Supermodel/Src/Debugger/ConsoleDebugger.cpp

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/**
** Supermodel
** A Sega Model 3 Arcade Emulator.
** Copyright 2011 Bart Trzynadlowski, Nik Henson
**
** This file is part of Supermodel.
**
** Supermodel 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, either version 3 of the License, or (at your option)
** any later version.
**
** Supermodel 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 for
** more details.
**
** You should have received a copy of the GNU General Public License along
** with Supermodel. If not, see <http://www.gnu.org/licenses/>.
**/
/*
* ConsoleDebugger.cpp
*/
#ifdef SUPERMODEL_DEBUGGER
#include "ConsoleDebugger.h"
#include "CPUDebug.h"
#include "CodeAnalyser.h"
#include "Label.h"
#include <cctype>
#include <string>
using namespace std;
namespace Debugger
{
CConsoleDebugger::CConsoleDebugger() : CDebugger(),
m_nextFrame(false), m_listDism(0), m_listMem(0), m_analyseCode(true),
m_addrFmt(HexDollar), m_portFmt(Decimal), m_dataFmt(HexDollar),
m_showLabels(true), m_labelsOverAddr(true), m_showOpCodes(false), m_memBytesPerRow(16), m_file(NULL)
{
//
}
// TODO - tidy up this function, ie do some proper parsing of commands - it is a mess!
void CConsoleDebugger::WaitCommand(CCPUDebug *cpu)
{
m_cpu = cpu;
UINT32 pc = m_cpu->pc;
m_listDism = (m_cpu->instrCount > 0 && pc > 10 * m_cpu->minInstrLen ? pc - 10 * m_cpu->minInstrLen : 0);
char bpChr;
char addrStr[20];
char labelStr[13];
char opCodes[50];
int codesLen;
char mnemonic[255];
char operands[255];
char cmd[255];
for (;;)
{
// Get code analyser and if available analyse code now if required
if (m_analyseCode)
{
CCodeAnalyser *analyser = m_cpu->GetCodeAnalyser();
if (analyser->NeedsAnalysis())
{
Print("Analysing %s...\n", m_cpu->name);
analyser->AnalyseCode();
}
}
// Close redirected output file, if exists
if (m_file != NULL)
{
fclose(m_file);
m_file = NULL;
}
// Get details for current PC address
bool hasLabel;
if (m_cpu->instrCount > 0)
{
m_cpu->FormatAddress(addrStr, pc);
hasLabel = GetLabelText(labelStr, 12, pc);
codesLen = m_cpu->Disassemble(pc, mnemonic, operands);
FormatOpCodes(opCodes, pc, abs(codesLen));
}
else
{
addrStr[0] = '-';
addrStr[1] = '\0';
hasLabel = false;
labelStr[0] = '\0';
opCodes[0] = '-';
opCodes[1] = '\0';
codesLen = 0;
}
CBreakpoint *bp = m_cpu->GetBreakpoint(pc);
bpChr = (bp != NULL ? bp->symbol : ' ');
// Output command prompt
Print("%s%c", m_cpu->name, bpChr);
if (m_showLabels)
{
if (m_labelsOverAddr)
Print("%-12s ", (hasLabel ? labelStr : addrStr));
else
Print("%s %-12s ", addrStr, labelStr);
}
else
Print("%s ", addrStr);
if (m_showOpCodes)
Print("[%s] ", opCodes);
if (codesLen > 0)
Print("%-*s %s > ", (int)m_cpu->maxMnemLen, mnemonic, operands);
else
Print("??? > ");
Flush();
// Wait for command
Read(cmd, 255);
if (cmd[0] == '\0')
{
m_cpu->SetStepMode(StepInto);
break;
}
// Check for redirection
char *pos = strchr(cmd, '>');
if (pos != NULL)
{
*pos = '\0';
pos++;
const char *mode;
if (*pos == '>')
{
mode = "ab";
pos++;
}
else
mode = "w";
while (*pos == ' ')
pos++;
if (*pos != '\0')
{
m_file = fopen(pos, mode);
if (m_file == NULL)
{
Error("Unable to direct output to file %s\n", pos);
continue;
}
}
else
{
Error("Missing file to direct output to\n");
continue;
}
}
char *token = strtok(cmd, " ");
if (ProcessToken(token, cmd))
break;
pc = m_cpu->pc;
}
}
bool CConsoleDebugger::ProcessToken(const char *token, const char *cmd)
{
UINT32 pc = m_cpu->pc;
int number;
unsigned size;
const char *sizeStr;
UINT32 addr;
UINT16 portNum;
UINT64 data;
char addrStr[50];
char portNumStr[50];
char dataStr[50];
char mod[10];
EFormat fmt;
//
// Execution
//
if (CheckToken(token, "n", "next")) // next [<count>=1]
{
// Parse arguments
token = strtok(NULL, " ");
if (token != NULL)
{
if (!ParseInt(token, &number) || number <= 0)
{
Error("Enter a valid instruction count.\n");
return false;
}
if (number > 1)
Print("Running %d instructions.\n", number);
m_cpu->SetCount(number);
}
else
m_cpu->SetStepMode(StepInto);
return true;
}
else if (CheckToken(token, "nf", "nextframe")) // nextframe [<count>=1]
{
// Parse arguments
token = strtok(NULL, " ");
if (token != NULL)
{
if (!ParseInt(token, &number) || number <= 0)
{
Error("Enter a valid frame count.\n");
return false;
}
if (number > 1)
Print("Running %d frames.\n", number);
m_nextFrameCount = number;
}
else
m_nextFrameCount = 1;
m_nextFrame = true;
return true;
}
else if (CheckToken(token, "s", "stepover")) // stepover
{
m_cpu->SetStepMode(StepOver);
return true;
}
else if (CheckToken(token, "si", "stepinto")) // stepinto
{
m_cpu->SetStepMode(StepInto);
return true;
}
else if (CheckToken(token, "so", "stepout")) // stepout
{
m_cpu->SetStepMode(StepOut);
return true;
}
else if (CheckToken(token, "c", "continue")) // continue [<addr>]
{
// Parse arguments
token = strtok(NULL, " ");
if (token != NULL)
{
if (!ParseAddress(token, &addr))
{
Error("Enter a valid address.\n");
return false;
}
m_cpu->FormatAddress(addrStr, addr);
Print("Continuing until %s.\n", addrStr);
m_cpu->SetUntil(addr);
}
else
m_cpu->SetContinue();
return true;
}
else if (CheckToken(token, "spc", "setpc")) // setpc <addr>
{
// Parse arguments
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing address.\n");
return false;
}
if (!ParseAddress(token, &addr))
{
Error("Enter a valid address.\n");
return false;
}
if (!m_cpu->SetPC(addr))
{
Error("Unable to set PC.\n");
return false;
}
m_cpu->FormatAddress(addrStr, addr);
Print("PC set to %s.\n", addrStr);
return true;
}
//
// CPUs
//
else if (CheckToken(token, "lc", "listcpus")) // listcpus
{
ListCPUs();
}
else if (CheckToken(token, "sc", "switchcpu")) // switchcpu (<name>|<num>)
{
// Parse arguments
token = strtok(NULL, " ");
CCPUDebug *cpu;
if (!ParseCPU(token, cpu))
return false;
if (!cpu->IsEnabled())
{
Error("CPU %s is currently disabled for debugging.\n", cpu->name);
return false;
}
m_cpu = cpu;
pc = cpu->pc;
m_listDism = (cpu->instrCount > 0 && pc > 10 * cpu->minInstrLen ? pc - 10 * cpu->minInstrLen : 0);
return false;
}
else if (CheckToken(token, "dc", "disablecpu")) // disablecpu (<name>|<num>)
{
// Parse arguments
token = strtok(NULL, " ");
CCPUDebug *cpu;
if (!ParseCPU(token, cpu))
return false;
if (cpu == m_cpu)
{
Error("Cannot enable/disable debugging on current CPU.\n");
return false;
}
cpu->SetEnabled(false);
Print("Disabled debugging on CPU %s.\n", cpu->name);
}
else if (CheckToken(token, "ec", "enablecpu")) // enablecpu (<name>|<num>)
{
// Parse arguments
token = strtok(NULL, " ");
CCPUDebug *cpu;
if (!ParseCPU(token, cpu))
return false;
if (cpu == m_cpu)
{
Error("Cannot enable/disable debugging on current CPU.\n");
return false;
}
cpu->SetEnabled(true);
Print("Enabled debugging on CPU %s.\n", cpu->name);
}
//
// Registers
//
else if (CheckToken(token, "lr", "listregisters")) // listregisters
{
ListRegisters();
}
else if (CheckToken(token, "pr", "printregister")) // printregister <reg>
{
// Parse arguments
token = strtok(NULL, " ");
CRegister *reg;
if (!ParseRegister(token, reg))
return false;
reg->GetValue(dataStr);
Print("Register %s = %s\n", reg->name, dataStr);
}
else if (CheckToken(token, "sr", "setregister")) // setregister <reg> <expr>
{
// Parse arguments
token = strtok(NULL, " ");
CRegister *reg;
if (!ParseRegister(token, reg))
return false;
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing value to set.\n");
return false;
}
if (!reg->SetValue(token))
{
Error("Unable to set value of register %s.\n", reg->name);
return false;
}
reg->GetValue(dataStr);
Print("Set register %s to %s.\n", reg->name, dataStr);
}
else if (CheckToken(token, "lm", "listmonitors")) // listmonitors
{
ListMonitors();
}
else if (CheckToken(token, "m", "monitor") || // addmonitor <reg>
CheckToken(token, "am", "addmonitor"))
{
// Parse arguments
token = strtok(NULL, " ");
CRegister *reg;
if (!ParseRegister(token, reg))
return false;
m_cpu->AddRegMonitor(reg->name);
Print("Monitor added to register %s.\n", reg->name);
}
else if (CheckToken(token, "rm", "removemonitor")) // removemonitor <reg>
{
// Parse arguments
token = strtok(NULL, " ");
CRegister *reg;
if (!ParseRegister(token, reg))
return false;
m_cpu->RemoveRegMonitor(reg->name);
Print("Monitor for register %s removed.\n", reg->name);
}
else if (CheckToken(token, "ram", "removeallmonitors")) // removeallmonitors
{
m_cpu->RemoveAllRegMonitors();
Print("All register monitors removed.\n");
}
//
// Exceptions & interrupts
//
else if (CheckToken(token, "le", "listexceptions")) // listexceptions
{
ListExceptions();
}
else if (CheckToken(token, "li", "listinterrupts")) // listinterrupts
{
ListInterrupts();
}
else if (CheckToken(token, "t", "trap") || // addtrap ((e)xception|(i)nterrupt) <id>
CheckToken(token, "at", "addtrap"))
{
// Parse arguments
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing type (e)xception or (i)interrupt\n");
return false;
}
if (CheckToken(token, "e", "exception"))
{
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing exception id.\n");
return false;
}
CException *ex = m_cpu->GetException(token);
if (ex == NULL)
{
Error("Enter a valid exception id.\n");
return false;
}
ex->trap = true;
Print("Trap added for exceptions of type %s.\n", ex->id);
}
else if (CheckToken(token, "i", "interrupt"))
{
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing interrupt id.\n");
return false;
}
CInterrupt *in = m_cpu->GetInterrupt(token);
if (in == NULL)
{
Error("Enter a valid interrupt id.\n");
return false;
}
in->trap = true;
Print("Trap added for interrupts of type %s.\n", in->id);
}
else
{
Error("Enter valid type (e)xception or (i)interrupt.\n");
return false;
}
}
else if (CheckToken(token, "rt", "removetrap")) // removetrap ((e)xception|(i)nterrupt) <id>
{
// Parse arguments
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing type (e)xception or (i)interrupt.\n");
return false;
}
if (CheckToken(token, "e", "exception"))
{
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing exception id.\n");
return false;
}
CException *ex = m_cpu->GetException(token);
if (ex == NULL)
{
Error("Enter a valid exception id.\n");
return false;
}
ex->trap = false;
Print("Trap for exceptions of type %s removed.\n", ex->id);
}
else if (CheckToken(token, "i", "interrupt"))
{
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing interrupt id.\n");
return false;
}
CInterrupt *in = m_cpu->GetInterrupt(token);
if (in == NULL)
{
Error("Enter a valid interrupt id.\n");
return false;
}
in->trap = false;
Print("Trap for interrupts ot type %s removed.\n", in->id);
}
else
{
Error("Enter a valid type (e)xception or (i)interrupt.\n");
return false;
}
}
else if (CheckToken(token, "rat", "removealltraps")) // removealltraps [(a)ll|(e)xceptions|(i)nterrupts]
{
bool removeExs;
bool removeInts;
const char *coverage;
if (token == NULL || CheckToken(token, "a", "all"))
{
removeExs = true;
removeInts = true;
coverage = "exceptions and interrupts";
}
else if (CheckToken(token, "e", "exceptions"))
{
removeExs = true;
removeInts = false;
coverage = "exceptions";
}
else if (CheckToken(token, "i", "interrupts"))
{
removeExs = false;
removeInts = true;
coverage = "interrupts";
}
else
{
Error("Enter a valid mode (a)ll, (e)xceptions or (i)nterrupts\n");
return false;
}
if (removeExs)
{
for (vector<CException*>::iterator it = m_cpu->exceps.begin(); it != m_cpu->exceps.end(); it++)
(*it)->trap = false;
}
if (removeInts)
{
for (vector<CInterrupt*>::iterator it = m_cpu->inters.begin(); it != m_cpu->inters.end(); it++)
(*it)->trap = false;
}
Print("All traps for %s removed.\n", coverage);
}
//
// Disassembly, labels & comments
//
else if (CheckToken(token, "l", "list") || // listdisassembly [<start>=last [#<instrs>=20|<end>]]
CheckToken(token, "ld", "listdisassembly"))
{
// Get start address
UINT32 start;
token = strtok(NULL, " ");
if (token == NULL)
token = "last";
if (stricmp(token, "last") == 0)
{
// Use end of last listing
start = m_listDism;
}
else if (!ParseAddress(token, &start))
{
Error("Enter a valid start address.\n");
return false;
}
// Get end address
UINT32 end;
unsigned numInstrs;
token = strtok(NULL, " ");
if (token != NULL)
{
if (token[0] == '#')
{
if (!ParseInt(token + 1, &number) || number <= 0)
{
Error("Enter a valid number of instructions.\n");
return false;
}
numInstrs = (unsigned)number;
end = 0xFFFFFFFF;
}
else
{
if (!ParseAddress(token, &end))
{
Error("Enter a valid end address.\n");
return false;
}
numInstrs = 0xFFFFFFFF;
}
}
else
{
// Default is 20 instructions after start
end = 0xFFFFFFFF;
numInstrs = 20;
}
// List the disassembled code
m_listDism = ListDisassembly(start, end, numInstrs);
}
else if (CheckToken(token, "ll", "listlabels")) // listlabels [(d)efault|(c)ustom|(a)utos|(e)ntrypoints|e(x)cephandlers|(i)interhandlers|(j)umptargets|(l)ooppoints]
{
// Parse arguments
token = strtok(NULL, " ");
bool customLabels;
ELabelFlags labelFlags;
if (token == NULL || CheckToken(token, "d", "default"))
{
customLabels = true;
labelFlags = (ELabelFlags)(LFEntryPoint | LFExcepHandler | LFInterHandler | LFSubroutine);
}
else if (CheckToken(token, "c", "custom"))
{
customLabels = true;
labelFlags = LFNone;
}
else if (CheckToken(token, "a", "autos"))
{
customLabels = true;
labelFlags = (ELabelFlags)(LFEntryPoint | LFExcepHandler | LFInterHandler | LFSubroutine | LFJumpTarget | LFLoopPoint);
}
else if (CheckToken(token, "e", "entrypoints"))
{
customLabels = false;
labelFlags = LFEntryPoint;
}
else if (CheckToken(token, "x", "excephandlers"))
{
customLabels = false;
labelFlags = LFExcepHandler;
}
else if (CheckToken(token, "i", "interhandlers"))
{
customLabels = false;
labelFlags = LFInterHandler;
}
else if (CheckToken(token, "s", "subroutines"))
{
customLabels = false;
labelFlags = LFSubroutine;
}
else if (CheckToken(token, "j", "jumptargets"))
{
customLabels = false;
labelFlags = LFJumpTarget;
}
else if (CheckToken(token, "l", "looppoints"))
{
customLabels = false;
labelFlags = LFLoopPoint;
}
else
{
Error("Enter a valid filter (a)ll, (c)ustom, (e)ntrypoints, e(x)cephandlers, (i)interhandlers, (j)umptargets or (l)ooppoints.\n");
return false;
}
ListLabels(customLabels, labelFlags);
}
else if (CheckToken(token, "al", "addlabel")) // addlabel <addr> <name>
{
// Parse arguments
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing label address.\n");
return false;
}
else if (!ParseAddress(token, &addr))
{
Error("Enter a valid label address.\n");
return false;
}
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing label name.\n");
return false;
}
const char *name = token;
// Add label
CLabel *label = m_cpu->AddLabel(addr, name);
m_cpu->FormatAddress(addrStr, label->addr);
Print("Label %s added at %s.\n", label->name, addrStr);
}
else if (CheckToken(token, "rl", "removelabel")) // removelabel [<name>|<addr>]
{
// Parse arguments
token = strtok(NULL, " ");
if (token == NULL)
token = "-";
if (!ParseAddress(token, &addr))
{
Error("Enter a valid label name or address.\n");
return false;
}
CLabel *label = m_cpu->GetLabel(addr);
if (label == NULL)
{
m_cpu->FormatAddress(addrStr, addr);
Error("No label at %s.\n", addrStr);
return false;
}
const char *name = label->name;
m_cpu->FormatAddress(addrStr, label->addr);
Print("Custom label '%s' removed at address %s.\n", name, addrStr);
}
else if (CheckToken(token, "ral", "removealllabels")) // removealllabels
{
m_cpu->RemoveAllLabels();
Print("All custom labels removed.\n");
}
else if (CheckToken(token, "ac", "addcomment")) // addcomment <addr> <text...>
{
// Parse arguments
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing comment address.\n");
return false;
}
else if (!ParseAddress(token, &addr))
{
Error("Enter a valid comment address.\n");
return false;
}
char text[255];
text[0] = '\0';
token = strtok(NULL, " ");
while (token != NULL)
{
size_t len = strlen(text);
if (len + strlen(token) > 253)
break;
if (len > 0)
strcat(text, " ");
strcat(text, token);
token = strtok(NULL, " ");
}
if (text[0] == '\0')
{
Error("Missing comment text.\n");
return false;
}
// Add comment
CComment *comment = m_cpu->AddComment(addr, text);
m_cpu->FormatAddress(addrStr, comment->addr);
Print("Comment added at %s.\n", addrStr);
}
else if (CheckToken(token, "rc", "removecomment")) // removecomment [<addr>]
{
// Parse arguments
token = strtok(NULL, " ");
if (token == NULL)
token = "-";
if (!ParseAddress(token, &addr))
{
Error("Enter a valid comment address.\n");
return false;
}
m_cpu->FormatAddress(addrStr, addr);
if (m_cpu->RemoveComment(addr))
Print("Comment at address %s removed.\n", addrStr);
else
Error("No comment at address %s.\n", addrStr);
}
else if (CheckToken(token, "rac", "removeallcomments")) // removeallcomments
{
m_cpu->RemoveAllComments();
Print("All comments removed.\n");
}
//
// Breakpoints
//
else if (CheckToken(token, "lb", "listbreakpoints")) // listbreakpoints
{
ListBreakpoints();
}
else if (CheckToken(token, "b", "breakpoint") || // addbreakpoint [<addr> [[s)imple|(c)ount <count>)]]
CheckToken(token, "ab", "addbreakpoint"))
{
// Parse arguments
token = strtok(NULL, " ");
if (token == NULL)
token = "-";
if (!ParseAddress(token, &addr))
{
Error("Enter a valid address.\n");
return false;
}
token = strtok(NULL, " ");
CBreakpoint *bp;
if (token == NULL || CheckToken(token, "s", "simple"))
bp = m_cpu->AddSimpleBreakpoint(addr);
else if (CheckToken(token, "c", "count"))
{
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing count.\n");
return false;
}
int count;
if (!ParseInt(token, &count) || count <= 0)
{
Error("Enter a valid count.\n");
return false;
}
bp = m_cpu->AddCountBreakpoint(addr, count);
}
else if (CheckToken(token, "p", "print"))
bp = m_cpu->AddPrintBreakpoint(addr);
else
{
Error("Enter a valid breakpoint type (s)imple or (c)ount.\n");
return false;
}
m_cpu->FormatAddress(addrStr, bp->addr);
Print("Breakpoint #%d added at address %s.\n", bp->num, addrStr);
}
else if (CheckToken(token, "rb", "removebreakpoint")) // removebreakpoint [#<num>|<addr>]
{
// Parse arguments
token = strtok(NULL, " ");
if (token == NULL)
token = "-";
if (token[0] == '#')
{
// Remove breakpoint by number
if (!ParseInt(token + 1, &number) || number < 0 || number >= m_cpu->bps.size())
{
Error("Enter a valid breakpoint number.\n");
return false;
}
// Remove breakpoint
m_cpu->RemoveBreakpoint(m_cpu->bps[number]);
Print("Breakpoint #%d removed.\n", number);
}
else
{
// Remove breakpoint by address
if (!ParseAddress(token, &addr))
{
Error("Enter a valid address.\n");
return false;
}
// Remove breakpoint
m_cpu->FormatAddress(addrStr, addr);
if (m_cpu->RemoveBreakpoint(addr))
Print("Breakpoint at address %s removed.\n", addrStr);
else
Error("No breakpoint at address %s.\n", addrStr);
}
}
else if (CheckToken(token, "rab", "removeallbreakpoints")) // removeallbreakpoints
{
m_cpu->RemoveAllBreakpoints();
Print("All breakpoints removed.\n");
}
//
// Memory, I/O & watches
//
else if (CheckToken(token, "ln", "listregions")) // listregions
{
ListRegions();
}
else if (CheckToken(token, "ly", "listmemory")) // listmemory [<start>=last [#<rows>=8|<end>]]
{
// Get start address
UINT32 start;
token = strtok(NULL, " ");
if (token == NULL)
token = "last";
if (stricmp(token, "last") == 0)
{
// Use end of last listing
start = m_listMem;
}
else if (!ParseAddress(token, &start))
{
Error("Enter a valid start address.\n");
return false;
}
// Get end address
UINT32 end;
token = strtok(NULL, " ");
if (token != NULL)
{
if (token[0] == '#')
{
if (!ParseInt(token + 1, &number) || number <= 0)
{
Error("Enter a valid number of rows.\n");
return false;
}
end = start + number * m_memBytesPerRow;
}
else
{
if (!ParseAddress(token, &end))
{
Error("Enter a valid end address.\n");
return false;
}
}
}
else
// Default is 8 rows after start
end = start + 8 * m_memBytesPerRow;
// List the memory
m_listMem = ListMemory(start, end, m_memBytesPerRow);
}
else if (CheckToken(token, "py", "printmemory", mod, 9, "b")) // printmemory[.<size>=b] <addr> [(h)ex|hexdo(l)lar|hex(p)osth|(d)ecimal|(b)inary]
{
// Parse arguments
if (!ParseDataSize(mod, size))
return false;
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing address.\n");
return false;
}
if (!ParseAddress(token, &addr))
{
Error("Enter a valid address.\n");
return false;
}
token = strtok(NULL, " ");
if (token != NULL)
{
if (!ParseFormat(token, fmt))
return false;
}
else
fmt = m_dataFmt;
// Read and print memory
char uSizeStr[12];
sizeStr = GetDataSizeStr(size, false);
UpperFirst(uSizeStr, sizeStr);
data = m_cpu->ReadMem(addr, size);
FormatData(dataStr, fmt, size, data);
m_cpu->FormatAddress(addrStr, addr);
Print("%s data at %s = %s.\n", uSizeStr, addrStr, dataStr);
}
else if (CheckToken(token, "sy", "setmemory", mod, 9, "b")) // setmemory[.<size>=b] <addr> <value>
{
// Parse arguments
if (!ParseDataSize(mod, size))
return false;
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing address.\n");
return false;
}
if (!ParseAddress(token, &addr))
{
Error("Enter a valid address.\n");
return false;
}
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing value to set.\n");
return false;
}
sizeStr = GetDataSizeStr(size, false);
if (!m_cpu->ParseData(token, size, &data))
{
Error("Enter a valid %s value.\n", sizeStr);
return false;
}
// Set memory
char uSizeStr[12];
UpperFirst(uSizeStr, sizeStr);
m_cpu->WriteMem(addr, size, data);
m_cpu->FormatData(dataStr, size, data);
m_cpu->FormatAddress(addrStr, addr);
Print("Set %s data at %s to %s.\n", uSizeStr, addrStr, dataStr);
}
else if (CheckToken(token, "lo", "listios")) // listios
{
ListIOs();
}
else if (CheckToken(token, "lw", "listmemwatches")) // listmemwatches
{
ListMemWatches();
}
else if (CheckToken(token, "w", "memwatch", mod, 9, "b") || // addmemwatch[.<size>=b] <addr> [((n)one|(r)ead|(w)rite|(rw)eadwrite) [((s)imple|(c)ount <count>|(m)atch <sequence>|captu(r)e <maxlen>|(p)rint)]]
CheckToken(token, "aw", "addmemwatch", mod, 9, "b"))
{
// Parse arguments
if (!ParseDataSize(mod, size))
return false;
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing address.\n");
return false;
}
if (!ParseAddress(token, &addr))
{
Error("Enter a valid address.\n");
return false;
}
token = strtok(NULL, " ");
bool read;
bool write;
if (token == NULL || CheckToken(token, "n", "none"))
{
read = false;
write = false;
}
else if (CheckToken(token, "r", "read"))
{
read = true;
write = false;
}
else if (CheckToken(token, "w", "write"))
{
read = false;
write = true;
}
else if (CheckToken(token, "rw", "read/write") || CheckToken(token, "wr", "write/read"))
{
read = true;
write = true;
}
else
{
Error("Enter valid read/write flags (n)one, (r)ead, (w)rite or (rw)ead/write.\n");
return false;
}
// Add mem watch
CWatch *watch;
token = strtok(NULL, " ");
if (token == NULL || CheckToken(token, "s", "simple"))
watch = m_cpu->AddSimpleMemWatch(addr, size, read, write);
else if (CheckToken(token, "c", "count"))
{
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing count.\n");
return false;
}
int count;
if (!ParseInt(token, &count) || count <= 0)
{
Error("Enter a valid count.\n");
return false;
}
watch = m_cpu->AddCountMemWatch(addr, size, read, write, count);
}
else if (CheckToken(token, "m", "match"))
{
vector<UINT64> dataSeq;
while ((token = strtok(NULL, " ")) != NULL)
{
if (m_cpu->ParseData(token, size, &data))
dataSeq.push_back(data);
}
if (dataSeq.size() == 0)
{
sizeStr = GetDataSizeStr(size, false);
Error("Enter a sequence of %s data to match.", sizeStr);
return false;
}
watch = m_cpu->AddMatchMemWatch(addr, size, read, write, dataSeq);
}
else if (CheckToken(token, "r", "capture"))
{
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing maximum capture length.\n");
return false;
}
int maxLen;
if (!ParseInt(token, &maxLen) || maxLen <= 0)
{
Error("Enter a valid maximum capture length.\n");
return false;
}
watch = m_cpu->AddCaptureMemWatch(addr, size, read, write, maxLen);
}
else if (CheckToken(token, "p", "print"))
watch = m_cpu->AddPrintMemWatch(addr, size, read, write);
else
{
Error("Enter a valid watch type (s)imple, (c)ount, (m)atch, captu(r)e or (p)rint.\n");
return false;
}
m_cpu->FormatAddress(addrStr, watch->addr);
number = GetIndexOfMemWatch(watch);
Print("Memory watch #%d added at address %s.\n", number, addrStr);
}
else if (CheckToken(token, "rw", "removememwatch")) // removememwatch (#<num>|<addr>)
{
// Parse arguments
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing watch number or address.\n");
return false;
}
if (token[0] == '#')
{
// Remove watch by number
vector<CWatch*> watches;
GetAllMemWatches(watches);
if (!ParseInt(token + 1, &number) || number < 0 || number >= watches.size())
{
Error("Enter a valid watch number.\n");
return false;
}
// Remove watch
m_cpu->RemoveWatch(watches[number]);
Print("Memory watch #%d removed.\n", number);
}
else
{
// Remove watch by address
if (!ParseAddress(token, &addr))
{
Error("Enter a valid address.\n");
return false;
}
// Remove watch
m_cpu->FormatAddress(addrStr, addr);
if (m_cpu->RemoveMemWatch(addr, 1))
Print("Memory watch at address %s removed.\n", addrStr);
else
Error("No memory watch at address %s.\n", addrStr);
}
}
else if (CheckToken(token, "raw", "removeallmemwatches")) // removeallmemwatches
{
// Remove all memory watches
vector<CWatch*> watches;
GetAllMemWatches(watches);
for (vector<CWatch*>::iterator it = watches.begin(); it != watches.end(); it++)
m_cpu->RemoveWatch(*it);
Print("All memory watches removed.\n");
}
else if (CheckToken(token, "lpw", "listportwatches")) // listportwatches
{
ListPortWatches();
}
else if (CheckToken(token, "pw", "portwatch") || // addportwatch <port> [((n)one|(i)nput|(o)|(io)nputoutput) [((s)imple|(c)ount <count>|(m)atch <sequence>|captu(r)e <maxlen>|(p)rint)]]
CheckToken(token, "apw", "addportwatch"))
{
// Parse arguments
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing port number.\n");
return false;
}
if (!m_cpu->ParsePortNum(token, &portNum))
{
Error("Enter a valid port number.\n");
return false;
}
token = strtok(NULL, " ");
bool input;
bool output;
if (token == NULL || CheckToken(token, "n", "none"))
{
input = false;
output = false;
}
else if (CheckToken(token, "i", "input"))
{
input = true;
output = false;
}
else if (CheckToken(token, "o", "output"))
{
input = false;
output = true;
}
else if (CheckToken(token, "io", "input/output") || CheckToken(token, "oi", "output/input"))
{
input = true;
output = true;
}
else
{
Error("Enter valid input/output flags (n)one, (i)nput, (o)utput or (io)nput/output.\n");
return false;
}
// Add watch
CPortIO *port = m_cpu->GetPortIO(portNum);
CWatch *watch;
token = strtok(NULL, " ");
if (token == NULL || CheckToken(token, "s", "simple"))
watch = port->AddSimpleWatch(input, output);
else if (CheckToken(token, "c", "count"))
{
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing count.\n");
return false;
}
int count;
if (!ParseInt(token, &count) || count <= 0)
{
Error("Enter a valid count.\n");
return false;
}
watch = port->AddCountWatch(input, output, count);
}
else if (CheckToken(token, "m", "match"))
{
vector<UINT64> dataSeq;
while ((token = strtok(NULL, " ")) != NULL)
{
if (m_cpu->ParseData(token, port->dataSize, &data))
dataSeq.push_back(data);
}
if (dataSeq.size() == 0)
{
Error("Enter a sequence of %s to match.", GetDataSizeStr(port->dataSize, false));
return false;
}
watch = port->AddMatchWatch(input, output, dataSeq);
}
else if (CheckToken(token, "r", "capture"))
{
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing maximum capture length.\n");
return false;
}
int maxLen;
if (!ParseInt(token, &maxLen) || maxLen <= 0)
{
Error("Enter a valid maximum capture length.\n");
return false;
}
watch = port->AddCaptureWatch(input, output, maxLen);
}
else if (CheckToken(token, "p", "print"))
watch = port->AddPrintWatch(input, output);
else
{
Error("Enter a valid watch type (s)imple, (c)ount, (m)atch, captu(r)e or (p)rint.\n");
return false;
}
m_cpu->FormatPortNum(portNumStr, portNum);
number = GetIndexOfPortWatch(watch);
Print("Port watch %d added for port %u.\n", number, portNumStr);
}
else if (CheckToken(token, "rpw", "removeportwatch")) // removeportwatch (a|n|p) [NUM|PORT]
{
// Parse arguments
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing watch number or port number.\n");
return false;
}
if (token[0] == '#')
{
// Remove watch by number
vector<CWatch*> watches;
GetAllPortWatches(watches);
if (!ParseInt(token + 1, &number) || number < 0 || number >= watches.size())
{
Error("Enter a valid watch number.\n");
return false;
}
// Remove watch
m_cpu->RemoveWatch(watches[number]);
Print("Port watch #%d removed.\n", number);
}
else
{
// Remove watch by port number
if (!m_cpu->ParsePortNum(token, &portNum))
{
Error("Enter a valid port number.\n");
return false;
}
// Remove watch
CPortIO *port = m_cpu->GetPortIO(portNum);
m_cpu->FormatPortNum(portNumStr, portNum);
if (port->RemoveWatch())
Print("Port watch for port %s removed.\n", portNumStr);
else
Error("No port watch for port %s.\n", portNumStr);
}
}
else if (CheckToken(token, "rapw", "removeallportwatches")) // removeallportwatches
{
// Remove all port watches
vector<CWatch*> watches;
GetAllPortWatches(watches);
for (vector<CWatch*>::iterator it = watches.begin(); it != watches.end(); it++)
m_cpu->RemoveWatch(*it);
Print("All port watches removed.\n");
}
//
// General
//
else if (CheckToken(token, "p", "print", mod, 9, "")) // print[.<size>=v] <expr> [(h)ex|hexdo(l)lar|hex(p)osth|(d)ecimal|(b)inary]
{
// Parse arguments
bool useDefSize;
if (mod[0] == '\0')
useDefSize = true;
else if (ParseDataSize(mod, size))
useDefSize = false;
else
return false;
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing expression.\n");
return false;
}
const char *expr = token;
token = strtok(NULL, " ");
if (token != NULL)
{
if (!ParseFormat(token, fmt))
return false;
}
else
fmt = m_dataFmt;
// Check labels and registers
CLabel *label = m_cpu->GetLabel(expr);
if (label != NULL)
{
data = label->addr;
if (useDefSize)
size = m_cpu->memBusWidth / 8;
}
else
{
CCodeAnalyser *analyser = m_cpu->GetCodeAnalyser();
CAutoLabel *autoLabel = analyser->analysis->GetAutoLabel(expr);
if (autoLabel != NULL)
{
data = autoLabel->addr;
if (useDefSize)
size = m_cpu->memBusWidth / 8;
}
else
{
CRegister *reg = m_cpu->GetRegister(expr);
if (reg != NULL)
{
data = reg->GetValueAsInt();
if (useDefSize)
size = reg->dataWidth / 8;
}
else
{
if (!ParseData(expr, m_dataFmt, 8, &data))
{
Print("Unable to parse expression %s\n", expr);
return false;
}
if (useDefSize)
size = 8;
}
}
}
char result[255];
FormatData(result, fmt, size, data);
if (useDefSize)
Print("%s = %s\n", expr, result);
else
{
sizeStr = GetDataSizeStr(size, true);
Print("%s = %s.%s\n", expr, result, sizeStr);
}
}
else if (CheckToken(token, "cfg", "configure")) // configure <options...>
{
// Parse arguments
token = strtok(NULL, " ");
if (token == NULL)
{
// If no arguments, then print out current configuration
Print("Configuration:\n");
Print(" %-20s %-12s %s\n", "Code Analysis", (m_analyseCode ? "On" : "Off"), "(a)nalysis");
Print(" %-20s %-12s %s\n", "Address Format", GetFmtConfig(m_addrFmt), "a(d)dressfmt");
Print(" %-20s %-12s %s\n", "Port Format", GetFmtConfig(m_portFmt), "(p)ortfmt");
Print(" %-20s %-12s %s\n", "Data Format", GetFmtConfig(m_dataFmt), "da(t)afmt");
Print(" %-20s %-12s %s\n", "Show Labels", (m_showLabels ? "On" : "Off"), "show(l)abels");
Print(" %-20s %-12s %s\n", "Show Opcodes", (m_showOpCodes ? "On" : "Off"), "show(o)pcodes");
Print(" %-20s %-12u %s\n", "Mem Bytes Per Row", m_memBytesPerRow, "mem(b)ytesrow");
return false;
}
if (CheckToken(token, "a", "analysis"))
{
token = strtok(NULL, " ");
SetBoolConfig(token, m_analyseCode);
}
else if (CheckToken(token, "d", "addressfmt"))
{
token = strtok(NULL, " ");
SetFmtConfig(token, m_addrFmt);
}
else if (CheckToken(token, "p", "portfmt"))
{
token = strtok(NULL, " ");
SetFmtConfig(token, m_portFmt);
}
else if (CheckToken(token, "t", "datafmt"))
{
token = strtok(NULL, " ");
SetFmtConfig(token, m_dataFmt);
}
else if (CheckToken(token, "l", "showlabels"))
{
token = strtok(NULL, " ");
SetBoolConfig(token, m_showLabels);
}
else if (CheckToken(token, "o", "showopcodes"))
{
token = strtok(NULL, " ");
SetBoolConfig(token, m_showOpCodes);
}
else if (CheckToken(token, "b", "membytesrow"))
{
token = strtok(NULL, " ");
SetNumConfig(token, m_memBytesPerRow);
}
else
{
Error("Enter a valid option (a)nalysis, a(d)dressfmt, (p)ortfmt, da(t)afmt, show(l)abels, show(o)pcodes, mem(b)ytesrow.\n");
return false;
}
}
else if (CheckToken(token, "ls", "loadstate")) // loadstate <filename>
{
// Parse arguments
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing filename.\n");
return false;
}
if (LoadState(token))
Print("Debugger state successfully loaded from <%s>\n", token);
else
Error("Unable to load debugger state from <%s>\n", token);
}
else if (CheckToken(token, "ss", "savestate")) // savestate <filename>
{
// Parse arguments
token = strtok(NULL, " ");
if (token == NULL)
{
Error("Missing filename.\n");
return false;
}
if (SaveState(token))
Print("Debugger state successfully saved to <%s>\n", token);
else
Error("Unable to save debugger state to <%s>\n", token);
}
else if (CheckToken(token, "h", "help")) // help
{
// TODO - improve the following
const char *fmt = " %-6s %-25s %s\n";
Print("Debugger Commands:\n");
Print(" Execution:\n");
Print(fmt, "n", "next", "[<count>=1]");
Print(fmt, "nf", "nextframe", "[<count>=1]");
Print(fmt, "s", "stepover", "");
Print(fmt, "si", "stepinto", "");
Print(fmt, "so", "stepout", "");
Print(fmt, "c", "continue", "[<addr>]");
Print(fmt, "spc", "setpc", "<addr>");
Print(" CPUs:\n");
Print(fmt, "lc", "listcpus", "");
Print(fmt, "sc", "switchcpu", "(<name>|<num>)");
Print(fmt, "dc", "disablecpu", "(<name>|<num>)");
Print(fmt, "ec", "enablecpu", "(<name>|<num>)");
Print(" Registers:\n");
Print(fmt, "lr", "listregisters", "");
Print(fmt, "pr", "printregister", "<reg>");
Print(fmt, "sr", "setregister", "<reg> <value>");
Print(fmt, "lm", "listmonitors", "");
Print(fmt, "m/am", "addmonitor", "<reg>");
Print(fmt, "rm", "removemonitor", "<reg>");
Print(fmt, "ram", "removeallmonitors", "");
Print(" Exceptions & interrupts:\n");
Print(fmt, "le", "listexceptions", "");
Print(fmt, "li", "listinterrupts", "");
Print(fmt, "t/at", "addtrap", "((e)xception|(i)nterrupt) <id>");
Print(fmt, "rt", "removetrap", "((e)xception|(i)nterrupt) <id>");
Print(fmt, "rat", "removealltraps", "[(a)ll|(e)xceptions|(i)nterrupts]");
Print(" Disassembly, labels & comments:\n");
Print(fmt, "l/ld", "listdisassembly", "[<start>=last [#<instrs>=20|<end>]]");
Print(fmt, "ll", "listlabels", "[(d)efault|(c)ustom|(a)utos|(e)ntrypoints|e(x)cephandlers|(i)interhandlers|(j)umptargets|(l)ooppoints]");
Print(fmt, "al", "addlabel", "<addr> <name>");
Print(fmt, "rl", "removelabel", "[<name>|<addr>]");
Print(fmt, "ral", "removealllabels", "");
Print(fmt, "ac", "addcomment", "<addr> <text...>");
Print(fmt, "rc", "removecomment", "[<addr>]");
Print(fmt, "rac", "removeallcomments", "");
Print(" Breakpoints:\n");
Print(fmt, "lb", "listbreakpoints", "");
Print(fmt, "b/ab", "addbreakpoint", "[<addr> [[s)imple|(c)ount <count>)]]");
Print(fmt, "rb", "removebreakpoint", "[#<num>|<addr>]");
Print(fmt, "rab", "removeallbreakpoints", "");
Print(" Memory, I/O & watches:\n");
Print(fmt, "ln", "listregions", "");
Print(fmt, "ly", "listmemory", "[<start>=last [#<rows>=8|<end>]]");
Print(fmt, "py", "printmemory[.<size>=b]", "<addr>");
Print(fmt, "sy", "setmemory[.<size>=b]", "<addr> <value>");
Print(fmt, "lo", "listios", "");
Print(fmt, "lw", "listmemwatches", "");
Print(fmt, "w/aw", "addmemwatch[.<size>=b]", "<addr> [((n)one|(r)ead|(w)rite|(rw)eadwrite) [((s)imple|(c)ount <count>|(m)atch <sequence>|captu(r)e <maxlen>|(p)rint)]]");
Print(fmt, "rw", "removememwatch", "(#<num>|<addr>)");
Print(fmt, "raw", "removeallmemwatches", "");
Print(fmt, "lpw", "listportwatches", "");
Print(fmt, "pw/apw", "addportwatch", "<port> [((n)one|(i)nput|(o)utput|(io)nputoutput) [(s)imple|(c)ount <count>|(m)atch <sequence>|captu(r)e <maxlen>|(p)rint]]");
Print(fmt, "rpw", "removeportwatch", "(#<num>|<port>)");
Print(fmt, "rapw", "removeallportwatches", "");
Print("General:\n");
Print(fmt, "p", "print[.<size>=v]", "<expr> [(h)ex|hexdo(l)lar|hex(p)osth|(d)ecimal|(b)inary]");
Print(fmt, "cfg", "configure", "<options...>");
Print(fmt, "ls", "loadstate", "<filename>");
Print(fmt, "ss", "savestate", "<filename>");
Print(fmt, "h", "help", "");
Print(fmt, "x", "exit", "");
}
else if (CheckToken(token, "x", "exit")) // exit
{
Print("Exiting...\n");
SetExit();
return true;
}
else
Print("Unknown command '%s'.\n", token);
return false;
}
void CConsoleDebugger::Read(char *str, size_t maxSize)
{
if (fgets(str, maxSize, stdin) != NULL)
{
char *pos = strchr(str, '\n');
if (pos)
*pos = '\0';
}
else
str[0] = '\0';
}
void CConsoleDebugger::Print(const char *fmtStr, ...)
{
va_list vl;
va_start(vl, fmtStr);
PrintVL(fmtStr, vl);
va_end(vl);
}
void CConsoleDebugger::Error(const char *fmtStr, ...)
{
// Don't log errors to file
va_list vl;
va_start(vl, fmtStr);
vprintf(fmtStr, vl);
va_end(vl);
}
void CConsoleDebugger::PrintVL(const char *fmtStr, va_list vl)
{
if (m_file != NULL)
vfprintf(m_file, fmtStr, vl);
else
vprintf(fmtStr, vl);
}
void CConsoleDebugger::Flush()
{
fflush(stdout);
}
bool CConsoleDebugger::CheckToken(const char *token, const char *simple, const char *full)
{
return stricmp(token, simple) == 0 || stricmp(token, full) == 0;
}
bool CConsoleDebugger::CheckToken(const char *token, const char *simple, const char *full, char *modifier, size_t modSize, const char *defaultMod)
{
const char *pos = strchr(token, '.');
if (pos == NULL)
{
strncpy(modifier, defaultMod, modSize);
modifier[modSize] = '\0';
return CheckToken(token, simple, full);
}
else
{
pos++;
// BEGIN
if (*pos == '\0')
// END
return false;
strncpy(modifier, pos, modSize);
modifier[modSize] = '\0';
char actual[255];
size_t actSize = min<size_t>(pos - token - 1, 254);
strncpy(actual, token, actSize);
actual[actSize] = '\0';
return CheckToken(actual, simple, full);
}
}
void CConsoleDebugger::Truncate(char *dst, size_t maxLen, const char *src)
{
strncpy(dst, src, maxLen);
if (strlen(src) > maxLen)
strncpy(&dst[maxLen - 3], "...", 3);
dst[maxLen] = '\0';
}
void CConsoleDebugger::UpperFirst(char *dst, const char *src)
{
if (*src != '\0')
{
*dst++ = toupper(*src++);
while (*src != '\0')
*dst++ = *src++;
}
*dst = '\0';
}
void CConsoleDebugger::FormatOpCodes(char *str, int addr, int codesLen)
{
char *p = str;
int i = 0;
while (i < codesLen)
{
UINT8 opCode = (UINT8)m_cpu->ReadMem(addr++, 1);
sprintf(p, "%02X", opCode);
p += 2;
i++;
}
while (i++ < m_cpu->maxInstrLen)
{
*p++ = ' ';
*p++ = ' ';
}
*p = '\0';
}
bool CConsoleDebugger::GetLabelText(char *str, int maxLen, UINT32 addr)
{
char labelStr[255];
CLabel *label = m_cpu->GetLabel(addr);
if (label != NULL)
{
Truncate(str, maxLen, label->name);
return true;
}
if (m_analyseCode)
{
CCodeAnalyser *analyser = m_cpu->GetCodeAnalyser();
CAutoLabel *autoLabel = analyser->analysis->GetAutoLabel(addr);
if (autoLabel != NULL && autoLabel->GetLabel(labelStr))
{
Truncate(str, maxLen, labelStr);
return true;
}
}
str[0] = '\0';
return false;
}
bool CConsoleDebugger::SetBoolConfig(const char *str, bool &cfg)
{
if (str == NULL)
{
Print("Current setting: %-12s\n", (cfg ? "On" : "Off"));
Print("Change setting with (o)n, o(f)f.\n");
return false;
}
if (CheckToken(str, "o", "on"))
{
cfg = true;
Print("Changed setting: On\n");
ApplyConfig();
return true;
}
else if (CheckToken(str, "f", "off"))
{
cfg = false;
Print("Changed setting: Off\n");
ApplyConfig();
return true;
}
else
{
Error("Enter a valid setting (o)n, o(f)f.\n");
return false;
}
}
bool CConsoleDebugger::SetNumConfig(const char *str, unsigned &cfg)
{
if (str == NULL)
{
Print("Current setting: %-12u\n", cfg);
return false;
}
int number;
if (!ParseInt(str, &number))
{
Error("Enter a valid number.\n");
return false;
}
cfg = (unsigned)number;
Print("Changed setting: %-12u\n", cfg);
ApplyConfig();
return true;
}
const char *CConsoleDebugger::GetFmtConfig(EFormat fmt)
{
switch (fmt)
{
case Hex0x: return "Hex (0x00)";
case HexDollar: return "Hex ($00)";
case HexPostH: return "Hex (00h)";
case Decimal: return "Decimal";
case Binary: return "Binary";
default: return "-";
}
}
bool CConsoleDebugger::SetFmtConfig(const char *str, EFormat &cfg)
{
if (str == NULL)
{
Print("Current setting: %-12s\n", GetFmtConfig(cfg));
Print("Change setting with (h)ex, hex(z)ero, hexdo(l)ar, hex(p)osth, (d)ecimal, (b)inary.\n");
return false;
}
if (!ParseFormat(str, cfg))
return false;
Print("Changed setting: %-12s\n", GetFmtConfig(cfg));
ApplyConfig();
return true;
}
bool CConsoleDebugger::ParseAddress(const char *str, UINT32 *addr)
{
if (m_cpu->instrCount > 0 && CheckToken(str, "-", "current"))
{
*addr = m_cpu->pc;
return true;
}
return m_cpu->ParseAddress(str, addr);
}
const char *CConsoleDebugger::GetDataSizeStr(unsigned dataSize, bool shortName)
{
switch (dataSize)
{
case 1: return (shortName ? "b" : "byte");
case 2: return (shortName ? "w" : "word");
case 4: return (shortName ? "l" : "long");
case 8: return (shortName ? "v" : "vlong");
default: return GetSizeString(dataSize);
}
}
bool CConsoleDebugger::ParseDataSize(const char *str, unsigned &dataSize)
{
int num = -1;
ParseInt(str, &num);
if (CheckToken(str, "b", "byte") || num == 1)
{
dataSize = 1;
return true;
}
else if (CheckToken(str, "w", "word") || num == 2)
{
dataSize = 2;
return true;
}
else if (CheckToken(str, "l", "long") || num == 4)
{
dataSize = 4;
return true;
}
else if (CheckToken(str, "v", "verylong") || num == 8)
{
dataSize = 8;
return true;
}
else
{
Error("Enter a valid size (b)yte, (w)ord, (l)ong or (v)erylong or a number 1, 2, 4 or 8.\n");
return false;
}
}
bool CConsoleDebugger::ParseFormat(const char *str, EFormat &fmt)
{
if (CheckToken(str, "h", "hex")) fmt = Hex;
else if (CheckToken(str, "z", "hexzero")) fmt = Hex0x;
else if (CheckToken(str, "l", "hexdollar")) fmt = HexDollar;
else if (CheckToken(str, "p", "hexposth")) fmt = HexPostH;
else if (CheckToken(str, "d", "decimal")) fmt = Decimal;
else if (CheckToken(str, "b", "binary")) fmt = Binary;
else
{
Error("Enter a valid format (h)ex, hex(z)ero, hexdo(l)ar, hex(p)osth, (d)ecimal, (b)inary.\n");
return false;
}
return true;
}
bool CConsoleDebugger::ParseCPU(const char *str, CCPUDebug *&cpu)
{
if (str == NULL)
{
Error("Missing CPU name or number.\n");
return false;
}
int cpuNum;
if (ParseInt(str, &cpuNum))
{
if (cpuNum >= 0 && cpuNum < (int)cpus.size())
{
cpu = cpus[cpuNum];
return true;
}
}
cpu = GetCPU(str);
if (cpu == NULL)
{
Error("No CPU with that name or number.\n");
return false;
}
return true;
}
bool CConsoleDebugger::ParseRegister(const char *str, CRegister *&reg)
{
if (str == NULL)
{
Error("Missing register name.\n");
return false;
}
reg = m_cpu->GetRegister(str);
if (reg == NULL)
{
Error("Enter a valid register name.\n");
return false;
}
return true;
}
void CConsoleDebugger::ListCPUs()
{
Print("CPUs:\n");
if (cpus.size() == 0)
{
Print(" None\n");
return;
}
Print(" %-3s %-9s %-6s %-9s %-7s %-12s %-12s %-9s\n", "Num", "Name", "Type", "Debugging", "State", "Instr Count", "Total Cycles", "Frequency");
unsigned num = 0;
double freq;
char onCPU;
const char *debugStr;
const char *stateStr;
for (vector<CCPUDebug*>::iterator it = cpus.begin(); it != cpus.end(); it++)
{
onCPU = (*it == m_cpu ? '*': ' ');
debugStr = ((*it)->IsEnabled() ? "Enabled" : "Disabled");
stateStr = ((*it)->active ? "Running" : "Waiting");
if ((*it)->instrCount > 0)
{
if (frameCount > 0)
{
freq = ((*it)->cyclesPerPoll * 60.0) / 1000000.0;
Print("%c%-3u %-9s %-6s %-9s %-7s %12llu %12llu %6.1fMHz\n", onCPU, num++, (*it)->name, (*it)->type, debugStr, stateStr, (*it)->instrCount - 1, (*it)->totalCycles, freq);
}
else
Print("%c%-3u %-9s %-6s %-9s %-7s %12llu %12llu %9s\n", onCPU, num++, (*it)->name, (*it)->type, debugStr, stateStr, (*it)->instrCount - 1, (*it)->totalCycles, "-");
}
else
Print("%c%-3u %-9s %-6s %-9s %-7s %12s %12s %9s\n", onCPU, num++, (*it)->name, (*it)->type, debugStr, stateStr, "-", "-", "-");
}
}
void CConsoleDebugger::ListRegisters()
{
Print("%s Registers:\n", m_cpu->name);
if (m_cpu->regs.size() == 0)
{
Print(" None\n");
return;
}
// Get groups
vector<const char*> groups;
vector<vector<CRegister*> > regsByGroup;
size_t totalRows = 0;
for (vector<CRegister*>::iterator it = m_cpu->regs.begin(); it != m_cpu->regs.end(); it++)
{
const char *group = (*it)->group;
// TODO - find with stricmp rather than default find
if (find(groups.begin(), groups.end(), group) == groups.end())
{
groups.push_back(group);
regsByGroup.resize(regsByGroup.size() + 1);
}
int index = find(groups.begin(), groups.end(), group) - groups.begin();
vector<CRegister*> *pRegsInGroup = &regsByGroup[index];
pRegsInGroup->push_back(*it);
totalRows = max<size_t>(totalRows, pRegsInGroup->size());
}
// Get max label and value widths in each group and print group headers
size_t numGroups = groups.size();
vector<size_t> labelWidths(numGroups);
vector<size_t> valueWidths(numGroups);
vector<size_t> groupWidths(numGroups);
char valStr[50];
Print(" ");
for (size_t index = 0; index < numGroups; index++)
{
labelWidths[index] = 0;
valueWidths[index] = 0;
vector<CRegister*> *pRegsInGroup = &regsByGroup[index];
for (vector<CRegister*>::iterator it = pRegsInGroup->begin(); it != pRegsInGroup->end(); it++)
{
labelWidths[index] = max<size_t>(labelWidths[index], strlen((*it)->name));
(*it)->GetValue(valStr);
valueWidths[index] = max<size_t>(valueWidths[index], strlen(valStr));
}
const char *group = groups[index];
groupWidths[index] = max<size_t>(labelWidths[index] + valueWidths[index] + 3, strlen(group) + 1);
Print("%-*s", (int)groupWidths[index], group);
}
Print("\n");
// Print rows of register values
char rowStr[50];
for (size_t row = 0; row < totalRows; row++)
{
Print(" ");
for (size_t index = 0; index < numGroups; index++)
{
vector<CRegister*> *pRegsInGroup = &regsByGroup[index];
if (row < pRegsInGroup->size())
{
CRegister *reg = (*pRegsInGroup)[row];
reg->GetValue(valStr);
bool hasMon = m_cpu->GetRegMonitor(reg->name) != NULL;
sprintf(rowStr, "%c%-*s %-*s", (hasMon ? '*' : ' '), (int)labelWidths[index], reg->name, (int)valueWidths[index], valStr);
}
else
rowStr[0] = '\0';
Print("%-*s", (int)groupWidths[index], rowStr);
}
Print("\n");
}
}
void CConsoleDebugger::ListExceptions()
{
Print("%s Exceptions:\n", m_cpu->name);
if (m_cpu->exceps.size() == 0)
{
Print(" None\n");
return;
}
char addrStr[20];
UINT32 handlerAddr;
for (vector<CException*>::iterator it = m_cpu->exceps.begin(); it != m_cpu->exceps.end(); it++)
{
if (m_cpu->GetHandlerAddr(*it, handlerAddr))
m_cpu->FormatAddress(addrStr, handlerAddr, true, (m_analyseCode ? LFExcepHandler : LFNone));
else
addrStr[0] = '\0';
Print("%c%-12s %-30s %-12s %u\n", ((*it)->trap ? '*' : ' '), (*it)->id, (*it)->name, addrStr, (*it)->count);
}
}
void CConsoleDebugger::ListInterrupts()
{
Print("%s Interrupts:\n", m_cpu->name);
if (m_cpu->inters.size() == 0)
{
Print(" None\n");
return;
}
char addrStr[20];
UINT32 handlerAddr;
for (vector<CInterrupt*>::iterator it = m_cpu->inters.begin(); it != m_cpu->inters.end(); it++)
{
if (m_cpu->GetHandlerAddr(*it, handlerAddr))
m_cpu->FormatAddress(addrStr, handlerAddr, true, (m_analyseCode ? LFInterHandler : LFNone));
else
addrStr[0] = '\0';
Print("%c%-12s %-30s %-12s %u\n", ((*it)->trap ? '*' : ' '), (*it)->id, (*it)->name, addrStr, (*it)->count);
}
}
void CConsoleDebugger::ListIOs()
{
Print("%s I/O Ports:\n", m_cpu->name);
if (m_cpu->ios.size() == 0)
{
Print(" None\n");
return;
}
const char *group = NULL;
char locStr[255];
char dirChar;
char inStr[50];
char outStr[50];
for (vector<CIO*>::iterator it = m_cpu->ios.begin(); it != m_cpu->ios.end(); it++)
{
// Print group heading if starting a new group
if (group == NULL || stricmp((*it)->group, group) != 0)
{
group = (*it)->group;
Print(" %s:\n", group);
}
// Get location string (memory address or port number)
(*it)->GetLocation(locStr);
// See whether port was last read or written
if ((*it)->inCount + (*it)->outCount > 0)
dirChar = ((*it)->last == &(*it)->lastIn ? '<' : '>');
else
dirChar = ' ';
// Format last input
if ((*it)->inCount > 0)
m_cpu->FormatData(inStr, (*it)->dataSize, (*it)->lastIn);
else
{
inStr[0] = '*';
inStr[1] = '\0';
}
size_t inLen = strlen(inStr);
int inLPad = 5 - (int)inLen / 2;
int inRPad = 5 - (int)inLen + (int)inLen / 2;
// Format last output
if ((*it)->outCount > 0)
m_cpu->FormatData(outStr, (*it)->dataSize, (*it)->lastOut);
else
{
outStr[0] = '*';
outStr[1] = '\0';
}
size_t outLen = strlen(outStr);
int outLPad = 5 - (int)outLen / 2;
int outRPad = 5 - (int)outLen + (int)outLen / 2;
// Print details
Print(" %c%-12s %-30s %-8s %*s%s%*s%c%*s%s%*s\n", ((*it)->watch != NULL ? '*' : ' '), locStr, (*it)->name,
GetDataSizeStr((*it)->dataSize, true), inLPad, "", inStr, inRPad, "", dirChar, outLPad, "", outStr, outRPad, "");
}
}
void CConsoleDebugger::ListRegions()
{
Print("%s Regions:\n", m_cpu->name);
if (m_cpu->regions.size() == 0)
{
Print(" None\n");
return;
}
char startStr[255];
char endStr[255];
for (vector<CRegion*>::iterator it = m_cpu->regions.begin(); it != m_cpu->regions.end(); it++)
{
// Format start and end address
m_cpu->FormatAddress(startStr, (*it)->addr);
m_cpu->FormatAddress(endStr, (*it)->addrEnd);
// Print details
Print("%c%s-%s %s\n", ((*it)->isCode ? '*' : ' '), startStr, endStr, (*it)->name);
}
}
void CConsoleDebugger::ListLabels(bool customLabels, ELabelFlags autoLabelFlags)
{
Print("%s Labels:\n", m_cpu->name);
unsigned count = 0;
char addrStr[20];
if (customLabels && m_cpu->labels.size() > 0)
{
Print(" Custom Labels:\n");
for (vector<CLabel*>::iterator it = m_cpu->labels.begin(); it != m_cpu->labels.end(); it++)
{
m_cpu->FormatAddress(addrStr, (*it)->addr);
Print(" %s %s\n", addrStr, (*it)->name);
count++;
}
}
if (m_analyseCode)
{
char labelStr[255];
CCodeAnalyser *analyser = m_cpu->GetCodeAnalyser();
for (unsigned index = 0; index < CAutoLabel::numLabelFlags; index++)
{
ELabelFlags flag = CAutoLabel::GetLabelFlag(index);
if (!(autoLabelFlags & flag))
continue;
vector<CAutoLabel*> withFlag = analyser->analysis->GetAutoLabels(flag);
if (withFlag.size() == 0)
continue;
const char *flagStr = CAutoLabel::GetFlagString(flag);
Print(" %ss:\n", flagStr);
for (vector<CAutoLabel*>::iterator it = withFlag.begin(); it != withFlag.end(); it++)
{
if (!(*it)->GetLabel(labelStr, flag))
continue;
CBreakpoint *bp = m_cpu->GetBreakpoint((*it)->addr);
char bpChr = (bp != NULL ? bp->symbol : ' ');
m_cpu->FormatAddress(addrStr, (*it)->addr);
Print(" %c%s %s\n", bpChr, addrStr, labelStr);
count++;
}
}
}
if (count == 0)
{
Print(" None\n");
return;
}
}
void CConsoleDebugger::GetAllMemWatches(vector<CWatch*> &watches)
{
for (vector<CWatch*>::iterator it = m_cpu->memWatches.begin(); it != m_cpu->memWatches.end(); it++)
watches.push_back(*it);
for (vector<CWatch*>::iterator it = m_cpu->ioWatches.begin(); it != m_cpu->ioWatches.end(); it++)
{
if (dynamic_cast<CMappedIO*>((*it)->io) != NULL)
watches.push_back(*it);
}
}
int CConsoleDebugger::GetIndexOfMemWatch(CWatch *watch)
{
vector<CWatch*> watches;
GetAllMemWatches(watches);
vector<CWatch*>::iterator it = find(watches.begin(), watches.end(), watch);
if (it == watches.end())
return -1;
return it - watches.begin();
}
void CConsoleDebugger::ListMemWatches()
{
Print("%s Memory Watches:\n", m_cpu->name);
vector<CWatch*> watches;
GetAllMemWatches(watches);
if (watches.size() == 0)
{
Print(" None\n");
return;
}
Print(" %-3s %-8s %-12s %-5s %-4s %-20s %s\n", "Num", "Type", "Address", "Size", "Trig", "Value", "Info");
char typeStr[12];
char addrStr[20];
char sizeStr[20];
const char *dSizeStr;
const char *trigStr;
char valStr[20];
char infoStr[255];
unsigned wNum = 0;
for (vector<CWatch*>::iterator it = watches.begin(); it != watches.end(); it++)
{
UpperFirst(typeStr, (*it)->type);
m_cpu->FormatAddress(addrStr, (*it)->addr, true);
dSizeStr = GetDataSizeStr((*it)->size, false);
UpperFirst(sizeStr, dSizeStr);
if ((*it)->trigRead && (*it)->trigWrite) trigStr = "R/W";
else if ((*it)->trigRead) trigStr = "R";
else if ((*it)->trigWrite) trigStr = "W";
else trigStr = "-";
m_cpu->FormatData(valStr, (*it)->size, (*it)->GetValue());
if (!(*it)->GetInfo(infoStr))
{
infoStr[0] = '-';
infoStr[1] = '\0';
}
Print(" %-3u %-8s %-12s %-5s %-4s %-20s %s\n", wNum++, typeStr, addrStr, sizeStr, trigStr, valStr, infoStr);
}
}
void CConsoleDebugger::GetAllPortWatches(vector<CWatch*> &watches)
{
for (vector<CWatch*>::iterator it = m_cpu->ioWatches.begin(); it != m_cpu->ioWatches.end(); it++)
{
if (dynamic_cast<CPortIO*>((*it)->io) != NULL)
watches.push_back(*it);
}
}
int CConsoleDebugger::GetIndexOfPortWatch(CWatch *watch)
{
vector<CWatch*> watches;
GetAllPortWatches(watches);
vector<CWatch*>::iterator it = find(watches.begin(), watches.end(), watch);
if (it == watches.end())
return -1;
return it - watches.begin();
}
void CConsoleDebugger::ListPortWatches()
{
Print("%s I/O Port Watches:\n", m_cpu->name);
vector<CWatch*> watches;
GetAllPortWatches(watches);
if (watches.size() == 0)
{
Print(" None\n");
return;
}
Print(" %-3s %-8s %-12s %-4s %-20s %s\n", "Num", "Type", "Location", "Trig", "Last In/Out", "Info");
char typeStr[12];
char locStr[255];
const char *trigStr;
char valStr[20];
char infoStr[255];
unsigned wNum = 0;
for (vector<CWatch*>::iterator it = watches.begin(); it != watches.end(); it++)
{
UpperFirst(typeStr, (*it)->type);
(*it)->io->GetLocation(locStr);
if ((*it)->trigRead && (*it)->trigWrite) trigStr = "I/O";
else if ((*it)->trigRead) trigStr = "I";
else if ((*it)->trigWrite) trigStr = "O";
else trigStr = "-";
if ((*it)->readCount + (*it)->writeCount == 0)
{
valStr[0] = '-';
valStr[1] = '\0';
}
else
m_cpu->FormatData(valStr, (*it)->size, (*it)->GetValue());
if (!(*it)->GetInfo(infoStr))
{
infoStr[0] = '-';
infoStr[1] = '\0';
}
Print(" %-3u %-8s %-12s %-4s %-20s %s\n", wNum++, typeStr, locStr, trigStr, valStr, infoStr);
}
}
void CConsoleDebugger::ListBreakpoints()
{
Print("%s Breakpoints:\n", m_cpu->name);
if (m_cpu->bps.size() == 0)
{
Print(" None\n");
return;
}
Print(" %-3s %-8s %-12s %-20s\n", "Num", "Type", "Address", "Info");
char typeStr[12];
char addrStr[20];
char infoStr[255];
for (vector<CBreakpoint*>::iterator it = m_cpu->bps.begin(); it != m_cpu->bps.end(); it++)
{
UpperFirst(typeStr, (*it)->type);
m_cpu->FormatAddress(addrStr, (*it)->addr, true, (m_analyseCode ? LFAll : LFNone));
if (!(*it)->GetInfo(infoStr))
{
infoStr[0] = '-';
infoStr[1] = '\0';
}
Print(" %-3u %-8s %-12s %-20s\n", (*it)->num, typeStr, addrStr, infoStr);
}
}
void CConsoleDebugger::ListMonitors()
{
Print("%s Register Monitors:\n", m_cpu->name);
if (m_cpu->regMons.size() == 0)
{
Print(" None\n");
return;
}
char valStr[255];
int num = 0;
for (vector<CRegMonitor*>::iterator it = m_cpu->regMons.begin(); it != m_cpu->regMons.end(); it++)
{
(*it)->GetBeforeValue(valStr);
Print(" %d - %s change from: %s\n", num++, (*it)->reg->name, valStr);
}
}
UINT32 CConsoleDebugger::ListDisassembly(UINT32 start, UINT32 end, unsigned numInstrs)
{
UINT32 addr;
char startStr[20];
char endStr[20];
char opCodes[50];
char mnemonic[100];
char operands[155];
char addrStr[20];
char labelStr[13];
unsigned instr;
UINT32 pc = m_cpu->pc;
CCodeAnalyser *analyser = (m_analyseCode ? m_cpu->GetCodeAnalyser() : NULL);
// Align address to instruction boundary
start -= start%m_cpu->minInstrLen;
if (analyser != NULL)
{
// Use code analyser to find valid start address
if (!analyser->analysis->GetNextValidAddr(start))
return start;
}
else
{
// In the absence of code analyser, try to align code with current PC address
if (m_cpu->instrCount > 0 && pc >= start && pc <= end)
{
UINT64 count = m_cpu->instrCount;
while (start < end && count-- > 0)
{
bool okay = false;
addr = start;
instr = 0;
while (addr < end && instr < numInstrs)
{
if (addr == pc)
{
okay = true;
break;
}
int codesLen = m_cpu->GetOpLength(addr);
addr += abs(codesLen);
instr++;
}
if (okay)
break;
start += m_cpu->minInstrLen;
}
}
}
// Get true end address
addr = start;
instr = 0;
while (addr < end && instr < numInstrs)
{
// Get instruction length
int codesLen = m_cpu->Disassemble(addr, mnemonic, operands);
// Move onto next valid instruction address
addr += abs(codesLen);
if (analyser != NULL && !analyser->analysis->GetNextValidAddr(addr))
break;
instr++;
}
end = addr;
// Format start and end addresses and output title
m_cpu->FormatAddress(startStr, start);
m_cpu->FormatAddress(endStr, end);
Print("%s Code %s - %s:\n", m_cpu->name, startStr, endStr);
// Output the disassembly
addr = start;
instr = 0;
while (addr < end)
{
// Add markers for current PC address and any breakpoints
char ind[4];
if (m_cpu->instrCount > 0 && addr == pc)
{
ind[0] = '>';
ind[1] = '>';
}
else
{
ind[0] = ' ';
ind[1] = ' ';
}
CBreakpoint *bp = m_cpu->GetBreakpoint(addr);
ind[2] = (bp != NULL ? bp->symbol : ' ');
ind[3] = '\0';
// Format current address
m_cpu->FormatAddress(addrStr, addr);
// Get labels at address (if any)
bool hasLabel = GetLabelText(labelStr, 12, addr);
// Get mnemonic, operands and instruction length and print them
int codesLen = m_cpu->Disassemble(addr, mnemonic, operands);
FormatOpCodes(opCodes, addr, abs(codesLen));
// Get comment at address (if any)
CComment *comment = m_cpu->GetComment(addr);
// Output line
Print("%s", ind);
if (m_showLabels)
{
if (m_labelsOverAddr)
Print("%-12s ", (hasLabel ? labelStr : addrStr));
else
Print("%s %-12s ", addrStr, labelStr);
}
else
Print("%s ", addrStr);
if (m_showOpCodes)
Print("[%s] ", opCodes);
if (codesLen > 0)
Print("%-*s %-20s", (int)m_cpu->maxMnemLen, mnemonic, operands);
else
Print("???");
if (comment != NULL)
Print(" ; %s", comment->text);
Print("\n");
// Move onto next valid instruction address
addr += abs(codesLen);
if (analyser != NULL && !analyser->analysis->GetNextValidAddr(addr))
break;
}
return end;
}
UINT32 CConsoleDebugger::ListMemory(UINT32 start, UINT32 end, unsigned bytesPerRow)
{
char startStr[255];
char endStr[255];
char addrStr[20];
char labelStr[13];
char wChar, dChar;
UINT8 data;
// Adjust start/end points to be on row boundary
start -= (start % bytesPerRow);
end += bytesPerRow - (end % bytesPerRow);
// Format start and end addresses and output title
m_cpu->FormatAddress(startStr, start);
m_cpu->FormatAddress(endStr, end);
Print("%s Memory %s - %s:\n", m_cpu->name, startStr, endStr);
UINT32 addr = start;
while (addr < end)
{
// TODO - check address going out of region or out of range
// Format current address
m_cpu->FormatAddress(addrStr, addr);
// Get labels at address (if any)
bool hasLabel = GetLabelText(labelStr, 12, addr);
// Output line
if (m_showLabels)
{
if (m_labelsOverAddr)
Print(" %-12s", (hasLabel ? labelStr : addrStr));
else
Print(" %s %-12s", addrStr, labelStr);
}
else
Print(" %s%c", addrStr);
UINT32 lAddr = addr;
for (unsigned i = 0; i < bytesPerRow; i++)
{
CWatch *watch = m_cpu->GetMemWatch(lAddr, 1);
// TODO - handling of mapped I/O
//CMappedIO *io = m_cpu->GetMappedIO(lAddr);
wChar = (watch != NULL ? watch->symbol : ' ');
//if (io != NULL)
// data = (UINT8)io->last;
//else
data = (UINT8)m_cpu->ReadMem(lAddr, 1);
Print("%c%02X", wChar, data);
lAddr++;
}
Print(" ");
lAddr = addr;
for (unsigned i = 0; i < bytesPerRow; i++)
{
// TODO - handling of mapped I/O
//CMappedIO *io = m_cpu->GetMappedIO(lAddr);
//if (io != NULL)
// data = io->last;
//else
data = (UINT8)m_cpu->ReadMem(lAddr, 1);
dChar = (data >= 32 && data <= 126 ? (char)data : '.');
Print("%c", dChar);
lAddr++;
}
Print("\n");
addr += bytesPerRow;
}
return addr;
}
void CConsoleDebugger::AnalysisUpdated(CCodeAnalyser *analyser)
{
//
}
void CConsoleDebugger::ExceptionTrapped(CException *ex)
{
PrintEvent(ex->cpu, "Exception %s (%s) trapped.\n", ex->id, ex->name);
}
void CConsoleDebugger::InterruptTrapped(CInterrupt *in)
{
PrintEvent(in->cpu, "Interrupt %s (%s) trapped.\n", in->id, in->name);
}
void CConsoleDebugger::MemWatchTriggered(CWatch *watch, UINT32 addr, unsigned dataSize, UINT64 data, bool isRead)
{
const char *sizeStr = GetDataSizeStr(dataSize, true);
const char *rwStr = (isRead ? "Read from" : "Write to");
char dataStr[50];
char addrStr[255];
m_cpu->FormatData(dataStr, dataSize, data);
watch->cpu->FormatAddress(addrStr, addr, true);
int num = GetIndexOfMemWatch(watch);
PrintEvent(watch->cpu, "%s %s (%s.%s) triggered memory watch #%d.\n", rwStr, addrStr, dataStr, sizeStr, num);
}
void CConsoleDebugger::IOWatchTriggered(CWatch *watch, CIO *io, UINT64 data, bool isInput)
{
const char *sizeStr = GetDataSizeStr(io->dataSize, true);
const char *ioStr = (isInput ? "Input from" : "Output to");
char dataStr[50];
char locStr[255];
m_cpu->FormatData(dataStr, io->dataSize, data);
watch->io->GetLocation(locStr);
int num = GetIndexOfPortWatch(watch);
if (num >= 0)
PrintEvent(watch->cpu, "%s %s (%s.%s) triggered port watch #%d.\n", ioStr, locStr, dataStr, sizeStr, num);
else
{
num = GetIndexOfMemWatch(watch);
PrintEvent(watch->cpu, "%s %s (%s.%s) triggered memory watch #%d.\n", ioStr, locStr, dataStr, sizeStr, num);
}
}
void CConsoleDebugger::BreakpointReached(CBreakpoint *bp)
{
PrintEvent(bp->cpu, "Breakpoint #%d triggered.\n", bp->num);
}
void CConsoleDebugger::MonitorTriggered(CRegMonitor *regMon)
{
char valStr[255];
CRegister *reg = regMon->reg;
reg->GetValue(valStr);
PrintEvent(reg->cpu, "Write to register %s (%s) triggered monitor.\n", reg->name, valStr);
}
void CConsoleDebugger::ExecutionHalted(CCPUDebug *cpu, EHaltReason reason)
{
if (reason&HaltUser)
PrintEvent(cpu, "Execution halted.\n");
}
void CConsoleDebugger::Log(CCPUDebug *cpu, const char *typeStr, const char *fmtStr, va_list vl)
{
if (cpu != NULL)
{
char pcStr[255];
cpu->FormatAddress(pcStr, cpu->pc, true, LFNone);
Print("%s @ %s: ", cpu->name, pcStr);
}
if (typeStr != NULL)
Print(" %s - ", typeStr);
PrintVL(fmtStr, vl);
}
void CConsoleDebugger::Attach()
{
CDebugger::Attach();
ApplyConfig();
Attached();
}
void CConsoleDebugger::Detach()
{
Detaching();
CDebugger::Detach();
// Close redirected output file, if exists
if (m_file != NULL)
{
fclose(m_file);
m_file = NULL;
}
}
void CConsoleDebugger::Poll()
{
CDebugger::Poll();
if (m_nextFrame)
{
if (--m_nextFrameCount == 0)
ForceBreak(true);
}
}
void CConsoleDebugger::ApplyConfig()
{
for (vector<CCPUDebug*>::iterator it = cpus.begin(); it != cpus.end(); it++)
{
(*it)->addrFmt = m_addrFmt;
(*it)->portFmt = m_portFmt;
(*it)->dataFmt = m_dataFmt;
}
}
void CConsoleDebugger::Attached()
{
//
}
void CConsoleDebugger::Detaching()
{
//
}
}
#endif // SUPERMODEL_DEBUGGER