citra/src/common/break_points.cpp
archshift ef24e72b26 Asserts: break/crash program, fit to style guide; log.h->assert.h
Involves making asserts use printf instead of the log functions (log functions are asynchronous and, as such, the log won't be printed in time)
As such, the log type argument was removed (printf obviously can't use it, and it's made obsolete by the file and line printing)

Also removed some GEKKO cruft.
2015-02-10 18:30:31 -08:00

193 lines
5.3 KiB
C++

// Copyright 2013 Dolphin Emulator Project / 2014 Citra Emulator Project
// Licensed under GPLv2 or any later version
// Refer to the license.txt file included.
#include "common/common.h"
#include "common/debug_interface.h"
#include "common/break_points.h"
#include "common/logging/log.h"
#include <sstream>
#include <algorithm>
bool BreakPoints::IsAddressBreakPoint(u32 iAddress)
{
auto cond = [&iAddress](const TBreakPoint& bp) { return bp.iAddress == iAddress; };
auto it = std::find_if(m_BreakPoints.begin(), m_BreakPoints.end(), cond);
return it != m_BreakPoints.end();
}
bool BreakPoints::IsTempBreakPoint(u32 iAddress)
{
auto cond = [&iAddress](const TBreakPoint& bp) { return bp.iAddress == iAddress && bp.bTemporary; };
auto it = std::find_if(m_BreakPoints.begin(), m_BreakPoints.end(), cond);
return it != m_BreakPoints.end();
}
BreakPoints::TBreakPointsStr BreakPoints::GetStrings() const
{
TBreakPointsStr bps;
for (auto breakpoint : m_BreakPoints)
{
if (!breakpoint.bTemporary)
{
std::stringstream bp;
bp << std::hex << breakpoint.iAddress << " " << (breakpoint.bOn ? "n" : "");
bps.push_back(bp.str());
}
}
return bps;
}
void BreakPoints::AddFromStrings(const TBreakPointsStr& bps)
{
for (auto bps_item : bps)
{
TBreakPoint bp;
std::stringstream bpstr;
bpstr << std::hex << bps_item;
bpstr >> bp.iAddress;
bp.bOn = bps_item.find("n") != bps_item.npos;
bp.bTemporary = false;
Add(bp);
}
}
void BreakPoints::Add(const TBreakPoint& bp)
{
if (!IsAddressBreakPoint(bp.iAddress))
{
m_BreakPoints.push_back(bp);
//if (jit)
// jit->GetBlockCache()->InvalidateICache(bp.iAddress, 4);
}
}
void BreakPoints::Add(u32 em_address, bool temp)
{
if (!IsAddressBreakPoint(em_address)) // only add new addresses
{
TBreakPoint pt; // breakpoint settings
pt.bOn = true;
pt.bTemporary = temp;
pt.iAddress = em_address;
m_BreakPoints.push_back(pt);
//if (jit)
// jit->GetBlockCache()->InvalidateICache(em_address, 4);
}
}
void BreakPoints::Remove(u32 em_address)
{
auto cond = [&em_address](const TBreakPoint& bp) { return bp.iAddress == em_address; };
auto it = std::find_if(m_BreakPoints.begin(), m_BreakPoints.end(), cond);
if (it != m_BreakPoints.end())
m_BreakPoints.erase(it);
}
void BreakPoints::Clear()
{
//if (jit)
//{
// std::for_each(m_BreakPoints.begin(), m_BreakPoints.end(),
// [](const TBreakPoint& bp)
// {
// jit->GetBlockCache()->InvalidateICache(bp.iAddress, 4);
// }
// );
//}
m_BreakPoints.clear();
}
MemChecks::TMemChecksStr MemChecks::GetStrings() const
{
TMemChecksStr mcs;
for (auto memcheck : m_MemChecks)
{
std::stringstream mc;
mc << std::hex << memcheck.StartAddress;
mc << " " << (memcheck.bRange ? memcheck.EndAddress : memcheck.StartAddress) << " "
<< (memcheck.bRange ? "n" : "")
<< (memcheck.OnRead ? "r" : "")
<< (memcheck.OnWrite ? "w" : "")
<< (memcheck.Log ? "l" : "")
<< (memcheck.Break ? "p" : "");
mcs.push_back(mc.str());
}
return mcs;
}
void MemChecks::AddFromStrings(const TMemChecksStr& mcs)
{
for (auto mcs_item : mcs)
{
TMemCheck mc;
std::stringstream mcstr;
mcstr << std::hex << mcs_item;
mcstr >> mc.StartAddress;
mc.bRange = mcs_item.find("n") != mcs_item.npos;
mc.OnRead = mcs_item.find("r") != mcs_item.npos;
mc.OnWrite = mcs_item.find("w") != mcs_item.npos;
mc.Log = mcs_item.find("l") != mcs_item.npos;
mc.Break = mcs_item.find("p") != mcs_item.npos;
if (mc.bRange)
mcstr >> mc.EndAddress;
else
mc.EndAddress = mc.StartAddress;
Add(mc);
}
}
void MemChecks::Add(const TMemCheck& rMemoryCheck)
{
if (GetMemCheck(rMemoryCheck.StartAddress) == 0)
m_MemChecks.push_back(rMemoryCheck);
}
void MemChecks::Remove(u32 Address)
{
auto cond = [&Address](const TMemCheck& mc) { return mc.StartAddress == Address; };
auto it = std::find_if(m_MemChecks.begin(), m_MemChecks.end(), cond);
if (it != m_MemChecks.end())
m_MemChecks.erase(it);
}
TMemCheck *MemChecks::GetMemCheck(u32 address)
{
for (auto i = m_MemChecks.begin(); i != m_MemChecks.end(); ++i)
{
if (i->bRange)
{
if (address >= i->StartAddress && address <= i->EndAddress)
return &(*i);
}
else if (i->StartAddress == address)
return &(*i);
}
// none found
return 0;
}
void TMemCheck::Action(DebugInterface *debug_interface, u32 iValue, u32 addr,
bool write, int size, u32 pc)
{
if ((write && OnWrite) || (!write && OnRead))
{
if (Log)
{
LOG_DEBUG(Debug_Breakpoint, "CHK %08x (%s) %s%i %0*x at %08x (%s)",
pc, debug_interface->getDescription(pc).c_str(),
write ? "Write" : "Read", size*8, size*2, iValue, addr,
debug_interface->getDescription(addr).c_str()
);
}
if (Break)
debug_interface->breakNow();
}
}