ppsspp/Core/Debugger/DisassemblyManager.cpp
Unknown W. Brackets 6da10463f9 Debugger: Make reg names safer, stop using v000.
Better to use S000, etc. as that's more clear throughout.
2023-04-29 09:48:33 -07:00

1118 lines
27 KiB
C++

// Copyright (c) 2012- PPSSPP Project.
// This program is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, version 2.0 or later versions.
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License 2.0 for more details.
// A copy of the GPL 2.0 should have been included with the program.
// If not, see http://www.gnu.org/licenses/
// Official git repository and contact information can be found at
// https://github.com/hrydgard/ppsspp and http://www.ppsspp.org/.
#include "ppsspp_config.h"
#include <string>
#include <algorithm>
#include <map>
#include "ext/xxhash.h"
#include "Common/CommonTypes.h"
#include "Common/Data/Encoding/Utf8.h"
#include "Common/StringUtils.h"
#include "Core/MemMap.h"
#include "Core/System.h"
#include "Core/MIPS/MIPSCodeUtils.h"
#include "Core/MIPS/MIPSTables.h"
#include "Core/Debugger/DebugInterface.h"
#include "Core/Debugger/SymbolMap.h"
#include "Core/Debugger/DisassemblyManager.h"
std::map<u32, DisassemblyEntry*> DisassemblyManager::entries;
std::recursive_mutex DisassemblyManager::entriesLock_;
DebugInterface* DisassemblyManager::cpu;
int DisassemblyManager::maxParamChars = 29;
bool isInInterval(u32 start, u32 size, u32 value)
{
return start <= value && value <= (start+size-1);
}
bool IsLikelyStringAt(uint32_t addr) {
uint32_t maxLen = Memory::ValidSize(addr, 128);
if (maxLen <= 1)
return false;
const char *p = Memory::GetCharPointer(addr);
// If there's no terminator nearby, let's say no.
if (memchr(p, 0, maxLen) == nullptr)
return false;
// Allow tabs and newlines.
static constexpr bool validControl[] = {
false, false, false, false, false, false, false, false,
false, true, true, true, false, true, false, false,
false, false, false, false, false, false, false, false,
false, false, false, false, false, false, false, false,
};
// Check that there's some bytes before the terminator that look like a string.
UTF8 utf(p);
if (utf.end())
return false;
char verify[4];
while (!utf.end()) {
if (utf.invalid())
return false;
int pos = utf.byteIndex();
uint32_t c = utf.next();
int len = UTF8::encode(verify, c);
// Our decoder is a bit lax, so let's verify this is a normal encoding.
// This prevents us from trying to output invalid encodings in the debugger.
if (memcmp(p + pos, verify, len) != 0 || pos + len != utf.byteIndex())
return false;
if (c < ARRAY_SIZE(validControl) && !validControl[c])
return false;
if (c > 0x0010FFFF)
return false;
}
return true;
}
static HashType computeHash(u32 address, u32 size)
{
if (!Memory::IsValidAddress(address))
return 0;
size = Memory::ValidSize(address, size);
#if PPSSPP_ARCH(AMD64)
return XXH3_64bits(Memory::GetPointerUnchecked(address), size);
#else
return XXH3_64bits(Memory::GetPointerUnchecked(address), size) & 0xFFFFFFFF;
#endif
}
static void parseDisasm(const char *disasm, char *opcode, size_t opcodeSize, char *arguments, size_t argumentsSize, bool insertSymbols) {
// copy opcode
size_t opcodePos = 0;
while (*disasm != 0 && *disasm != '\t' && opcodePos + 1 < opcodeSize) {
opcode[opcodePos++] = *disasm++;
}
opcode[opcodePos] = 0;
// Otherwise it's a tab, and we skip intentionally.
if (*disasm++ == 0) {
*arguments = 0;
return;
}
const char* jumpAddress = strstr(disasm,"->$");
const char* jumpRegister = strstr(disasm,"->");
size_t argumentsPos = 0;
while (*disasm != 0 && argumentsPos + 1 < argumentsSize) {
// parse symbol
if (disasm == jumpAddress) {
u32 branchTarget = 0;
sscanf(disasm+3, "%08x", &branchTarget);
const std::string addressSymbol = g_symbolMap->GetLabelString(branchTarget);
if (!addressSymbol.empty() && insertSymbols) {
argumentsPos += snprintf(&arguments[argumentsPos], argumentsSize - argumentsPos, "%s", addressSymbol.c_str());
} else {
argumentsPos += snprintf(&arguments[argumentsPos], argumentsSize - argumentsPos, "0x%08X", branchTarget);
}
disasm += 3+8;
continue;
}
if (disasm == jumpRegister)
disasm += 2;
if (*disasm == ' ') {
disasm++;
continue;
}
arguments[argumentsPos++] = *disasm++;
}
arguments[argumentsPos] = 0;
}
std::map<u32,DisassemblyEntry*>::iterator findDisassemblyEntry(std::map<u32,DisassemblyEntry*>& entries, u32 address, bool exact)
{
if (exact)
return entries.find(address);
if (entries.size() == 0)
return entries.end();
// find first elem that's >= address
auto it = entries.lower_bound(address);
if (it != entries.end())
{
// it may be an exact match
if (isInInterval(it->second->getLineAddress(0),it->second->getTotalSize(),address))
return it;
// otherwise it may point to the next
if (it != entries.begin())
{
it--;
if (isInInterval(it->second->getLineAddress(0),it->second->getTotalSize(),address))
return it;
}
}
// check last entry manually
auto rit = entries.rbegin();
if (isInInterval(rit->second->getLineAddress(0),rit->second->getTotalSize(),address))
{
return (++rit).base();
}
// no match otherwise
return entries.end();
}
void DisassemblyManager::analyze(u32 address, u32 size = 1024)
{
u32 end = address+size;
address &= ~3;
u32 start = address;
while (address < end && start <= address)
{
if (!PSP_IsInited())
return;
auto memLock = Memory::Lock();
std::lock_guard<std::recursive_mutex> guard(entriesLock_);
auto it = findDisassemblyEntry(entries, address, false);
if (it != entries.end())
{
DisassemblyEntry* entry = it->second;
entry->recheck();
address = entry->getLineAddress(0)+entry->getTotalSize();
continue;
}
SymbolInfo info;
if (!g_symbolMap->GetSymbolInfo(&info,address,ST_ALL))
{
if (address % 4)
{
u32 next = std::min<u32>((address+3) & ~3,g_symbolMap->GetNextSymbolAddress(address,ST_ALL));
DisassemblyData* data = new DisassemblyData(address,next-address,DATATYPE_BYTE);
entries[address] = data;
address = next;
continue;
}
u32 next = g_symbolMap->GetNextSymbolAddress(address,ST_ALL);
if ((next % 4) && next != (u32)-1)
{
u32 alignedNext = next & ~3;
if (alignedNext != address)
{
DisassemblyOpcode* opcode = new DisassemblyOpcode(address,(alignedNext-address)/4);
entries[address] = opcode;
}
DisassemblyData* data = new DisassemblyData(address,next-alignedNext,DATATYPE_BYTE);
entries[alignedNext] = data;
} else {
DisassemblyOpcode* opcode = new DisassemblyOpcode(address,(next-address)/4);
entries[address] = opcode;
}
address = next;
continue;
}
switch (info.type)
{
case ST_FUNCTION:
{
DisassemblyFunction* function = new DisassemblyFunction(info.address,info.size);
entries[info.address] = function;
address = info.address+info.size;
}
break;
case ST_DATA:
{
DisassemblyData* data = new DisassemblyData(info.address,info.size,g_symbolMap->GetDataType(info.address));
entries[info.address] = data;
address = info.address+info.size;
}
break;
default:
break;
}
}
}
std::vector<BranchLine> DisassemblyManager::getBranchLines(u32 start, u32 size)
{
std::vector<BranchLine> result;
std::lock_guard<std::recursive_mutex> guard(entriesLock_);
auto it = findDisassemblyEntry(entries,start,false);
if (it != entries.end())
{
do
{
it->second->getBranchLines(start,size,result);
it++;
} while (it != entries.end() && start+size > it->second->getLineAddress(0));
}
return result;
}
void DisassemblyManager::getLine(u32 address, bool insertSymbols, DisassemblyLineInfo &dest, DebugInterface *cpuDebug)
{
// This is here really to avoid lock ordering issues.
auto memLock = Memory::Lock();
std::lock_guard<std::recursive_mutex> guard(entriesLock_);
auto it = findDisassemblyEntry(entries,address,false);
if (it == entries.end())
{
analyze(address);
it = findDisassemblyEntry(entries,address,false);
}
if (it != entries.end()) {
DisassemblyEntry *entry = it->second;
if (entry->disassemble(address, dest, insertSymbols, cpuDebug))
return;
}
dest.type = DISTYPE_OTHER;
memset(&dest.info, 0, sizeof(dest.info));
dest.info.opcodeAddress = address;
if (address % 4)
dest.totalSize = ((address+3) & ~3)-address;
else
dest.totalSize = 4;
if (Memory::IsValidRange(address, 4)) {
dest.name = "ERROR";
dest.params = "Disassembly failure";
} else {
dest.name = "-";
dest.params.clear();
}
}
u32 DisassemblyManager::getStartAddress(u32 address)
{
auto memLock = Memory::Lock();
std::lock_guard<std::recursive_mutex> guard(entriesLock_);
auto it = findDisassemblyEntry(entries,address,false);
if (it == entries.end())
{
analyze(address);
it = findDisassemblyEntry(entries,address,false);
if (it == entries.end())
return address;
}
DisassemblyEntry* entry = it->second;
int line = entry->getLineNum(address,true);
return entry->getLineAddress(line);
}
u32 DisassemblyManager::getNthPreviousAddress(u32 address, int n)
{
auto memLock = Memory::Lock();
std::lock_guard<std::recursive_mutex> guard(entriesLock_);
while (Memory::IsValidAddress(address))
{
auto it = findDisassemblyEntry(entries,address,false);
if (it == entries.end())
break;
while (it != entries.end())
{
DisassemblyEntry* entry = it->second;
int oldLineNum = entry->getLineNum(address,true);
if (n <= oldLineNum)
{
return entry->getLineAddress(oldLineNum-n);
}
address = entry->getLineAddress(0)-1;
n -= oldLineNum+1;
it = findDisassemblyEntry(entries,address,false);
}
analyze(address-127,128);
}
return (address - n * 4) & ~3;
}
u32 DisassemblyManager::getNthNextAddress(u32 address, int n)
{
auto memLock = Memory::Lock();
std::lock_guard<std::recursive_mutex> guard(entriesLock_);
while (Memory::IsValidAddress(address))
{
auto it = findDisassemblyEntry(entries,address,false);
if (it == entries.end()) {
break;
}
while (it != entries.end())
{
DisassemblyEntry* entry = it->second;
int oldLineNum = entry->getLineNum(address,true);
int oldNumLines = entry->getNumLines();
if (oldLineNum+n < oldNumLines)
{
return entry->getLineAddress(oldLineNum+n);
}
address = entry->getLineAddress(0)+entry->getTotalSize();
n -= (oldNumLines-oldLineNum);
it = findDisassemblyEntry(entries,address,false);
}
analyze(address);
}
return (address + n * 4) & ~3;
}
DisassemblyManager::~DisassemblyManager() {
}
void DisassemblyManager::clear()
{
auto memLock = Memory::Lock();
std::lock_guard<std::recursive_mutex> guard(entriesLock_);
for (auto it = entries.begin(); it != entries.end(); it++)
{
delete it->second;
}
entries.clear();
}
DisassemblyFunction::DisassemblyFunction(u32 _address, u32 _size): address(_address), size(_size)
{
auto memLock = Memory::Lock();
if (!PSP_IsInited())
return;
hash = computeHash(address,size);
load();
}
DisassemblyFunction::~DisassemblyFunction() {
clear();
}
void DisassemblyFunction::recheck()
{
auto memLock = Memory::Lock();
if (!PSP_IsInited())
return;
HashType newHash = computeHash(address,size);
if (hash != newHash)
{
hash = newHash;
clear();
load();
}
}
int DisassemblyFunction::getNumLines()
{
std::lock_guard<std::recursive_mutex> guard(lock_);
return (int) lineAddresses.size();
}
int DisassemblyFunction::getLineNum(u32 address, bool findStart)
{
std::lock_guard<std::recursive_mutex> guard(lock_);
if (findStart)
{
int last = (int)lineAddresses.size() - 1;
for (int i = 0; i < last; i++)
{
u32 next = lineAddresses[i + 1];
if (lineAddresses[i] <= address && next > address)
return i;
}
if (lineAddresses[last] <= address && this->address + this->size > address)
return last;
}
else
{
int last = (int)lineAddresses.size() - 1;
for (int i = 0; i < last; i++)
{
if (lineAddresses[i] == address)
return i;
}
if (lineAddresses[last] == address)
return last;
}
return 0;
}
u32 DisassemblyFunction::getLineAddress(int line)
{
std::lock_guard<std::recursive_mutex> guard(lock_);
return lineAddresses[line];
}
bool DisassemblyFunction::disassemble(u32 address, DisassemblyLineInfo &dest, bool insertSymbols, DebugInterface *cpuDebug)
{
std::lock_guard<std::recursive_mutex> guard(lock_);
auto it = findDisassemblyEntry(entries,address,false);
if (it == entries.end())
return false;
return it->second->disassemble(address, dest, insertSymbols, cpuDebug);
}
void DisassemblyFunction::getBranchLines(u32 start, u32 size, std::vector<BranchLine>& dest)
{
u32 end = start+size;
std::lock_guard<std::recursive_mutex> guard(lock_);
for (size_t i = 0; i < lines.size(); i++)
{
BranchLine& line = lines[i];
u32 first = line.first;
u32 second = line.second;
// skip branches that are entirely before or entirely after the window
if ((first < start && second < start) ||
(first > end && second > end))
continue;
dest.push_back(line);
}
}
#define NUM_LANES 16
void DisassemblyFunction::generateBranchLines()
{
struct LaneInfo
{
bool used;
u32 end;
};
LaneInfo lanes[NUM_LANES];
for (int i = 0; i < NUM_LANES; i++)
lanes[i].used = false;
u32 end = address+size;
std::lock_guard<std::recursive_mutex> guard(lock_);
DebugInterface* cpu = DisassemblyManager::getCpu();
for (u32 funcPos = address; funcPos < end; funcPos += 4)
{
MIPSAnalyst::MipsOpcodeInfo opInfo = MIPSAnalyst::GetOpcodeInfo(cpu,funcPos);
bool inFunction = (opInfo.branchTarget >= address && opInfo.branchTarget < end);
if (opInfo.isBranch && !opInfo.isBranchToRegister && !opInfo.isLinkedBranch && inFunction) {
if (!Memory::IsValidAddress(opInfo.branchTarget))
continue;
BranchLine line;
if (opInfo.branchTarget < funcPos) {
line.first = opInfo.branchTarget;
line.second = funcPos;
line.type = LINE_UP;
} else {
line.first = funcPos;
line.second = opInfo.branchTarget;
line.type = LINE_DOWN;
}
lines.push_back(line);
}
}
std::sort(lines.begin(),lines.end());
for (size_t i = 0; i < lines.size(); i++)
{
for (int l = 0; l < NUM_LANES; l++)
{
if (lines[i].first > lanes[l].end)
lanes[l].used = false;
}
int lane = -1;
for (int l = 0; l < NUM_LANES; l++)
{
if (lanes[l].used == false)
{
lane = l;
break;
}
}
if (lane == -1)
{
// Let's just pile on.
lines[i].laneIndex = 15;
continue;
}
lanes[lane].end = lines[i].second;
lanes[lane].used = true;
lines[i].laneIndex = lane;
}
}
void DisassemblyFunction::addOpcodeSequence(u32 start, u32 end)
{
DisassemblyOpcode* opcode = new DisassemblyOpcode(start,(end-start)/4);
std::lock_guard<std::recursive_mutex> guard(lock_);
entries[start] = opcode;
for (u32 pos = start; pos < end; pos += 4)
{
lineAddresses.push_back(pos);
}
}
void DisassemblyFunction::load()
{
generateBranchLines();
// gather all branch targets
std::set<u32> branchTargets;
{
std::lock_guard<std::recursive_mutex> guard(lock_);
for (size_t i = 0; i < lines.size(); i++)
{
switch (lines[i].type)
{
case LINE_DOWN:
branchTargets.insert(lines[i].second);
break;
case LINE_UP:
branchTargets.insert(lines[i].first);
break;
default:
break;
}
}
}
DebugInterface* cpu = DisassemblyManager::getCpu();
u32 funcPos = address;
u32 funcEnd = address+size;
u32 nextData = g_symbolMap->GetNextSymbolAddress(funcPos-1,ST_DATA);
u32 opcodeSequenceStart = funcPos;
while (funcPos < funcEnd)
{
if (funcPos == nextData)
{
if (opcodeSequenceStart != funcPos)
addOpcodeSequence(opcodeSequenceStart,funcPos);
DisassemblyData* data = new DisassemblyData(funcPos,g_symbolMap->GetDataSize(funcPos),g_symbolMap->GetDataType(funcPos));
std::lock_guard<std::recursive_mutex> guard(lock_);
entries[funcPos] = data;
lineAddresses.push_back(funcPos);
funcPos += data->getTotalSize();
nextData = g_symbolMap->GetNextSymbolAddress(funcPos-1,ST_DATA);
opcodeSequenceStart = funcPos;
continue;
}
// force align
if (funcPos % 4)
{
u32 nextPos = (funcPos+3) & ~3;
DisassemblyComment* comment = new DisassemblyComment(funcPos,nextPos-funcPos,".align","4");
std::lock_guard<std::recursive_mutex> guard(lock_);
entries[funcPos] = comment;
lineAddresses.push_back(funcPos);
funcPos = nextPos;
opcodeSequenceStart = funcPos;
continue;
}
MIPSAnalyst::MipsOpcodeInfo opInfo = MIPSAnalyst::GetOpcodeInfo(cpu,funcPos);
u32 opAddress = funcPos;
funcPos += 4;
// skip branches and their delay slots
if (opInfo.isBranch)
{
funcPos += 4;
continue;
}
// lui
if (MIPS_GET_OP(opInfo.encodedOpcode) == 0x0F && funcPos < funcEnd && funcPos != nextData)
{
MIPSOpcode next = Memory::Read_Instruction(funcPos);
MIPSInfo nextInfo = MIPSGetInfo(next);
u32 immediate = ((opInfo.encodedOpcode & 0xFFFF) << 16) + (s16)(next.encoding & 0xFFFF);
int rt = MIPS_GET_RT(opInfo.encodedOpcode);
int nextRs = MIPS_GET_RS(next.encoding);
int nextRt = MIPS_GET_RT(next.encoding);
// both rs and rt of the second op have to match rt of the first,
// otherwise there may be hidden consequences if the macro is displayed.
// also, don't create a macro if something branches into the middle of it
if (nextRs == rt && nextRt == rt && branchTargets.find(funcPos) == branchTargets.end())
{
DisassemblyMacro* macro = NULL;
switch (MIPS_GET_OP(next.encoding))
{
case 0x09: // addiu
macro = new DisassemblyMacro(opAddress);
macro->setMacroLi(immediate,rt);
funcPos += 4;
break;
case 0x20: // lb
case 0x21: // lh
case 0x23: // lw
case 0x24: // lbu
case 0x25: // lhu
case 0x28: // sb
case 0x29: // sh
case 0x2B: // sw
macro = new DisassemblyMacro(opAddress);
int dataSize = MIPSGetMemoryAccessSize(next);
if (dataSize == 0) {
delete macro;
return;
}
macro->setMacroMemory(MIPSGetName(next),immediate,rt,dataSize);
funcPos += 4;
break;
}
if (macro != NULL)
{
if (opcodeSequenceStart != opAddress)
addOpcodeSequence(opcodeSequenceStart,opAddress);
std::lock_guard<std::recursive_mutex> guard(lock_);
entries[opAddress] = macro;
for (int i = 0; i < macro->getNumLines(); i++)
{
lineAddresses.push_back(macro->getLineAddress(i));
}
opcodeSequenceStart = funcPos;
continue;
}
}
}
// just a normal opcode
}
if (opcodeSequenceStart != funcPos)
addOpcodeSequence(opcodeSequenceStart,funcPos);
}
void DisassemblyFunction::clear()
{
std::lock_guard<std::recursive_mutex> guard(lock_);
for (auto it = entries.begin(); it != entries.end(); it++)
{
delete it->second;
}
entries.clear();
lines.clear();
lineAddresses.clear();
hash = 0;
}
bool DisassemblyOpcode::disassemble(u32 address, DisassemblyLineInfo &dest, bool insertSymbols, DebugInterface *cpuDebug)
{
if (!cpuDebug)
cpuDebug = DisassemblyManager::getCpu();
char opcode[64],arguments[256];
char dizz[512];
cpuDebug->DisAsm(address, dizz, sizeof(dizz));
parseDisasm(dizz, opcode, sizeof(opcode), arguments, sizeof(arguments), insertSymbols);
dest.type = DISTYPE_OPCODE;
dest.name = opcode;
dest.params = arguments;
dest.totalSize = 4;
dest.info = MIPSAnalyst::GetOpcodeInfo(cpuDebug, address);
return true;
}
void DisassemblyOpcode::getBranchLines(u32 start, u32 size, std::vector<BranchLine>& dest)
{
if (start < address)
{
size = start+size-address;
start = address;
}
if (start+size > address+num*4)
size = address+num*4-start;
int lane = 0;
for (u32 pos = start; pos < start+size; pos += 4)
{
MIPSAnalyst::MipsOpcodeInfo info = MIPSAnalyst::GetOpcodeInfo(DisassemblyManager::getCpu(),pos);
if (info.isBranch && !info.isBranchToRegister && !info.isLinkedBranch) {
if (!Memory::IsValidAddress(info.branchTarget))
continue;
BranchLine line;
line.laneIndex = lane++;
if (info.branchTarget < pos) {
line.first = info.branchTarget;
line.second = pos;
line.type = LINE_UP;
} else {
line.first = pos;
line.second = info.branchTarget;
line.type = LINE_DOWN;
}
dest.push_back(line);
}
}
}
void DisassemblyMacro::setMacroLi(u32 _immediate, u8 _rt)
{
type = MACRO_LI;
name = "li";
immediate = _immediate;
rt = _rt;
numOpcodes = 2;
}
void DisassemblyMacro::setMacroMemory(std::string _name, u32 _immediate, u8 _rt, int _dataSize)
{
type = MACRO_MEMORYIMM;
name = _name;
immediate = _immediate;
rt = _rt;
dataSize = _dataSize;
numOpcodes = 2;
}
bool DisassemblyMacro::disassemble(u32 address, DisassemblyLineInfo &dest, bool insertSymbols, DebugInterface *cpuDebug)
{
if (!cpuDebug)
cpuDebug = DisassemblyManager::getCpu();
char buffer[64];
dest.type = DISTYPE_MACRO;
dest.info = MIPSAnalyst::GetOpcodeInfo(cpuDebug, address);
std::string addressSymbol;
switch (type)
{
case MACRO_LI:
dest.name = name;
addressSymbol = g_symbolMap->GetLabelString(immediate);
if (!addressSymbol.empty() && insertSymbols) {
snprintf(buffer, sizeof(buffer), "%s,%s", cpuDebug->GetRegName(0, rt).c_str(), addressSymbol.c_str());
} else {
snprintf(buffer, sizeof(buffer), "%s,0x%08X", cpuDebug->GetRegName(0, rt).c_str(), immediate);
}
dest.params = buffer;
dest.info.hasRelevantAddress = true;
dest.info.relevantAddress = immediate;
break;
case MACRO_MEMORYIMM:
dest.name = name;
addressSymbol = g_symbolMap->GetLabelString(immediate);
if (!addressSymbol.empty() && insertSymbols) {
snprintf(buffer, sizeof(buffer), "%s,%s", cpuDebug->GetRegName(0, rt).c_str(), addressSymbol.c_str());
} else {
snprintf(buffer, sizeof(buffer), "%s,0x%08X", cpuDebug->GetRegName(0, rt).c_str(), immediate);
}
dest.params = buffer;
dest.info.isDataAccess = true;
dest.info.dataAddress = immediate;
dest.info.dataSize = dataSize;
dest.info.hasRelevantAddress = true;
dest.info.relevantAddress = immediate;
break;
default:
return false;
}
dest.totalSize = getTotalSize();
return true;
}
DisassemblyData::DisassemblyData(u32 _address, u32 _size, DataType _type): address(_address), size(_size), type(_type)
{
auto memLock = Memory::Lock();
if (!PSP_IsInited())
return;
hash = computeHash(address,size);
createLines();
}
void DisassemblyData::recheck()
{
auto memLock = Memory::Lock();
if (!PSP_IsInited())
return;
HashType newHash = computeHash(address,size);
if (newHash != hash)
{
hash = newHash;
createLines();
}
}
bool DisassemblyData::disassemble(u32 address, DisassemblyLineInfo &dest, bool insertSymbols, DebugInterface *cpuDebug)
{
dest.type = DISTYPE_DATA;
switch (type)
{
case DATATYPE_BYTE:
dest.name = ".byte";
break;
case DATATYPE_HALFWORD:
dest.name = ".half";
break;
case DATATYPE_WORD:
dest.name = ".word";
break;
case DATATYPE_ASCII:
dest.name = ".ascii";
break;
default:
return false;
}
std::lock_guard<std::recursive_mutex> guard(lock_);
auto it = lines.find(address);
if (it == lines.end())
return false;
dest.params = it->second.text;
dest.totalSize = it->second.size;
return true;
}
int DisassemblyData::getLineNum(u32 address, bool findStart)
{
std::lock_guard<std::recursive_mutex> guard(lock_);
auto it = lines.upper_bound(address);
if (it != lines.end())
{
if (it == lines.begin())
return 0;
it--;
return it->second.lineNum;
}
return lines.rbegin()->second.lineNum;
}
void DisassemblyData::createLines()
{
std::lock_guard<std::recursive_mutex> guard(lock_);
lines.clear();
lineAddresses.clear();
u32 pos = address;
u32 end = address+size;
u32 maxChars = DisassemblyManager::getMaxParamChars();
std::string currentLine;
u32 currentLineStart = pos;
int lineCount = 0;
if (type == DATATYPE_ASCII)
{
bool inString = false;
while (pos < end)
{
u8 b = Memory::Read_U8(pos++);
if (b >= 0x20 && b <= 0x7F)
{
if (currentLine.size()+1 >= maxChars)
{
if (inString == true)
currentLine += "\"";
DataEntry entry = {currentLine,pos-1-currentLineStart,lineCount++};
lines[currentLineStart] = entry;
lineAddresses.push_back(currentLineStart);
currentLine.clear();
currentLineStart = pos-1;
inString = false;
}
if (inString == false)
currentLine += "\"";
currentLine += (char)b;
inString = true;
} else {
char buffer[64];
if (pos == end && b == 0)
truncate_cpy(buffer, "0");
else
snprintf(buffer, sizeof(buffer), "0x%02X", b);
if (currentLine.size()+strlen(buffer) >= maxChars)
{
if (inString == true)
currentLine += "\"";
DataEntry entry = {currentLine,pos-1-currentLineStart,lineCount++};
lines[currentLineStart] = entry;
lineAddresses.push_back(currentLineStart);
currentLine.clear();
currentLineStart = pos-1;
inString = false;
}
bool comma = false;
if (currentLine.size() != 0)
comma = true;
if (inString)
currentLine += "\"";
if (comma)
currentLine += ",";
currentLine += buffer;
inString = false;
}
}
if (inString == true)
currentLine += "\"";
if (currentLine.size() != 0)
{
DataEntry entry = {currentLine,pos-currentLineStart,lineCount++};
lines[currentLineStart] = entry;
lineAddresses.push_back(currentLineStart);
}
} else {
while (pos < end)
{
char buffer[256];
u32 value;
u32 currentPos = pos;
switch (type)
{
case DATATYPE_BYTE:
value = Memory::Read_U8(pos);
snprintf(buffer, sizeof(buffer), "0x%02X", value);
pos++;
break;
case DATATYPE_HALFWORD:
value = Memory::Read_U16(pos);
snprintf(buffer, sizeof(buffer), "0x%04X", value);
pos += 2;
break;
case DATATYPE_WORD:
{
value = Memory::Read_U32(pos);
const std::string label = g_symbolMap->GetLabelString(value);
if (!label.empty())
snprintf(buffer, sizeof(buffer), "%s", label.c_str());
else
snprintf(buffer, sizeof(buffer), "0x%08X", value);
pos += 4;
}
break;
default:
break;
}
size_t len = strlen(buffer);
if (currentLine.size() != 0 && currentLine.size()+len >= maxChars)
{
DataEntry entry = {currentLine,currentPos-currentLineStart,lineCount++};
lines[currentLineStart] = entry;
lineAddresses.push_back(currentLineStart);
currentLine.clear();
currentLineStart = currentPos;
}
if (currentLine.size() != 0)
currentLine += ",";
currentLine += buffer;
}
if (currentLine.size() != 0) {
DataEntry entry = {currentLine,pos-currentLineStart,lineCount++};
lines[currentLineStart] = entry;
lineAddresses.push_back(currentLineStart);
}
}
}
DisassemblyComment::DisassemblyComment(u32 _address, u32 _size, std::string _name, std::string _param)
: address(_address), size(_size), name(_name), param(_param)
{
}
bool DisassemblyComment::disassemble(u32 address, DisassemblyLineInfo &dest, bool insertSymbols, DebugInterface *cpuDebug)
{
dest.type = DISTYPE_OTHER;
dest.name = name;
dest.params = param;
dest.totalSize = size;
return true;
}