreg(reg_size, instr->Rm())); break;
|
| - case FCMP_s_zero:
|
| - case FCMP_d_zero: FPCompare(fn_val, 0.0); break;
|
| - default: UNIMPLEMENTED();
|
| - }
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitFPConditionalCompare(Instruction* instr) {
|
| - AssertSupportedFPCR();
|
| -
|
| - switch (instr->Mask(FPConditionalCompareMask)) {
|
| - case FCCMP_s:
|
| - case FCCMP_d: {
|
| - if (ConditionPassed(static_cast<Condition>(instr->Condition()))) {
|
| - // If the condition passes, set the status flags to the result of
|
| - // comparing the operands.
|
| - unsigned reg_size = (instr->Mask(FP64) == FP64) ? kDRegSizeInBits
|
| - : kSRegSizeInBits;
|
| - FPCompare(fpreg(reg_size, instr->Rn()), fpreg(reg_size, instr->Rm()));
|
| - } else {
|
| - // If the condition fails, set the status flags to the nzcv immediate.
|
| - nzcv().SetFlags(instr->Nzcv());
|
| - }
|
| - break;
|
| - }
|
| - default: UNIMPLEMENTED();
|
| - }
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitFPConditionalSelect(Instruction* instr) {
|
| - AssertSupportedFPCR();
|
| -
|
| - Instr selected;
|
| - if (ConditionPassed(static_cast<Condition>(instr->Condition()))) {
|
| - selected = instr->Rn();
|
| - } else {
|
| - selected = instr->Rm();
|
| - }
|
| -
|
| - switch (instr->Mask(FPConditionalSelectMask)) {
|
| - case FCSEL_s: set_sreg(instr->Rd(), sreg(selected)); break;
|
| - case FCSEL_d: set_dreg(instr->Rd(), dreg(selected)); break;
|
| - default: UNIMPLEMENTED();
|
| - }
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitFPDataProcessing1Source(Instruction* instr) {
|
| - AssertSupportedFPCR();
|
| -
|
| - unsigned fd = instr->Rd();
|
| - unsigned fn = instr->Rn();
|
| -
|
| - switch (instr->Mask(FPDataProcessing1SourceMask)) {
|
| - case FMOV_s: set_sreg(fd, sreg(fn)); break;
|
| - case FMOV_d: set_dreg(fd, dreg(fn)); break;
|
| - case FABS_s: set_sreg(fd, std::fabs(sreg(fn))); break;
|
| - case FABS_d: set_dreg(fd, std::fabs(dreg(fn))); break;
|
| - case FNEG_s: set_sreg(fd, -sreg(fn)); break;
|
| - case FNEG_d: set_dreg(fd, -dreg(fn)); break;
|
| - case FSQRT_s: set_sreg(fd, FPSqrt(sreg(fn))); break;
|
| - case FSQRT_d: set_dreg(fd, FPSqrt(dreg(fn))); break;
|
| - case FRINTA_s: set_sreg(fd, FPRoundInt(sreg(fn), FPTieAway)); break;
|
| - case FRINTA_d: set_dreg(fd, FPRoundInt(dreg(fn), FPTieAway)); break;
|
| - case FRINTN_s: set_sreg(fd, FPRoundInt(sreg(fn), FPTieEven)); break;
|
| - case FRINTN_d: set_dreg(fd, FPRoundInt(dreg(fn), FPTieEven)); break;
|
| - case FRINTZ_s: set_sreg(fd, FPRoundInt(sreg(fn), FPZero)); break;
|
| - case FRINTZ_d: set_dreg(fd, FPRoundInt(dreg(fn), FPZero)); break;
|
| - case FCVT_ds: set_dreg(fd, FPToDouble(sreg(fn))); break;
|
| - case FCVT_sd: set_sreg(fd, FPToFloat(dreg(fn), FPTieEven)); break;
|
| - default: UNIMPLEMENTED();
|
| - }
|
| -}
|
| -
|
| -
|
| -// Assemble the specified IEEE-754 components into the target type and apply
|
| -// appropriate rounding.
|
| -// sign: 0 = positive, 1 = negative
|
| -// exponent: Unbiased IEEE-754 exponent.
|
| -// mantissa: The mantissa of the input. The top bit (which is not encoded for
|
| -// normal IEEE-754 values) must not be omitted. This bit has the
|
| -// value 'pow(2, exponent)'.
|
| -//
|
| -// The input value is assumed to be a normalized value. That is, the input may
|
| -// not be infinity or NaN. If the source value is subnormal, it must be
|
| -// normalized before calling this function such that the highest set bit in the
|
| -// mantissa has the value 'pow(2, exponent)'.
|
| -//
|
| -// Callers should use FPRoundToFloat or FPRoundToDouble directly, rather than
|
| -// calling a templated FPRound.
|
| -template <class T, int ebits, int mbits>
|
| -static T FPRound(int64_t sign, int64_t exponent, uint64_t mantissa,
|
| - FPRounding round_mode) {
|
| - ASSERT((sign == 0) || (sign == 1));
|
| -
|
| - // Only the FPTieEven rounding mode is implemented.
|
| - ASSERT(round_mode == FPTieEven);
|
| - USE(round_mode);
|
| -
|
| - // Rounding can promote subnormals to normals, and normals to infinities. For
|
| - // example, a double with exponent 127 (FLT_MAX_EXP) would appear to be
|
| - // encodable as a float, but rounding based on the low-order mantissa bits
|
| - // could make it overflow. With ties-to-even rounding, this value would become
|
| - // an infinity.
|
| -
|
| - // ---- Rounding Method ----
|
| - //
|
| - // The exponent is irrelevant in the rounding operation, so we treat the
|
| - // lowest-order bit that will fit into the result ('onebit') as having
|
| - // the value '1'. Similarly, the highest-order bit that won't fit into
|
| - // the result ('halfbit') has the value '0.5'. The 'point' sits between
|
| - // 'onebit' and 'halfbit':
|
| - //
|
| - // These bits fit into the result.
|
| - // |---------------------|
|
| - // mantissa = 0bxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx
|
| - // ||
|
| - // / |
|
| - // / halfbit
|
| - // onebit
|
| - //
|
| - // For subnormal outputs, the range of representable bits is smaller and
|
| - // the position of onebit and halfbit depends on the exponent of the
|
| - // input, but the method is otherwise similar.
|
| - //
|
| - // onebit(frac)
|
| - // |
|
| - // | halfbit(frac) halfbit(adjusted)
|
| - // | / /
|
| - // | | |
|
| - // 0b00.0 (exact) -> 0b00.0 (exact) -> 0b00
|
| - // 0b00.0... -> 0b00.0... -> 0b00
|
| - // 0b00.1 (exact) -> 0b00.0111..111 -> 0b00
|
| - // 0b00.1... -> 0b00.1... -> 0b01
|
| - // 0b01.0 (exact) -> 0b01.0 (exact) -> 0b01
|
| - // 0b01.0... -> 0b01.0... -> 0b01
|
| - // 0b01.1 (exact) -> 0b01.1 (exact) -> 0b10
|
| - // 0b01.1... -> 0b01.1... -> 0b10
|
| - // 0b10.0 (exact) -> 0b10.0 (exact) -> 0b10
|
| - // 0b10.0... -> 0b10.0... -> 0b10
|
| - // 0b10.1 (exact) -> 0b10.0111..111 -> 0b10
|
| - // 0b10.1... -> 0b10.1... -> 0b11
|
| - // 0b11.0 (exact) -> 0b11.0 (exact) -> 0b11
|
| - // ... / | / |
|
| - // / | / |
|
| - // / |
|
| - // adjusted = frac - (halfbit(mantissa) & ~onebit(frac)); / |
|
| - //
|
| - // mantissa = (mantissa >> shift) + halfbit(adjusted);
|
| -
|
| - static const int mantissa_offset = 0;
|
| - static const int exponent_offset = mantissa_offset + mbits;
|
| - static const int sign_offset = exponent_offset + ebits;
|
| - STATIC_ASSERT(sign_offset == (sizeof(T) * kByteSize - 1));
|
| -
|
| - // Bail out early for zero inputs.
|
| - if (mantissa == 0) {
|
| - return sign << sign_offset;
|
| - }
|
| -
|
| - // If all bits in the exponent are set, the value is infinite or NaN.
|
| - // This is true for all binary IEEE-754 formats.
|
| - static const int infinite_exponent = (1 << ebits) - 1;
|
| - static const int max_normal_exponent = infinite_exponent - 1;
|
| -
|
| - // Apply the exponent bias to encode it for the result. Doing this early makes
|
| - // it easy to detect values that will be infinite or subnormal.
|
| - exponent += max_normal_exponent >> 1;
|
| -
|
| - if (exponent > max_normal_exponent) {
|
| - // Overflow: The input is too large for the result type to represent. The
|
| - // FPTieEven rounding mode handles overflows using infinities.
|
| - exponent = infinite_exponent;
|
| - mantissa = 0;
|
| - return (sign << sign_offset) |
|
| - (exponent << exponent_offset) |
|
| - (mantissa << mantissa_offset);
|
| - }
|
| -
|
| - // Calculate the shift required to move the top mantissa bit to the proper
|
| - // place in the destination type.
|
| - const int highest_significant_bit = 63 - CountLeadingZeros(mantissa, 64);
|
| - int shift = highest_significant_bit - mbits;
|
| -
|
| - if (exponent <= 0) {
|
| - // The output will be subnormal (before rounding).
|
| -
|
| - // For subnormal outputs, the shift must be adjusted by the exponent. The +1
|
| - // is necessary because the exponent of a subnormal value (encoded as 0) is
|
| - // the same as the exponent of the smallest normal value (encoded as 1).
|
| - shift += -exponent + 1;
|
| -
|
| - // Handle inputs that would produce a zero output.
|
| - //
|
| - // Shifts higher than highest_significant_bit+1 will always produce a zero
|
| - // result. A shift of exactly highest_significant_bit+1 might produce a
|
| - // non-zero result after rounding.
|
| - if (shift > (highest_significant_bit + 1)) {
|
| - // The result will always be +/-0.0.
|
| - return sign << sign_offset;
|
| - }
|
| -
|
| - // Properly encode the exponent for a subnormal output.
|
| - exponent = 0;
|
| - } else {
|
| - // Clear the topmost mantissa bit, since this is not encoded in IEEE-754
|
| - // normal values.
|
| - mantissa &= ~(1UL << highest_significant_bit);
|
| - }
|
| -
|
| - if (shift > 0) {
|
| - // We have to shift the mantissa to the right. Some precision is lost, so we
|
| - // need to apply rounding.
|
| - uint64_t onebit_mantissa = (mantissa >> (shift)) & 1;
|
| - uint64_t halfbit_mantissa = (mantissa >> (shift-1)) & 1;
|
| - uint64_t adjusted = mantissa - (halfbit_mantissa & ~onebit_mantissa);
|
| - T halfbit_adjusted = (adjusted >> (shift-1)) & 1;
|
| -
|
| - T result = (sign << sign_offset) |
|
| - (exponent << exponent_offset) |
|
| - ((mantissa >> shift) << mantissa_offset);
|
| -
|
| - // A very large mantissa can overflow during rounding. If this happens, the
|
| - // exponent should be incremented and the mantissa set to 1.0 (encoded as
|
| - // 0). Applying halfbit_adjusted after assembling the float has the nice
|
| - // side-effect that this case is handled for free.
|
| - //
|
| - // This also handles cases where a very large finite value overflows to
|
| - // infinity, or where a very large subnormal value overflows to become
|
| - // normal.
|
| - return result + halfbit_adjusted;
|
| - } else {
|
| - // We have to shift the mantissa to the left (or not at all). The input
|
| - // mantissa is exactly representable in the output mantissa, so apply no
|
| - // rounding correction.
|
| - return (sign << sign_offset) |
|
| - (exponent << exponent_offset) |
|
| - ((mantissa << -shift) << mantissa_offset);
|
| - }
|
| -}
|
| -
|
| -
|
| -// See FPRound for a description of this function.
|
| -static inline double FPRoundToDouble(int64_t sign, int64_t exponent,
|
| - uint64_t mantissa, FPRounding round_mode) {
|
| - int64_t bits =
|
| - FPRound<int64_t, kDoubleExponentBits, kDoubleMantissaBits>(sign,
|
| - exponent,
|
| - mantissa,
|
| - round_mode);
|
| - return rawbits_to_double(bits);
|
| -}
|
| -
|
| -
|
| -// See FPRound for a description of this function.
|
| -static inline float FPRoundToFloat(int64_t sign, int64_t exponent,
|
| - uint64_t mantissa, FPRounding round_mode) {
|
| - int32_t bits =
|
| - FPRound<int32_t, kFloatExponentBits, kFloatMantissaBits>(sign,
|
| - exponent,
|
| - mantissa,
|
| - round_mode);
|
| - return rawbits_to_float(bits);
|
| -}
|
| -
|
| -
|
| -double Simulator::FixedToDouble(int64_t src, int fbits, FPRounding round) {
|
| - if (src >= 0) {
|
| - return UFixedToDouble(src, fbits, round);
|
| - } else {
|
| - // This works for all negative values, including INT64_MIN.
|
| - return -UFixedToDouble(-src, fbits, round);
|
| - }
|
| -}
|
| -
|
| -
|
| -double Simulator::UFixedToDouble(uint64_t src, int fbits, FPRounding round) {
|
| - // An input of 0 is a special case because the result is effectively
|
| - // subnormal: The exponent is encoded as 0 and there is no implicit 1 bit.
|
| - if (src == 0) {
|
| - return 0.0;
|
| - }
|
| -
|
| - // Calculate the exponent. The highest significant bit will have the value
|
| - // 2^exponent.
|
| - const int highest_significant_bit = 63 - CountLeadingZeros(src, 64);
|
| - const int64_t exponent = highest_significant_bit - fbits;
|
| -
|
| - return FPRoundToDouble(0, exponent, src, round);
|
| -}
|
| -
|
| -
|
| -float Simulator::FixedToFloat(int64_t src, int fbits, FPRounding round) {
|
| - if (src >= 0) {
|
| - return UFixedToFloat(src, fbits, round);
|
| - } else {
|
| - // This works for all negative values, including INT64_MIN.
|
| - return -UFixedToFloat(-src, fbits, round);
|
| - }
|
| -}
|
| -
|
| -
|
| -float Simulator::UFixedToFloat(uint64_t src, int fbits, FPRounding round) {
|
| - // An input of 0 is a special case because the result is effectively
|
| - // subnormal: The exponent is encoded as 0 and there is no implicit 1 bit.
|
| - if (src == 0) {
|
| - return 0.0f;
|
| - }
|
| -
|
| - // Calculate the exponent. The highest significant bit will have the value
|
| - // 2^exponent.
|
| - const int highest_significant_bit = 63 - CountLeadingZeros(src, 64);
|
| - const int32_t exponent = highest_significant_bit - fbits;
|
| -
|
| - return FPRoundToFloat(0, exponent, src, round);
|
| -}
|
| -
|
| -
|
| -double Simulator::FPRoundInt(double value, FPRounding round_mode) {
|
| - if ((value == 0.0) || (value == kFP64PositiveInfinity) ||
|
| - (value == kFP64NegativeInfinity)) {
|
| - return value;
|
| - } else if (std::isnan(value)) {
|
| - return FPProcessNaN(value);
|
| - }
|
| -
|
| - double int_result = floor(value);
|
| - double error = value - int_result;
|
| - switch (round_mode) {
|
| - case FPTieAway: {
|
| - // If the error is greater than 0.5, or is equal to 0.5 and the integer
|
| - // result is positive, round up.
|
| - if ((error > 0.5) || ((error == 0.5) && (int_result >= 0.0))) {
|
| - int_result++;
|
| - }
|
| - break;
|
| - }
|
| - case FPTieEven: {
|
| - // If the error is greater than 0.5, or is equal to 0.5 and the integer
|
| - // result is odd, round up.
|
| - if ((error > 0.5) ||
|
| - ((error == 0.5) && (fmod(int_result, 2) != 0))) {
|
| - int_result++;
|
| - }
|
| - break;
|
| - }
|
| - case FPZero: {
|
| - // If value > 0 then we take floor(value)
|
| - // otherwise, ceil(value)
|
| - if (value < 0) {
|
| - int_result = ceil(value);
|
| - }
|
| - break;
|
| - }
|
| - case FPNegativeInfinity: {
|
| - // We always use floor(value).
|
| - break;
|
| - }
|
| - default: UNIMPLEMENTED();
|
| - }
|
| - return int_result;
|
| -}
|
| -
|
| -
|
| -double Simulator::FPToDouble(float value) {
|
| - switch (std::fpclassify(value)) {
|
| - case FP_NAN: {
|
| - if (fpcr().DN()) return kFP64DefaultNaN;
|
| -
|
| - // Convert NaNs as the processor would:
|
| - // - The sign is propagated.
|
| - // - The payload (mantissa) is transferred entirely, except that the top
|
| - // bit is forced to '1', making the result a quiet NaN. The unused
|
| - // (low-order) payload bits are set to 0.
|
| - uint32_t raw = float_to_rawbits(value);
|
| -
|
| - uint64_t sign = raw >> 31;
|
| - uint64_t exponent = (1 << 11) - 1;
|
| - uint64_t payload = unsigned_bitextract_64(21, 0, raw);
|
| - payload <<= (52 - 23); // The unused low-order bits should be 0.
|
| - payload |= (1L << 51); // Force a quiet NaN.
|
| -
|
| - return rawbits_to_double((sign << 63) | (exponent << 52) | payload);
|
| - }
|
| -
|
| - case FP_ZERO:
|
| - case FP_NORMAL:
|
| - case FP_SUBNORMAL:
|
| - case FP_INFINITE: {
|
| - // All other inputs are preserved in a standard cast, because every value
|
| - // representable using an IEEE-754 float is also representable using an
|
| - // IEEE-754 double.
|
| - return static_cast<double>(value);
|
| - }
|
| - }
|
| -
|
| - UNREACHABLE();
|
| - return static_cast<double>(value);
|
| -}
|
| -
|
| -
|
| -float Simulator::FPToFloat(double value, FPRounding round_mode) {
|
| - // Only the FPTieEven rounding mode is implemented.
|
| - ASSERT(round_mode == FPTieEven);
|
| - USE(round_mode);
|
| -
|
| - switch (std::fpclassify(value)) {
|
| - case FP_NAN: {
|
| - if (fpcr().DN()) return kFP32DefaultNaN;
|
| -
|
| - // Convert NaNs as the processor would:
|
| - // - The sign is propagated.
|
| - // - The payload (mantissa) is transferred as much as possible, except
|
| - // that the top bit is forced to '1', making the result a quiet NaN.
|
| - uint64_t raw = double_to_rawbits(value);
|
| -
|
| - uint32_t sign = raw >> 63;
|
| - uint32_t exponent = (1 << 8) - 1;
|
| - uint32_t payload = unsigned_bitextract_64(50, 52 - 23, raw);
|
| - payload |= (1 << 22); // Force a quiet NaN.
|
| -
|
| - return rawbits_to_float((sign << 31) | (exponent << 23) | payload);
|
| - }
|
| -
|
| - case FP_ZERO:
|
| - case FP_INFINITE: {
|
| - // In a C++ cast, any value representable in the target type will be
|
| - // unchanged. This is always the case for +/-0.0 and infinities.
|
| - return static_cast<float>(value);
|
| - }
|
| -
|
| - case FP_NORMAL:
|
| - case FP_SUBNORMAL: {
|
| - // Convert double-to-float as the processor would, assuming that FPCR.FZ
|
| - // (flush-to-zero) is not set.
|
| - uint64_t raw = double_to_rawbits(value);
|
| - // Extract the IEEE-754 double components.
|
| - uint32_t sign = raw >> 63;
|
| - // Extract the exponent and remove the IEEE-754 encoding bias.
|
| - int32_t exponent = unsigned_bitextract_64(62, 52, raw) - 1023;
|
| - // Extract the mantissa and add the implicit '1' bit.
|
| - uint64_t mantissa = unsigned_bitextract_64(51, 0, raw);
|
| - if (std::fpclassify(value) == FP_NORMAL) {
|
| - mantissa |= (1UL << 52);
|
| - }
|
| - return FPRoundToFloat(sign, exponent, mantissa, round_mode);
|
| - }
|
| - }
|
| -
|
| - UNREACHABLE();
|
| - return value;
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitFPDataProcessing2Source(Instruction* instr) {
|
| - AssertSupportedFPCR();
|
| -
|
| - unsigned fd = instr->Rd();
|
| - unsigned fn = instr->Rn();
|
| - unsigned fm = instr->Rm();
|
| -
|
| - // Fmaxnm and Fminnm have special NaN handling.
|
| - switch (instr->Mask(FPDataProcessing2SourceMask)) {
|
| - case FMAXNM_s: set_sreg(fd, FPMaxNM(sreg(fn), sreg(fm))); return;
|
| - case FMAXNM_d: set_dreg(fd, FPMaxNM(dreg(fn), dreg(fm))); return;
|
| - case FMINNM_s: set_sreg(fd, FPMinNM(sreg(fn), sreg(fm))); return;
|
| - case FMINNM_d: set_dreg(fd, FPMinNM(dreg(fn), dreg(fm))); return;
|
| - default:
|
| - break; // Fall through.
|
| - }
|
| -
|
| - if (FPProcessNaNs(instr)) return;
|
| -
|
| - switch (instr->Mask(FPDataProcessing2SourceMask)) {
|
| - case FADD_s: set_sreg(fd, FPAdd(sreg(fn), sreg(fm))); break;
|
| - case FADD_d: set_dreg(fd, FPAdd(dreg(fn), dreg(fm))); break;
|
| - case FSUB_s: set_sreg(fd, FPSub(sreg(fn), sreg(fm))); break;
|
| - case FSUB_d: set_dreg(fd, FPSub(dreg(fn), dreg(fm))); break;
|
| - case FMUL_s: set_sreg(fd, FPMul(sreg(fn), sreg(fm))); break;
|
| - case FMUL_d: set_dreg(fd, FPMul(dreg(fn), dreg(fm))); break;
|
| - case FDIV_s: set_sreg(fd, FPDiv(sreg(fn), sreg(fm))); break;
|
| - case FDIV_d: set_dreg(fd, FPDiv(dreg(fn), dreg(fm))); break;
|
| - case FMAX_s: set_sreg(fd, FPMax(sreg(fn), sreg(fm))); break;
|
| - case FMAX_d: set_dreg(fd, FPMax(dreg(fn), dreg(fm))); break;
|
| - case FMIN_s: set_sreg(fd, FPMin(sreg(fn), sreg(fm))); break;
|
| - case FMIN_d: set_dreg(fd, FPMin(dreg(fn), dreg(fm))); break;
|
| - case FMAXNM_s:
|
| - case FMAXNM_d:
|
| - case FMINNM_s:
|
| - case FMINNM_d:
|
| - // These were handled before the standard FPProcessNaNs() stage.
|
| - UNREACHABLE();
|
| - default: UNIMPLEMENTED();
|
| - }
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitFPDataProcessing3Source(Instruction* instr) {
|
| - AssertSupportedFPCR();
|
| -
|
| - unsigned fd = instr->Rd();
|
| - unsigned fn = instr->Rn();
|
| - unsigned fm = instr->Rm();
|
| - unsigned fa = instr->Ra();
|
| -
|
| - // The C99 (and C++11) fma function performs a fused multiply-accumulate.
|
| - switch (instr->Mask(FPDataProcessing3SourceMask)) {
|
| - // fd = fa +/- (fn * fm)
|
| - case FMADD_s: set_sreg(fd, FPMulAdd(sreg(fa), sreg(fn), sreg(fm))); break;
|
| - case FMSUB_s: set_sreg(fd, FPMulAdd(sreg(fa), -sreg(fn), sreg(fm))); break;
|
| - case FMADD_d: set_dreg(fd, FPMulAdd(dreg(fa), dreg(fn), dreg(fm))); break;
|
| - case FMSUB_d: set_dreg(fd, FPMulAdd(dreg(fa), -dreg(fn), dreg(fm))); break;
|
| - // Negated variants of the above.
|
| - case FNMADD_s:
|
| - set_sreg(fd, FPMulAdd(-sreg(fa), -sreg(fn), sreg(fm)));
|
| - break;
|
| - case FNMSUB_s:
|
| - set_sreg(fd, FPMulAdd(-sreg(fa), sreg(fn), sreg(fm)));
|
| - break;
|
| - case FNMADD_d:
|
| - set_dreg(fd, FPMulAdd(-dreg(fa), -dreg(fn), dreg(fm)));
|
| - break;
|
| - case FNMSUB_d:
|
| - set_dreg(fd, FPMulAdd(-dreg(fa), dreg(fn), dreg(fm)));
|
| - break;
|
| - default: UNIMPLEMENTED();
|
| - }
|
| -}
|
| -
|
| -
|
| -template <typename T>
|
| -T Simulator::FPAdd(T op1, T op2) {
|
| - // NaNs should be handled elsewhere.
|
| - ASSERT(!std::isnan(op1) && !std::isnan(op2));
|
| -
|
| - if (isinf(op1) && isinf(op2) && (op1 != op2)) {
|
| - // inf + -inf returns the default NaN.
|
| - return FPDefaultNaN<T>();
|
| - } else {
|
| - // Other cases should be handled by standard arithmetic.
|
| - return op1 + op2;
|
| - }
|
| -}
|
| -
|
| -
|
| -template <typename T>
|
| -T Simulator::FPDiv(T op1, T op2) {
|
| - // NaNs should be handled elsewhere.
|
| - ASSERT(!std::isnan(op1) && !std::isnan(op2));
|
| -
|
| - if ((isinf(op1) && isinf(op2)) || ((op1 == 0.0) && (op2 == 0.0))) {
|
| - // inf / inf and 0.0 / 0.0 return the default NaN.
|
| - return FPDefaultNaN<T>();
|
| - } else {
|
| - // Other cases should be handled by standard arithmetic.
|
| - return op1 / op2;
|
| - }
|
| -}
|
| -
|
| -
|
| -template <typename T>
|
| -T Simulator::FPMax(T a, T b) {
|
| - // NaNs should be handled elsewhere.
|
| - ASSERT(!std::isnan(a) && !std::isnan(b));
|
| -
|
| - if ((a == 0.0) && (b == 0.0) &&
|
| - (copysign(1.0, a) != copysign(1.0, b))) {
|
| - // a and b are zero, and the sign differs: return +0.0.
|
| - return 0.0;
|
| - } else {
|
| - return (a > b) ? a : b;
|
| - }
|
| -}
|
| -
|
| -
|
| -template <typename T>
|
| -T Simulator::FPMaxNM(T a, T b) {
|
| - if (IsQuietNaN(a) && !IsQuietNaN(b)) {
|
| - a = kFP64NegativeInfinity;
|
| - } else if (!IsQuietNaN(a) && IsQuietNaN(b)) {
|
| - b = kFP64NegativeInfinity;
|
| - }
|
| -
|
| - T result = FPProcessNaNs(a, b);
|
| - return std::isnan(result) ? result : FPMax(a, b);
|
| -}
|
| -
|
| -template <typename T>
|
| -T Simulator::FPMin(T a, T b) {
|
| - // NaNs should be handled elsewhere.
|
| - ASSERT(!isnan(a) && !isnan(b));
|
| -
|
| - if ((a == 0.0) && (b == 0.0) &&
|
| - (copysign(1.0, a) != copysign(1.0, b))) {
|
| - // a and b are zero, and the sign differs: return -0.0.
|
| - return -0.0;
|
| - } else {
|
| - return (a < b) ? a : b;
|
| - }
|
| -}
|
| -
|
| -
|
| -template <typename T>
|
| -T Simulator::FPMinNM(T a, T b) {
|
| - if (IsQuietNaN(a) && !IsQuietNaN(b)) {
|
| - a = kFP64PositiveInfinity;
|
| - } else if (!IsQuietNaN(a) && IsQuietNaN(b)) {
|
| - b = kFP64PositiveInfinity;
|
| - }
|
| -
|
| - T result = FPProcessNaNs(a, b);
|
| - return isnan(result) ? result : FPMin(a, b);
|
| -}
|
| -
|
| -
|
| -template <typename T>
|
| -T Simulator::FPMul(T op1, T op2) {
|
| - // NaNs should be handled elsewhere.
|
| - ASSERT(!std::isnan(op1) && !std::isnan(op2));
|
| -
|
| - if ((isinf(op1) && (op2 == 0.0)) || (isinf(op2) && (op1 == 0.0))) {
|
| - // inf * 0.0 returns the default NaN.
|
| - return FPDefaultNaN<T>();
|
| - } else {
|
| - // Other cases should be handled by standard arithmetic.
|
| - return op1 * op2;
|
| - }
|
| -}
|
| -
|
| -
|
| -template<typename T>
|
| -T Simulator::FPMulAdd(T a, T op1, T op2) {
|
| - T result = FPProcessNaNs3(a, op1, op2);
|
| -
|
| - T sign_a = copysign(1.0, a);
|
| - T sign_prod = copysign(1.0, op1) * copysign(1.0, op2);
|
| - bool isinf_prod = std::isinf(op1) || std::isinf(op2);
|
| - bool operation_generates_nan =
|
| - (std::isinf(op1) && (op2 == 0.0)) || // inf * 0.0
|
| - (std::isinf(op2) && (op1 == 0.0)) || // 0.0 * inf
|
| - (std::isinf(a) && isinf_prod && (sign_a != sign_prod)); // inf - inf
|
| -
|
| - if (std::isnan(result)) {
|
| - // Generated NaNs override quiet NaNs propagated from a.
|
| - if (operation_generates_nan && IsQuietNaN(a)) {
|
| - return FPDefaultNaN<T>();
|
| - } else {
|
| - return result;
|
| - }
|
| - }
|
| -
|
| - // If the operation would produce a NaN, return the default NaN.
|
| - if (operation_generates_nan) {
|
| - return FPDefaultNaN<T>();
|
| - }
|
| -
|
| - // Work around broken fma implementations for exact zero results: The sign of
|
| - // exact 0.0 results is positive unless both a and op1 * op2 are negative.
|
| - if (((op1 == 0.0) || (op2 == 0.0)) && (a == 0.0)) {
|
| - return ((sign_a < 0) && (sign_prod < 0)) ? -0.0 : 0.0;
|
| - }
|
| -
|
| - result = FusedMultiplyAdd(op1, op2, a);
|
| - ASSERT(!std::isnan(result));
|
| -
|
| - // Work around broken fma implementations for rounded zero results: If a is
|
| - // 0.0, the sign of the result is the sign of op1 * op2 before rounding.
|
| - if ((a == 0.0) && (result == 0.0)) {
|
| - return copysign(0.0, sign_prod);
|
| - }
|
| -
|
| - return result;
|
| -}
|
| -
|
| -
|
| -template <typename T>
|
| -T Simulator::FPSqrt(T op) {
|
| - if (std::isnan(op)) {
|
| - return FPProcessNaN(op);
|
| - } else if (op < 0.0) {
|
| - return FPDefaultNaN<T>();
|
| - } else {
|
| - return std::sqrt(op);
|
| - }
|
| -}
|
| -
|
| -
|
| -template <typename T>
|
| -T Simulator::FPSub(T op1, T op2) {
|
| - // NaNs should be handled elsewhere.
|
| - ASSERT(!std::isnan(op1) && !std::isnan(op2));
|
| -
|
| - if (isinf(op1) && isinf(op2) && (op1 == op2)) {
|
| - // inf - inf returns the default NaN.
|
| - return FPDefaultNaN<T>();
|
| - } else {
|
| - // Other cases should be handled by standard arithmetic.
|
| - return op1 - op2;
|
| - }
|
| -}
|
| -
|
| -
|
| -template <typename T>
|
| -T Simulator::FPProcessNaN(T op) {
|
| - ASSERT(std::isnan(op));
|
| - return fpcr().DN() ? FPDefaultNaN<T>() : ToQuietNaN(op);
|
| -}
|
| -
|
| -
|
| -template <typename T>
|
| -T Simulator::FPProcessNaNs(T op1, T op2) {
|
| - if (IsSignallingNaN(op1)) {
|
| - return FPProcessNaN(op1);
|
| - } else if (IsSignallingNaN(op2)) {
|
| - return FPProcessNaN(op2);
|
| - } else if (std::isnan(op1)) {
|
| - ASSERT(IsQuietNaN(op1));
|
| - return FPProcessNaN(op1);
|
| - } else if (std::isnan(op2)) {
|
| - ASSERT(IsQuietNaN(op2));
|
| - return FPProcessNaN(op2);
|
| - } else {
|
| - return 0.0;
|
| - }
|
| -}
|
| -
|
| -
|
| -template <typename T>
|
| -T Simulator::FPProcessNaNs3(T op1, T op2, T op3) {
|
| - if (IsSignallingNaN(op1)) {
|
| - return FPProcessNaN(op1);
|
| - } else if (IsSignallingNaN(op2)) {
|
| - return FPProcessNaN(op2);
|
| - } else if (IsSignallingNaN(op3)) {
|
| - return FPProcessNaN(op3);
|
| - } else if (std::isnan(op1)) {
|
| - ASSERT(IsQuietNaN(op1));
|
| - return FPProcessNaN(op1);
|
| - } else if (std::isnan(op2)) {
|
| - ASSERT(IsQuietNaN(op2));
|
| - return FPProcessNaN(op2);
|
| - } else if (std::isnan(op3)) {
|
| - ASSERT(IsQuietNaN(op3));
|
| - return FPProcessNaN(op3);
|
| - } else {
|
| - return 0.0;
|
| - }
|
| -}
|
| -
|
| -
|
| -bool Simulator::FPProcessNaNs(Instruction* instr) {
|
| - unsigned fd = instr->Rd();
|
| - unsigned fn = instr->Rn();
|
| - unsigned fm = instr->Rm();
|
| - bool done = false;
|
| -
|
| - if (instr->Mask(FP64) == FP64) {
|
| - double result = FPProcessNaNs(dreg(fn), dreg(fm));
|
| - if (std::isnan(result)) {
|
| - set_dreg(fd, result);
|
| - done = true;
|
| - }
|
| - } else {
|
| - float result = FPProcessNaNs(sreg(fn), sreg(fm));
|
| - if (std::isnan(result)) {
|
| - set_sreg(fd, result);
|
| - done = true;
|
| - }
|
| - }
|
| -
|
| - return done;
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitSystem(Instruction* instr) {
|
| - // Some system instructions hijack their Op and Cp fields to represent a
|
| - // range of immediates instead of indicating a different instruction. This
|
| - // makes the decoding tricky.
|
| - if (instr->Mask(SystemSysRegFMask) == SystemSysRegFixed) {
|
| - switch (instr->Mask(SystemSysRegMask)) {
|
| - case MRS: {
|
| - switch (instr->ImmSystemRegister()) {
|
| - case NZCV: set_xreg(instr->Rt(), nzcv().RawValue()); break;
|
| - case FPCR: set_xreg(instr->Rt(), fpcr().RawValue()); break;
|
| - default: UNIMPLEMENTED();
|
| - }
|
| - break;
|
| - }
|
| - case MSR: {
|
| - switch (instr->ImmSystemRegister()) {
|
| - case NZCV: nzcv().SetRawValue(xreg(instr->Rt())); break;
|
| - case FPCR: fpcr().SetRawValue(xreg(instr->Rt())); break;
|
| - default: UNIMPLEMENTED();
|
| - }
|
| - break;
|
| - }
|
| - }
|
| - } else if (instr->Mask(SystemHintFMask) == SystemHintFixed) {
|
| - ASSERT(instr->Mask(SystemHintMask) == HINT);
|
| - switch (instr->ImmHint()) {
|
| - case NOP: break;
|
| - default: UNIMPLEMENTED();
|
| - }
|
| - } else if (instr->Mask(MemBarrierFMask) == MemBarrierFixed) {
|
| - __sync_synchronize();
|
| - } else {
|
| - UNIMPLEMENTED();
|
| - }
|
| -}
|
| -
|
| -
|
| -bool Simulator::GetValue(const char* desc, int64_t* value) {
|
| - int regnum = CodeFromName(desc);
|
| - if (regnum >= 0) {
|
| - unsigned code = regnum;
|
| - if (code == kZeroRegCode) {
|
| - // Catch the zero register and return 0.
|
| - *value = 0;
|
| - return true;
|
| - } else if (code == kSPRegInternalCode) {
|
| - // Translate the stack pointer code to 31, for Reg31IsStackPointer.
|
| - code = 31;
|
| - }
|
| - if (desc[0] == 'w') {
|
| - *value = wreg(code, Reg31IsStackPointer);
|
| - } else {
|
| - *value = xreg(code, Reg31IsStackPointer);
|
| - }
|
| - return true;
|
| - } else if (strncmp(desc, "0x", 2) == 0) {
|
| - return SScanF(desc + 2, "%" SCNx64,
|
| - reinterpret_cast<uint64_t*>(value)) == 1;
|
| - } else {
|
| - return SScanF(desc, "%" SCNu64,
|
| - reinterpret_cast<uint64_t*>(value)) == 1;
|
| - }
|
| -}
|
| -
|
| -
|
| -bool Simulator::PrintValue(const char* desc) {
|
| - if (strcmp(desc, "csp") == 0) {
|
| - ASSERT(CodeFromName(desc) == static_cast<int>(kSPRegInternalCode));
|
| - PrintF("%s csp:%s 0x%016" PRIx64 "%s\n",
|
| - clr_reg_name, clr_reg_value, xreg(31, Reg31IsStackPointer), clr_normal);
|
| - return true;
|
| - } else if (strcmp(desc, "wcsp") == 0) {
|
| - ASSERT(CodeFromName(desc) == static_cast<int>(kSPRegInternalCode));
|
| - PrintF("%s wcsp:%s 0x%08" PRIx32 "%s\n",
|
| - clr_reg_name, clr_reg_value, wreg(31, Reg31IsStackPointer), clr_normal);
|
| - return true;
|
| - }
|
| -
|
| - int i = CodeFromName(desc);
|
| - STATIC_ASSERT(kNumberOfRegisters == kNumberOfFPRegisters);
|
| - if (i < 0 || static_cast<unsigned>(i) >= kNumberOfFPRegisters) return false;
|
| -
|
| - if (desc[0] == 'v') {
|
| - PrintF("%s %s:%s 0x%016" PRIx64 "%s (%s%s:%s %g%s %s:%s %g%s)\n",
|
| - clr_fpreg_name, VRegNameForCode(i),
|
| - clr_fpreg_value, double_to_rawbits(dreg(i)),
|
| - clr_normal,
|
| - clr_fpreg_name, DRegNameForCode(i),
|
| - clr_fpreg_value, dreg(i),
|
| - clr_fpreg_name, SRegNameForCode(i),
|
| - clr_fpreg_value, sreg(i),
|
| - clr_normal);
|
| - return true;
|
| - } else if (desc[0] == 'd') {
|
| - PrintF("%s %s:%s %g%s\n",
|
| - clr_fpreg_name, DRegNameForCode(i),
|
| - clr_fpreg_value, dreg(i),
|
| - clr_normal);
|
| - return true;
|
| - } else if (desc[0] == 's') {
|
| - PrintF("%s %s:%s %g%s\n",
|
| - clr_fpreg_name, SRegNameForCode(i),
|
| - clr_fpreg_value, sreg(i),
|
| - clr_normal);
|
| - return true;
|
| - } else if (desc[0] == 'w') {
|
| - PrintF("%s %s:%s 0x%08" PRIx32 "%s\n",
|
| - clr_reg_name, WRegNameForCode(i), clr_reg_value, wreg(i), clr_normal);
|
| - return true;
|
| - } else {
|
| - // X register names have a wide variety of starting characters, but anything
|
| - // else will be an X register.
|
| - PrintF("%s %s:%s 0x%016" PRIx64 "%s\n",
|
| - clr_reg_name, XRegNameForCode(i), clr_reg_value, xreg(i), clr_normal);
|
| - return true;
|
| - }
|
| -}
|
| -
|
| -
|
| -void Simulator::Debug() {
|
| -#define COMMAND_SIZE 63
|
| -#define ARG_SIZE 255
|
| -
|
| -#define STR(a) #a
|
| -#define XSTR(a) STR(a)
|
| -
|
| - char cmd[COMMAND_SIZE + 1];
|
| - char arg1[ARG_SIZE + 1];
|
| - char arg2[ARG_SIZE + 1];
|
| - char* argv[3] = { cmd, arg1, arg2 };
|
| -
|
| - // Make sure to have a proper terminating character if reaching the limit.
|
| - cmd[COMMAND_SIZE] = 0;
|
| - arg1[ARG_SIZE] = 0;
|
| - arg2[ARG_SIZE] = 0;
|
| -
|
| - bool done = false;
|
| - bool cleared_log_disasm_bit = false;
|
| -
|
| - while (!done) {
|
| - // Disassemble the next instruction to execute before doing anything else.
|
| - PrintInstructionsAt(pc_, 1);
|
| - // Read the command line.
|
| - char* line = ReadLine("sim> ");
|
| - if (line == NULL) {
|
| - break;
|
| - } else {
|
| - // Repeat last command by default.
|
| - char* last_input = last_debugger_input();
|
| - if (strcmp(line, "\n") == 0 && (last_input != NULL)) {
|
| - DeleteArray(line);
|
| - line = last_input;
|
| - } else {
|
| - // Update the latest command ran
|
| - set_last_debugger_input(line);
|
| - }
|
| -
|
| - // Use sscanf to parse the individual parts of the command line. At the
|
| - // moment no command expects more than two parameters.
|
| - int argc = SScanF(line,
|
| - "%" XSTR(COMMAND_SIZE) "s "
|
| - "%" XSTR(ARG_SIZE) "s "
|
| - "%" XSTR(ARG_SIZE) "s",
|
| - cmd, arg1, arg2);
|
| -
|
| - // stepi / si ------------------------------------------------------------
|
| - if ((strcmp(cmd, "si") == 0) || (strcmp(cmd, "stepi") == 0)) {
|
| - // We are about to execute instructions, after which by default we
|
| - // should increment the pc_. If it was set when reaching this debug
|
| - // instruction, it has not been cleared because this instruction has not
|
| - // completed yet. So clear it manually.
|
| - pc_modified_ = false;
|
| -
|
| - if (argc == 1) {
|
| - ExecuteInstruction();
|
| - } else {
|
| - int64_t number_of_instructions_to_execute = 1;
|
| - GetValue(arg1, &number_of_instructions_to_execute);
|
| -
|
| - set_log_parameters(log_parameters() | LOG_DISASM);
|
| - while (number_of_instructions_to_execute-- > 0) {
|
| - ExecuteInstruction();
|
| - }
|
| - set_log_parameters(log_parameters() & ~LOG_DISASM);
|
| - PrintF("\n");
|
| - }
|
| -
|
| - // If it was necessary, the pc has already been updated or incremented
|
| - // when executing the instruction. So we do not want it to be updated
|
| - // again. It will be cleared when exiting.
|
| - pc_modified_ = true;
|
| -
|
| - // next / n --------------------------------------------------------------
|
| - } else if ((strcmp(cmd, "next") == 0) || (strcmp(cmd, "n") == 0)) {
|
| - // Tell the simulator to break after the next executed BL.
|
| - break_on_next_ = true;
|
| - // Continue.
|
| - done = true;
|
| -
|
| - // continue / cont / c ---------------------------------------------------
|
| - } else if ((strcmp(cmd, "continue") == 0) ||
|
| - (strcmp(cmd, "cont") == 0) ||
|
| - (strcmp(cmd, "c") == 0)) {
|
| - // Leave the debugger shell.
|
| - done = true;
|
| -
|
| - // disassemble / disasm / di ---------------------------------------------
|
| - } else if (strcmp(cmd, "disassemble") == 0 ||
|
| - strcmp(cmd, "disasm") == 0 ||
|
| - strcmp(cmd, "di") == 0) {
|
| - int64_t n_of_instrs_to_disasm = 10; // default value.
|
| - int64_t address = reinterpret_cast<int64_t>(pc_); // default value.
|
| - if (argc >= 2) { // disasm <n of instrs>
|
| - GetValue(arg1, &n_of_instrs_to_disasm);
|
| - }
|
| - if (argc >= 3) { // disasm <n of instrs> <address>
|
| - GetValue(arg2, &address);
|
| - }
|
| -
|
| - // Disassemble.
|
| - PrintInstructionsAt(reinterpret_cast<Instruction*>(address),
|
| - n_of_instrs_to_disasm);
|
| - PrintF("\n");
|
| -
|
| - // print / p -------------------------------------------------------------
|
| - } else if ((strcmp(cmd, "print") == 0) || (strcmp(cmd, "p") == 0)) {
|
| - if (argc == 2) {
|
| - if (strcmp(arg1, "all") == 0) {
|
| - PrintRegisters(true);
|
| - PrintFPRegisters(true);
|
| - } else {
|
| - if (!PrintValue(arg1)) {
|
| - PrintF("%s unrecognized\n", arg1);
|
| - }
|
| - }
|
| - } else {
|
| - PrintF(
|
| - "print <register>\n"
|
| - " Print the content of a register. (alias 'p')\n"
|
| - " 'print all' will print all registers.\n"
|
| - " Use 'printobject' to get more details about the value.\n");
|
| - }
|
| -
|
| - // printobject / po ------------------------------------------------------
|
| - } else if ((strcmp(cmd, "printobject") == 0) ||
|
| - (strcmp(cmd, "po") == 0)) {
|
| - if (argc == 2) {
|
| - int64_t value;
|
| - if (GetValue(arg1, &value)) {
|
| - Object* obj = reinterpret_cast<Object*>(value);
|
| - PrintF("%s: \n", arg1);
|
| -#ifdef DEBUG
|
| - obj->PrintLn();
|
| -#else
|
| - obj->ShortPrint();
|
| - PrintF("\n");
|
| -#endif
|
| - } else {
|
| - PrintF("%s unrecognized\n", arg1);
|
| - }
|
| - } else {
|
| - PrintF("printobject <value>\n"
|
| - "printobject <register>\n"
|
| - " Print details about the value. (alias 'po')\n");
|
| - }
|
| -
|
| - // stack / mem ----------------------------------------------------------
|
| - } else if (strcmp(cmd, "stack") == 0 || strcmp(cmd, "mem") == 0) {
|
| - int64_t* cur = NULL;
|
| - int64_t* end = NULL;
|
| - int next_arg = 1;
|
| -
|
| - if (strcmp(cmd, "stack") == 0) {
|
| - cur = reinterpret_cast<int64_t*>(jssp());
|
| -
|
| - } else { // "mem"
|
| - int64_t value;
|
| - if (!GetValue(arg1, &value)) {
|
| - PrintF("%s unrecognized\n", arg1);
|
| - continue;
|
| - }
|
| - cur = reinterpret_cast<int64_t*>(value);
|
| - next_arg++;
|
| - }
|
| -
|
| - int64_t words = 0;
|
| - if (argc == next_arg) {
|
| - words = 10;
|
| - } else if (argc == next_arg + 1) {
|
| - if (!GetValue(argv[next_arg], &words)) {
|
| - PrintF("%s unrecognized\n", argv[next_arg]);
|
| - PrintF("Printing 10 double words by default");
|
| - words = 10;
|
| - }
|
| - } else {
|
| - UNREACHABLE();
|
| - }
|
| - end = cur + words;
|
| -
|
| - while (cur < end) {
|
| - PrintF(" 0x%016" PRIx64 ": 0x%016" PRIx64 " %10" PRId64,
|
| - reinterpret_cast<uint64_t>(cur), *cur, *cur);
|
| - HeapObject* obj = reinterpret_cast<HeapObject*>(*cur);
|
| - int64_t value = *cur;
|
| - Heap* current_heap = v8::internal::Isolate::Current()->heap();
|
| - if (((value & 1) == 0) || current_heap->Contains(obj)) {
|
| - PrintF(" (");
|
| - if ((value & kSmiTagMask) == 0) {
|
| - STATIC_ASSERT(kSmiValueSize == 32);
|
| - int32_t untagged = (value >> kSmiShift) & 0xffffffff;
|
| - PrintF("smi %" PRId32, untagged);
|
| - } else {
|
| - obj->ShortPrint();
|
| - }
|
| - PrintF(")");
|
| - }
|
| - PrintF("\n");
|
| - cur++;
|
| - }
|
| -
|
| - // trace / t -------------------------------------------------------------
|
| - } else if (strcmp(cmd, "trace") == 0 || strcmp(cmd, "t") == 0) {
|
| - if ((log_parameters() & (LOG_DISASM | LOG_REGS)) !=
|
| - (LOG_DISASM | LOG_REGS)) {
|
| - PrintF("Enabling disassembly and registers tracing\n");
|
| - set_log_parameters(log_parameters() | LOG_DISASM | LOG_REGS);
|
| - } else {
|
| - PrintF("Disabling disassembly and registers tracing\n");
|
| - set_log_parameters(log_parameters() & ~(LOG_DISASM | LOG_REGS));
|
| - }
|
| -
|
| - // break / b -------------------------------------------------------------
|
| - } else if (strcmp(cmd, "break") == 0 || strcmp(cmd, "b") == 0) {
|
| - if (argc == 2) {
|
| - int64_t value;
|
| - if (GetValue(arg1, &value)) {
|
| - SetBreakpoint(reinterpret_cast<Instruction*>(value));
|
| - } else {
|
| - PrintF("%s unrecognized\n", arg1);
|
| - }
|
| - } else {
|
| - ListBreakpoints();
|
| - PrintF("Use `break <address>` to set or disable a breakpoint\n");
|
| - }
|
| -
|
| - // gdb -------------------------------------------------------------------
|
| - } else if (strcmp(cmd, "gdb") == 0) {
|
| - PrintF("Relinquishing control to gdb.\n");
|
| - OS::DebugBreak();
|
| - PrintF("Regaining control from gdb.\n");
|
| -
|
| - // sysregs ---------------------------------------------------------------
|
| - } else if (strcmp(cmd, "sysregs") == 0) {
|
| - PrintSystemRegisters();
|
| -
|
| - // help / h --------------------------------------------------------------
|
| - } else if (strcmp(cmd, "help") == 0 || strcmp(cmd, "h") == 0) {
|
| - PrintF(
|
| - "stepi / si\n"
|
| - " stepi <n>\n"
|
| - " Step <n> instructions.\n"
|
| - "next / n\n"
|
| - " Continue execution until a BL instruction is reached.\n"
|
| - " At this point a breakpoint is set just after this BL.\n"
|
| - " Then execution is resumed. It will probably later hit the\n"
|
| - " breakpoint just set.\n"
|
| - "continue / cont / c\n"
|
| - " Continue execution from here.\n"
|
| - "disassemble / disasm / di\n"
|
| - " disassemble <n> <address>\n"
|
| - " Disassemble <n> instructions from current <address>.\n"
|
| - " By default <n> is 20 and <address> is the current pc.\n"
|
| - "print / p\n"
|
| - " print <register>\n"
|
| - " Print the content of a register.\n"
|
| - " 'print all' will print all registers.\n"
|
| - " Use 'printobject' to get more details about the value.\n"
|
| - "printobject / po\n"
|
| - " printobject <value>\n"
|
| - " printobject <register>\n"
|
| - " Print details about the value.\n"
|
| - "stack\n"
|
| - " stack [<words>]\n"
|
| - " Dump stack content, default dump 10 words\n"
|
| - "mem\n"
|
| - " mem <address> [<words>]\n"
|
| - " Dump memory content, default dump 10 words\n"
|
| - "trace / t\n"
|
| - " Toggle disassembly and register tracing\n"
|
| - "break / b\n"
|
| - " break : list all breakpoints\n"
|
| - " break <address> : set / enable / disable a breakpoint.\n"
|
| - "gdb\n"
|
| - " Enter gdb.\n"
|
| - "sysregs\n"
|
| - " Print all system registers (including NZCV).\n");
|
| - } else {
|
| - PrintF("Unknown command: %s\n", cmd);
|
| - PrintF("Use 'help' for more information.\n");
|
| - }
|
| - }
|
| - if (cleared_log_disasm_bit == true) {
|
| - set_log_parameters(log_parameters_ | LOG_DISASM);
|
| - }
|
| - }
|
| -}
|
| -
|
| -
|
| -void Simulator::VisitException(Instruction* instr) {
|
| - switch (instr->Mask(ExceptionMask)) {
|
| - case HLT: {
|
| - if (instr->ImmException() == kImmExceptionIsDebug) {
|
| - // Read the arguments encoded inline in the instruction stream.
|
| - uint32_t code;
|
| - uint32_t parameters;
|
| -
|
| - memcpy(&code,
|
| - pc_->InstructionAtOffset(kDebugCodeOffset),
|
| - sizeof(code));
|
| - memcpy(¶meters,
|
| - pc_->InstructionAtOffset(kDebugParamsOffset),
|
| - sizeof(parameters));
|
| - char const *message =
|
| - reinterpret_cast<char const*>(
|
| - pc_->InstructionAtOffset(kDebugMessageOffset));
|
| -
|
| - // Always print something when we hit a debug point that breaks.
|
| - // We are going to break, so printing something is not an issue in
|
| - // terms of speed.
|
| - if (FLAG_trace_sim_messages || FLAG_trace_sim || (parameters & BREAK)) {
|
| - if (message != NULL) {
|
| - PrintF("%sDebugger hit %d: %s%s%s\n",
|
| - clr_debug_number,
|
| - code,
|
| - clr_debug_message,
|
| - message,
|
| - clr_normal);
|
| - } else {
|
| - PrintF("%sDebugger hit %d.%s\n",
|
| - clr_debug_number,
|
| - code,
|
| - clr_normal);
|
| - }
|
| - }
|
| -
|
| - // Other options.
|
| - switch (parameters & kDebuggerTracingDirectivesMask) {
|
| - case TRACE_ENABLE:
|
| - set_log_parameters(log_parameters() | parameters);
|
| - if (parameters & LOG_SYS_REGS) { PrintSystemRegisters(); }
|
| - if (parameters & LOG_REGS) { PrintRegisters(); }
|
| - if (parameters & LOG_FP_REGS) { PrintFPRegisters(); }
|
| - break;
|
| - case TRACE_DISABLE:
|
| - set_log_parameters(log_parameters() & ~parameters);
|
| - break;
|
| - case TRACE_OVERRIDE:
|
| - set_log_parameters(parameters);
|
| - break;
|
| - default:
|
| - // We don't support a one-shot LOG_DISASM.
|
| - ASSERT((parameters & LOG_DISASM) == 0);
|
| - // Don't print information that is already being traced.
|
| - parameters &= ~log_parameters();
|
| - // Print the requested information.
|
| - if (parameters & LOG_SYS_REGS) PrintSystemRegisters(true);
|
| - if (parameters & LOG_REGS) PrintRegisters(true);
|
| - if (parameters & LOG_FP_REGS) PrintFPRegisters(true);
|
| - }
|
| -
|
| - // The stop parameters are inlined in the code. Skip them:
|
| - // - Skip to the end of the message string.
|
| - size_t size = kDebugMessageOffset + strlen(message) + 1;
|
| - pc_ = pc_->InstructionAtOffset(RoundUp(size, kInstructionSize));
|
| - // - Verify that the unreachable marker is present.
|
| - ASSERT(pc_->Mask(ExceptionMask) == HLT);
|
| - ASSERT(pc_->ImmException() == kImmExceptionIsUnreachable);
|
| - // - Skip past the unreachable marker.
|
| - set_pc(pc_->following());
|
| -
|
| - // Check if the debugger should break.
|
| - if (parameters & BREAK) Debug();
|
| -
|
| - } else if (instr->ImmException() == kImmExceptionIsRedirectedCall) {
|
| - DoRuntimeCall(instr);
|
| - } else if (instr->ImmException() == kImmExceptionIsPrintf) {
|
| - // Read the argument encoded inline in the instruction stream.
|
| - uint32_t type;
|
| - memcpy(&type,
|
| - pc_->InstructionAtOffset(kPrintfTypeOffset),
|
| - sizeof(type));
|
| -
|
| - const char* format = reg<const char*>(0);
|
| -
|
| - // Pass all of the relevant PCS registers onto printf. It doesn't
|
| - // matter if we pass too many as the extra ones won't be read.
|
| - int result;
|
| - fputs(clr_printf, stream_);
|
| - if (type == CPURegister::kRegister) {
|
| - result = fprintf(stream_, format,
|
| - xreg(1), xreg(2), xreg(3), xreg(4),
|
| - xreg(5), xreg(6), xreg(7));
|
| - } else if (type == CPURegister::kFPRegister) {
|
| - result = fprintf(stream_, format,
|
| - dreg(0), dreg(1), dreg(2), dreg(3),
|
| - dreg(4), dreg(5), dreg(6), dreg(7));
|
| - } else {
|
| - ASSERT(type == CPURegister::kNoRegister);
|
| - result = fprintf(stream_, "%s", format);
|
| - }
|
| - fputs(clr_normal, stream_);
|
| -
|
| -#ifdef DEBUG
|
| - CorruptAllCallerSavedCPURegisters();
|
| -#endif
|
| -
|
| - set_xreg(0, result);
|
| -
|
| - // The printf parameters are inlined in the code, so skip them.
|
| - set_pc(pc_->InstructionAtOffset(kPrintfLength));
|
| -
|
| - // Set LR as if we'd just called a native printf function.
|
| - set_lr(pc());
|
| -
|
| - } else if (instr->ImmException() == kImmExceptionIsUnreachable) {
|
| - fprintf(stream_, "Hit UNREACHABLE marker at PC=%p.\n",
|
| - reinterpret_cast<void*>(pc_));
|
| - abort();
|
| -
|
| - } else {
|
| - OS::DebugBreak();
|
| - }
|
| - break;
|
| - }
|
| -
|
| - default:
|
| - UNIMPLEMENTED();
|
| - }
|
| -}
|
| -
|
| -#endif // USE_SIMULATOR
|
| -
|
| -} } // namespace v8::internal
|
| -
|
| -#endif // V8_TARGET_ARCH_A64
|
|
|
Chromium Code Reviews
Issue 207823003:
Rename A64 port to ARM64 port (Closed)
Base URL: https://v8.googlecode.com/svn/branches/bleeding_edge