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// Copyright 2014, ARM Limited
// 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 ARM Limited 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 ARM LIMITED 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 ARM LIMITED 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 "jstypes.h"
#ifdef JS_SIMULATOR_ARM64
#include "jit/arm64/vixl/Debugger-vixl.h"
#include "mozilla/Vector.h"
#include "js/AllocPolicy.h"
namespace vixl {
// List of commands supported by the debugger.
#define DEBUG_COMMAND_LIST(C) \
C(HelpCommand) \
C(ContinueCommand) \
C(StepCommand) \
C(DisasmCommand) \
C(PrintCommand) \
C(ExamineCommand)
// Debugger command lines are broken up in token of different type to make
// processing easier later on.
class Token {
public:
virtual ~Token() {}
// Token type.
virtual bool IsRegister() const { return false; }
virtual bool IsFPRegister() const { return false; }
virtual bool IsIdentifier() const { return false; }
virtual bool IsAddress() const { return false; }
virtual bool IsInteger() const { return false; }
virtual bool IsFormat() const { return false; }
virtual bool IsUnknown() const { return false; }
// Token properties.
virtual bool CanAddressMemory() const { return false; }
virtual uint8_t* ToAddress(Debugger* debugger) const = 0;
virtual void Print(FILE* out = stdout) const = 0;
static Token* Tokenize(const char* arg);
};
typedef mozilla::Vector<Token*, 0, js::SystemAllocPolicy> TokenVector;
// Tokens often hold one value.
template<typename T> class ValueToken : public Token {
public:
explicit ValueToken(T value) : value_(value) {}
ValueToken() {}
T value() const { return value_; }
virtual uint8_t* ToAddress(Debugger* debugger) const override {
USE(debugger);
VIXL_ABORT();
}
protected:
T value_;
};
// Integer registers (X or W) and their aliases.
// Format: wn or xn with 0 <= n < 32 or a name in the aliases list.
class RegisterToken : public ValueToken<const Register> {
public:
explicit RegisterToken(const Register reg)
: ValueToken<const Register>(reg) {}
virtual bool IsRegister() const override { return true; }
virtual bool CanAddressMemory() const override { return value().Is64Bits(); }
virtual uint8_t* ToAddress(Debugger* debugger) const override;
virtual void Print(FILE* out = stdout) const override;
const char* Name() const;
static Token* Tokenize(const char* arg);
static RegisterToken* Cast(Token* tok) {
VIXL_ASSERT(tok->IsRegister());
return reinterpret_cast<RegisterToken*>(tok);
}
private:
static const int kMaxAliasNumber = 4;
static const char* kXAliases[kNumberOfRegisters][kMaxAliasNumber];
static const char* kWAliases[kNumberOfRegisters][kMaxAliasNumber];
};
// Floating point registers (D or S).
// Format: sn or dn with 0 <= n < 32.
class FPRegisterToken : public ValueToken<const FPRegister> {
public:
explicit FPRegisterToken(const FPRegister fpreg)
: ValueToken<const FPRegister>(fpreg) {}
virtual bool IsFPRegister() const override { return true; }
virtual void Print(FILE* out = stdout) const override;
static Token* Tokenize(const char* arg);
static FPRegisterToken* Cast(Token* tok) {
VIXL_ASSERT(tok->IsFPRegister());
return reinterpret_cast<FPRegisterToken*>(tok);
}
};
// Non-register identifiers.
// Format: Alphanumeric string starting with a letter.
class IdentifierToken : public ValueToken<char*> {
public:
explicit IdentifierToken(const char* name) {
size_t size = strlen(name) + 1;
value_ = js_pod_malloc<char>(size);
strncpy(value_, name, size);
}
virtual ~IdentifierToken() { js_free(value_); }
virtual bool IsIdentifier() const override { return true; }
virtual bool CanAddressMemory() const override { return strcmp(value(), "pc") == 0; }
virtual uint8_t* ToAddress(Debugger* debugger) const override;
virtual void Print(FILE* out = stdout) const override;
static Token* Tokenize(const char* arg);
static IdentifierToken* Cast(Token* tok) {
VIXL_ASSERT(tok->IsIdentifier());
return reinterpret_cast<IdentifierToken*>(tok);
}
};
// 64-bit address literal.
// Format: 0x... with up to 16 hexadecimal digits.
class AddressToken : public ValueToken<uint8_t*> {
public:
explicit AddressToken(uint8_t* address) : ValueToken<uint8_t*>(address) {}
virtual bool IsAddress() const override { return true; }
virtual bool CanAddressMemory() const override { return true; }
virtual uint8_t* ToAddress(Debugger* debugger) const override;
virtual void Print(FILE* out = stdout) const override;
static Token* Tokenize(const char* arg);
static AddressToken* Cast(Token* tok) {
VIXL_ASSERT(tok->IsAddress());
return reinterpret_cast<AddressToken*>(tok);
}
};
// 64-bit decimal integer literal.
// Format: n.
class IntegerToken : public ValueToken<int64_t> {
public:
explicit IntegerToken(int64_t value) : ValueToken<int64_t>(value) {}
virtual bool IsInteger() const override { return true; }
virtual void Print(FILE* out = stdout) const override;
static Token* Tokenize(const char* arg);
static IntegerToken* Cast(Token* tok) {
VIXL_ASSERT(tok->IsInteger());
return reinterpret_cast<IntegerToken*>(tok);
}
};
// Literal describing how to print a chunk of data (up to 64 bits).
// Format: .ln
// where l (letter) is one of
// * x: hexadecimal
// * s: signed integer
// * u: unsigned integer
// * f: floating point
// * i: instruction
// and n (size) is one of 8, 16, 32 and 64. n should be omitted for
// instructions.
class FormatToken : public Token {
public:
FormatToken() {}
virtual bool IsFormat() const override { return true; }
virtual int SizeOf() const = 0;
virtual char type_code() const = 0;
virtual void PrintData(void* data, FILE* out = stdout) const = 0;
virtual void Print(FILE* out = stdout) const override = 0;
virtual uint8_t* ToAddress(Debugger* debugger) const override {
USE(debugger);
VIXL_ABORT();
}
static Token* Tokenize(const char* arg);
static FormatToken* Cast(Token* tok) {
VIXL_ASSERT(tok->IsFormat());
return reinterpret_cast<FormatToken*>(tok);
}
};
template<typename T> class Format : public FormatToken {
public:
Format(const char* fmt, char type_code) : fmt_(fmt), type_code_(type_code) {}
virtual int SizeOf() const override { return sizeof(T); }
virtual char type_code() const override { return type_code_; }
virtual void PrintData(void* data, FILE* out = stdout) const override {
T value;
memcpy(&value, data, sizeof(value));
fprintf(out, fmt_, value);
}
virtual void Print(FILE* out = stdout) const override;
private:
const char* fmt_;
char type_code_;
};
// Tokens which don't fit any of the above.
class UnknownToken : public Token {
public:
explicit UnknownToken(const char* arg) {
size_t size = strlen(arg) + 1;
unknown_ = js_pod_malloc<char>(size);
strncpy(unknown_, arg, size);
}
virtual ~UnknownToken() { js_free(unknown_); }
virtual uint8_t* ToAddress(Debugger* debugger) const override {
USE(debugger);
VIXL_ABORT();
}
virtual bool IsUnknown() const override { return true; }
virtual void Print(FILE* out = stdout) const override;
private:
char* unknown_;
};
// All debugger commands must subclass DebugCommand and implement Run, Print
// and Build. Commands must also define kHelp and kAliases.
class DebugCommand {
public:
explicit DebugCommand(Token* name) : name_(IdentifierToken::Cast(name)) {}
DebugCommand() : name_(NULL) {}
virtual ~DebugCommand() { js_delete(name_); }
const char* name() { return name_->value(); }
// Run the command on the given debugger. The command returns true if
// execution should move to the next instruction.
virtual bool Run(Debugger * debugger) = 0;
virtual void Print(FILE* out = stdout);
static bool Match(const char* name, const char** aliases);
static DebugCommand* Parse(char* line);
static void PrintHelp(const char** aliases,
const char* args,
const char* help);
private:
IdentifierToken* name_;
};
// For all commands below see their respective kHelp and kAliases in
// debugger-a64.cc
class HelpCommand : public DebugCommand {
public:
explicit HelpCommand(Token* name) : DebugCommand(name) {}
virtual bool Run(Debugger* debugger) override;
static DebugCommand* Build(TokenVector&& args);
static const char* kHelp;
static const char* kAliases[];
static const char* kArguments;
};
class ContinueCommand : public DebugCommand {
public:
explicit ContinueCommand(Token* name) : DebugCommand(name) {}
virtual bool Run(Debugger* debugger) override;
static DebugCommand* Build(TokenVector&& args);
static const char* kHelp;
static const char* kAliases[];
static const char* kArguments;
};
class StepCommand : public DebugCommand {
public:
StepCommand(Token* name, IntegerToken* count)
: DebugCommand(name), count_(count) {}
virtual ~StepCommand() { js_delete(count_); }
int64_t count() { return count_->value(); }
virtual bool Run(Debugger* debugger) override;
virtual void Print(FILE* out = stdout) override;
static DebugCommand* Build(TokenVector&& args);
static const char* kHelp;
static const char* kAliases[];
static const char* kArguments;
private:
IntegerToken* count_;
};
class DisasmCommand : public DebugCommand {
public:
static DebugCommand* Build(TokenVector&& args);
static const char* kHelp;
static const char* kAliases[];
static const char* kArguments;
};
class PrintCommand : public DebugCommand {
public:
PrintCommand(Token* name, Token* target, FormatToken* format)
: DebugCommand(name), target_(target), format_(format) {}
virtual ~PrintCommand() {
js_delete(target_);
js_delete(format_);
}
Token* target() { return target_; }
FormatToken* format() { return format_; }
virtual bool Run(Debugger* debugger) override;
virtual void Print(FILE* out = stdout) override;
static DebugCommand* Build(TokenVector&& args);
static const char* kHelp;
static const char* kAliases[];
static const char* kArguments;
private:
Token* target_;
FormatToken* format_;
};
class ExamineCommand : public DebugCommand {
public:
ExamineCommand(Token* name,
Token* target,
FormatToken* format,
IntegerToken* count)
: DebugCommand(name), target_(target), format_(format), count_(count) {}
virtual ~ExamineCommand() {
js_delete(target_);
js_delete(format_);
js_delete(count_);
}
Token* target() { return target_; }
FormatToken* format() { return format_; }
IntegerToken* count() { return count_; }
virtual bool Run(Debugger* debugger) override;
virtual void Print(FILE* out = stdout) override;
static DebugCommand* Build(TokenVector&& args);
static const char* kHelp;
static const char* kAliases[];
static const char* kArguments;
private:
Token* target_;
FormatToken* format_;
IntegerToken* count_;
};
// Commands which name does not match any of the known commnand.
class UnknownCommand : public DebugCommand {
public:
explicit UnknownCommand(TokenVector&& args) : args_(std::move(args)) {}
virtual ~UnknownCommand();
virtual bool Run(Debugger* debugger) override;
private:
TokenVector args_;
};
// Commands which name match a known command but the syntax is invalid.
class InvalidCommand : public DebugCommand {
public:
InvalidCommand(TokenVector&& args, int index, const char* cause)
: args_(std::move(args)), index_(index), cause_(cause) {}
virtual ~InvalidCommand();
virtual bool Run(Debugger* debugger) override;
private:
TokenVector args_;
int index_;
const char* cause_;
};
const char* HelpCommand::kAliases[] = { "help", NULL };
const char* HelpCommand::kArguments = NULL;
const char* HelpCommand::kHelp = " Print this help.";
const char* ContinueCommand::kAliases[] = { "continue", "c", NULL };
const char* ContinueCommand::kArguments = NULL;
const char* ContinueCommand::kHelp = " Resume execution.";
const char* StepCommand::kAliases[] = { "stepi", "si", NULL };
const char* StepCommand::kArguments = "[n = 1]";
const char* StepCommand::kHelp = " Execute n next instruction(s).";
const char* DisasmCommand::kAliases[] = { "disasm", "di", NULL };
const char* DisasmCommand::kArguments = "[n = 10]";
const char* DisasmCommand::kHelp =
" Disassemble n instruction(s) at pc.\n"
" This command is equivalent to x pc.i [n = 10]."
;
const char* PrintCommand::kAliases[] = { "print", "p", NULL };
const char* PrintCommand::kArguments = "<entity>[.format]";
const char* PrintCommand::kHelp =
" Print the given entity according to the given format.\n"
" The format parameter only affects individual registers; it is ignored\n"
" for other entities.\n"
" <entity> can be one of the following:\n"
" * A register name (such as x0, s1, ...).\n"
" * 'regs', to print all integer (W and X) registers.\n"
" * 'fpregs' to print all floating-point (S and D) registers.\n"
" * 'sysregs' to print all system registers (including NZCV).\n"
" * 'pc' to print the current program counter.\n"
;
const char* ExamineCommand::kAliases[] = { "m", "mem", "x", NULL };
const char* ExamineCommand::kArguments = "<addr>[.format] [n = 10]";
const char* ExamineCommand::kHelp =
" Examine memory. Print n items of memory at address <addr> according to\n"
" the given [.format].\n"
" Addr can be an immediate address, a register name or pc.\n"
" Format is made of a type letter: 'x' (hexadecimal), 's' (signed), 'u'\n"
" (unsigned), 'f' (floating point), i (instruction) and a size in bits\n"
" when appropriate (8, 16, 32, 64)\n"
" E.g 'x sp.x64' will print 10 64-bit words from the stack in\n"
" hexadecimal format."
;
const char* RegisterToken::kXAliases[kNumberOfRegisters][kMaxAliasNumber] = {
{ "x0", NULL },
{ "x1", NULL },
{ "x2", NULL },
{ "x3", NULL },
{ "x4", NULL },
{ "x5", NULL },
{ "x6", NULL },
{ "x7", NULL },
{ "x8", NULL },
{ "x9", NULL },
{ "x10", NULL },
{ "x11", NULL },
{ "x12", NULL },
{ "x13", NULL },
{ "x14", NULL },
{ "x15", NULL },
{ "ip0", "x16", NULL },
{ "ip1", "x17", NULL },
{ "x18", "pr", NULL },
{ "x19", NULL },
{ "x20", NULL },
{ "x21", NULL },
{ "x22", NULL },
{ "x23", NULL },
{ "x24", NULL },
{ "x25", NULL },
{ "x26", NULL },
{ "x27", NULL },
{ "x28", NULL },
{ "fp", "x29", NULL },
{ "lr", "x30", NULL },
{ "sp", NULL}
};
const char* RegisterToken::kWAliases[kNumberOfRegisters][kMaxAliasNumber] = {
{ "w0", NULL },
{ "w1", NULL },
{ "w2", NULL },
{ "w3", NULL },
{ "w4", NULL },
{ "w5", NULL },
{ "w6", NULL },
{ "w7", NULL },
{ "w8", NULL },
{ "w9", NULL },
{ "w10", NULL },
{ "w11", NULL },
{ "w12", NULL },
{ "w13", NULL },
{ "w14", NULL },
{ "w15", NULL },
{ "w16", NULL },
{ "w17", NULL },
{ "w18", NULL },
{ "w19", NULL },
{ "w20", NULL },
{ "w21", NULL },
{ "w22", NULL },
{ "w23", NULL },
{ "w24", NULL },
{ "w25", NULL },
{ "w26", NULL },
{ "w27", NULL },
{ "w28", NULL },
{ "w29", NULL },
{ "w30", NULL },
{ "wsp", NULL }
};
Debugger::Debugger(Decoder* decoder, FILE* stream)
: Simulator(decoder, stream),
debug_parameters_(DBG_INACTIVE),
pending_request_(false),
steps_(0),
last_command_(NULL) {
disasm_ = js_new<PrintDisassembler>(stdout);
printer_ = js_new<Decoder>();
printer_->AppendVisitor(disasm_);
}
Debugger::~Debugger() {
js_delete(disasm_);
js_delete(printer_);
}
void Debugger::Run() {
pc_modified_ = false;
while (pc_ != kEndOfSimAddress) {
if (pending_request()) RunDebuggerShell();
ExecuteInstruction();
LogAllWrittenRegisters();
}
}
void Debugger::PrintInstructions(const void* address, int64_t count) {
if (count == 0) {
return;
}
const Instruction* from = Instruction::CastConst(address);
if (count < 0) {
count = -count;
from -= (count - 1) * kInstructionSize;
}
const Instruction* to = from + count * kInstructionSize;
for (const Instruction* current = from;
current < to;
current = current->NextInstruction()) {
printer_->Decode(current);
}
}
void Debugger::PrintMemory(const uint8_t* address,
const FormatToken* format,
int64_t count) {
if (count == 0) {
return;
}
const uint8_t* from = address;
int size = format->SizeOf();
if (count < 0) {
count = -count;
from -= (count - 1) * size;
}
const uint8_t* to = from + count * size;
for (const uint8_t* current = from; current < to; current += size) {
if (((current - from) % 8) == 0) {
printf("\n%p: ", current);
}
uint64_t data = Memory::Read<uint64_t>(current);
format->PrintData(&data);
printf(" ");
}
printf("\n\n");
}
void Debugger::PrintRegister(const Register& target_reg,
const char* name,
const FormatToken* format) {
const uint64_t reg_size = target_reg.size();
const uint64_t format_size = format->SizeOf() * 8;
const uint64_t count = reg_size / format_size;
const uint64_t mask = 0xffffffffffffffff >> (64 - format_size);
const uint64_t reg_value = reg<uint64_t>(target_reg.code(),
Reg31IsStackPointer);
VIXL_ASSERT(count > 0);
printf("%s = ", name);
for (uint64_t i = 1; i <= count; i++) {
uint64_t data = reg_value >> (reg_size - (i * format_size));
data &= mask;
format->PrintData(&data);
printf(" ");
}
printf("\n");
}
// TODO(all): fix this for vector registers.
void Debugger::PrintFPRegister(const FPRegister& target_fpreg,
const FormatToken* format) {
const unsigned fpreg_size = target_fpreg.size();
const uint64_t format_size = format->SizeOf() * 8;
const uint64_t count = fpreg_size / format_size;
const uint64_t mask = 0xffffffffffffffff >> (64 - format_size);
const uint64_t fpreg_value = vreg<uint64_t>(fpreg_size, target_fpreg.code());
VIXL_ASSERT(count > 0);
if (target_fpreg.Is32Bits()) {
printf("s%u = ", target_fpreg.code());
} else {
printf("d%u = ", target_fpreg.code());
}
for (uint64_t i = 1; i <= count; i++) {
uint64_t data = fpreg_value >> (fpreg_size - (i * format_size));
data &= mask;
format->PrintData(&data);
printf(" ");
}
printf("\n");
}
void Debugger::VisitException(const Instruction* instr) {
switch (instr->Mask(ExceptionMask)) {
case BRK:
DoBreakpoint(instr);
return;
case HLT:
VIXL_FALLTHROUGH();
default: Simulator::VisitException(instr);
}
}
// Read a command. A command will be at most kMaxDebugShellLine char long and
// ends with '\n\0'.
// TODO: Should this be a utility function?
char* Debugger::ReadCommandLine(const char* prompt, char* buffer, int length) {
int fgets_calls = 0;
char* end = NULL;
printf("%s", prompt);
fflush(stdout);
do {
if (fgets(buffer, length, stdin) == NULL) {
printf(" ** Error while reading command. **\n");
return NULL;
}
fgets_calls++;
end = strchr(buffer, '\n');
} while (end == NULL);
if (fgets_calls != 1) {
printf(" ** Command too long. **\n");
return NULL;
}
// Remove the newline from the end of the command.
VIXL_ASSERT(end[1] == '\0');
VIXL_ASSERT((end - buffer) < (length - 1));
end[0] = '\0';
return buffer;
}
void Debugger::RunDebuggerShell() {
if (IsDebuggerRunning()) {
if (steps_ > 0) {
// Finish stepping first.
--steps_;
return;
}
printf("Next: ");
PrintInstructions(pc());
bool done = false;
while (!done) {
char buffer[kMaxDebugShellLine];
char* line = ReadCommandLine("vixl> ", buffer, kMaxDebugShellLine);
if (line == NULL) continue; // An error occurred.
DebugCommand* command = DebugCommand::Parse(line);
if (command != NULL) {
last_command_ = command;
}
if (last_command_ != NULL) {
done = last_command_->Run(this);
} else {
printf("No previous command to run!\n");
}
}
if ((debug_parameters_ & DBG_BREAK) != 0) {
// The break request has now been handled, move to next instruction.
debug_parameters_ &= ~DBG_BREAK;
increment_pc();
}
}
}
void Debugger::DoBreakpoint(const Instruction* instr) {
VIXL_ASSERT(instr->Mask(ExceptionMask) == BRK);
printf("Hit breakpoint at pc=%p.\n", reinterpret_cast<const void*>(instr));
set_debug_parameters(debug_parameters() | DBG_BREAK | DBG_ACTIVE);
// Make the shell point to the brk instruction.
set_pc(instr);
}
static bool StringToUInt64(uint64_t* value, const char* line, int base = 10) {
char* endptr = NULL;
errno = 0; // Reset errors.
uint64_t parsed = strtoul(line, &endptr, base);
if (errno == ERANGE) {
// Overflow.
return false;
}
if (endptr == line) {
// No digits were parsed.
return false;
}
if (*endptr != '\0') {
// Non-digit characters present at the end.
return false;
}
*value = parsed;
return true;
}
static bool StringToInt64(int64_t* value, const char* line, int base = 10) {
char* endptr = NULL;
errno = 0; // Reset errors.
int64_t parsed = strtol(line, &endptr, base);
if (errno == ERANGE) {
// Overflow, undeflow.
return false;
}
if (endptr == line) {
// No digits were parsed.
return false;
}
if (*endptr != '\0') {
// Non-digit characters present at the end.
return false;
}
*value = parsed;
return true;
}
Token* Token::Tokenize(const char* arg) {
if ((arg == NULL) || (*arg == '\0')) {
return NULL;
}
// The order is important. For example Identifier::Tokenize would consider
// any register to be a valid identifier.
Token* token = RegisterToken::Tokenize(arg);
if (token != NULL) {
return token;
}
token = FPRegisterToken::Tokenize(arg);
if (token != NULL) {
return token;
}
token = IdentifierToken::Tokenize(arg);
if (token != NULL) {
return token;
}
token = AddressToken::Tokenize(arg);
if (token != NULL) {
return token;
}
token = IntegerToken::Tokenize(arg);
if (token != NULL) {
return token;
}
return js_new<UnknownToken>(arg);
}
uint8_t* RegisterToken::ToAddress(Debugger* debugger) const {
VIXL_ASSERT(CanAddressMemory());
uint64_t reg_value = debugger->xreg(value().code(), Reg31IsStackPointer);
uint8_t* address = NULL;
memcpy(&address, ®_value, sizeof(address));
return address;
}
void RegisterToken::Print(FILE* out) const {
VIXL_ASSERT(value().IsValid());
fprintf(out, "[Register %s]", Name());
}
const char* RegisterToken::Name() const {
if (value().Is32Bits()) {
return kWAliases[value().code()][0];
} else {
return kXAliases[value().code()][0];
}
}
Token* RegisterToken::Tokenize(const char* arg) {
for (unsigned i = 0; i < kNumberOfRegisters; i++) {
// Is it a X register or alias?
for (const char** current = kXAliases[i]; *current != NULL; current++) {
if (strcmp(arg, *current) == 0) {
return js_new<RegisterToken>(Register::XRegFromCode(i));
}
}
// Is it a W register or alias?
for (const char** current = kWAliases[i]; *current != NULL; current++) {
if (strcmp(arg, *current) == 0) {
return js_new<RegisterToken>(Register::WRegFromCode(i));
}
}
}
return NULL;
}
void FPRegisterToken::Print(FILE* out) const {
VIXL_ASSERT(value().IsValid());
char prefix = value().Is32Bits() ? 's' : 'd';
fprintf(out, "[FPRegister %c%" PRIu32 "]", prefix, value().code());
}
Token* FPRegisterToken::Tokenize(const char* arg) {
if (strlen(arg) < 2) {
return NULL;
}
switch (*arg) {
case 's':
case 'd':
const char* cursor = arg + 1;
uint64_t code = 0;
if (!StringToUInt64(&code, cursor)) {
return NULL;
}
if (code > kNumberOfFPRegisters) {
return NULL;
}
VRegister fpreg = NoVReg;
switch (*arg) {
case 's':
fpreg = VRegister::SRegFromCode(static_cast<unsigned>(code));
break;
case 'd':
fpreg = VRegister::DRegFromCode(static_cast<unsigned>(code));
break;
default: VIXL_UNREACHABLE();
}
return js_new<FPRegisterToken>(fpreg);
}
return NULL;
}
uint8_t* IdentifierToken::ToAddress(Debugger* debugger) const {
VIXL_ASSERT(CanAddressMemory());
const Instruction* pc_value = debugger->pc();
uint8_t* address = NULL;
memcpy(&address, &pc_value, sizeof(address));
return address;
}
void IdentifierToken::Print(FILE* out) const {
fprintf(out, "[Identifier %s]", value());
}
Token* IdentifierToken::Tokenize(const char* arg) {
if (!isalpha(arg[0])) {
return NULL;
}
const char* cursor = arg + 1;
while ((*cursor != '\0') && isalnum(*cursor)) {
++cursor;
}
if (*cursor == '\0') {
return js_new<IdentifierToken>(arg);
}
return NULL;
}
uint8_t* AddressToken::ToAddress(Debugger* debugger) const {
USE(debugger);
return value();
}
void AddressToken::Print(FILE* out) const {
fprintf(out, "[Address %p]", value());
}
Token* AddressToken::Tokenize(const char* arg) {
if ((strlen(arg) < 3) || (arg[0] != '0') || (arg[1] != 'x')) {
return NULL;
}
uint64_t ptr = 0;
if (!StringToUInt64(&ptr, arg, 16)) {
return NULL;
}
uint8_t* address = reinterpret_cast<uint8_t*>(ptr);
return js_new<AddressToken>(address);
}
void IntegerToken::Print(FILE* out) const {
fprintf(out, "[Integer %" PRId64 "]", value());
}
Token* IntegerToken::Tokenize(const char* arg) {
int64_t value = 0;
if (!StringToInt64(&value, arg)) {
return NULL;
}
return js_new<IntegerToken>(value);
}
Token* FormatToken::Tokenize(const char* arg) {
size_t length = strlen(arg);
switch (arg[0]) {
case 'x':
case 's':
case 'u':
case 'f':
if (length == 1) return NULL;
break;
case 'i':
if (length == 1) return js_new<Format<uint32_t>>("%08" PRIx32, 'i');
VIXL_FALLTHROUGH();
default: return NULL;
}
char* endptr = NULL;
errno = 0; // Reset errors.
uint64_t count = strtoul(arg + 1, &endptr, 10);
if (errno != 0) {
// Overflow, etc.
return NULL;
}
if (endptr == arg) {
// No digits were parsed.
return NULL;
}
if (*endptr != '\0') {
// There are unexpected (non-digit) characters after the number.
return NULL;
}
switch (arg[0]) {
case 'x':
switch (count) {
case 8: return js_new<Format<uint8_t>>("%02" PRIx8, 'x');
case 16: return js_new<Format<uint16_t>>("%04" PRIx16, 'x');
case 32: return js_new<Format<uint32_t>>("%08" PRIx32, 'x');
case 64: return js_new<Format<uint64_t>>("%016" PRIx64, 'x');
default: return NULL;
}
case 's':
switch (count) {
case 8: return js_new<Format<int8_t>>("%4" PRId8, 's');
case 16: return js_new<Format<int16_t>>("%6" PRId16, 's');
case 32: return js_new<Format<int32_t>>("%11" PRId32, 's');
case 64: return js_new<Format<int64_t>>("%20" PRId64, 's');
default: return NULL;
}
case 'u':
switch (count) {
case 8: return js_new<Format<uint8_t>>("%3" PRIu8, 'u');
case 16: return js_new<Format<uint16_t>>("%5" PRIu16, 'u');
case 32: return js_new<Format<uint32_t>>("%10" PRIu32, 'u');
case 64: return js_new<Format<uint64_t>>("%20" PRIu64, 'u');
default: return NULL;
}
case 'f':
switch (count) {
case 32: return js_new<Format<float>>("%13g", 'f');
case 64: return js_new<Format<double>>("%13g", 'f');
default: return NULL;
}
default:
VIXL_UNREACHABLE();
return NULL;
}
}
template<typename T>
void Format<T>::Print(FILE* out) const {
unsigned size = sizeof(T) * 8;
fprintf(out, "[Format %c%u - %s]", type_code_, size, fmt_);
}
void UnknownToken::Print(FILE* out) const {
fprintf(out, "[Unknown %s]", unknown_);
}
void DebugCommand::Print(FILE* out) {
fprintf(out, "%s", name());
}
bool DebugCommand::Match(const char* name, const char** aliases) {
for (const char** current = aliases; *current != NULL; current++) {
if (strcmp(name, *current) == 0) {
return true;
}
}
return false;
}
DebugCommand* DebugCommand::Parse(char* line) {
TokenVector args;
for (char* chunk = strtok(line, " \t");
chunk != NULL;
chunk = strtok(NULL, " \t")) {
char* dot = strchr(chunk, '.');
if (dot != NULL) {
// 'Token.format'.
Token* format = FormatToken::Tokenize(dot + 1);
if (format != NULL) {
*dot = '\0';
(void)args.append(Token::Tokenize(chunk));
(void)args.append(format);
} else {
// Error while parsing the format, push the UnknownToken so an error
// can be accurately reported.
(void)args.append(Token::Tokenize(chunk));
}
} else {
(void)args.append(Token::Tokenize(chunk));
}
}
if (args.empty()) {
return NULL;
}
if (!args[0]->IsIdentifier()) {
return js_new<InvalidCommand>(std::move(args), 0, "command name is not valid");
}
const char* name = IdentifierToken::Cast(args[0])->value();
#define RETURN_IF_MATCH(Command) \
if (Match(name, Command::kAliases)) { \
return Command::Build(std::move(args)); \
}
DEBUG_COMMAND_LIST(RETURN_IF_MATCH);
#undef RETURN_IF_MATCH
return js_new<UnknownCommand>(std::move(args));
}
void DebugCommand::PrintHelp(const char** aliases,
const char* args,
const char* help) {
VIXL_ASSERT(aliases[0] != NULL);
VIXL_ASSERT(help != NULL);
printf("\n----\n\n");
for (const char** current = aliases; *current != NULL; current++) {
if (args != NULL) {
printf("%s %s\n", *current, args);
} else {
printf("%s\n", *current);
}
}
printf("\n%s\n", help);
}
bool HelpCommand::Run(Debugger* debugger) {
VIXL_ASSERT(debugger->IsDebuggerRunning());
USE(debugger);
#define PRINT_HELP(Command) \
DebugCommand::PrintHelp(Command::kAliases, \
Command::kArguments, \
Command::kHelp);
DEBUG_COMMAND_LIST(PRINT_HELP);
#undef PRINT_HELP
printf("\n----\n\n");
return false;
}
DebugCommand* HelpCommand::Build(TokenVector&& args) {
if (args.length() != 1) {
return js_new<InvalidCommand>(std::move(args), -1, "too many arguments");
}
return js_new<HelpCommand>(args[0]);
}
bool ContinueCommand::Run(Debugger* debugger) {
VIXL_ASSERT(debugger->IsDebuggerRunning());
debugger->set_debug_parameters(debugger->debug_parameters() & ~DBG_ACTIVE);
return true;
}
DebugCommand* ContinueCommand::Build(TokenVector&& args) {
if (args.length() != 1) {
return js_new<InvalidCommand>(std::move(args), -1, "too many arguments");
}
return js_new<ContinueCommand>(args[0]);
}
bool StepCommand::Run(Debugger* debugger) {
VIXL_ASSERT(debugger->IsDebuggerRunning());
int64_t steps = count();
if (steps < 0) {
printf(" ** invalid value for steps: %" PRId64 " (<0) **\n", steps);
} else if (steps > 1) {
debugger->set_steps(steps - 1);
}
return true;
}
void StepCommand::Print(FILE* out) {
fprintf(out, "%s %" PRId64 "", name(), count());
}
DebugCommand* StepCommand::Build(TokenVector&& args) {
IntegerToken* count = NULL;
switch (args.length()) {
case 1: { // step [1]
count = js_new<IntegerToken>(1);
break;
}
case 2: { // step n
Token* first = args[1];
if (!first->IsInteger()) {
return js_new<InvalidCommand>(std::move(args), 1, "expects int");
}
count = IntegerToken::Cast(first);
break;
}
default:
return js_new<InvalidCommand>(std::move(args), -1, "too many arguments");
}
return js_new<StepCommand>(args[0], count);
}
DebugCommand* DisasmCommand::Build(TokenVector&& args) {
IntegerToken* count = NULL;
switch (args.length()) {
case 1: { // disasm [10]
count = js_new<IntegerToken>(10);
break;
}
case 2: { // disasm n
Token* first = args[1];
if (!first->IsInteger()) {
return js_new<InvalidCommand>(std::move(args), 1, "expects int");
}
count = IntegerToken::Cast(first);
break;
}
default:
return js_new<InvalidCommand>(std::move(args), -1, "too many arguments");
}
Token* target = js_new<IdentifierToken>("pc");
FormatToken* format = js_new<Format<uint32_t>>("%08" PRIx32, 'i');
return js_new<ExamineCommand>(args[0], target, format, count);
}
void PrintCommand::Print(FILE* out) {
fprintf(out, "%s ", name());
target()->Print(out);
if (format() != NULL) format()->Print(out);
}
bool PrintCommand::Run(Debugger* debugger) {
VIXL_ASSERT(debugger->IsDebuggerRunning());
Token* tok = target();
if (tok->IsIdentifier()) {
char* identifier = IdentifierToken::Cast(tok)->value();
if (strcmp(identifier, "regs") == 0) {
debugger->PrintRegisters();
} else if (strcmp(identifier, "fpregs") == 0) {
debugger->PrintVRegisters();
} else if (strcmp(identifier, "sysregs") == 0) {
debugger->PrintSystemRegisters();
} else if (strcmp(identifier, "pc") == 0) {
printf("pc = %16p\n", reinterpret_cast<const void*>(debugger->pc()));
} else {
printf(" ** Unknown identifier to print: %s **\n", identifier);
}
return false;
}
FormatToken* format_tok = format();
VIXL_ASSERT(format_tok != NULL);
if (format_tok->type_code() == 'i') {
// TODO(all): Add support for instruction disassembly.
printf(" ** unsupported format: instructions **\n");
return false;
}
if (tok->IsRegister()) {
RegisterToken* reg_tok = RegisterToken::Cast(tok);
Register reg = reg_tok->value();
debugger->PrintRegister(reg, reg_tok->Name(), format_tok);
return false;
}
if (tok->IsFPRegister()) {
FPRegister fpreg = FPRegisterToken::Cast(tok)->value();
debugger->PrintFPRegister(fpreg, format_tok);
return false;
}
VIXL_UNREACHABLE();
return false;
}
DebugCommand* PrintCommand::Build(TokenVector&& args) {
if (args.length() < 2) {
return js_new<InvalidCommand>(std::move(args), -1, "too few arguments");
}
Token* target = args[1];
if (!target->IsRegister() &&
!target->IsFPRegister() &&
!target->IsIdentifier()) {
return js_new<InvalidCommand>(std::move(args), 1, "expects reg or identifier");
}
FormatToken* format = NULL;
int target_size = 0;
if (target->IsRegister()) {
Register reg = RegisterToken::Cast(target)->value();
target_size = reg.SizeInBytes();
} else if (target->IsFPRegister()) {
FPRegister fpreg = FPRegisterToken::Cast(target)->value();
target_size = fpreg.SizeInBytes();
}
// If the target is an identifier there must be no format. This is checked
// in the switch statement below.
switch (args.length()) {
case 2: {
if (target->IsRegister()) {
switch (target_size) {
case 4: format = js_new<Format<uint32_t>>("%08" PRIx32, 'x'); break;
case 8: format = js_new<Format<uint64_t>>("%016" PRIx64, 'x'); break;
default: VIXL_UNREACHABLE();
}
} else if (target->IsFPRegister()) {
switch (target_size) {
case 4: format = js_new<Format<float>>("%8g", 'f'); break;
case 8: format = js_new<Format<double>>("%8g", 'f'); break;
default: VIXL_UNREACHABLE();
}
}
break;
}
case 3: {
if (target->IsIdentifier()) {
return js_new<InvalidCommand>(std::move(args), 2,
"format is only allowed with registers");
}
Token* second = args[2];
if (!second->IsFormat()) {
return js_new<InvalidCommand>(std::move(args), 2, "expects format");
}
format = FormatToken::Cast(second);
if (format->SizeOf() > target_size) {
return js_new<InvalidCommand>(std::move(args), 2, "format too wide");
}
break;
}
default:
return js_new<InvalidCommand>(std::move(args), -1, "too many arguments");
}
return js_new<PrintCommand>(args[0], target, format);
}
bool ExamineCommand::Run(Debugger* debugger) {
VIXL_ASSERT(debugger->IsDebuggerRunning());
uint8_t* address = target()->ToAddress(debugger);
int64_t amount = count()->value();
if (format()->type_code() == 'i') {
debugger->PrintInstructions(address, amount);
} else {
debugger->PrintMemory(address, format(), amount);
}
return false;
}
void ExamineCommand::Print(FILE* out) {
fprintf(out, "%s ", name());
format()->Print(out);
target()->Print(out);
}
DebugCommand* ExamineCommand::Build(TokenVector&& args) {
if (args.length() < 2) {
return js_new<InvalidCommand>(std::move(args), -1, "too few arguments");
}
Token* target = args[1];
if (!target->CanAddressMemory()) {
return js_new<InvalidCommand>(std::move(args), 1, "expects address");
}
FormatToken* format = NULL;
IntegerToken* count = NULL;
switch (args.length()) {
case 2: { // mem addr[.x64] [10]
format = js_new<Format<uint64_t>>("%016" PRIx64, 'x');
count = js_new<IntegerToken>(10);
break;
}
case 3: { // mem addr.format [10]
// mem addr[.x64] n
Token* second = args[2];
if (second->IsFormat()) {
format = FormatToken::Cast(second);
count = js_new<IntegerToken>(10);
break;
} else if (second->IsInteger()) {
format = js_new<Format<uint64_t>>("%016" PRIx64, 'x');
count = IntegerToken::Cast(second);
} else {
return js_new<InvalidCommand>(std::move(args), 2, "expects format or integer");
}
VIXL_UNREACHABLE();
break;
}
case 4: { // mem addr.format n
Token* second = args[2];
Token* third = args[3];
if (!second->IsFormat() || !third->IsInteger()) {
return js_new<InvalidCommand>(std::move(args), -1, "expects addr[.format] [n]");
}
format = FormatToken::Cast(second);
count = IntegerToken::Cast(third);
break;
}
default:
return js_new<InvalidCommand>(std::move(args), -1, "too many arguments");
}
return js_new<ExamineCommand>(args[0], target, format, count);
}
UnknownCommand::~UnknownCommand() {
const size_t size = args_.length();
for (size_t i = 0; i < size; ++i) {
js_delete(args_[i]);
}
}
bool UnknownCommand::Run(Debugger* debugger) {
VIXL_ASSERT(debugger->IsDebuggerRunning());
USE(debugger);
printf(" ** Unknown Command:");
const size_t size = args_.length();
for (size_t i = 0; i < size; ++i) {
printf(" ");
args_[i]->Print(stdout);
}
printf(" **\n");
return false;
}
InvalidCommand::~InvalidCommand() {
const size_t size = args_.length();
for (size_t i = 0; i < size; ++i) {
js_delete(args_[i]);
}
}
bool InvalidCommand::Run(Debugger* debugger) {
VIXL_ASSERT(debugger->IsDebuggerRunning());
USE(debugger);
printf(" ** Invalid Command:");
const size_t size = args_.length();
for (size_t i = 0; i < size; ++i) {
printf(" ");
if (i == static_cast<size_t>(index_)) {
printf(">>");
args_[i]->Print(stdout);
printf("<<");
} else {
args_[i]->Print(stdout);
}
}
printf(" **\n");
printf(" ** %s\n", cause_);
return false;
}
} // namespace vixl
#endif // JS_SIMULATOR_ARM64