vgturtle127's Beautification 14 - Source\Project64-video directory and final cleanup

This commit is contained in:
zilmar 2021-05-18 21:21:36 +09:30
parent d6bf03bf20
commit ee864797ab
277 changed files with 5770 additions and 5859 deletions

View File

@ -40,7 +40,7 @@ void JavaBridge::GfxThreadDone()
JNIEnv *env = Android_JNI_GetEnv();
if (g_GLThread != NULL && env != NULL)
{
WriteTrace(TraceUserInterface, TraceDebug, "calling java GLThread::ThreadExiting");
WriteTrace(TraceUserInterface, TraceDebug, "Calling java GLThread::ThreadExiting");
jclass GLThreadClass = env->GetObjectClass(g_GLThread);
jmethodID midThreadExiting = env->GetMethodID(GLThreadClass, "ThreadExiting", "()V");
env->CallVoidMethod(g_GLThread, midThreadExiting);

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@ -16,7 +16,7 @@ public:
void GfxThreadDone();
void SwapWindow();
// ROM List
// ROM list
void RomListReset(void);
void RomListAddItem(const char * FullFileName, const char * FileName, const char * GoodName, uint32_t TextColor);
void RomListLoaded(void);

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@ -125,7 +125,7 @@ void CNotificationImp::BreakPoint(const char * FileName, int32_t LineNumber)
}
else
{
FatalError("Fatal Error: Emulation stopped");
FatalError("Fatal error: emulation stopped");
}
}

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@ -210,7 +210,7 @@ void AddRecentRom(const char * ImagePath)
if (g_JavaBridge)
{
WriteTrace(TraceUserInterface, TraceDebug, "calling RecentRomsUpdated");
WriteTrace(TraceUserInterface, TraceDebug, "Calling RecentRomsUpdated");
g_JavaBridge->RecentRomsUpdated();
}
WriteTrace(TraceUserInterface, TraceDebug, "Done");
@ -220,7 +220,7 @@ void GameCpuRunning(void * /*NotUsed*/)
{
WriteTrace(TraceUserInterface, TraceDebug, "Start");
bool Running = g_Settings->LoadBool(GameRunning_CPU_Running);
WriteTrace(TraceUserInterface, TraceDebug, Running ? "Game Started" : "Game Stopped");
WriteTrace(TraceUserInterface, TraceDebug, Running ? "Game started" : "Game stopped");
JNIEnv *env = Android_JNI_GetEnv();
if (Running)
{
@ -232,7 +232,7 @@ void GameCpuRunning(void * /*NotUsed*/)
g_System->RefreshGameSettings();
int RunCount = UISettingsLoadDword(Game_RunCount);
WriteTrace(TraceUserInterface, TraceDebug, "Setting Run Count to %d", RunCount + 1);
WriteTrace(TraceUserInterface, TraceDebug, "Setting run count to %d", RunCount + 1);
UISettingsSaveDword(Game_RunCount, RunCount + 1);
if (env != NULL)
{
@ -265,12 +265,12 @@ void GameCpuRunning(void * /*NotUsed*/)
WriteTrace(TraceUserInterface, TraceError, "No Java bridge");
}
// call in to java that emulation done
// Call in to java that emulation done
WriteTrace(TraceUserInterface, TraceDebug, "Clean up global activity");
env->DeleteGlobalRef(g_Activity);
g_Activity = NULL;
WriteTrace(TraceUserInterface, TraceDebug, "Clean up global gl thread");
WriteTrace(TraceUserInterface, TraceDebug, "Clean up global GL thread");
if (g_JavaBridge)
{
g_JavaBridge->GfxThreadDone();
@ -300,7 +300,7 @@ EXPORT jboolean CALL Java_emu_project64_jni_NativeExports_appInit(JNIEnv* env, j
Notify().DisplayMessage(10, " / ____/ / / /_/ / / / __/ /__/ /_/ /_/ /__ __/");
Notify().DisplayMessage(10, "/_/ /_/ \\____/_/ /\\___/\\___/\\__/\\____/ /_/");
Notify().DisplayMessage(10, " /___/");
Notify().DisplayMessage(10, "http://www.pj64-emu.com/");
Notify().DisplayMessage(10, "https://www.pj64-emu.com/");
Notify().DisplayMessage(10, stdstr_f("%s Version %s", VER_FILE_DESCRIPTION_STR, VER_FILE_VERSION_STR).c_str());
Notify().DisplayMessage(10, "");

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@ -89,8 +89,8 @@ typedef struct
Function: CloseDLL
Purpose: This function is called when the emulator is closing
down allowing the DLL to de-initialize.
input: none
output: none
Input: None
Output: None
*/
EXPORT void CALL CloseDLL(void);
@ -99,15 +99,15 @@ EXPORT void CALL CloseDLL(void);
Function: ControllerCommand
Purpose: To process the raw data that has just been sent to a
specific controller.
input: - Controller Number (0 to 3) and -1 signaling end of
Input: Controller Number (0 to 3) and -1 signaling end of
processing the PIF RAM.
- Pointer of data to be processed.
output: none
Output: None
note: This function is only needed if the DLL is allowing raw
Note: This function is only needed if the DLL is allowing raw
data, or the plugin is set to raw
the data that is being processed looks like this:
The data that is being processed looks like this:
initialize controller: 01 03 00 FF FF FF
read controller: 01 04 01 FF FF FF FF
*/
@ -118,8 +118,8 @@ EXPORT void CALL ControllerCommand(int Control, uint8_t * Command);
Function: DllAbout
Purpose: This function is optional function that is provided
to give further information about the DLL.
input: a handle to the window that calls this function
output: none
Input: A handle to the window that calls this function
Output: None
*/
EXPORT void CALL DllAbout(void * hParent);
@ -128,8 +128,8 @@ EXPORT void CALL DllAbout(void * hParent);
Function: DllConfig
Purpose: This function is optional function that is provided
to allow the user to configure the DLL
input: a handle to the window that calls this function
output: none
Input: A handle to the window that calls this function
Output: None
*/
EXPORT void CALL DllConfig(void * hParent);
@ -138,8 +138,8 @@ EXPORT void CALL DllConfig(void * hParent);
Function: DllTest
Purpose: This function is optional function that is provided
to allow the user to test the DLL
input: a handle to the window that calls this function
output: none
Input: A handle to the window that calls this function
Output: None
*/
EXPORT void CALL DllTest(void * hParent);
@ -148,9 +148,9 @@ EXPORT void CALL DllTest(void * hParent);
Function: GetDllInfo
Purpose: This function allows the emulator to gather information
about the DLL by filling in the PluginInfo structure.
input: a pointer to a PLUGIN_INFO structure that needs to be
filled by the function. (see def above)
output: none
Input: A pointer to a PLUGIN_INFO structure that needs to be
filled by the function (see def above)
Output: None
*/
EXPORT void CALL GetDllInfo(PLUGIN_INFO * PluginInfo);
@ -158,10 +158,10 @@ EXPORT void CALL GetDllInfo(PLUGIN_INFO * PluginInfo);
/*
Function: GetKeys
Purpose: To get the current state of the controllers buttons.
input: - Controller Number (0 to 3)
Input: Controller Number (0 to 3)
- A pointer to a BUTTONS structure to be filled with
the controller state.
output: none
Output: None
*/
EXPORT void CALL GetKeys(int32_t Control, BUTTONS * Keys);
@ -170,10 +170,10 @@ EXPORT void CALL GetKeys(int32_t Control, BUTTONS * Keys);
Function: InitiateControllers
Purpose: This function initializes how each of the controllers
should be handled.
input: - The handle to the main window.
Input: - The handle to the main window.
- A controller structure that needs to be filled for
the emulator to know how to handle each controller.
output: none
Output: None
*/
EXPORT void CALL InitiateControllers(CONTROL_INFO ControlInfo);
@ -182,11 +182,11 @@ EXPORT void CALL InitiateControllers(CONTROL_INFO ControlInfo);
Function: ReadController
Purpose: To process the raw data in the PIF RAM that is about to
be read.
input: - Controller Number (0 to 3) and -1 signaling end of
Input: Controller Number (0 to 3) and -1 signaling end of
processing the PIF RAM.
- Pointer of data to be processed.
output: none
note: This function is only needed if the DLL is allowing raw
Output: None
Note: This function is only needed if the DLL is allowing raw
data.
*/
@ -195,18 +195,18 @@ EXPORT void CALL ReadController(int Control, uint8_t * Command);
/*
Function: RomClosed
Purpose: This function is called when a ROM is closed.
input: none
output: none
Input: None
Output: None
*/
EXPORT void CALL RomClosed(void);
/*
Function: RomOpen
Purpose: This function is called when a ROM is open. (from the
Purpose: This function is called when a ROM is open (from the
emulation thread)
input: none
output: none
Input: None
Output: None
*/
EXPORT void CALL RomOpen(void);
@ -215,8 +215,8 @@ EXPORT void CALL RomOpen(void);
Function: WM_KeyDown
Purpose: To pass the WM_KeyDown message from the emulator to the
plugin.
input: wParam and lParam of the WM_KEYDOWN message.
output: none
Input: wParam and lParam of the WM_KEYDOWN message.
Output: None
*/
EXPORT void CALL WM_KeyDown(uint32_t wParam, uint32_t lParam);
@ -225,8 +225,8 @@ EXPORT void CALL WM_KeyDown(uint32_t wParam, uint32_t lParam);
Function: WM_KeyUp
Purpose: To pass the WM_KEYUP message from the emulator to the
plugin.
input: wParam and lParam of the WM_KEYDOWN message.
output: none
Input: wParam and lParam of the WM_KEYDOWN message.
Output: None
*/
EXPORT void CALL WM_KeyUp(uint32_t wParam, uint32_t lParam);

View File

@ -12,46 +12,46 @@ BUTTONS g_buttons;
void ShowAboutWindow (void * hParent);
/******************************************************************
/*
Function: CloseDLL
Purpose: This function is called when the emulator is closing
down allowing the DLL to de-initialize.
input: none
output: none
*******************************************************************/
Input: None
Output: None
*/
EXPORT void CALL CloseDLL (void)
{
}
/******************************************************************
/*
Function: ControllerCommand
Purpose: To process the raw data that has just been sent to a
specific controller.
input: - Controller Number (0 to 3) and -1 signaling end of
Input: Controller Number (0 to 3) and -1 signaling end of
processing the PIF RAM.
- Pointer of data to be processed.
output: none
Output: None
note: This function is only needed if the DLL is allowing raw
Note: This function is only needed if the DLL is allowing raw
data, or the plugin is set to raw
the data that is being processed looks like this:
initialize controller: 01 03 00 FF FF FF
read controller: 01 04 01 FF FF FF FF
*******************************************************************/
The data that is being processed looks like this:
Initialize controller: 01 03 00 FF FF FF
Read controller: 01 04 01 FF FF FF FF
*/
EXPORT void CALL ControllerCommand ( int /*Control*/, uint8_t * /*Command*/)
{
}
/******************************************************************
/*
Function: DllAbout
Purpose: This function is optional function that is provided
to give further information about the DLL.
input: a handle to the window that calls this function
output: none
*******************************************************************/
Input: A handle to the window that calls this function
Output: None
*/
EXPORT void CALL DllAbout ( void * hParent )
{
@ -60,38 +60,38 @@ EXPORT void CALL DllAbout ( void * hParent )
#endif
}
/******************************************************************
/*
Function: DllConfig
Purpose: This function is optional function that is provided
to allow the user to configure the DLL
input: a handle to the window that calls this function
output: none
*******************************************************************/
Input: A handle to the window that calls this function
Output: None
*/
EXPORT void CALL DllConfig ( void * /*hParent*/ )
{
}
/******************************************************************
/*
Function: DllTest
Purpose: This function is optional function that is provided
to allow the user to test the DLL
input: a handle to the window that calls this function
output: none
*******************************************************************/
Input: A handle to the window that calls this function
Output: None
*/
EXPORT void CALL DllTest ( void * /*hParent*/ )
{
}
/******************************************************************
/*
Function: GetDllInfo
Purpose: This function allows the emulator to gather information
about the DLL by filling in the PluginInfo structure.
input: a pointer to a PLUGIN_INFO structure that needs to be
Input: A pointer to a PLUGIN_INFO structure that needs to be
filled by the function. (see def above)
output: none
*******************************************************************/
Output: None
*/
EXPORT void CALL GetDllInfo ( PLUGIN_INFO * PluginInfo )
{
@ -104,14 +104,14 @@ EXPORT void CALL GetDllInfo ( PLUGIN_INFO * PluginInfo )
#endif
}
/******************************************************************
/*
Function: GetKeys
Purpose: To get the current state of the controllers buttons.
input: - Controller Number (0 to 3)
Input: Controller Number (0 to 3)
- A pointer to a BUTTONS structure to be filled with
the controller state.
output: none
*******************************************************************/
Output: None
*/
EXPORT void CALL GetKeys(int Control, BUTTONS * Keys )
{
@ -121,15 +121,15 @@ EXPORT void CALL GetKeys(int Control, BUTTONS * Keys )
}
}
/******************************************************************
/*
Function: InitiateControllers
Purpose: This function initializes how each of the controllers
should be handled.
input: - The handle to the main window.
Input: The handle to the main window.
- A controller structure that needs to be filled for
the emulator to know how to handle each controller.
output: none
*******************************************************************/
Output: None
*/
EXPORT void CALL InitiateControllers (CONTROL_INFO ControlInfo)
{
@ -138,65 +138,65 @@ EXPORT void CALL InitiateControllers (CONTROL_INFO ControlInfo)
g_control_info.Controls[0].Plugin = PLUGIN_MEMPAK;
}
/******************************************************************
/*
Function: ReadController
Purpose: To process the raw data in the PIF RAM that is about to
be read.
input: - Controller Number (0 to 3) and -1 signaling end of
Input: Controller Number (0 to 3) and -1 signaling end of
processing the PIF RAM.
- Pointer of data to be processed.
output: none
note: This function is only needed if the DLL is allowing raw
Output: None
Note: This function is only needed if the DLL is allowing raw
data.
*******************************************************************/
*/
EXPORT void CALL ReadController ( int /*Control*/, uint8_t * /*Command*/ )
{
}
/******************************************************************
/*
Function: RomClosed
Purpose: This function is called when a ROM is closed.
input: none
output: none
*******************************************************************/
Input: None
Output: None
*/
EXPORT void CALL RomClosed (void)
{
}
/******************************************************************
/*
Function: RomOpen
Purpose: This function is called when a ROM is open. (from the
Purpose: This function is called when a ROM is open (from the
emulation thread)
input: none
output: none
*******************************************************************/
Input: None
Output: None
*/
EXPORT void CALL RomOpen (void)
{
memset(&g_buttons, 0, sizeof(g_buttons));
}
/******************************************************************
/*
Function: WM_KeyDown
Purpose: To pass the WM_KeyDown message from the emulator to the
plugin.
input: wParam and lParam of the WM_KEYDOWN message.
output: none
*******************************************************************/
Input: wParam and lParam of the WM_KEYDOWN message.
Output: None
*/
EXPORT void CALL WM_KeyDown( uint32_t /*wParam*/, uint32_t /*lParam*/ )
{
}
/******************************************************************
/*
Function: WM_KeyUp
Purpose: To pass the WM_KEYUP message from the emulator to the
plugin.
input: wParam and lParam of the WM_KEYDOWN message.
output: none
*******************************************************************/
Input: wParam and lParam of the WM_KEYDOWN message.
Output: None
*/
EXPORT void CALL WM_KeyUp( uint32_t /*wParam*/, uint32_t /*lParam*/ )
{

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@ -5,6 +5,6 @@
void ShowAboutWindow (void * hParent)
{
#ifdef _WIN32
MessageBox((HWND)hParent,L"Android Input Plugin",L"Dll About",MB_OK);
MessageBox((HWND)hParent,L"Android input plugin",L"Dll About",MB_OK);
#endif
}

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@ -1,5 +1,5 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64
// Copyright(C) 2014 Bobby Smiles
// Copyright(C) 2009 Richard Goedeken
@ -286,7 +286,7 @@ void alist_envmix_exp( CHle * hle, bool init, bool aux, uint16_t dmem_dl, uint16
ramps[1].value = *(int32_t *)(save_buffer + 18); // 14-15
}
// init which ensure ramp.step != 0 iff ramp.value == ramp.target
// Initialize which ensure ramp.step != 0 iff ramp.value == ramp.target
ramps[0].step = ramps[0].target - ramps[0].value;
ramps[1].step = ramps[1].target - ramps[1].value;

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@ -1,5 +1,5 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64
// Copyright(C) 2014 Bobby Smiles
// GNU/GPLv2 licensed: https://gnu.org/licenses/gpl-2.0.html

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@ -1,5 +1,5 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64
// Copyright(C) 2014 Bobby Smiles
// Copyright(C) 2009 Richard Goedeken

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@ -1,5 +1,5 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64
// Copyright(C) 2014 Bobby Smiles
// Copyright(C) 2009 Richard Goedeken

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@ -1,5 +1,5 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64
// Copyright(C) 2014 Bobby Smiles
// Copyright(C) 2009 Richard Goedeken
@ -284,12 +284,12 @@ static void FILTER(CHle * hle, uint32_t w1, uint32_t w2)
if (flags > 1) {
hle->alist_nead().filter_count = w1;
hle->alist_nead().filter_lut_address[0] = address; // t6
hle->alist_nead().filter_lut_address[0] = address; // T6
}
else {
uint16_t dmem = w1;
hle->alist_nead().filter_lut_address[1] = address + 0x10; // t5
hle->alist_nead().filter_lut_address[1] = address + 0x10; // T5
alist_filter(hle, dmem, hle->alist_nead().filter_count, address, hle->alist_nead().filter_lut_address);
}
}

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@ -1,5 +1,5 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64
// Copyright(C) 2014 Bobby Smiles
// GNU/GPLv2 licensed: https://gnu.org/licenses/gpl-2.0.html

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@ -1,5 +1,5 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64
// Copyright(C) 2014 Bobby Smiles
// GNU/GPLv2 licensed: https://gnu.org/licenses/gpl-2.0.html

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@ -1,5 +1,5 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64
// Copyright(C) 2014 Bobby Smiles
// GNU/GPLv2 licensed: https://gnu.org/licenses/gpl-2.0.html
@ -14,7 +14,7 @@ static inline int16_t adpcm_predict_sample(uint8_t byte, uint8_t mask,
unsigned lshift, unsigned rshift)
{
int16_t sample = (uint16_t)(byte & mask) << lshift;
sample >>= rshift; // signed
sample >>= rshift; // Signed
return sample;
}

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@ -1,5 +1,5 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64
// Copyright(C) 2012 Bobby Smiles
// Copyright(C) 2009 Richard Goedeken

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@ -1,5 +1,5 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64
// Copyright(C) 2014 Bobby Smiles
// Copyright(C) 2009 Richard Goedeken

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@ -1,5 +1,5 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64
// Copyright(C) 2012 Bobby Smiles
// Copyright(C) 2009 Richard Goedeken
@ -294,7 +294,7 @@ void CHle::normal_task_dispatching(void)
return;
}
WarnMessage("unknown OSTask: sum: %x PC:%x", sum, *m_sp_pc);
WarnMessage("Unknown OSTask: sum: %x PC:%x", sum, *m_sp_pc);
#ifdef ENABLE_TASK_DUMP
dump_unknown_task(this, sum);
#endif
@ -311,7 +311,7 @@ void CHle::non_task_dispatching(void)
return;
}
WarnMessage("unknown RSP code: sum: %x PC:%x", sum, *m_sp_pc);
WarnMessage("Unknown RSP code: sum: %x PC:%x", sum, *m_sp_pc);
#ifdef ENABLE_TASK_DUMP
dump_unknown_non_task(hle, sum);
#endif
@ -324,7 +324,7 @@ void CHle::non_task_dispatching(void)
void CHle::VerboseMessage(const char *message, ...)
{
#if defined(_WIN32) && defined(_DEBUG)
// These can get annoying.
// These can get annoying
#if 0
MessageBox(NULL, message, "HLE verbose message", MB_OK);
#endif

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@ -1,5 +1,5 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64
// Copyright(C) 2014 Bobby Smiles
// GNU/GPLv2 licensed: https://gnu.org/licenses/gpl-2.0.html
@ -13,59 +13,59 @@
enum
{
SP_CLR_HALT = 0x00001, /* Bit 0: Clear halt */
SP_SET_HALT = 0x00002, /* Bit 1: Set halt */
SP_CLR_BROKE = 0x00004, /* Bit 2: Clear broke */
SP_CLR_INTR = 0x00008, /* Bit 3: Clear INTR */
SP_SET_INTR = 0x00010, /* Bit 4: Set INTR */
SP_CLR_SSTEP = 0x00020, /* Bit 5: Clear SSTEP */
SP_SET_SSTEP = 0x00040, /* Bit 6: Set SSTEP */
SP_CLR_INTR_BREAK = 0x00080, /* Bit 7: Clear INTR on break */
SP_SET_INTR_BREAK = 0x00100, /* Bit 8: Set INTR on break */
SP_CLR_SIG0 = 0x00200, /* Bit 9: Clear signal 0 */
SP_SET_SIG0 = 0x00400, /* Bit 10: Set signal 0 */
SP_CLR_SIG1 = 0x00800, /* Bit 11: Clear signal 1 */
SP_SET_SIG1 = 0x01000, /* Bit 12: Set signal 1 */
SP_CLR_SIG2 = 0x02000, /* Bit 13: Clear signal 2 */
SP_SET_SIG2 = 0x04000, /* Bit 14: Set signal 2 */
SP_CLR_SIG3 = 0x08000, /* Bit 15: Clear signal 3 */
SP_SET_SIG3 = 0x10000, /* Bit 16: Set signal 3 */
SP_CLR_SIG4 = 0x20000, /* Bit 17: Clear signal 4 */
SP_SET_SIG4 = 0x40000, /* Bit 18: Set signal 4 */
SP_CLR_SIG5 = 0x80000, /* Bit 19: Clear signal 5 */
SP_SET_SIG5 = 0x100000, /* Bit 20: Set signal 5 */
SP_CLR_SIG6 = 0x200000, /* Bit 21: Clear signal 6 */
SP_SET_SIG6 = 0x400000, /* Bit 22: Set signal 6 */
SP_CLR_SIG7 = 0x800000, /* Bit 23: Clear signal 7 */
SP_SET_SIG7 = 0x1000000, /* Bit 24: Set signal 7 */
SP_CLR_HALT = 0x00001, // Bit 0: Clear halt
SP_SET_HALT = 0x00002, // Bit 1: Set halt
SP_CLR_BROKE = 0x00004, // Bit 2: Clear broke
SP_CLR_INTR = 0x00008, // Bit 3: Clear INTR
SP_SET_INTR = 0x00010, // Bit 4: Set INTR
SP_CLR_SSTEP = 0x00020, // Bit 5: Clear SSTEP
SP_SET_SSTEP = 0x00040, // Bit 6: Set SSTEP
SP_CLR_INTR_BREAK = 0x00080, // Bit 7: Clear INTR on break
SP_SET_INTR_BREAK = 0x00100, // Bit 8: Set INTR on break
SP_CLR_SIG0 = 0x00200, // Bit 9: Clear signal 0
SP_SET_SIG0 = 0x00400, // Bit 10: Set signal 0
SP_CLR_SIG1 = 0x00800, // Bit 11: Clear signal 1
SP_SET_SIG1 = 0x01000, // Bit 12: Set signal 1
SP_CLR_SIG2 = 0x02000, // Bit 13: Clear signal 2
SP_SET_SIG2 = 0x04000, // Bit 14: Set signal 2
SP_CLR_SIG3 = 0x08000, // Bit 15: Clear signal 3
SP_SET_SIG3 = 0x10000, // Bit 16: Set signal 3
SP_CLR_SIG4 = 0x20000, // Bit 17: Clear signal 4
SP_SET_SIG4 = 0x40000, // Bit 18: Set signal 4
SP_CLR_SIG5 = 0x80000, // Bit 19: Clear signal 5
SP_SET_SIG5 = 0x100000, // Bit 20: Set signal 5
SP_CLR_SIG6 = 0x200000, // Bit 21: Clear signal 6
SP_SET_SIG6 = 0x400000, // Bit 22: Set signal 6
SP_CLR_SIG7 = 0x800000, // Bit 23: Clear signal 7
SP_SET_SIG7 = 0x1000000, // Bit 24: Set signal 7
SP_STATUS_HALT = 0x001, /* Bit 0: Halt */
SP_STATUS_BROKE = 0x002, /* Bit 1: Broke */
SP_STATUS_DMA_BUSY = 0x004, /* Bit 2: DMA busy */
SP_STATUS_DMA_FULL = 0x008, /* Bit 3: DMA full */
SP_STATUS_IO_FULL = 0x010, /* Bit 4: IO full */
SP_STATUS_SSTEP = 0x020, /* Bit 5: Single step */
SP_STATUS_INTR_BREAK = 0x040, /* Bit 6: Interrupt on break */
SP_STATUS_SIG0 = 0x080, /* Bit 7: Signal 0 set */
SP_STATUS_SIG1 = 0x100, /* Bit 8: Signal 1 set */
SP_STATUS_SIG2 = 0x200, /* Bit 9: Signal 2 set */
SP_STATUS_SIG3 = 0x400, /* Bit 10: Signal 3 set */
SP_STATUS_SIG4 = 0x800, /* Bit 11: Signal 4 set */
SP_STATUS_SIG5 = 0x1000, /* Bit 12: Signal 5 set */
SP_STATUS_SIG6 = 0x2000, /* Bit 13: Signal 6 set */
SP_STATUS_SIG7 = 0x4000, /* Bit 14: Signal 7 set */
SP_STATUS_HALT = 0x001, // Bit 0: Halt
SP_STATUS_BROKE = 0x002, // Bit 1: Broke
SP_STATUS_DMA_BUSY = 0x004, // Bit 2: DMA busy
SP_STATUS_DMA_FULL = 0x008, // Bit 3: DMA full
SP_STATUS_IO_FULL = 0x010, // Bit 4: IO full
SP_STATUS_SSTEP = 0x020, // Bit 5: Single step
SP_STATUS_INTR_BREAK = 0x040, // Bit 6: Interrupt on break
SP_STATUS_SIG0 = 0x080, // Bit 7: Signal 0 set
SP_STATUS_SIG1 = 0x100, // Bit 8: Signal 1 set
SP_STATUS_SIG2 = 0x200, // Bit 9: Signal 2 set
SP_STATUS_SIG3 = 0x400, // Bit 10: Signal 3 set
SP_STATUS_SIG4 = 0x800, // Bit 11: Signal 4 set
SP_STATUS_SIG5 = 0x1000, // Bit 12: Signal 5 set
SP_STATUS_SIG6 = 0x2000, // Bit 13: Signal 6 set
SP_STATUS_SIG7 = 0x4000, // Bit 14: Signal 7 set
};
// MIPS interface flags
enum
{
MI_INTR_SP = 0x01, /* Bit 0: SP INTR */
MI_INTR_SI = 0x02, /* Bit 1: SI INTR */
MI_INTR_AI = 0x04, /* Bit 2: AI INTR */
MI_INTR_VI = 0x08, /* Bit 3: VI INTR */
MI_INTR_PI = 0x10, /* Bit 4: PI INTR */
MI_INTR_DP = 0x20, /* Bit 5: DP INTR */
MI_INTR_SP = 0x01, // Bit 0: SP INTR
MI_INTR_SI = 0x02, // Bit 1: SI INTR
MI_INTR_AI = 0x04, // Bit 2: AI INTR
MI_INTR_VI = 0x08, // Bit 3: VI INTR
MI_INTR_PI = 0x10, // Bit 4: PI INTR
MI_INTR_DP = 0x20, // Bit 5: DP INTR
};
class CHle

View File

@ -1,5 +1,5 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64
// Copyright(C) 2012 Bobby Smiles
// Copyright(C) 2009 Richard Goedeken
@ -373,7 +373,7 @@ static void decode_macroblock_ob(int16_t *macroblock, int32_t *y_dc, int32_t *u_
for (sb = 0; sb < 6; ++sb) {
int16_t tmp_sb[SUBBLOCK_SIZE];
// Update DC
// Update decode
int32_t dc = (int32_t)macroblock[0];
switch (sb) {
case 0:

View File

@ -19,8 +19,8 @@ BOOL WINAPI DllMain(void * hinst, DWORD /*fdwReason*/, LPVOID /*lpvReserved*/)
Function: CloseDLL
Purpose: This function is called when the emulator is closing
down allowing the DLL to de-initialize.
input: none
output: none
Input: None
Output: None
*/
void CloseDLL(void)
@ -36,8 +36,8 @@ void CloseDLL(void)
Function: DllAbout
Purpose: This function is optional function that is provided
to give further information about the DLL.
input: a handle to the window that calls this function
output: none
Input: A handle to the window that calls this function
Output: None
*/
void DllAbout(void * hParent)
@ -52,8 +52,8 @@ Function: DoRspCycles
Purpose: This function is to allow the RSP to run in parallel with
the r4300 switching control back to the r4300 once the
function ends.
input: The number of cycles that is meant to be executed
output: The number of cycles that was executed. This value can
Input: The number of cycles that is meant to be executed
Output: The number of cycles that was executed. This value can
be greater than the number of cycles that the RSP
should have performed.
(this value is ignored if the RSP is stopped)
@ -72,9 +72,9 @@ uint32_t DoRspCycles(uint32_t Cycles)
Function: GetDllInfo
Purpose: This function allows the emulator to gather information
about the DLL by filling in the PluginInfo structure.
input: a pointer to a PLUGIN_INFO structure that needs to be
Input: A pointer to a PLUGIN_INFO structure that needs to be
filled by the function. (see def above)
output: none
Output: None
*/
void GetDllInfo(PLUGIN_INFO * PluginInfo)
@ -95,11 +95,11 @@ Function: InitiateRSP
Purpose: This function is called when the DLL is started to give
information from the emulator that the N64 RSP
interface needs
input: Rsp_Info is passed to this function which is defined
Input: Rsp_Info is passed to this function which is defined
above.
CycleCount is the number of cycles between switching
control between the RSP and r4300i core.
output: none
Output: None
*/
void InitiateRSP(RSP_INFO Rsp_Info, uint32_t * /*CycleCount*/)
@ -114,9 +114,9 @@ void InitiateRSP(RSP_INFO Rsp_Info, uint32_t * /*CycleCount*/)
/*
Function: RomOpen
Purpose: This function is called when a ROM is opened.
input: none
output: none
Purpose: This function is called when a ROM is opened
Input: None
Output: None
*/
void RomOpen(void)
@ -125,9 +125,9 @@ void RomOpen(void)
/*
Function: RomClosed
Purpose: This function is called when a ROM is closed.
input: none
output: none
Purpose: This function is called when a ROM is closed
Input: None
Output: None
*/
void RomClosed(void)

View File

@ -1,5 +1,5 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64
// Copyright(C) 2012 Bobby Smiles
// GNU/GPLv2 licensed: https://gnu.org/licenses/gpl-2.0.html

View File

@ -1,5 +1,5 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64
// Copyright(C) 2014 Bobby Smiles
// GNU/GPLv2 licensed: https://gnu.org/licenses/gpl-2.0.html

View File

@ -1,5 +1,5 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64
// Copyright(C) 2014 Bobby Smiles
// Copyright(C) 2009 Richard Goedeken
@ -197,8 +197,8 @@ void mp3_task(CHle * hle, unsigned int index, uint32_t address)
uint32_t t4;// = (w1 & 0x1E);
// Initialization code
uint32_t readPtr; // s5
uint32_t writePtr; // s6
uint32_t readPtr; // S5
uint32_t writePtr; // S6
uint32_t tmp;
int cnt, cnt2;
@ -217,9 +217,9 @@ void mp3_task(CHle * hle, unsigned int index, uint32_t address)
{
// DMA: 0xCF0 <- RDRAM[s5] : 0x180
memcpy(hle->mp3_buffer() + 0xCF0, hle->dram() + readPtr, 0x180);
inPtr = 0xCF0; // s7
outPtr = 0xE70; // s3
// --------------- Inner Loop Start --------------------
inPtr = 0xCF0; // S7
outPtr = 0xE70; // S3
// Inner loop start
for (cnt2 = 0; cnt2 < 0x180; cnt2 += 0x40)
{
t6 &= 0xFFE0;
@ -234,7 +234,7 @@ void mp3_task(CHle * hle, unsigned int index, uint32_t address)
inPtr += 0x40;
outPtr += 0x40;
}
// --------------- Inner Loop End --------------------
// Inner loop end
memcpy(hle->dram() + writePtr, hle->mp3_buffer() + 0xe70, 0x180);
writePtr += 0x180;
readPtr += 0x180;
@ -326,7 +326,7 @@ static void InnerLoop(CHle * hle, uint32_t outPtr, uint32_t inPtr, uint32_t t6,
MP3AB0(v);
// Part 5 - 1-Wide Butterflies - 100% accurate but need SSVs!
// Part 5 - 1-wide butterflies - 100% accurate but need SSVs!
t0 = t6 + 0x100;
t1 = t6 + 0x200;
@ -485,7 +485,7 @@ static void InnerLoop(CHle * hle, uint32_t outPtr, uint32_t inPtr, uint32_t t6,
MP3AB0(v);
// Part 7: - 100% accurate + SSV - Unoptimized
// Part 7: - 100% accurate + SSV - unoptimized (TODO: optimize?)
v[0] = (v[17] + v[16]) >> 1;
v[1] = ((v[17] * (int)((short)0xA57E * 2)) + (v[16] * 0xB504)) >> 0x10;
@ -582,7 +582,7 @@ static void InnerLoop(CHle * hle, uint32_t outPtr, uint32_t inPtr, uint32_t t6,
v18 = v6 + v8;
// Clamp(v0);
// Clamp(v18);
// clamp???
// Clamp?
*(int16_t *)(hle->mp3_buffer() + (outPtr ^ S16)) = v0;
*(int16_t *)(hle->mp3_buffer() + ((outPtr + 2)^S16)) = v18;
outPtr += 4;
@ -643,7 +643,7 @@ static void InnerLoop(CHle * hle, uint32_t outPtr, uint32_t inPtr, uint32_t t6,
v18 = v6 + v8;
// Clamp(v0);
// Clamp(v18);
// clamp???
// Clamp?
*(int16_t *)(hle->mp3_buffer() + ((outPtr + 2)^S16)) = v0;
*(int16_t *)(hle->mp3_buffer() + ((outPtr + 4)^S16)) = v18;
outPtr += 4;

View File

@ -1,5 +1,5 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64
// Copyright(C) 2013 Bobby Smiles
// GNU/GPLv2 licensed: https://gnu.org/licenses/gpl-2.0.html
@ -252,7 +252,6 @@ void musyx_v2_task(CHle * hle)
if (ptr_10)
{
// TODO:
hle->WarnMessage("ptr_10=%08x mask_14=%02x ptr_24=%08x", ptr_10, mask_14, ptr_24);
}
@ -320,7 +319,7 @@ static void update_base_vol(CHle * hle, int32_t *base_vol,
hle->VerboseMessage("base_vol voice_mask = %08x", voice_mask);
hle->VerboseMessage("BEFORE: base_vol = %08x %08x %08x %08x", base_vol[0], base_vol[1], base_vol[2], base_vol[3]);
// optimization: skip voices contributions entirely if voice_mask is empty
// Optimization: skip voices contributions entirely if voice_mask is empty
if (voice_mask != 0)
{
for (i = 0, mask = 1; i < MAX_VOICES; ++i, mask <<= 1, last_sample_ptr += 8)
@ -337,7 +336,7 @@ static void update_base_vol(CHle * hle, int32_t *base_vol,
}
}
// optimization: skip contributions entirely if mask_15 is empty
// Optimization: skip contributions entirely if mask_15 is empty
if (mask_15 != 0)
{
for(i = 0, mask = 1; i < 4; ++i, mask <<= 1, ptr_24 += 8)
@ -846,7 +845,7 @@ static void interleave_stage_v1(CHle * hle, musyx_t *musyx, uint32_t output_ptr)
int16_t *right;
uint32_t *dst;
hle->VerboseMessage("interleave: %08x", output_ptr);
hle->VerboseMessage("Interleave: %08x", output_ptr);
base_left = clamp_s16(musyx->base_vol[0]);
base_right = clamp_s16(musyx->base_vol[1]);

View File

@ -1,5 +1,5 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64
// Copyright(C) 2014 Bobby Smiles
// GNU/GPLv2 licensed: https://gnu.org/licenses/gpl-2.0.html

View File

@ -72,10 +72,10 @@ private:
std::string m_CurrentSection;
bool m_CurrentSectionDirty;
int m_CurrentSectionFilePos; // Where in the file is the current section
int m_CurrentSectionFilePos;
KeyValueList m_CurrentSectionData;
long m_lastSectionSearch; // When scanning for a section, what was the last scanned POS
long m_lastSectionSearch;
bool m_ReadOnly;
bool m_InstantFlush;

View File

@ -141,7 +141,7 @@ uint32_t CThread::GetCurrentThreadId(void)
#ifdef _WIN32
return ::GetCurrentThreadId();
#elif defined(SYS_gettid) || defined(__NR_gettid)
return syscall(__NR_gettid); /* GLIBC has no implementation of gettid(). */
return syscall(__NR_gettid); // GLIBC has no implementation of gettid()
#else
return gettid();
#endif

View File

@ -207,7 +207,7 @@ CTraceFileLog::CTraceFileLog(const char * FileName, bool FlushFile, CLog::LOG_OP
m_hLogFile.SetTruncateFile(true);
if (dwMaxFileSize < 3 || dwMaxFileSize > 2047)
{ /* Clamp file size to 5 MB if it exceeds 2047 or falls short of 3. */
{ // Clamp file size to 5MB if it exceeds 2047 or falls short of 3
dwMaxFileSize = 5;
}
m_hLogFile.SetMaxFileSize((uint32_t)(dwMaxFileSize * MB));

View File

@ -53,7 +53,7 @@ bool pjutil::TerminatedExistingExe()
}
if (!AskedUser)
{
stdstr_f Message("%s currently running\n\nTerminate pid %d now?", ModuleName.c_str(), lppe.th32ProcessID);
stdstr_f Message("%s currently running\n\nTerminate PID %d now?", ModuleName.c_str(), lppe.th32ProcessID);
stdstr_f Caption("Terminate %s", ModuleName.c_str());
AskedUser = true;
@ -73,7 +73,7 @@ bool pjutil::TerminatedExistingExe()
}
else
{
stdstr_f Message("Failed to terminate pid %d", lppe.th32ProcessID);
stdstr_f Message("Failed to terminate PID %d", lppe.th32ProcessID);
stdstr_f Caption("Terminate %s failed!", ModuleName.c_str());
MessageBox(nullptr, Message.ToUTF16().c_str(), Caption.ToUTF16().c_str(), MB_YESNO | MB_ICONEXCLAMATION);
}

View File

@ -9,15 +9,15 @@ implied warranty of any kind.
The translator/ modifier does not claim (1) that MD5 will do what you think
it does; (2) that this translation/ modification is accurate; or (3) that
this software is "merchantable." (Language for this disclaimer partially
copied from the disclaimer below).
this software is "merchantable." (language for this disclaimer partially
copied from the disclaimer below)
based on:
MD5.H - header file for MD5C.C
MDDRIVER.C - test driver for MD2, MD4 and MD5
Copyright (C) 1991-2, RSA Data Security, Inc. Created 1991. All rights reserved.
Copyright (C) 1991-1992, RSA Data Security, Inc. Created 1991. All rights reserved.
License to copy and use this software is granted provided that it
is identified as the "RSA Data Security, Inc. MD5 Message-Digest
@ -59,7 +59,7 @@ MD5::~MD5()
void MD5::update(const uint1 *input, uint4 input_length)
{
uint4 input_index, buffer_index;
uint4 buffer_space; // How much space is left in the buffer
uint4 buffer_space;
if (finalized) // So we can't update!
{
@ -78,7 +78,7 @@ void MD5::update(const uint1 *input, uint4 input_length)
count[1] += ((uint4)input_length >> 29);
buffer_space = 64 - buffer_index; // How much space is left in the buffer
buffer_space = 64 - buffer_index;
// Transform as many times as possible
if (input_length >= buffer_space) // i.e. we have enough to fill the buffer
@ -93,11 +93,11 @@ void MD5::update(const uint1 *input, uint4 input_length)
transform((unsigned char *)(input + input_index));
}
buffer_index = 0; // So we can buffer remaining
buffer_index = 0;
}
else
{
input_index = 0; // So we can buffer the whole input
input_index = 0;
}
// Here we do the buffering:
@ -246,7 +246,7 @@ const char *MD5::hex_digest()
return m_hex_digest.c_str();
}
// PRIVATE METHODS:
// Private methods:
void MD5::init()
{

View File

@ -9,15 +9,15 @@ implied warranty of any kind.
The translator/ modifier does not claim (1) that MD5 will do what you think
it does; (2) that this translation/ modification is accurate; or (3) that
this software is "merchantable." (Language for this disclaimer partially
copied from the disclaimer below).
this software is "merchantable." (language for this disclaimer partially
copied from the disclaimer below)
based on:
MD5.H - header file for MD5C.C
MDDRIVER.C - test driver for MD2, MD4 and MD5
Copyright (C) 1991-2, RSA Data Security, Inc. Created 1991. All rights reserved.
Copyright (C) 1991-1992, RSA Data Security, Inc. Created 1991. All rights reserved.
License to copy and use this software is granted provided that it
is identified as the "RSA Data Security, Inc. MD5 Message-Digest

View File

@ -233,7 +233,7 @@ CPath& CPath::operator =(const std::string& strPath)
/*
Post: Converts path to string
Task: Convert path to string
Warning: because this pointer to string point in the data
Warning: Because this pointer to string point in the data
of this class, it is possible to cast the result of this
function in any non-constant pointer and alter the data.
Very dangerous!
@ -281,7 +281,7 @@ Task: Return the individual components of this path.
For any given argument, you can pass nullptr if you are not
interested in that component.
Do not rely on pNames being <= 8 characters, extensions
being <= 3 characters, or drives being 1 character
being <= 3 characters, or drives being 1 character.
*/
#ifdef _WIN32
@ -922,7 +922,7 @@ Task: To determine if the directory exists, we need to
create a test path with a wildcard (*.*) extension
and see if FindFirstFile returns anything. We don't
use CPath::FindFirst() because that routine parses out
'.' and '..', which fails for empty directories
'.' and '..', which fails for empty directories.
*/
bool CPath::DirectoryExists() const
@ -1041,10 +1041,10 @@ bool CPath::Delete(bool bEvenIfReadOnly) const
/*
Post: Return TRUE on success, false if there is such a target file
and we weren't granted permission to overwrite file or if we get an error
and we weren't granted permission to overwrite file or if we get an error.
Task: Copy file
Since ::CopyFile will not overwrite read-only files
we will make sure the target file is writable first
we will make sure the target file is writable first.
*/
bool CPath::CopyTo(const char * lpcszTargetFile, bool bOverwrite)
@ -1053,7 +1053,7 @@ bool CPath::CopyTo(const char * lpcszTargetFile, bool bOverwrite)
{
return false;
}
WriteTrace(TracePath, TraceDebug, "copy \"%s\" to \"%s\"",m_strPath.c_str(),lpcszTargetFile);
WriteTrace(TracePath, TraceDebug, "Copy \"%s\" to \"%s\"",m_strPath.c_str(),lpcszTargetFile);
#ifdef _WIN32
// Check if the target file exists
CPath TargetFile(lpcszTargetFile);
@ -1164,7 +1164,7 @@ bool CPath::CopyTo(const char * lpcszTargetFile, bool bOverwrite)
}
// Post: Return TRUE on success, false if there is such a target file
// and we weren't granted permission to overwrite file or get an error
// and we weren't granted permission to overwrite file or get an error.
// Task: Move file
bool CPath::MoveTo(const char * lpcszTargetFile, bool bOverwrite)
@ -1228,7 +1228,7 @@ These attributes do not follow a simple additive logic.
Note that FIND_ATTRIBUTE_FILES is 0x00, so it effectively cannot be
removed from the attribute set. You will therefore always
get normal files, and may also get Archive, Hidden, etc.
if you specify those attributes
if you specify those attributes.
See also: FindFirstFile, FindNextFile
*/
@ -1347,12 +1347,12 @@ bool CPath::FindNext()
strcmp(pEntry->d_name,"..") == 0 ||
!wildcmp(m_FindWildcard.c_str(),pEntry->d_name))
{
WriteTrace(TracePath, TraceVerbose, "continue, d_name = %s",pEntry->d_name);
WriteTrace(TracePath, TraceVerbose, "Continue, d_name = %s",pEntry->d_name);
continue;
}
if ((FIND_ATTRIBUTE_SUBDIR & dwFileAttributes) == FIND_ATTRIBUTE_SUBDIR)
{
WriteTrace(TracePath, TraceVerbose, "is dir");
WriteTrace(TracePath, TraceVerbose, "is a directory");
if (IsDirectory())
{
// Found a directory
@ -1366,7 +1366,7 @@ bool CPath::FindNext()
}
else
{
WriteTrace(TracePath, TraceVerbose, "is file");
WriteTrace(TracePath, TraceVerbose, "is a file");
// Found a file
if (IsDirectory())
{

View File

@ -1,5 +1,5 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64.
// Copyright(C) 2015 Gilles Siberlin
// Copyright(C) 2007-2009 Richard Goedeken

View File

@ -79,11 +79,11 @@ typedef struct
Function: AiDacrateChanged
Purpose: This function is called to notify the DLL that the
AiDacrate registers value has been changed.
input: The System type:
Input: The system type:
SYSTEM_NTSC 0
SYSTEM_PAL 1
SYSTEM_MPAL 2
output: none
Output: None
*/
EXPORT void CALL AiDacrateChanged(int32_t SystemType);
@ -92,8 +92,8 @@ EXPORT void CALL AiDacrateChanged(int32_t SystemType);
Function: AiLenChanged
Purpose: This function is called to notify the DLL that the
AiLen registers value has been changed.
input: none
output: none
Input: None
Output: None
*/
EXPORT void CALL AiLenChanged(void);
@ -102,8 +102,8 @@ EXPORT void CALL AiLenChanged(void);
Function: AiReadLength
Purpose: This function is called to allow the DLL to return the
value that AI_LEN_REG should equal
input: none
output: The amount of bytes still left to play.
Input: None
Output: The amount of bytes still left to play.
*/
EXPORT uint32_t CALL AiReadLength(void);
@ -116,9 +116,9 @@ go, copy more stuff to the buffer, anything you like).
The function is designed to go in to the message loop
of the main window...but can be placed anywhere you
like.
input: if Wait is set to true, then this function should wait
Input: If wait is set to true, then this function should wait
till there is a message in its message queue.
output: none
Output: None
*/
EXPORT void CALL AiUpdate(int32_t Wait);
@ -127,8 +127,8 @@ EXPORT void CALL AiUpdate(int32_t Wait);
Function: CloseDLL
Purpose: This function is called when the emulator is closing
down allowing the DLL to de-initialize.
input: none
output: none
Input: None
Output: None
*/
EXPORT void CALL CloseDLL(void);
@ -137,8 +137,8 @@ EXPORT void CALL CloseDLL(void);
Function: DllAbout
Purpose: This function is optional function that is provided
to give further information about the DLL.
input: a handle to the window that calls this function
output: none
Input: A handle to the window that calls this function.
Output: None
*/
EXPORT void CALL DllAbout(void * hParent);
@ -147,8 +147,8 @@ EXPORT void CALL DllAbout(void * hParent);
Function: DllConfig
Purpose: This function is optional function that is provided
to allow the user to configure the DLL
input: a handle to the window that calls this function
output: none
Input: A handle to the window that calls this function
Output: None
*/
EXPORT void CALL DllConfig(void * hParent);
@ -157,8 +157,8 @@ EXPORT void CALL DllConfig(void * hParent);
Function: DllTest
Purpose: This function is optional function that is provided
to allow the user to test the DLL
input: a handle to the window that calls this function
output: none
Input: A handle to the window that calls this function
Output: None
*/
EXPORT void CALL DllTest(void * hParent);
@ -167,9 +167,9 @@ EXPORT void CALL DllTest(void * hParent);
Function: GetDllInfo
Purpose: This function allows the emulator to gather information
about the DLL by filling in the PluginInfo structure.
input: a pointer to a PLUGIN_INFO structure that needs to be
Input: A pointer to a PLUGIN_INFO structure that needs to be
filled by the function. (see def above)
output: none
Output: None
*/
EXPORT void CALL GetDllInfo(PLUGIN_INFO * PluginInfo);
@ -181,10 +181,9 @@ information from the emulator that the N64 audio
interface needs
Input: Audio_Info is passed to this function which is defined
above.
Output: TRUE on success
Output: True on success
FALSE on failure to initialize
** Note on interrupts **:
Note on interrupts:
To generate an interrupt set the appropriate bit in MI_INTR_REG
and then call the function CheckInterrupts to tell the emulator
that there is a waiting interrupt.
@ -197,8 +196,8 @@ Function: ProcessAList
Purpose: This function is called when there is a Alist to be
processed. The DLL will have to work out all the info
about the AList itself.
input: none
output: none
Input: None
Output: None
*/
EXPORT void CALL ProcessAList(void);
@ -206,8 +205,8 @@ EXPORT void CALL ProcessAList(void);
/*
Function: RomClosed
Purpose: This function is called when a ROM is closed.
input: none
output: none
Input: None
Output: None
*/
EXPORT void CALL RomClosed(void);

View File

@ -1,5 +1,5 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64.
// Copyright(C) 2000-2015 Azimer
// GNU/GPLv2 licensed: https://gnu.org/licenses/gpl-2.0.html

View File

@ -1,5 +1,5 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64.
// Copyright(C) 2015 Gilles Siberlin
// Copyright(C) 2007 - 2009 Richard Goedeken
@ -45,7 +45,7 @@ enum { SECONDARY_BUFFER_NBR = 2 };
// This sets default frequency what is used if ROM doesn't want to change it.
// Probably only game that needs this is Zelda: Ocarina Of Time Master Quest
// TODO: We should try to find out why Demos' frequencies are always wrong
// They tend to rely on a default frequency, but apparently never the same one ;)
// They tend to rely on a default frequency, but apparently never the same one
enum { DEFAULT_FREQUENCY = 33600 };
@ -87,7 +87,7 @@ int g_OutputFreq = 44100;
bool g_critical_failure = false;
#ifdef ANDROID
// Thread Lock
// Thread lock
threadLock g_lock;
// Engine interfaces
@ -192,7 +192,7 @@ static void CloseAudio(void)
g_engineEngine = nullptr;
}
// Destroy thread Locks
// Destroy thread locks
pthread_cond_signal(&(g_lock.cond));
pthread_mutex_unlock(&(g_lock.mutex));
pthread_cond_destroy(&(g_lock.cond));
@ -379,7 +379,7 @@ void OpenSLESDriver::AI_SetFrequency(uint32_t freq, uint32_t BufferSize)
if (g_critical_failure)
{
WriteTrace(TraceAudioInitShutdown, TraceInfo, "Critical failure in setting up plugin, ignoring init...");
WriteTrace(TraceAudioInitShutdown, TraceInfo, "Critical failure in setting up plugin, ignoring initialization...");
WriteTrace(TraceAudioInitShutdown, TraceDebug, "Done");
return;
}
@ -437,7 +437,7 @@ void OpenSLESDriver::AI_SetFrequency(uint32_t freq, uint32_t BufferSize)
}
#ifdef ANDROID
// Create thread Locks to ensure synchronization between callback and processing code
// Create thread locks to ensure synchronization between callback and processing code
if (pthread_mutex_init(&(g_lock.mutex), (pthread_mutexattr_t*)nullptr) != 0)
{
WriteTrace(TraceAudioInitShutdown, TraceError, "pthread_mutex_init failed");

View File

@ -1,5 +1,5 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64.
// Copyright(C) 2015 Gilles Siberlin
// Copyright(C) 2007 - 2009 Richard Goedeken

View File

@ -1,5 +1,5 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64
// Copyright(C) 2000-2015 Azimer
// GNU/GPLv2 licensed: https://gnu.org/licenses/gpl-2.0.html
@ -119,7 +119,7 @@ void SoundDriverBase::LoadAiBuffer(uint8_t *start, uint32_t length)
bool DMAEnabled = (*g_AudioInfo.AI_CONTROL_REG & AI_CONTROL_DMA_ON) == AI_CONTROL_DMA_ON;
if (!DMAEnabled)
{
WriteTrace(TraceAudioDriver, TraceVerbose, "Return silence -- DMA is disabled");
WriteTrace(TraceAudioDriver, TraceVerbose, "Return silence - DMA is disabled");
memset(ptrStart, 0, bytesToMove);
return;
}

View File

@ -1,5 +1,5 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64
// Copyright(C) 2000-2015 Azimer
// GNU/GPLv2 licensed: https://gnu.org/licenses/gpl-2.0.html

View File

@ -196,7 +196,7 @@ static bool ParseCommand(int32_t argc, char **argv)
}
else
{
WriteTrace(TraceAppInit, TraceError, "not enough parameters for '%d: %s'", i, argv[i]);
WriteTrace(TraceAppInit, TraceError, "Not enough parameters for '%d: %s'", i, argv[i]);
return false;
}
}
@ -207,7 +207,7 @@ static bool ParseCommand(int32_t argc, char **argv)
}
else
{
WriteTrace(TraceAppInit, TraceError, "unrecognized command-line parameter '%d: %s'", i, argv[i]);
WriteTrace(TraceAppInit, TraceError, "Unrecognized command-line parameter '%d: %s'", i, argv[i]);
}
}
return false;
@ -222,17 +222,17 @@ bool AppInit(CNotification * Notify, const char * BaseDirectory, int argc, char
WriteTrace(TraceAppInit, TraceDebug, "Starting (BaseDirectory: %s)", BaseDirectory ? BaseDirectory : "null");
if (Notify == nullptr)
{
WriteTrace(TraceAppInit, TraceError, "No Notification class passed");
WriteTrace(TraceAppInit, TraceError, "No notification class passed");
return false;
}
WriteTrace(TraceAppInit, TraceDebug, "Settings up settings");
WriteTrace(TraceAppInit, TraceDebug, "Setting up settings");
g_Settings = new CSettings;
g_Settings->Initialize(BaseDirectory, AppName());
WriteTrace(TraceAppInit, TraceDebug, "Parse Commands");
WriteTrace(TraceAppInit, TraceDebug, "Parse commands");
if (!ParseCommand(argc, argv))
{
WriteTrace(TraceAppInit, TraceError, "Failed to Parse Commands, exiting now");
WriteTrace(TraceAppInit, TraceError, "Failed to parse commands, exiting now");
return false;
}
@ -254,33 +254,33 @@ bool AppInit(CNotification * Notify, const char * BaseDirectory, int argc, char
#else
if (!CMipsMemoryVM::SetupSegvHandler())
{
WriteTrace(TraceAppInit, TraceDebug, "Setup Segv Handler Failed");
WriteTrace(TraceAppInit, TraceDebug, "Setup SEGV handler failed");
return false;
}
#endif
g_Enhancements = new CEnhancements();
//Create the plugin container
WriteTrace(TraceAppInit, TraceInfo, "Create Plugins");
WriteTrace(TraceAppInit, TraceInfo, "Create plugins");
g_Plugins = new CPlugins(Directory_Plugin, false);
g_Lang = new CLanguage();
g_Lang->LoadCurrentStrings();
g_Notify->AppInitDone();
WriteTrace(TraceAppInit, TraceDebug, "Initialized Successfully");
WriteTrace(TraceAppInit, TraceDebug, "Initialized successfully");
return true;
}
catch (...)
{
g_Notify->DisplayError(stdstr_f("Exception caught\nFile: %s\nLine: %d", __FILE__, __LINE__).c_str());
WriteTrace(TraceAppInit, TraceError, "Exception caught, Init was not successfull");
WriteTrace(TraceAppInit, TraceError, "Exception caught, initialization was not successful");
return false;
}
}
void AppCleanup(void)
{
WriteTrace(TraceAppCleanup, TraceDebug, "cleaning up global objects");
WriteTrace(TraceAppCleanup, TraceDebug, "Cleaning up global objects");
CleanupTrace();
if (g_Enhancements) { delete g_Enhancements; g_Enhancements = nullptr; }

View File

@ -188,7 +188,7 @@ bool CMipsMemoryVM::FilterX86Exception(uint32_t MemAddress, X86_CONTEXT & contex
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to load byte\n\nMIPS Address: %08X\nX86 Address: %08X", MemAddress, (uint8_t *)*context.Eip).c_str());
g_Notify->DisplayError(stdstr_f("Failed to load byte\n\nMIPS address: %08X\nX86 address: %08X", MemAddress, (uint8_t *)*context.Eip).c_str());
}
}
*context.Eip = (uint32_t)ReadPos;
@ -198,7 +198,7 @@ bool CMipsMemoryVM::FilterX86Exception(uint32_t MemAddress, X86_CONTEXT & contex
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to load half word\n\nMIPS Address: %08X\nX86 Address: %08X", MemAddress, (uint8_t *)*context.Eip).c_str());
g_Notify->DisplayError(stdstr_f("Failed to load half word\n\nMIPS address: %08X\nX86 address: %08X", MemAddress, (uint8_t *)*context.Eip).c_str());
}
}
*context.Eip = (uint32_t)ReadPos;
@ -208,7 +208,7 @@ bool CMipsMemoryVM::FilterX86Exception(uint32_t MemAddress, X86_CONTEXT & contex
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to load byte\n\nMIPS Address: %08X\nX86 Address: %08X", MemAddress, (uint8_t *)*context.Eip).c_str());
g_Notify->DisplayError(stdstr_f("Failed to load byte\n\nMIPS address: %08X\nX86 address: %08X", MemAddress, (uint8_t *)*context.Eip).c_str());
}
}
*context.Eip = (uint32_t)ReadPos;
@ -218,7 +218,7 @@ bool CMipsMemoryVM::FilterX86Exception(uint32_t MemAddress, X86_CONTEXT & contex
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to load half word\n\nMIPS Address: %08X\nX86 Address: %08X", MemAddress, (uint8_t *)*context.Eip).c_str());
g_Notify->DisplayError(stdstr_f("Failed to load half word\n\nMIPS address: %08X\nX86 address: %08X", MemAddress, (uint8_t *)*context.Eip).c_str());
}
}
*context.Eip = (uint32_t)ReadPos;
@ -239,7 +239,7 @@ bool CMipsMemoryVM::FilterX86Exception(uint32_t MemAddress, X86_CONTEXT & contex
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to half word\n\nMIPS Address: %08X\nX86 Address: %08X", MemAddress, (uint8_t *)*context.Eip).c_str());
g_Notify->DisplayError(stdstr_f("Failed to half word\n\nMIPS address: %08X\nX86 address: %08X", MemAddress, (uint8_t *)*context.Eip).c_str());
}
}
*context.Eip = (uint32_t)ReadPos;
@ -249,7 +249,7 @@ bool CMipsMemoryVM::FilterX86Exception(uint32_t MemAddress, X86_CONTEXT & contex
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to store half word\n\nMIPS Address: %08X\nX86 Address: %08X", MemAddress,
g_Notify->DisplayError(stdstr_f("Failed to store half word\n\nMIPS address: %08X\nX86 address: %08X", MemAddress,
(uint8_t *)*context.Eip).c_str());
}
}
@ -268,7 +268,7 @@ bool CMipsMemoryVM::FilterX86Exception(uint32_t MemAddress, X86_CONTEXT & contex
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to store half word\n\nMIPS Address: %08X\nX86 Address: %08X", MemAddress, (uint8_t *)*context.Eip).c_str());
g_Notify->DisplayError(stdstr_f("Failed to store half word\n\nMIPS address: %08X\nX86 address: %08X", MemAddress, (uint8_t *)*context.Eip).c_str());
}
}
*context.Eip = (uint32_t)(ReadPos + 2);
@ -286,7 +286,7 @@ bool CMipsMemoryVM::FilterX86Exception(uint32_t MemAddress, X86_CONTEXT & contex
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to store byte\n\nMIPS Address: %08X\nX86 Address: %08X", MemAddress, (uint8_t *)*context.Eip).c_str());
g_Notify->DisplayError(stdstr_f("Failed to store byte\n\nMIPS address: %08X\nX86 address: %08X", MemAddress, (uint8_t *)*context.Eip).c_str());
}
}
*context.Eip = (uint32_t)ReadPos;
@ -296,7 +296,7 @@ bool CMipsMemoryVM::FilterX86Exception(uint32_t MemAddress, X86_CONTEXT & contex
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to load byte\n\nMIPS Address: %08X\nX86 Address: %08X", MemAddress, (uint8_t *)*context.Eip).c_str());
g_Notify->DisplayError(stdstr_f("Failed to load byte\n\nMIPS address: %08X\nX86 address: %08X", MemAddress, (uint8_t *)*context.Eip).c_str());
}
}
*context.Eip = (uint32_t)ReadPos;
@ -306,7 +306,7 @@ bool CMipsMemoryVM::FilterX86Exception(uint32_t MemAddress, X86_CONTEXT & contex
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to load word\n\nMIPS Address: %08X\nX86 Address: %08X", MemAddress, (uint8_t *)*context.Eip).c_str());
g_Notify->DisplayError(stdstr_f("Failed to load word\n\nMIPS address: %08X\nX86 address: %08X", MemAddress, (uint8_t *)*context.Eip).c_str());
}
}
*context.Eip = (uint32_t)ReadPos;
@ -316,7 +316,7 @@ bool CMipsMemoryVM::FilterX86Exception(uint32_t MemAddress, X86_CONTEXT & contex
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to store word\n\nMIPS Address: %08X\nX86 Address: %08X", MemAddress, (uint8_t *)*context.Eip).c_str());
g_Notify->DisplayError(stdstr_f("Failed to store word\n\nMIPS address: %08X\nX86 address: %08X", MemAddress, (uint8_t *)*context.Eip).c_str());
}
}
*context.Eip = (uint32_t)ReadPos;
@ -334,7 +334,7 @@ bool CMipsMemoryVM::FilterX86Exception(uint32_t MemAddress, X86_CONTEXT & contex
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to store byte\n\nMIPS Address: %08X\nX86 Address: %08X", MemAddress, (uint8_t *)*context.Eip).c_str());
g_Notify->DisplayError(stdstr_f("Failed to store byte\n\nMIPS address: %08X\nX86 address: %08X", MemAddress, (uint8_t *)*context.Eip).c_str());
}
}
*context.Eip = (uint32_t)(ReadPos + 1);
@ -352,7 +352,7 @@ bool CMipsMemoryVM::FilterX86Exception(uint32_t MemAddress, X86_CONTEXT & contex
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to store word\n\nMIPS Address: %08X\nX86 Address: %08X", MemAddress, (uint8_t *)*context.Eip).c_str());
g_Notify->DisplayError(stdstr_f("Failed to store word\n\nMIPS address: %08X\nX86 address: %08X", MemAddress, (uint8_t *)*context.Eip).c_str());
}
}
*context.Eip = (uint32_t)(ReadPos + 4);
@ -371,7 +371,7 @@ void CMipsMemoryVM::DumpArmExceptionInfo(uint32_t MemAddress, mcontext_t & conte
{
ArmThumbOpcode * OpCode = (ArmThumbOpcode *)context.arm_pc;
Arm32Opcode * OpCode32 = (Arm32Opcode *)context.arm_pc;
WriteTrace(TraceExceptionHandler, TraceError, "Program Counter 0x%lx", g_Reg->m_PROGRAM_COUNTER);
WriteTrace(TraceExceptionHandler, TraceError, "Program counter 0x%lx", g_Reg->m_PROGRAM_COUNTER);
for (int i = 0, n = (sizeof(g_BaseSystem->m_LastSuccessSyncPC) / sizeof(g_BaseSystem->m_LastSuccessSyncPC[0])); i < n; i++)
{
WriteTrace(TraceExceptionHandler, TraceError, "m_LastSuccessSyncPC[%d] = 0x%lx", i, g_BaseSystem->m_LastSuccessSyncPC[i]);
@ -467,7 +467,7 @@ bool CMipsMemoryVM::FilterArmException(uint32_t MemAddress, mcontext_t & context
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to load word\n\nMIPS Address: %08X\nPC Address: %08X", MemAddress, context.arm_pc).c_str());
g_Notify->DisplayError(stdstr_f("Failed to load word\n\nMIPS address: %08X\nPC address: %08X", MemAddress, context.arm_pc).c_str());
}
}
context.arm_pc = context.arm_pc + 2;
@ -479,7 +479,7 @@ bool CMipsMemoryVM::FilterArmException(uint32_t MemAddress, mcontext_t & context
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to store word\n\nMIPS Address: %08X\nPC Address: %08X", MemAddress, context.arm_pc).c_str());
g_Notify->DisplayError(stdstr_f("Failed to store word\n\nMIPS address: %08X\nPC address: %08X", MemAddress, context.arm_pc).c_str());
}
}
context.arm_pc = context.arm_pc + 2;
@ -493,7 +493,7 @@ bool CMipsMemoryVM::FilterArmException(uint32_t MemAddress, mcontext_t & context
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to store word\n\nMIPS Address: %08X\nPC Address: %08X", MemAddress, context.arm_pc).c_str());
g_Notify->DisplayError(stdstr_f("Failed to store word\n\nMIPS address: %08X\nPC address: %08X", MemAddress, context.arm_pc).c_str());
}
}
context.arm_pc = context.arm_pc + 4;
@ -507,7 +507,7 @@ bool CMipsMemoryVM::FilterArmException(uint32_t MemAddress, mcontext_t & context
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to store word\n\nMIPS Address: %08X\nPC Address: %08X", MemAddress, context.arm_pc).c_str());
g_Notify->DisplayError(stdstr_f("Failed to store word\n\nMIPS address: %08X\nPC address: %08X", MemAddress, context.arm_pc).c_str());
}
}
context.arm_pc = context.arm_pc + 4;
@ -521,7 +521,7 @@ bool CMipsMemoryVM::FilterArmException(uint32_t MemAddress, mcontext_t & context
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to load word\n\nMIPS Address: %08X\nPC Address: %08X", MemAddress, context.arm_pc).c_str());
g_Notify->DisplayError(stdstr_f("Failed to load word\n\nMIPS address: %08X\nPC address: %08X", MemAddress, context.arm_pc).c_str());
}
}
context.arm_pc = context.arm_pc + 4;
@ -536,7 +536,7 @@ bool CMipsMemoryVM::FilterArmException(uint32_t MemAddress, mcontext_t & context
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to store word\n\nMIPS Address: %08X\nPC Address: %08X", MemAddress, context.arm_pc).c_str());
g_Notify->DisplayError(stdstr_f("Failed to store word\n\nMIPS address: %08X\nPC address: %08X", MemAddress, context.arm_pc).c_str());
}
}
context.arm_pc = context.arm_pc + 4;
@ -549,7 +549,7 @@ bool CMipsMemoryVM::FilterArmException(uint32_t MemAddress, mcontext_t & context
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to store byte\n\nMIPS Address: %08X\nPC Address: %08X", MemAddress, context.arm_pc).c_str());
g_Notify->DisplayError(stdstr_f("Failed to store byte\n\nMIPS address: %08X\nPC address: %08X", MemAddress, context.arm_pc).c_str());
}
}
context.arm_pc = context.arm_pc + 2;
@ -563,7 +563,7 @@ bool CMipsMemoryVM::FilterArmException(uint32_t MemAddress, mcontext_t & context
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to store byte\n\nMIPS Address: %08X\nPC Address: %08X", MemAddress, context.arm_pc).c_str());
g_Notify->DisplayError(stdstr_f("Failed to store byte\n\nMIPS address: %08X\nPC address: %08X", MemAddress, context.arm_pc).c_str());
}
}
context.arm_pc = context.arm_pc + 4;
@ -577,7 +577,7 @@ bool CMipsMemoryVM::FilterArmException(uint32_t MemAddress, mcontext_t & context
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to store half word\n\nMIPS Address: %08X\nPC Address: %08X", MemAddress, context.arm_pc).c_str());
g_Notify->DisplayError(stdstr_f("Failed to store half word\n\nMIPS address: %08X\nPC address: %08X", MemAddress, context.arm_pc).c_str());
}
}
context.arm_pc = context.arm_pc + 4;
@ -591,7 +591,7 @@ bool CMipsMemoryVM::FilterArmException(uint32_t MemAddress, mcontext_t & context
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to store half word\n\nMIPS Address: %08X\nPC Address: %08X", MemAddress, context.arm_pc).c_str());
g_Notify->DisplayError(stdstr_f("Failed to store half word\n\nMIPS address: %08X\nPC address: %08X", MemAddress, context.arm_pc).c_str());
}
}
context.arm_pc = context.arm_pc + 2;
@ -605,7 +605,7 @@ bool CMipsMemoryVM::FilterArmException(uint32_t MemAddress, mcontext_t & context
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to store half word\n\nMIPS Address: %08X\nPC Address: %08X", MemAddress, context.arm_pc).c_str());
g_Notify->DisplayError(stdstr_f("Failed to store half word\n\nMIPS address: %08X\nPC address: %08X", MemAddress, context.arm_pc).c_str());
}
}
context.arm_pc = context.arm_pc + 2;
@ -619,7 +619,7 @@ bool CMipsMemoryVM::FilterArmException(uint32_t MemAddress, mcontext_t & context
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to store word\n\nMIPS Address: %08X\nPC Address: %08X", MemAddress, context.arm_pc).c_str());
g_Notify->DisplayError(stdstr_f("Failed to store word\n\nMIPS address: %08X\nPC address: %08X", MemAddress, context.arm_pc).c_str());
}
}
context.arm_pc = context.arm_pc + 2;
@ -633,7 +633,7 @@ bool CMipsMemoryVM::FilterArmException(uint32_t MemAddress, mcontext_t & context
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to load word\n\nMIPS Address: %08X\nPC Address: %08X", MemAddress, context.arm_pc).c_str());
g_Notify->DisplayError(stdstr_f("Failed to load word\n\nMIPS address: %08X\nPC address: %08X", MemAddress, context.arm_pc).c_str());
}
}
context.arm_pc = context.arm_pc + 2;
@ -647,7 +647,7 @@ bool CMipsMemoryVM::FilterArmException(uint32_t MemAddress, mcontext_t & context
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to store byte\n\nMIPS Address: %08X\nPC Address: %08X", MemAddress, context.arm_pc).c_str());
g_Notify->DisplayError(stdstr_f("Failed to store byte\n\nMIPS address: %08X\nPC address: %08X", MemAddress, context.arm_pc).c_str());
}
}
context.arm_pc = context.arm_pc + 2;
@ -661,7 +661,7 @@ bool CMipsMemoryVM::FilterArmException(uint32_t MemAddress, mcontext_t & context
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to store half word\n\nMIPS Address: %08X\nPC Address: %08X", MemAddress, context.arm_pc).c_str());
g_Notify->DisplayError(stdstr_f("Failed to store half word\n\nMIPS address: %08X\nPC address: %08X", MemAddress, context.arm_pc).c_str());
}
}
context.arm_pc = context.arm_pc + 4;
@ -675,7 +675,7 @@ bool CMipsMemoryVM::FilterArmException(uint32_t MemAddress, mcontext_t & context
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to store word\n\nMIPS Address: %08X\nPC Address: %08X", MemAddress, context.arm_pc).c_str());
g_Notify->DisplayError(stdstr_f("Failed to store word\n\nMIPS address: %08X\nPC address: %08X", MemAddress, context.arm_pc).c_str());
}
}
context.arm_pc = context.arm_pc + 4;
@ -689,7 +689,7 @@ bool CMipsMemoryVM::FilterArmException(uint32_t MemAddress, mcontext_t & context
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to load half word\n\nMIPS Address: %08X\nPC Address: %08X", MemAddress, context.arm_pc).c_str());
g_Notify->DisplayError(stdstr_f("Failed to load half word\n\nMIPS address: %08X\nPC address: %08X", MemAddress, context.arm_pc).c_str());
}
}
context.arm_pc = context.arm_pc + 4;
@ -703,7 +703,7 @@ bool CMipsMemoryVM::FilterArmException(uint32_t MemAddress, mcontext_t & context
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to load half word\n\nMIPS Address: %08X\nPC Address: %08X", MemAddress, context.arm_pc).c_str());
g_Notify->DisplayError(stdstr_f("Failed to load half word\n\nMIPS address: %08X\nPC address: %08X", MemAddress, context.arm_pc).c_str());
}
}
context.arm_pc = context.arm_pc + 4;
@ -718,7 +718,7 @@ bool CMipsMemoryVM::FilterArmException(uint32_t MemAddress, mcontext_t & context
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to load half word\n\nMIPS Address: %08X\nPC Address: %08X", MemAddress, context.arm_pc).c_str());
g_Notify->DisplayError(stdstr_f("Failed to load half word\n\nMIPS address: %08X\nPC address: %08X", MemAddress, context.arm_pc).c_str());
}
}
context.arm_pc = context.arm_pc + 4;
@ -732,7 +732,7 @@ bool CMipsMemoryVM::FilterArmException(uint32_t MemAddress, mcontext_t & context
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to load word\n\nMIPS Address: %08X\nPC Address: %08X", MemAddress, context.arm_pc).c_str());
g_Notify->DisplayError(stdstr_f("Failed to load word\n\nMIPS address: %08X\nPC address: %08X", MemAddress, context.arm_pc).c_str());
}
}
context.arm_pc = context.arm_pc + 4;
@ -746,7 +746,7 @@ bool CMipsMemoryVM::FilterArmException(uint32_t MemAddress, mcontext_t & context
{
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("Failed to load word\n\nMIPS Address: %08X\nPC Address: %08X", MemAddress, context.arm_pc).c_str());
g_Notify->DisplayError(stdstr_f("Failed to load word\n\nMIPS address: %08X\nPC address: %08X", MemAddress, context.arm_pc).c_str());
}
}
context.arm_pc = context.arm_pc + 4;

View File

@ -4,7 +4,7 @@ enum LanguageStringID
{
EMPTY_STRING = 0,
// Meta Information
// Meta information
// About DLL
LANGUAGE_NAME = 1,
@ -110,7 +110,7 @@ enum LanguageStringID
MENU_SLOT_10 = 200,
MENU_SLOT_SAVE = 201,
// Pop up menu
// Pop-up menu
POPUP_PLAY = 210,
POPUP_INFO = 211,
POPUP_SETTINGS = 212,
@ -171,7 +171,6 @@ enum LanguageStringID
MENUDES_GAME_SETTINGS = 285,
MENUDES_GAME_CHEATS = 286,
// ROM browser
// ROM browser fields
@ -197,7 +196,6 @@ enum LanguageStringID
RB_FILE_FORMAT = 319,
RB_NAME = 321,
// Select ROM
SELECT_ROM_DIR = 320,

View File

@ -373,7 +373,7 @@ void CLanguage::LoadDefaultStrings(void)
DEF_STR(DISKSAVE_SHADOW, "Full Disk Copy");
DEF_STR(DISKSAVE_RAM, "Save Area Only");
// ROM Information
// ROM information
// ROM info title
DEF_STR(INFO_TITLE, "ROM Information");
@ -434,7 +434,7 @@ void CLanguage::LoadDefaultStrings(void)
DEF_STR(CHEAT_CHANGED_MSG, "Cheat has been changed.\n\nDo you want to update?");
DEF_STR(CHEAT_CHANGED_TITLE, "Cheat updated");
// Cheat Pop-up menu
// Cheat pop-up menu
DEF_STR(CHEAT_ADDNEW, "Add New Cheat...");
DEF_STR(CHEAT_EDIT, "Edit");
DEF_STR(CHEAT_DELETE, "Delete");

View File

@ -44,7 +44,7 @@ void CN64System::CloseCpu()
m_EndEmulation = true;
if (g_Settings->LoadBool(GameRunning_CPU_Paused))
{
WriteTrace(TraceN64System, TraceDebug, "Resume cpu");
WriteTrace(TraceN64System, TraceDebug, "Resume CPU");
m_hPauseEvent.Trigger();
}

View File

@ -145,7 +145,7 @@ CEnhancement::CEnhancement(const char * Ident, const char * Entry) :
m_Name = &(Lines[0][CurrentLine]);
m_NameAndExtension = m_Name;
//key=value
// Key=value
while (CurrentLine < Lines.size())
{
const char * Pos = strchr(Lines[CurrentLine].c_str(), '=');
@ -189,7 +189,7 @@ CEnhancement::CEnhancement(const char * Ident, const char * Entry) :
}
}
//Gameshark Code
// Gameshark code
while (CurrentLine < Lines.size())
{
char TempFormat[128] = { 0 };

View File

@ -183,7 +183,7 @@ bool CEnhancmentFile::MoveToSection(const char * Section, bool ChangeCurrentSect
{
m_File.Seek(m_lastSectionSearch, CFileBase::begin);
//long Fpos;
// Long Fpos;
uint8_t pUTF8[3];
pUTF8[0] = 0xef;
pUTF8[1] = 0xbb;
@ -195,7 +195,7 @@ bool CEnhancmentFile::MoveToSection(const char * Section, bool ChangeCurrentSect
if (result <= 1) { continue; }
if (strlen(CleanLine(Input)) <= 1) { continue; }
//We Only care about sections
// We only care about sections
char * CurrentSection = Input;
if (m_lastSectionSearch == 0 && !memcmp(CurrentSection, pUTF8, 3))
@ -206,7 +206,7 @@ bool CEnhancmentFile::MoveToSection(const char * Section, bool ChangeCurrentSect
if (CurrentSection[0] != '[') { continue; }
int lineEndPos = (int)strlen(CurrentSection) - 1;
if (CurrentSection[lineEndPos] != ']') { continue; }
//take off the ']' from the end of the string
// Take off the ']' from the end of the string
CurrentSection[lineEndPos] = 0;
CurrentSection += 1;
m_lastSectionSearch = (m_File.GetPosition() - DataSize) + ReadPos;
@ -524,7 +524,7 @@ const char * CEnhancmentFile::CleanLine(char * Line)
}
}
//strip any spaces or line feeds from the end of the line
// Strip any spaces or line feeds from the end of the line
for (int32_t i = (int32_t)strlen(&Line[0]) - 1; i >= 0; i--)
{
if (Line[i] != ' ' && Line[i] != '\r')
@ -620,4 +620,3 @@ void CEnhancmentFile::ClearSectionPosList(long FilePos)
m_lastSectionSearch = FilePos;
}
}

View File

@ -411,7 +411,7 @@ void CEnhancements::ApplyGameSharkCodes(CMipsMemoryVM & MMU, CODES & CodeEntry,
switch (Code.Command() & 0xFF000000)
{
case 0x50000000: // Gameshark / AR
case 0x50000000: // Gameshark / Action Replay
if ((CurrentEntry + 1) >= (int)CodeEntry.size())
{
g_Notify->BreakPoint(__FILE__, __LINE__);
@ -532,7 +532,7 @@ void CEnhancements::ApplyGameSharkCodes(CMipsMemoryVM & MMU, CODES & CodeEntry,
case 0x89000000:
case 0xA8000000:
case 0xA9000000:
//Ignore - GS Button
// Ignore - Gameshark (GS) button
break;
default:
g_Notify->BreakPoint(__FILE__, __LINE__);
@ -681,7 +681,7 @@ void CEnhancements::ScanFileThread(void)
{
do
{
CEnhancmentFile EnhancmentFile(File, "Enhancment");
CEnhancmentFile EnhancmentFile(File, CEnhancement::EnhancementIdent);
CEnhancmentFile::SectionList Sections;
EnhancmentFile.GetSections(Sections);
for (CEnhancmentFile::SectionList::const_iterator itr = Sections.begin(); itr != Sections.end(); itr++)
@ -699,7 +699,7 @@ void CEnhancements::ScanFileThread(void)
{
do
{
CEnhancmentFile EnhancmentFile(File, "Enhancment");
CEnhancmentFile EnhancmentFile(File, CEnhancement::EnhancementIdent);
CEnhancmentFile::SectionList Sections;
EnhancmentFile.GetSections(Sections);
for (CEnhancmentFile::SectionList::const_iterator itr = Sections.begin(); itr != Sections.end(); itr++)

View File

@ -88,7 +88,7 @@ bool DelaySlotEffectsCompare(uint32_t PC, uint32_t Reg1, uint32_t Reg2)
default:
if (CDebugSettings::HaveDebugger())
{
g_Notify->DisplayError(stdstr_f("Does %s effect Delay slot at %X?", R4300iOpcodeName(Command.Hex, PC + 4), PC).c_str());
g_Notify->DisplayError(stdstr_f("Does %s effect delay slot at %X?", R4300iOpcodeName(Command.Hex, PC + 4), PC).c_str());
}
return true;
}
@ -119,7 +119,7 @@ bool DelaySlotEffectsCompare(uint32_t PC, uint32_t Reg1, uint32_t Reg2)
default:
if (CDebugSettings::HaveDebugger())
{
g_Notify->DisplayError(stdstr_f("Does %s effect Delay slot at %X?\n6", R4300iOpcodeName(Command.Hex, PC + 4), PC).c_str());
g_Notify->DisplayError(stdstr_f("Does %s effect delay slot at %X?\n6", R4300iOpcodeName(Command.Hex, PC + 4), PC).c_str());
}
return true;
}
@ -128,7 +128,7 @@ bool DelaySlotEffectsCompare(uint32_t PC, uint32_t Reg1, uint32_t Reg2)
{
if (CDebugSettings::HaveDebugger())
{
g_Notify->DisplayError(stdstr_f("Does %s effect Delay slot at %X?\n7", R4300iOpcodeName(Command.Hex, PC + 4), PC).c_str());
g_Notify->DisplayError(stdstr_f("Does %s effect delay slot at %X?\n7", R4300iOpcodeName(Command.Hex, PC + 4), PC).c_str());
}
return true;
}
@ -157,7 +157,7 @@ bool DelaySlotEffectsCompare(uint32_t PC, uint32_t Reg1, uint32_t Reg2)
default:
if (CDebugSettings::HaveDebugger())
{
g_Notify->DisplayError(stdstr_f("Does %s effect Delay slot at %X?", R4300iOpcodeName(Command.Hex, PC + 4), PC).c_str());
g_Notify->DisplayError(stdstr_f("Does %s effect delay slot at %X?", R4300iOpcodeName(Command.Hex, PC + 4), PC).c_str());
}
return true;
}
@ -205,7 +205,7 @@ bool DelaySlotEffectsCompare(uint32_t PC, uint32_t Reg1, uint32_t Reg2)
default:
if (CDebugSettings::HaveDebugger())
{
g_Notify->DisplayError(stdstr_f("Does %s effect Delay slot at %X?", R4300iOpcodeName(Command.Hex, PC + 4), PC).c_str());
g_Notify->DisplayError(stdstr_f("Does %s effect delay slot at %X?", R4300iOpcodeName(Command.Hex, PC + 4), PC).c_str());
}
return true;
}
@ -230,13 +230,13 @@ void CInterpreterCPU::BuildCPU()
void CInterpreterCPU::InPermLoop()
{
// *** Changed ***/
// Changed
//if (CPU_Type == CPU_SyncCores)
//{
// SyncRegisters.CP0[9] +=5;
//}
/* Interrupts enabled */
// Interrupts enabled
if ((g_Reg->STATUS_REGISTER & STATUS_IE) == 0 ||
(g_Reg->STATUS_REGISTER & STATUS_EXL) != 0 ||
(g_Reg->STATUS_REGISTER & STATUS_ERL) != 0 ||
@ -294,7 +294,7 @@ void CInterpreterCPU::ExecuteCPU()
g_Settings->SaveBool(Debugger_SteppingOps, true);
}
g_Debugger->CPUStepStarted(); // may set stepping ops/skip op
g_Debugger->CPUStepStarted(); // May set stepping ops/skip op
if (isStepping())
{
@ -320,7 +320,7 @@ void CInterpreterCPU::ExecuteCPU()
} */
m_R4300i_Opcode[Opcode.op]();
_GPR[0].DW = 0; /* MIPS $zero hard-wired to 0 */
_GPR[0].DW = 0; // MIPS $zero hard-wired to 0
NextTimer -= CountPerOp;
if (CDebugSettings::HaveDebugger()) { g_Debugger->CPUStepEnded(); }

View File

@ -739,7 +739,8 @@ void TestInterpreterJump(uint32_t PC, uint32_t TargetPC, int32_t Reg1, int32_t R
R4300iOp::m_TestTimer = true;
}
/************************* Opcode functions *************************/
// Opcode functions
void R4300iOp::J()
{
m_NextInstruction = DELAY_SLOT;
@ -1686,7 +1687,9 @@ void R4300iOp::SD()
TLB_WRITE_EXCEPTION(Address);
}
}
/********************** R4300i OpCodes: Special **********************/
// R4300i opcodes: Special
void R4300iOp::SPECIAL_SLL()
{
_GPR[m_Opcode.rd].DW = (_GPR[m_Opcode.rt].W[0] << m_Opcode.sa);
@ -1810,7 +1813,7 @@ void R4300iOp::SPECIAL_DIV()
{
if (bShowDivByZero())
{
g_Notify->DisplayError("DIV by 0 ???");
g_Notify->DisplayError("DIV by 0");
}
_RegLO->DW = 0;
_RegHI->DW = 0;
@ -1828,7 +1831,7 @@ void R4300iOp::SPECIAL_DIVU()
{
if (bShowDivByZero())
{
g_Notify->DisplayError("DIVU by 0 ???");
g_Notify->DisplayError("DIVU by 0");
}
_RegLO->DW = 0;
_RegHI->DW = 0;
@ -1874,7 +1877,7 @@ void R4300iOp::SPECIAL_DDIV()
{
if (HaveDebugger())
{
g_Notify->DisplayError("DDIV by 0 ???");
g_Notify->DisplayError("DDIV by 0");
}
}
}
@ -1890,7 +1893,7 @@ void R4300iOp::SPECIAL_DDIVU()
{
if (HaveDebugger())
{
g_Notify->DisplayError("DDIVU by 0 ???");
g_Notify->DisplayError("DDIVU by 0");
}
}
}
@ -2063,7 +2066,8 @@ void R4300iOp::SPECIAL_DSRA32()
_GPR[m_Opcode.rd].DW = (_GPR[m_Opcode.rt].DW >> (m_Opcode.sa + 32));
}
/********************** R4300i OpCodes: RegImm **********************/
// R4300i opcodes: RegImm
void R4300iOp::REGIMM_BLTZ()
{
m_NextInstruction = DELAY_SLOT;
@ -2256,12 +2260,13 @@ void R4300iOp::REGIMM_TNEI()
}
}
/************************** COP0 functions **************************/
// COP0 functions
void R4300iOp::COP0_MF()
{
if (LogCP0reads())
{
LogMessage("%08X: R4300i Read from %s (0x%08X)", (*_PROGRAM_COUNTER), CRegName::Cop0[m_Opcode.rd], _CP0[m_Opcode.rd]);
LogMessage("%08X: R4300i read from %s (0x%08X)", (*_PROGRAM_COUNTER), CRegName::Cop0[m_Opcode.rd], _CP0[m_Opcode.rd]);
}
if (m_Opcode.rd == 9)
@ -2275,7 +2280,7 @@ void R4300iOp::COP0_MT()
{
if (LogCP0changes())
{
LogMessage("%08X: Writing 0x%X to %s register (Originally: 0x%08X)", (*_PROGRAM_COUNTER), _GPR[m_Opcode.rt].UW[0], CRegName::Cop0[m_Opcode.rd], _CP0[m_Opcode.rd]);
LogMessage("%08X: Writing 0x%X to %s register (originally: 0x%08X)", (*_PROGRAM_COUNTER), _GPR[m_Opcode.rt].UW[0], CRegName::Cop0[m_Opcode.rd], _CP0[m_Opcode.rd]);
if (m_Opcode.rd == 11) // Compare
{
LogMessage("%08X: Cause register changed from %08X to %08X", (*_PROGRAM_COUNTER), g_Reg->CAUSE_REGISTER, (g_Reg->CAUSE_REGISTER & ~CAUSE_IP7));
@ -2332,7 +2337,7 @@ void R4300iOp::COP0_MT()
}
g_Reg->CheckInterrupts();
break;
case 13: //cause
case 13: // Cause
_CP0[m_Opcode.rd] &= 0xFFFFCFF;
if ((_GPR[m_Opcode.rt].UW[0] & 0x300) != 0 && HaveDebugger())
{
@ -2344,7 +2349,8 @@ void R4300iOp::COP0_MT()
}
}
/************************** COP0 CO functions ***********************/
// COP0 CO functions
void R4300iOp::COP0_CO_TLBR()
{
if (!g_System->bUseTlb())
@ -2399,7 +2405,8 @@ void R4300iOp::COP0_CO_ERET()
m_TestTimer = true;
}
/************************** COP1 functions **************************/
// COP1 functions
void R4300iOp::COP1_MF()
{
TEST_COP1_USABLE_EXCEPTION();
@ -2419,7 +2426,7 @@ void R4300iOp::COP1_CF()
{
if (HaveDebugger())
{
g_Notify->DisplayError("CFC1 what register are you writing to ?");
g_Notify->DisplayError("CFC1: what register are you writing to?");
}
return;
}
@ -2455,11 +2462,12 @@ void R4300iOp::COP1_CT()
}
if (HaveDebugger())
{
g_Notify->DisplayError("CTC1 what register are you writing to ?");
g_Notify->DisplayError("CTC1: what register are you writing to?");
}
}
/************************* COP1: BC1 functions ***********************/
// COP1: BC1 functions
void R4300iOp::COP1_BCF()
{
TEST_COP1_USABLE_EXCEPTION();
@ -2517,18 +2525,20 @@ void R4300iOp::COP1_BCTL()
m_JumpToLocation = (*_PROGRAM_COUNTER) + 8;
}
}
/************************** COP1: S functions ************************/
// COP1: S functions
__inline void Float_RoundToInteger32(int32_t * Dest, const float * Source, int RoundType)
{
#pragma warning(push)
#pragma warning(disable:4244) //warning C4244: disabe conversion from 'float' to 'int32_t', possible loss of data
#pragma warning(disable:4244) // warning C4244: disable conversion from 'float' to 'int32_t', possible loss of data
if (RoundType == FE_TONEAREST)
{
float reminder = *Source - floorf(*Source);
if (reminder == 0.5)
{
//make any decimal point in even to go to odd and any decimal point in odd stay as odd
// Make any decimal point that is even odd, and any decimal point that is odd stay odd
if (*Source < 0)
{
*Dest = (int)truncf(*Source) % 2 != 0 ? floorf(*Source) : ceilf(*Source);
@ -2553,14 +2563,14 @@ __inline void Float_RoundToInteger32(int32_t * Dest, const float * Source, int R
__inline void Float_RoundToInteger64(int64_t * Dest, const float * Source, int RoundType)
{
#pragma warning(push)
#pragma warning(disable:4244) //warning C4244: disabe conversion from 'float' to 'int64_t', possible loss of data
#pragma warning(disable:4244) // warning C4244: disable conversion from 'float' to 'int64_t', possible loss of data
if (RoundType == FE_TONEAREST)
{
float reminder = *Source - floorf(*Source);
if (reminder == 0.5)
{
//make any decimal point in even to go to odd and any decimal point in odd stay as odd
// Make any decimal point that is even odd, and any decimal point that is odd stay odd
if (*Source < 0)
{
*Dest = (int)truncf(*Source) % 2 != 0 ? floorf(*Source) : ceilf(*Source);
@ -2753,18 +2763,19 @@ void R4300iOp::COP1_S_CMP()
}
}
/************************** COP1: D functions ************************/
// COP1: D functions
__inline void Double_RoundToInteger32(int32_t * Dest, const double * Source, int RoundType)
{
#pragma warning(push)
#pragma warning(disable:4244) //warning C4244: disabe conversion from 'double' to 'uint32_t', possible loss of data
#pragma warning(disable:4244) // warning C4244: disable conversion from 'double' to 'uint32_t', possible loss of data
if (RoundType == FE_TONEAREST)
{
double reminder = *Source - floor(*Source);
if (reminder == 0.5)
{
//make any decimal point in even to go to odd and any decimal point in odd stay as odd
// Make any decimal point that is even odd, and any decimal point that is odd stay odd
if (*Source < 0)
{
*Dest = (int)truncf(*Source) % 2 != 0 ? floor(*Source) : ceil(*Source);
@ -2793,14 +2804,14 @@ __inline void Double_RoundToInteger32(int32_t * Dest, const double * Source, int
__inline void Double_RoundToInteger64(int64_t * Dest, const double * Source, int RoundType)
{
#pragma warning(push)
#pragma warning(disable:4244) //warning C4244: disabe conversion from 'double' to 'uint64_t', possible loss of data
#pragma warning(disable:4244) // warning C4244: disable conversion from 'double' to 'uint64_t', possible loss of data
if (RoundType == FE_TONEAREST)
{
double reminder = *Source - floor(*Source);
if (reminder == 0.5)
{
//make any decimal point in even to go to odd and any decimal point in odd stay as odd
// Make any decimal point that is even odd, and any decimal point that is odd stay odd
if (*Source < 0)
{
*Dest = (int)truncf(*Source) % 2 != 0 ? floor(*Source) : ceil(*Source);
@ -2997,7 +3008,8 @@ void R4300iOp::COP1_D_CMP()
}
}
/************************** COP1: W functions ************************/
// COP1: W functions
void R4300iOp::COP1_W_CVT_S()
{
TEST_COP1_USABLE_EXCEPTION();
@ -3012,7 +3024,8 @@ void R4300iOp::COP1_W_CVT_D()
*(double *)_FPR_D[m_Opcode.fd] = (double)*(int32_t *)_FPR_S[m_Opcode.fs];
}
/************************** COP1: L functions ************************/
// COP1: L functions
void R4300iOp::COP1_L_CVT_S()
{
TEST_COP1_USABLE_EXCEPTION();
@ -3027,10 +3040,11 @@ void R4300iOp::COP1_L_CVT_D()
*(double *)_FPR_D[m_Opcode.fd] = (double)*(int64_t *)_FPR_D[m_Opcode.fs];
}
/************************** Other functions **************************/
// Other functions
void R4300iOp::UnknownOpcode()
{
g_Notify->DisplayError(stdstr_f("%s: %08X\n%s\n\nStopping Emulation !", GS(MSG_UNHANDLED_OP), (*_PROGRAM_COUNTER),
g_Notify->DisplayError(stdstr_f("%s: %08X\n%s\n\nStopping emulation", GS(MSG_UNHANDLED_OP), (*_PROGRAM_COUNTER),
R4300iOpcodeName(m_Opcode.Hex, (*_PROGRAM_COUNTER))).c_str());
g_System->m_EndEmulation = true;

View File

@ -12,7 +12,7 @@ class R4300iOp :
public:
typedef void(*Func)();
/************************* OpCode functions *************************/
// Opcode functions
static void J();
static void JAL();
static void BNE();
@ -59,7 +59,7 @@ public:
static void SDC1();
static void SD();
/********************** R4300i OpCodes: Special **********************/
// R4300i opcodes: Special
static void SPECIAL_SLL();
static void SPECIAL_SRL();
static void SPECIAL_SRA();
@ -113,7 +113,7 @@ public:
static void SPECIAL_DSRL32();
static void SPECIAL_DSRA32();
/********************** R4300i OpCodes: RegImm **********************/
// R4300i opcodes: RegImm
static void REGIMM_BLTZ();
static void REGIMM_BGEZ();
static void REGIMM_BLTZL();
@ -127,18 +127,18 @@ public:
static void REGIMM_TLTIU();
static void REGIMM_TNEI();
/************************** COP0 functions **************************/
// COP0 functions
static void COP0_MF();
static void COP0_MT();
/************************** COP0 CO functions ***********************/
// COP0 CO functions
static void COP0_CO_TLBR();
static void COP0_CO_TLBWI();
static void COP0_CO_TLBWR();
static void COP0_CO_TLBP();
static void COP0_CO_ERET();
/************************** COP1 functions **************************/
// COP1 functions
static void COP1_MF();
static void COP1_DMF();
static void COP1_CF();
@ -146,13 +146,13 @@ public:
static void COP1_DMT();
static void COP1_CT();
/************************* COP1: BC1 functions ***********************/
// COP1: BC1 functions
static void COP1_BCF();
static void COP1_BCT();
static void COP1_BCFL();
static void COP1_BCTL();
/************************** COP1: S functions ************************/
// COP1: S functions
static void COP1_S_ADD();
static void COP1_S_SUB();
static void COP1_S_MUL();
@ -174,7 +174,7 @@ public:
static void COP1_S_CVT_L();
static void COP1_S_CMP();
/************************** COP1: D functions ************************/
// COP1: D functions
static void COP1_D_ADD();
static void COP1_D_SUB();
static void COP1_D_MUL();
@ -196,15 +196,15 @@ public:
static void COP1_D_CVT_L();
static void COP1_D_CMP();
/************************** COP1: W functions ************************/
// COP1: W functions
static void COP1_W_CVT_S();
static void COP1_W_CVT_D();
/************************** COP1: L functions ************************/
// COP1: L functions
static void COP1_L_CVT_S();
static void COP1_L_CVT_D();
/************************** Other functions **************************/
// Other functions
static void UnknownOpcode();
static Func* BuildInterpreter();

View File

@ -622,7 +622,8 @@ R4300iOp32::Func * R4300iOp32::BuildInterpreter()
return Jump_Opcode;
}
/************************* Opcode functions *************************/
// Opcode functions
void R4300iOp32::JAL()
{
m_NextInstruction = DELAY_SLOT;
@ -1103,7 +1104,8 @@ void R4300iOp32::LL()
}
}
/********************** R4300i OpCodes: Special **********************/
// R4300i opcodes: Special
void R4300iOp32::SPECIAL_SLL()
{
_GPR[m_Opcode.rd].W[0] = (_GPR[m_Opcode.rt].W[0] << m_Opcode.sa);
@ -1211,11 +1213,12 @@ void R4300iOp32::SPECIAL_TEQ()
{
if (_GPR[m_Opcode.rs].W[0] == _GPR[m_Opcode.rt].W[0] && CDebugSettings::HaveDebugger())
{
g_Notify->DisplayError("Should trap this ???");
g_Notify->DisplayError("Should we trap this?");
}
}
/********************** R4300i OpCodes: RegImm **********************/
// R4300i opcodes: RegImm
void R4300iOp32::REGIMM_BLTZ()
{
m_NextInstruction = DELAY_SLOT;
@ -1352,12 +1355,13 @@ void R4300iOp32::REGIMM_BGEZAL()
_GPR[31].W[0] = (int32_t)((*_PROGRAM_COUNTER) + 8);
}
/************************** COP0 functions **************************/
// COP0 functions
void R4300iOp32::COP0_MF()
{
if (LogCP0reads())
{
LogMessage("%08X: R4300i Read from %s (0x%08X)", (*_PROGRAM_COUNTER), CRegName::Cop0[m_Opcode.rd], _CP0[m_Opcode.rd]);
LogMessage("%08X: R4300i read from %s (0x%08X)", (*_PROGRAM_COUNTER), CRegName::Cop0[m_Opcode.rd], _CP0[m_Opcode.rd]);
}
if (m_Opcode.rd == 9)
@ -1389,7 +1393,7 @@ void R4300iOp32::COP0_MT()
case 16: // Config
case 18: // WatchLo
case 19: // WatchHi
case 28: //Tag lo
case 28: // Tag Lo
case 29: // Tag Hi
case 30: // ErrEPC
_CP0[m_Opcode.rd] = _GPR[m_Opcode.rt].UW[0];
@ -1424,11 +1428,11 @@ void R4300iOp32::COP0_MT()
}
if ((_CP0[m_Opcode.rd] & 0x18) != 0 && CDebugSettings::HaveDebugger())
{
g_Notify->DisplayError("Left kernel mode ??");
g_Notify->DisplayError("Left kernel mode?");
}
g_Reg->CheckInterrupts();
break;
case 13: //cause
case 13: // Cause
_CP0[m_Opcode.rd] &= 0xFFFFCFF;
if ((_GPR[m_Opcode.rt].UW[0] & 0x300) != 0 && CDebugSettings::HaveDebugger())
{
@ -1440,7 +1444,8 @@ void R4300iOp32::COP0_MT()
}
}
/************************** COP1 functions **************************/
// COP1 functions
void R4300iOp32::COP1_MF()
{
TEST_COP1_USABLE_EXCEPTION
@ -1452,7 +1457,7 @@ void R4300iOp32::COP1_CF()
TEST_COP1_USABLE_EXCEPTION
if (m_Opcode.fs != 31 && m_Opcode.fs != 0)
{
if (CDebugSettings::HaveDebugger()) { g_Notify->DisplayError("CFC1 what register are you writing to ?"); }
if (CDebugSettings::HaveDebugger()) { g_Notify->DisplayError("CFC1: what register are you writing to?"); }
return;
}
_GPR[m_Opcode.rt].W[0] = (int32_t)_FPCR[m_Opcode.fs];

View File

@ -6,7 +6,7 @@ class R4300iOp32 :
public R4300iOp
{
public:
/************************* OpCode functions *************************/
// Opcode functions
static void JAL();
static void BEQ();
static void BNE();
@ -34,7 +34,7 @@ public:
static void LWU();
static void LL();
/********************** R4300i OpCodes: Special **********************/
// R4300i opcodes: Special
static void SPECIAL_SLL();
static void SPECIAL_SRL();
static void SPECIAL_SRA();
@ -53,7 +53,7 @@ public:
static void SPECIAL_SLTU();
static void SPECIAL_TEQ();
/********************** R4300i OpCodes: RegImm **********************/
// R4300i opcodes: RegImm
static void REGIMM_BLTZ();
static void REGIMM_BGEZ();
static void REGIMM_BLTZL();
@ -61,11 +61,11 @@ public:
static void REGIMM_BLTZAL();
static void REGIMM_BGEZAL();
/************************** COP0 functions **************************/
// COP0 functions
static void COP0_MF();
static void COP0_MT();
/************************** COP1 functions **************************/
// COP1 functions
static void COP1_MF();
static void COP1_CF();
static void COP1_DMT();

View File

@ -17,7 +17,7 @@ void CAudio::Reset()
m_SecondBuff = 0;
m_Status = 0;
m_BytesPerSecond = 0;
m_CountsPerByte = g_System->AiCountPerBytes(); // should be calculated ... see below, instead allow from user settings
m_CountsPerByte = g_System->AiCountPerBytes(); // Should be calculated, see below, instead allow from user settings
if (m_CountsPerByte == 0) m_CountsPerByte = 500; // If the user has no defined value, grant a default and we will calculate
m_FramesPerSecond = 60;
}
@ -47,7 +47,7 @@ void CAudio::LenChanged()
{
if (g_Reg->AI_LEN_REG >= 0x40000)
{
WriteTrace(TraceAudio, TraceDebug, "*** Ignoring Write, To Large (%X)", g_Reg->AI_LEN_REG);
WriteTrace(TraceAudio, TraceDebug, "Ignoring write, to large (%X)", g_Reg->AI_LEN_REG);
}
else
{
@ -57,12 +57,12 @@ void CAudio::LenChanged()
{
if (AudioLeft == 0)
{
WriteTrace(TraceAudio, TraceDebug, "Set Timer AI_LEN_REG: %d m_CountsPerByte: %d", g_Reg->AI_LEN_REG, m_CountsPerByte);
WriteTrace(TraceAudio, TraceDebug, "Set timer AI_LEN_REG: %d m_CountsPerByte: %d", g_Reg->AI_LEN_REG, m_CountsPerByte);
g_SystemTimer->SetTimer(CSystemTimer::AiTimerInterrupt, g_Reg->AI_LEN_REG * m_CountsPerByte, false);
}
else
{
WriteTrace(TraceAudio, TraceDebug, "Increasing Second Buffer (m_SecondBuff %d Increase: %d)", m_SecondBuff, g_Reg->AI_LEN_REG);
WriteTrace(TraceAudio, TraceDebug, "Increasing second buffer (m_SecondBuff %d Increase: %d)", m_SecondBuff, g_Reg->AI_LEN_REG);
m_SecondBuff += g_Reg->AI_LEN_REG;
m_Status |= ai_full;
}
@ -75,7 +75,7 @@ void CAudio::LenChanged()
}
else
{
WriteTrace(TraceAudio, TraceDebug, "*** Reset Timer to 0");
WriteTrace(TraceAudio, TraceDebug, "Reset timer to 0");
g_SystemTimer->StopTimer(CSystemTimer::AiTimerBusy);
g_SystemTimer->StopTimer(CSystemTimer::AiTimerInterrupt);
m_SecondBuff = 0;
@ -86,7 +86,7 @@ void CAudio::LenChanged()
{
WriteTrace(TraceAudio, TraceDebug, "Calling plugin AiLenChanged");
g_Plugins->Audio()->AiLenChanged();
WriteTrace(TraceAudio, TraceDebug, "plugin AiLenChanged Done");
WriteTrace(TraceAudio, TraceDebug, "Plugin AiLenChanged Done");
}
WriteTrace(TraceAudio, TraceDebug, "Done");
}

View File

@ -1,4 +1,4 @@
// Based from MAME's N64DD driver code by Happy_
// Based on MAME's N64DD driver code by Happy_
#include "stdafx.h"
#include "Disk.h"
#include <Project64-core/N64System/N64System.h>
@ -24,7 +24,7 @@ void DiskCommand()
{
//ASIC_CMD_STATUS - Commands
uint32_t cmd = g_Reg->ASIC_CMD;
WriteTrace(TraceN64System, TraceDebug, "DD CMD %08X - DATA %08X", cmd, g_Reg->ASIC_DATA);
WriteTrace(TraceN64System, TraceDebug, "N64DD CMD %08X - DATA %08X", cmd, g_Reg->ASIC_DATA);
#ifdef _WIN32
SYSTEMTIME sysTime;
@ -59,22 +59,22 @@ void DiskCommand()
switch (cmd & 0xFFFF0000)
{
case 0x00010000:
//Seek Read
// Seek read
g_Reg->ASIC_CUR_TK = g_Reg->ASIC_DATA | 0x60000000;
dd_write = false;
isSeek = true;
break;
case 0x00020000:
//Seek Write
// Seek write
g_Reg->ASIC_CUR_TK = g_Reg->ASIC_DATA | 0x60000000;
dd_write = true;
isSeek = true;
break;
case 0x00080000:
//Unset Disk Changed Bit
// Unset disk changed bit
g_Reg->ASIC_STATUS &= ~DD_STATUS_DISK_CHNG; break;
case 0x00090000:
//Unset Reset & Disk Changed bit Bit
// Unset reset and disk changed bit bit
g_Reg->ASIC_STATUS &= ~DD_STATUS_RST_STATE;
g_Reg->ASIC_STATUS &= ~DD_STATUS_DISK_CHNG;
// F-Zero X + Expansion Kit fix so it doesn't enable "swapping" at boot
@ -83,16 +83,16 @@ void DiskCommand()
g_Reg->ASIC_STATUS |= DD_STATUS_DISK_PRES;
break;
case 0x00120000:
//RTC Get Year & Month
// RTC get year and month
g_Reg->ASIC_DATA = (year << 24) | (month << 16); break;
case 0x00130000:
//RTC Get Day & Hour
// RTC get day and hour
g_Reg->ASIC_DATA = (day << 24) | (hour << 16); break;
case 0x00140000:
//RTC Get Minute & Second
// RTC get minute and second
g_Reg->ASIC_DATA = (minute << 24) | (second << 16); break;
case 0x001B0000:
//Disk Inquiry
// Disk inquiry
g_Reg->ASIC_DATA = 0x00000000; break;
}
@ -100,7 +100,7 @@ void DiskCommand()
{
if (g_System->DiskSeekTimingType() == DiskSeek_Turbo)
{
//Instant Response for Turbo
// Instant response for turbo
// Set timer for seek response
g_SystemTimer->SetTimer(g_SystemTimer->DDSeekTimer, 0, false);
@ -110,17 +110,17 @@ void DiskCommand()
}
else /* if (g_System->DiskSeekTimingType() == DiskSeek_Slow) */
{
//Emulate Seek Times, send interrupt later
// Emulate seek times, send interrupt later
uint32_t seektime = 0;
//Start Motor, can take half a second, delay the response
// Start motor, can take half a second, delay the response
if (g_Reg->ASIC_STATUS & DD_STATUS_MTR_N_SPIN)
{
seektime += (0x5A00000 / 2);
g_Reg->ASIC_STATUS &= ~DD_STATUS_MTR_N_SPIN;
}
//Get Zone to calculate seek times
// Get zone to calculate seek times
uint32_t track = g_Reg->ASIC_CUR_TK >> 16 & 0x0FFF;
uint32_t zone = 0;
uint32_t zonebound = 0;
@ -178,7 +178,7 @@ void DiskCommand()
void DiskReset(void)
{
//ASIC_HARD_RESET 0xAAAA0000
WriteTrace(TraceN64System, TraceDebug, "DD RESET");
WriteTrace(TraceN64System, TraceDebug, "N64DD reset");
g_Reg->ASIC_STATUS |= DD_STATUS_RST_STATE;
dd_swapdelay = 0;
if (g_Disk != nullptr)
@ -231,9 +231,9 @@ void DiskBMControl(void)
void DiskGapSectorCheck()
{
//On 64DD Status Register Read
// On 64DD status register read
//Buffer Manager Interrupt, Gap Sector Check
// Buffer manager interrupt, gap sector check
if (g_Reg->ASIC_STATUS & DD_STATUS_BM_INT)
{
if (SECTORS_PER_BLOCK < dd_current)
@ -245,7 +245,7 @@ void DiskGapSectorCheck()
}
}
//Delay Disk Swapping by removing the disk for a certain amount of time, then insert the newly loaded disk (after 50 Status Register reads, here).
// Delay disk swapping by removing the disk for a certain amount of time, then insert the newly loaded disk (after 50 status register reads, here)
if (!(g_Reg->ASIC_STATUS & DD_STATUS_DISK_PRES) && g_Disk != nullptr && g_Settings->LoadBool(GameRunning_LoadingInProgress) == false)
{
dd_swapdelay++;
@ -253,7 +253,7 @@ void DiskGapSectorCheck()
{
g_Reg->ASIC_STATUS |= (DD_STATUS_DISK_PRES | DD_STATUS_DISK_CHNG);
dd_swapdelay = 0;
WriteTrace(TraceN64System, TraceDebug, "DD SWAP DONE");
WriteTrace(TraceN64System, TraceDebug, "N64DD swap done");
}
}
}
@ -277,7 +277,7 @@ void DiskBMUpdate()
}
else if (dd_current < SECTORS_PER_BLOCK + 1)
{
//C2 Sector
// C2 sector
if (g_Reg->ASIC_BM_STATUS & DD_BM_STATUS_BLOCK)
{
dd_start_block = 1 - dd_start_block;
@ -303,16 +303,16 @@ void DiskBMUpdate()
}
else
{
//Read Data
// Read data
if (((g_Reg->ASIC_CUR_TK >> 16) & 0x1FFF) == 6 && g_Reg->ASIC_CUR_SECTOR == 0 && g_Disk->GetCountry() != Country_Unknown)
{
//Copy Protection if Retail Disk
// Copy protection if retail disk
g_Reg->ASIC_STATUS &= ~DD_STATUS_DATA_RQ;
g_Reg->ASIC_BM_STATUS |= DD_BM_STATUS_MICRO;
}
else if (dd_current < SECTORS_PER_BLOCK)
{
//User Sector
// User sector
if (!DiskBMReadWrite(false))
g_Reg->ASIC_STATUS |= DD_STATUS_DATA_RQ;
else
@ -321,14 +321,14 @@ void DiskBMUpdate()
}
else if (dd_current < SECTORS_PER_BLOCK + 4)
{
//C2 sectors (All 00s)
// C2 sectors (all 00s)
dd_current += 1;
if (dd_current == SECTORS_PER_BLOCK + 4)
g_Reg->ASIC_STATUS |= DD_STATUS_C2_XFER;
}
else if (dd_current == SECTORS_PER_BLOCK + 4)
{
//Gap Sector
// Gap sector
if (g_Reg->ASIC_BM_STATUS & DD_BM_STATUS_BLOCK)
{
dd_start_block = 1 - dd_start_block;

View File

@ -1,4 +1,4 @@
// Based from MAME's N64DD driver code by Happy_
// Based on MAME's N64DD driver code by Happy_
#pragma once
#include <stdint.h>

View File

@ -63,17 +63,17 @@ void CDMA::PI_DMA_READ()
return;
}
//64DD Buffers Write
// 64DD buffers write
if (g_Reg->PI_CART_ADDR_REG >= 0x05000000 && g_Reg->PI_CART_ADDR_REG <= 0x050003FF)
{
//64DD C2 Sectors (don't care)
// 64DD C2 sectors (don't care)
g_SystemTimer->SetTimer(g_SystemTimer->DDPiTimer, (PI_RD_LEN_REG * 63) / 25, false);
return;
}
if (g_Reg->PI_CART_ADDR_REG >= 0x05000400 && g_Reg->PI_CART_ADDR_REG <= 0x050004FF)
{
//64DD User Sector
// 64DD user sector
uint32_t i;
uint8_t * RDRAM = g_MMU->Rdram();
uint8_t * DISK = g_Disk->GetDiskAddressBuffer();
@ -94,7 +94,7 @@ void CDMA::PI_DMA_READ()
return;
}
//Write ROM Area (for 64DD Convert)
// Write ROM area (for 64DD conversion)
if (g_Reg->PI_CART_ADDR_REG >= 0x10000000 && g_Reg->PI_CART_ADDR_REG <= 0x1FBFFFFF && g_Settings->LoadBool(Game_AllowROMWrites))
{
uint32_t i;
@ -172,7 +172,7 @@ void CDMA::PI_DMA_READ()
}
if (g_System->m_SaveUsing == SaveChip_FlashRam)
{
g_Notify->DisplayError(stdstr_f("**** FLashRam DMA Read address %08X *****", g_Reg->PI_CART_ADDR_REG).c_str());
g_Notify->DisplayError(stdstr_f("**** FlashRAM DMA read address %08X ****", g_Reg->PI_CART_ADDR_REG).c_str());
g_Reg->PI_STATUS_REG &= ~PI_STATUS_DMA_BUSY;
g_Reg->MI_INTR_REG |= MI_INTR_PI;
g_Reg->CheckInterrupts();
@ -180,7 +180,7 @@ void CDMA::PI_DMA_READ()
}
if (HaveDebugger())
{
g_Notify->DisplayError(stdstr_f("PI_DMA_READ where are you dmaing to ? : %08X", g_Reg->PI_CART_ADDR_REG).c_str());
g_Notify->DisplayError(stdstr_f("PI_DMA_READ where are you DMAing to? : %08X", g_Reg->PI_CART_ADDR_REG).c_str());
}
g_Reg->PI_STATUS_REG &= ~PI_STATUS_DMA_BUSY;
g_Reg->MI_INTR_REG |= MI_INTR_PI;
@ -190,24 +190,24 @@ void CDMA::PI_DMA_READ()
void CDMA::PI_DMA_WRITE()
{
/* rounding PI_WR_LEN_REG up to the nearest even number fixes AI Shougi 3, Doraemon 3, etc. */
// Rounding PI_WR_LEN_REG up to the nearest even number fixes AI Shougi 3, Doraemon 3, etc.
uint32_t PI_WR_LEN_REG = ((g_Reg->PI_WR_LEN_REG) & 0x00FFFFFEul) + 2;
uint32_t PI_CART_ADDR_REG = !g_Settings->LoadBool(Game_UnalignedDMA) ? g_Reg->PI_CART_ADDR_REG & ~1 : g_Reg->PI_CART_ADDR_REG;
g_Reg->PI_STATUS_REG |= PI_STATUS_DMA_BUSY;
if (g_Reg->PI_DRAM_ADDR_REG + PI_WR_LEN_REG > g_MMU->RdramSize())
{
if (ShowUnhandledMemory()) { g_Notify->DisplayError(stdstr_f("PI_DMA_WRITE not in Memory: %08X", g_Reg->PI_DRAM_ADDR_REG + PI_WR_LEN_REG).c_str()); }
if (ShowUnhandledMemory()) { g_Notify->DisplayError(stdstr_f("PI_DMA_WRITE not in memory: %08X", g_Reg->PI_DRAM_ADDR_REG + PI_WR_LEN_REG).c_str()); }
g_Reg->PI_STATUS_REG &= ~PI_STATUS_DMA_BUSY;
g_Reg->MI_INTR_REG |= MI_INTR_PI;
g_Reg->CheckInterrupts();
return;
}
//64DD Buffers Read
// 64DD buffers read
if (PI_CART_ADDR_REG >= 0x05000000 && PI_CART_ADDR_REG <= 0x050003FF)
{
//64DD C2 Sectors (just read 0)
// 64DD C2 sectors (just read 0)
uint32_t i;
uint8_t * RDRAM = g_MMU->Rdram();
for (i = 0; i < PI_WR_LEN_REG; i++)
@ -215,14 +215,14 @@ void CDMA::PI_DMA_WRITE()
*(RDRAM + ((g_Reg->PI_DRAM_ADDR_REG + i) ^ 3)) = 0;
}
//Timer is needed for Track Read
// Timer is needed for track read
g_SystemTimer->SetTimer(g_SystemTimer->DDPiTimer, (PI_WR_LEN_REG * 63) / 25, false);
return;
}
if (PI_CART_ADDR_REG >= 0x05000400 && PI_CART_ADDR_REG <= 0x050004FF)
{
//64DD User Sector
// 64DD user sector
uint32_t i;
uint8_t * RDRAM = g_MMU->Rdram();
uint8_t * DISK = g_Disk->GetDiskAddressBuffer();
@ -231,7 +231,7 @@ void CDMA::PI_DMA_WRITE()
*(RDRAM + ((g_Reg->PI_DRAM_ADDR_REG + i) ^ 3)) = *(DISK + (i ^ 3));
}
//Timer is needed for Track Read
// Timer is needed for track read
g_SystemTimer->SetTimer(g_SystemTimer->DDPiTimer, (PI_WR_LEN_REG * 63) / 25, false);
return;
}
@ -483,7 +483,7 @@ void CDMA::SP_DMA_READ()
{
if (HaveDebugger())
{
g_Notify->DisplayError(stdstr_f("%s\nSP_DRAM_ADDR_REG not in RDRam space : % 08X", __FUNCTION__, g_Reg->SP_DRAM_ADDR_REG).c_str());
g_Notify->DisplayError(stdstr_f("%s\nSP_DRAM_ADDR_REG not in RDRAM space: % 08X", __FUNCTION__, g_Reg->SP_DRAM_ADDR_REG).c_str());
}
g_Reg->SP_DMA_BUSY_REG = 0;
g_Reg->SP_STATUS_REG &= ~SP_STATUS_DMA_BUSY;
@ -525,7 +525,7 @@ void CDMA::SP_DMA_WRITE()
{
if (HaveDebugger())
{
g_Notify->DisplayError(stdstr_f("%s\nSP_DRAM_ADDR_REG not in RDRam space : %08X", __FUNCTION__, g_Reg->SP_DRAM_ADDR_REG).c_str());
g_Notify->DisplayError(stdstr_f("%s\nSP_DRAM_ADDR_REG not in RDRAM space: %08X", __FUNCTION__, g_Reg->SP_DRAM_ADDR_REG).c_str());
}
return;
}
@ -534,7 +534,7 @@ void CDMA::SP_DMA_WRITE()
{
if (HaveDebugger())
{
g_Notify->DisplayError("SP DMA WRITE\ncould not fit copy in memory segement");
g_Notify->DisplayError("SP DMA WRITE\nCould not fit copy in memory segment");
}
return;
}

View File

@ -32,7 +32,7 @@ void CEeprom::EepromCommand(uint8_t * Command)
switch (Command[2])
{
case 0: // check
case 0: // Check
if (g_System->m_SaveUsing != SaveChip_Eeprom_4K && g_System->m_SaveUsing != SaveChip_Eeprom_16K)
{
Command[1] |= 0x80;
@ -61,7 +61,7 @@ void CEeprom::EepromCommand(uint8_t * Command)
Command[5] = 0x00;
}
break;
case 4: // Read from Eeprom
case 4: // Read from EEPROM
if (Command[0] != 2 && HaveDebugger())
{
ProcessingError(Command);
@ -72,7 +72,7 @@ void CEeprom::EepromCommand(uint8_t * Command)
}
ReadFrom(&Command[4], Command[3]);
break;
case 5: //Write to Eeprom
case 5: // Write to EEPROM
if (Command[0] != 10 && HaveDebugger())
{
ProcessingError(Command);
@ -83,7 +83,7 @@ void CEeprom::EepromCommand(uint8_t * Command)
}
WriteTo(&Command[4], Command[3]);
break;
case 6: //RTC Status query
case 6: // RTC status query
Command[3] = 0x00;
Command[4] = 0x10;
Command[5] = 0x00;
@ -97,11 +97,11 @@ void CEeprom::EepromCommand(uint8_t * Command)
Command[12] = 0x00;
break;
case 1:
//read block, Command[2], Unimplemented
// Read block, Command[2], unimplemented
break;
case 2: //Set RTC Time
case 2: // Set RTC time
time(&curtime_time);
memcpy(&curtime, localtime(&curtime_time), sizeof(curtime)); // fd's fix
memcpy(&curtime, localtime(&curtime_time), sizeof(curtime));
Command[4] = byte2bcd(curtime.tm_sec);
Command[5] = byte2bcd(curtime.tm_min);
Command[6] = 0x80 + byte2bcd(curtime.tm_hour);
@ -110,7 +110,7 @@ void CEeprom::EepromCommand(uint8_t * Command)
Command[9] = byte2bcd(curtime.tm_mon + 1);
Command[10] = byte2bcd(curtime.tm_year);
Command[11] = byte2bcd(curtime.tm_year / 100);
Command[12] = 0x00; // status
Command[12] = 0x00; // Status
break;
}
break;
@ -199,6 +199,6 @@ void CEeprom::ProcessingError(uint8_t * /*Command*/)
{
if (bShowPifRamErrors())
{
g_Notify->DisplayError("What am I meant to do with this Eeprom Command");
g_Notify->DisplayError("What am I meant to do with this EEPROM command?");
}
}

View File

@ -40,7 +40,7 @@ void CFlashram::DmaFromFlashram(uint8_t * dest, int32_t StartOffset, int32_t len
{
if (HaveDebugger())
{
g_Notify->DisplayError(stdstr_f("%s: Unaligned flash ram read ???", __FUNCTION__).c_str());
g_Notify->DisplayError(stdstr_f("%s: Unaligned flash RAM read?", __FUNCTION__).c_str());
}
return;
}
@ -178,7 +178,7 @@ void CFlashram::WriteToFlashCommand(uint32_t FlashRAM_Command)
}
break;
default:
g_Notify->DisplayError(stdstr_f("Writing %X to flash ram command register\nm_FlashFlag: %d", FlashRAM_Command, m_FlashFlag).c_str());
g_Notify->DisplayError(stdstr_f("Writing %X to flash RAM command register\nm_FlashFlag: %d", FlashRAM_Command, m_FlashFlag).c_str());
}
m_FlashFlag = FLASHRAM_MODE_NOPES;
break;
@ -199,7 +199,7 @@ void CFlashram::WriteToFlashCommand(uint32_t FlashRAM_Command)
m_FlashStatus = 0x1111800800C2001E;
break;
case 0xB4000000:
m_FlashFlag = FLASHRAM_MODE_WRITE; //????
m_FlashFlag = FLASHRAM_MODE_WRITE;
break;
case 0xA5000000:
m_FlashRAM_Offset = (FlashRAM_Command & 0xFFFF) * sizeof(EmptyBlock);
@ -208,7 +208,7 @@ void CFlashram::WriteToFlashCommand(uint32_t FlashRAM_Command)
default:
if (HaveDebugger())
{
g_Notify->DisplayError(stdstr_f("Writing %X to flash ram command register", FlashRAM_Command).c_str());
g_Notify->DisplayError(stdstr_f("Writing %X to flash RAM command register", FlashRAM_Command).c_str());
}
}
}

View File

@ -1,8 +1,9 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64
// Copyright(C) 2015 Bobby Smiles
// GNU/GPLv2 licensed: https://gnu.org/licenses/gpl-2.0.html
#include "stdafx.h"
#include "GBCart.h"
@ -15,10 +16,10 @@ static void read_gb_cart_normal(struct gb_cart* gb_cart, uint16_t address, uint8
if ((address >= 0x0000) && (address <= 0x7FFF))
{
//Read GB Cart
// Read Game Boy cart
if (address >= gb_cart->rom_size)
{
//If address is larger then our rome size, bail out
// If address is larger then our ROM size, bail out
return;
}
memcpy(data, &gb_cart->rom[address], 0x20);
@ -35,7 +36,7 @@ static void read_gb_cart_normal(struct gb_cart* gb_cart, uint16_t address, uint8
offset = address - 0xA000;
if (offset >= gb_cart->ram_size)
{
//Offset is larger then our ram size
// Offset is larger then our RAM size
return;
}
@ -59,7 +60,7 @@ static void write_gb_cart_normal(struct gb_cart* gb_cart, uint16_t address, cons
offset = address - 0xa000;
if (offset >= gb_cart->ram_size)
{
//Offset is larger then our ram size
// Offset is larger then our RAM size
return;
}
@ -71,7 +72,7 @@ static void read_gb_cart_mbc1(struct gb_cart* gb_cart, uint16_t address, uint8_t
{
size_t offset;
if ((address >= 0x0000) && (address <= 0x3FFF)) //No nbanked memory
if ((address >= 0x0000) && (address <= 0x3FFF)) // No unbanked memory
{
memcpy(data, &gb_cart->rom[address], 0x20);
}
@ -107,10 +108,10 @@ static void write_gb_cart_mbc1(struct gb_cart* gb_cart, uint16_t address, const
}
else if ((address >= 0x2000) && (address <= 0x3FFF)) // ROM bank select
{
gb_cart->rom_bank &= 0x60; // keep MSB
gb_cart->rom_bank &= 0x60; // Keep MSB
gb_cart->rom_bank |= data[0] & 0x1F;
// emulate quirk: 0x00 -> 0x01, 0x20 -> 0x21, 0x40->0x41, 0x60 -> 0x61
// Emulate quirk: 0x00 -> 0x01, 0x20 -> 0x21, 0x40->0x41, 0x60 -> 0x61
if ((gb_cart->rom_bank & 0x1F) == 0)
{
gb_cart->rom_bank |= 0x01;
@ -125,27 +126,27 @@ static void write_gb_cart_mbc1(struct gb_cart* gb_cart, uint16_t address, const
else
{
gb_cart->rom_bank &= 0x1F;
gb_cart->rom_bank |= ((data[0] & 0x03) << 5); // set bits 5 and 6 of ROM bank
gb_cart->rom_bank |= ((data[0] & 0x03) << 5); // Set bits 5 and 6 of ROM bank
}
}
else if ((address >= 0x6000) && (address <= 0x7FFF)) // MBC1 mode select
{
// this is overly complicated, but it keeps us from having to do bitwise math later
// Basically we shuffle the 2 "magic bits" between rom_bank and ram_bank as necessary.
// This is overly complicated, but it keeps us from having to do bitwise math later
// Basically we shuffle the 2 "magic bits" between rom_bank and ram_bank as necessary
if (gb_cart->ram_bank_mode != (data[0] & 0x01))
{
// we should only alter the ROM and RAM bank numbers if we have changed modes
// We should only alter the ROM and RAM bank numbers if we have changed modes
gb_cart->ram_bank_mode = data[0] & 0x01;
if (gb_cart->ram_bank_mode)
{
gb_cart->ram_bank = gb_cart->rom_bank >> 5; // set the ram bank to the "magic bits"
gb_cart->rom_bank &= 0x1F; // zero out bits 5 and 6 to keep consistency
gb_cart->ram_bank = gb_cart->rom_bank >> 5; // Set the RAM bank to the "magic bits"
gb_cart->rom_bank &= 0x1F; // Zero out bits 5 and 6 to keep consistency
}
else
{
gb_cart->rom_bank &= 0x1F;
gb_cart->rom_bank |= (gb_cart->ram_bank << 5);
gb_cart->ram_bank = 0x00; // we can only reach RAM page 0
gb_cart->ram_bank = 0x00; // We can only reach RAM page 0
}
}
}
@ -166,11 +167,11 @@ static void read_gb_cart_mbc2(struct gb_cart* gb_cart, uint16_t address, uint8_t
{
size_t offset;
if ((address < 0x4000)) //Rom Bank 0
if ((address < 0x4000)) // ROM bank 0
{
memcpy(data, &gb_cart->rom[address], 0x20);
}
else if ((address >= 0x4000) && (address < 0x8000)) //Switchable Rom Bank
else if ((address >= 0x4000) && (address < 0x8000)) // Switchable ROM bank
{
offset = (address - 0x4000) + (gb_cart->rom_bank * 0x4000);
if (offset < gb_cart->rom_size)
@ -178,7 +179,7 @@ static void read_gb_cart_mbc2(struct gb_cart* gb_cart, uint16_t address, uint8_t
memcpy(data, &gb_cart->rom[offset], 0x20);
}
}
else if ((address >= 0xA000) && (address <= 0xC000)) //Upper Bounds of memory map
else if ((address >= 0xA000) && (address <= 0xC000)) // Upper bounds of memory map
{
if (gb_cart->ram != nullptr)
{
@ -232,7 +233,7 @@ void memoryUpdateMBC3Clock(struct gb_cart* gb_cart)
time_t now = time(nullptr);
time_t diff = now - gb_cart->rtc_last_time;
if (diff > 0) {
// update the clock according to the last update time
// Update the clock according to the last update time
gb_cart->rtc_data[0] += (int)(diff % 60);
if (gb_cart->rtc_data[0] > 59) {
gb_cart->rtc_data[0] -= 60;
@ -270,11 +271,11 @@ static void read_gb_cart_mbc3(struct gb_cart* gb_cart, uint16_t address, uint8_t
{
size_t offset;
if ((address < 0x4000)) //Rom Bank 0
if ((address < 0x4000)) // ROM bank 0
{
memcpy(data, &gb_cart->rom[address], 0x20);
}
else if ((address >= 0x4000) && (address < 0x8000)) //Switchable Rom Bank
else if ((address >= 0x4000) && (address < 0x8000)) // Switchable ROM bank
{
offset = (address - 0x4000) + (gb_cart->rom_bank * 0x4000);
if (offset < gb_cart->rom_size)
@ -282,7 +283,7 @@ static void read_gb_cart_mbc3(struct gb_cart* gb_cart, uint16_t address, uint8_t
memcpy(data, &gb_cart->rom[offset], 0x20);
}
}
else if ((address >= 0xA000) && (address <= 0xC000)) //Upper Bounds of memory map
else if ((address >= 0xA000) && (address <= 0xC000)) // Upper bounds of memory map
{
if (gb_cart->ram != nullptr)
{
@ -323,7 +324,7 @@ static void write_gb_cart_mbc3(struct gb_cart* gb_cart, uint16_t address, const
if ((address >= 0x0000) && (address <= 0x1FFF)) // We shouldn't be able to read/write to RAM unless this is toggled on
{
//Enable / Disable RAM -- NOT WORKING -- FIXME
// Enable / Disable RAM -- NOT WORKING --
gb_cart->ram_enabled = (data[0] & 0x0F) == 0x0A;
}
else if ((address >= 0x2000) && (address <= 0x3FFF)) // ROM bank select
@ -331,7 +332,7 @@ static void write_gb_cart_mbc3(struct gb_cart* gb_cart, uint16_t address, const
bank = data[0] & 0x7F;
gb_cart->rom_bank = (bank == 0) ? 1 : bank;
}
else if ((address >= 0x4000) && (address <= 0x5FFF)) // RAM/Clock bank select
else if ((address >= 0x4000) && (address <= 0x5FFF)) // RAM/clock bank select
{
if (gb_cart->ram != nullptr)
{
@ -375,7 +376,7 @@ static void write_gb_cart_mbc3(struct gb_cart* gb_cart, uint16_t address, const
}
else if (gb_cart->has_rtc)
{
/* RTC write */
// RTC write
gb_cart->rtc_data[gb_cart->ram_bank - 0x08] = data[0];
}
}
@ -396,11 +397,11 @@ static void read_gb_cart_mbc5(struct gb_cart * gb_cart, uint16_t address, uint8_
{
size_t offset;
if ((address < 0x4000)) //Rom Bank 0
if ((address < 0x4000)) // ROM bank 0
{
memcpy(data, &gb_cart->rom[address], 0x20);
}
else if ((address >= 0x4000) && (address < 0x8000)) //Switchable ROM BANK
else if ((address >= 0x4000) && (address < 0x8000)) // Switchable ROM bank
{
offset = (address - 0x4000) + (gb_cart->rom_bank * 0x4000);
if (offset < gb_cart->rom_size)
@ -427,7 +428,7 @@ static void write_gb_cart_mbc5(struct gb_cart* gb_cart, uint16_t address, const
if ((address >= 0x0000) && (address <= 0x1FFF)) // We shouldn't be able to read/write to RAM unless this is toggled on
{
//Enable / Disable RAM -- NOT WORKING -- CHECK ME
// Enable / Disable RAM -- NOT WORKING --
gb_cart->ram_enabled = (data[0] & 0x0F) == 0x0A;
}
else if ((address >= 0x2000) && (address <= 0x2FFF)) // ROM bank select, low bits
@ -474,11 +475,11 @@ static void read_gb_cart_pocket_cam(struct gb_cart * gb_cart, uint16_t address,
{
size_t offset;
if ((address < 0x4000)) //Rom Bank 0
if ((address < 0x4000)) // ROM bank 0
{
memcpy(data, &gb_cart->rom[address], 0x20);
}
else if ((address >= 0x4000) && (address < 0x8000)) //Switchable ROM BANK
else if ((address >= 0x4000) && (address < 0x8000)) // Switchable ROM bank
{
offset = (address - 0x4000) + (gb_cart->rom_bank * 0x4000);
if (offset < gb_cart->rom_size)
@ -493,8 +494,8 @@ static void read_gb_cart_pocket_cam(struct gb_cart * gb_cart, uint16_t address,
{
if (gb_cart->ram_bank & 0x10)
{
//Where in register mode, based off NRAGE we just fill the memory with Zeroes.
//Seems to be incorrect behaviour but need to find more doccumentation
// When in register mode, based off of N-Rage code we just fill the memory with zeroes
// Seems to be incorrect behavior, but need to find more documentation
memset(data, 0x00, 0x20);
}
else
@ -524,18 +525,18 @@ static void write_gb_cart_pocket_cam(struct gb_cart* gb_cart, uint16_t address,
gb_cart->rom_bank &= 0xFF00;
gb_cart->rom_bank |= data[0];
}
else if ((address >= 0x4000) && (address <= 0x4FFF)) // Camera Register & RAM bank select
else if ((address >= 0x4000) && (address <= 0x4FFF)) // Camera register and RAM bank select
{
if (gb_cart->ram != nullptr)
{
if (data[0] & 0x10)
{
//REGISTER MODE
// Register mode
gb_cart->ram_bank = data[0];
}
else
{
//RAM MODE
// RAM mode
gb_cart->ram_bank = data[0] & 0x0F;
}
}
@ -546,11 +547,11 @@ static void write_gb_cart_pocket_cam(struct gb_cart* gb_cart, uint16_t address,
{
if (gb_cart->ram_bank & 0x10)
{
//REGISTER MODE (DO NOTHING)
// Register mode (do nothing)
}
else
{
//RAM MODE
// RAM mode
offset = (address - 0xA000) + (gb_cart->ram_bank * 0x2000);
if (offset < gb_cart->ram_size)
{
@ -688,10 +689,10 @@ bool GBCart::init_gb_cart(struct gb_cart* gb_cart, const char* gb_file)
size_t ram_size = 0;
CFile tempFile;
/* load GB cart ROM */
// Load Game Boy cart ROM
if (!tempFile.Open(gb_file, CFileBase::modeRead))
{
g_Notify->DisplayError("Failed to open Transferpak ROM");
g_Notify->DisplayError("Failed to open Transfer Pak ROM");
return false;
}
@ -706,7 +707,7 @@ bool GBCart::init_gb_cart(struct gb_cart* gb_cart, const char* gb_file)
return false;
}
/* get and parse cart type */
// Get and parse cart type
uint8_t cart_type = rom.get()[0x147];
type = parse_cart_type(cart_type);
if (type == nullptr)
@ -714,7 +715,7 @@ bool GBCart::init_gb_cart(struct gb_cart* gb_cart, const char* gb_file)
return false;
}
/* load ram (if present) */
// Load RAM (if present)
if (type->extra_devices & GED_RAM)
{
ram_size = 0;
@ -737,7 +738,7 @@ bool GBCart::init_gb_cart(struct gb_cart* gb_cart, const char* gb_file)
if (!tempFile.Open(g_Settings->LoadStringVal(Game_Transferpak_Sav).c_str(), CFileBase::modeRead))
{
g_Notify->DisplayError("Failed to open Transferpak SAV File");
g_Notify->DisplayError("Failed to open Transfer Pak SAV file");
return false;
}
@ -763,7 +764,7 @@ bool GBCart::init_gb_cart(struct gb_cart* gb_cart, const char* gb_file)
tempFile.Close();
}
/* update gb_cart */
// Update gb_cart
gb_cart->rom = rom.release();
gb_cart->ram = ram.release();
gb_cart->rom_size = rom_size;

View File

@ -38,6 +38,3 @@ public:
static void read_gb_cart(struct gb_cart* gb_cart, uint16_t address, uint8_t* data);
static void write_gb_cart(struct gb_cart* gb_cart, uint16_t address, const uint8_t* data);
};

View File

@ -141,7 +141,7 @@ bool CMipsMemoryVM::Initialize(bool SyncSystem)
}
if (m_RDRAM == nullptr)
{
WriteTrace(TraceN64System, TraceError, "Failed to Reserve RDRAM (Size: 0x%X)", 0x20000000);
WriteTrace(TraceN64System, TraceError, "Failed to reserve RDRAM (Size: 0x%X)", 0x20000000);
FreeMemory();
return false;
}
@ -149,14 +149,14 @@ bool CMipsMemoryVM::Initialize(bool SyncSystem)
m_AllocatedRdramSize = g_Settings->LoadDword(Game_RDRamSize);
if (CommitMemory(m_RDRAM, m_AllocatedRdramSize, MEM_READWRITE) == nullptr)
{
WriteTrace(TraceN64System, TraceError, "Failed to Allocate RDRAM (Size: 0x%X)", m_AllocatedRdramSize);
WriteTrace(TraceN64System, TraceError, "Failed to allocate RDRAM (Size: 0x%X)", m_AllocatedRdramSize);
FreeMemory();
return false;
}
if (CommitMemory(m_RDRAM + 0x04000000, 0x2000, MEM_READWRITE) == nullptr)
{
WriteTrace(TraceN64System, TraceError, "Failed to Allocate DMEM/IMEM (Size: 0x%X)", 0x2000);
WriteTrace(TraceN64System, TraceError, "Failed to allocate DMEM/IMEM (Size: 0x%X)", 0x2000);
FreeMemory();
return false;
}
@ -171,7 +171,7 @@ bool CMipsMemoryVM::Initialize(bool SyncSystem)
m_RomSize = g_Rom->GetRomSize();
if (CommitMemory(m_Rom, g_Rom->GetRomSize(), MEM_READWRITE) == nullptr)
{
WriteTrace(TraceN64System, TraceError, "Failed to Allocate Rom (Size: 0x%X)", g_Rom->GetRomSize());
WriteTrace(TraceN64System, TraceError, "Failed to allocate ROM (Size: 0x%X)", g_Rom->GetRomSize());
FreeMemory();
return false;
}
@ -196,7 +196,7 @@ bool CMipsMemoryVM::Initialize(bool SyncSystem)
m_DDRomSize = g_DDRom->GetRomSize();
if (CommitMemory(m_DDRom, g_DDRom->GetRomSize(), MEM_READWRITE) == nullptr)
{
WriteTrace(TraceN64System, TraceError, "Failed to Allocate Rom (Size: 0x%X)", g_DDRom->GetRomSize());
WriteTrace(TraceN64System, TraceError, "Failed to allocate ROM (Size: 0x%X)", g_DDRom->GetRomSize());
FreeMemory();
return false;
}
@ -217,7 +217,7 @@ bool CMipsMemoryVM::Initialize(bool SyncSystem)
m_TLB_ReadMap = new size_t[0x100000];
if (m_TLB_ReadMap == nullptr)
{
WriteTrace(TraceN64System, TraceError, "Failed to Allocate m_TLB_ReadMap (Size: 0x%X)", 0x100000 * sizeof(size_t));
WriteTrace(TraceN64System, TraceError, "Failed to allocate m_TLB_ReadMap (Size: 0x%X)", 0x100000 * sizeof(size_t));
FreeMemory();
return false;
}
@ -225,7 +225,7 @@ bool CMipsMemoryVM::Initialize(bool SyncSystem)
m_TLB_WriteMap = new size_t[0x100000];
if (m_TLB_WriteMap == nullptr)
{
WriteTrace(TraceN64System, TraceError, "Failed to Allocate m_TLB_WriteMap (Size: 0x%X)", 0xFFFFF * sizeof(size_t));
WriteTrace(TraceN64System, TraceError, "Failed to allocate m_TLB_WriteMap (Size: 0x%X)", 0xFFFFF * sizeof(size_t));
FreeMemory();
return false;
}
@ -583,7 +583,7 @@ bool CMipsMemoryVM::VAddrToRealAddr(uint32_t VAddr, void * &RealAddress) const
bool CMipsMemoryVM::TranslateVaddr(uint32_t VAddr, uint32_t &PAddr) const
{
//Change the Virtual address to a Physical Address
// Change the virtual address to a physical address
if (m_TLB_ReadMap[VAddr >> 12] == 0)
{
return false;
@ -807,7 +807,7 @@ bool CMipsMemoryVM::SW_NonMemory(uint32_t PAddr, uint32_t Value)
VirtualProtect(ROM, RomFileSize, PAGE_NOACCESS, &OldProtect);
}
#endif
//LogMessage("%X: Wrote To Rom %08X from %08X",PROGRAM_COUNTER,Value,PAddr);
//LogMessage("%X: Wrote To ROM %08X from %08X",PROGRAM_COUNTER,Value,PAddr);
}
else
{
@ -916,7 +916,7 @@ void CMipsMemoryVM::ProtectMemory(uint32_t StartVaddr, uint32_t EndVaddr)
return;
}
//Get Physical Addresses passed
// Get physical addresses passed
uint32_t StartPAddr, EndPAddr;
if (!TranslateVaddr(StartVaddr, StartPAddr))
{
@ -927,7 +927,7 @@ void CMipsMemoryVM::ProtectMemory(uint32_t StartVaddr, uint32_t EndVaddr)
g_Notify->BreakPoint(__FILE__, __LINE__);
}
//Get Length of memory being protected
// Get length of memory being protected
int32_t Length = ((EndPAddr + 3) - StartPAddr) & ~3;
if (Length < 0)
{
@ -946,7 +946,7 @@ void CMipsMemoryVM::UnProtectMemory(uint32_t StartVaddr, uint32_t EndVaddr)
WriteTrace(TraceProtectedMem, TraceDebug, "StartVaddr: %08X EndVaddr: %08X", StartVaddr, EndVaddr);
if (!ValidVaddr(StartVaddr) || !ValidVaddr(EndVaddr)) { return; }
//Get Physical Addresses passed
// Get physical addresses passed
uint32_t StartPAddr, EndPAddr;
if (!TranslateVaddr(StartVaddr, StartPAddr))
{
@ -957,7 +957,7 @@ void CMipsMemoryVM::UnProtectMemory(uint32_t StartVaddr, uint32_t EndVaddr)
g_Notify->BreakPoint(__FILE__, __LINE__);
}
//Get Length of memory being protected
// Get length of memory being protected
int32_t Length = ((EndPAddr + 3) - StartPAddr) & ~3;
if (Length < 0)
{
@ -1028,15 +1028,15 @@ void CMipsMemoryVM::RdramChanged(CMipsMemoryVM * _this)
void * result = CommitMemory(_this->m_RDRAM + old_size, new_size - old_size, MEM_READWRITE);
if (result == nullptr)
{
WriteTrace(TraceN64System, TraceError, "failed to allocate extended memory");
WriteTrace(TraceN64System, TraceError, "Failed to allocate extended memory");
g_Notify->FatalError(GS(MSG_MEM_ALLOC_ERROR));
}
}
if (new_size > 0xFFFFFFFFul)
{ // should be unreachable because: size_t new_size = g_Settings->(uint32_t)
{ // Should be unreachable because: size_t new_size = g_Settings->(uint32_t)
g_Notify->BreakPoint(__FILE__, __LINE__);
} // ...However, FFFFFFFF also is a limit to RCP addressing, so we care.
} // However, FFFFFFFF also is a limit to RCP addressing, so we care
_this->m_AllocatedRdramSize = (uint32_t)new_size;
}
@ -1452,7 +1452,7 @@ void CMipsMemoryVM::Load32CartridgeDomain1Address3(void)
void CMipsMemoryVM::Load32CartridgeDomain2Address1(void)
{
//64DD REGISTERS
// 64DD registers
if (g_Settings->LoadBool(Setting_EnableDisk))
{
switch (m_MemLookupAddress & 0x1FFFFFFF)
@ -1509,7 +1509,7 @@ void CMipsMemoryVM::Load32CartridgeDomain2Address2(void)
}
if (g_System->m_SaveUsing == SaveChip_Sram)
{
//Load Sram
// Load SRAM
uint8_t tmp[4] = "";
g_MMU->DmaFromSram(tmp, offset, 4);
m_MemLookupValue.UW[0] = tmp[3] << 24 | tmp[2] << 16 | tmp[1] << 8 | tmp[0];
@ -1561,7 +1561,7 @@ void CMipsMemoryVM::Load32Rom(void)
if (g_MMU->m_RomWrittenTo)
{
m_MemLookupValue.UW[0] = g_MMU->m_RomWroteValue;
//LogMessage("%X: Read crap from Rom %08X from %08X",PROGRAM_COUNTER,*Value,PAddr);
//LogMessage("%X: Read crap from ROM %08X from %08X",PROGRAM_COUNTER,*Value,PAddr);
g_MMU->m_RomWrittenTo = false;
#ifdef ROM_IN_MAPSPACE
{
@ -2021,7 +2021,7 @@ void CMipsMemoryVM::Write32AudioInterface(void)
break;
case 0x04500008: g_Reg->AI_CONTROL_REG = (m_MemLookupValue.UW[0] & 1); break;
case 0x0450000C:
/* Clear Interrupt */;
// Clear interrupt
g_Reg->MI_INTR_REG &= ~MI_INTR_AI;
g_Reg->m_AudioIntrReg &= ~MI_INTR_AI;
g_Reg->CheckInterrupts();
@ -2138,7 +2138,7 @@ void CMipsMemoryVM::Write32SerialInterface(void)
void CMipsMemoryVM::Write32CartridgeDomain2Address1(void)
{
//64DD Registers
// 64DD registers
if (g_Settings->LoadBool(Setting_EnableDisk))
{
switch (m_MemLookupAddress & 0xFFFFFFF)
@ -2174,7 +2174,7 @@ void CMipsMemoryVM::Write32CartridgeDomain2Address2(void)
uint32_t offset = (m_MemLookupAddress & 0x1FFFFFFF) - 0x08000000;
if (g_System->m_SaveUsing == SaveChip_Sram && offset < 0x8000)
{
//Store Sram
// Store SRAM
uint8_t tmp[4] = "";
tmp[0] = 0xFF & (m_MemLookupValue.UW[0]);
tmp[1] = 0xFF & (m_MemLookupValue.UW[0] >> 8);

View File

@ -14,14 +14,14 @@
#ifndef _WIN32
#include <signal.h>
/* siginfo_t */
// siginfo_t
#endif
/*
* To do: Have address translation functions here?
* TODO: Have address translation functions here?
* `return` either the translated address or the mask to XOR by?
*
* This will help us gradually be able to port Project64 for big-endian CPUs.
* This will help us gradually be able to port Project64 to big-endian CPUs.
* Currently it is written to assume 32-bit little-endian, like so:
*
* 0xAABBCCDD EEFFGGHH --> 0xDDCCBBAA HHGGFFEE
@ -88,7 +88,7 @@ public:
static void segv_handler(int signal, siginfo_t *siginfo, void *sigcontext);
#endif
//Protect the Memory from being written to
// Protect the memory from being written to
void ProtectMemory(uint32_t StartVaddr, uint32_t EndVaddr);
void UnProtectMemory(uint32_t StartVaddr, uint32_t EndVaddr);
@ -179,24 +179,24 @@ private:
static bool FilterArmException(uint32_t MemAddress, mcontext_t & context);
#endif
//Memory Locations
// Memory locations
static uint8_t * m_Reserve1, *m_Reserve2;
uint8_t * m_RDRAM, *m_DMEM, *m_IMEM;
uint32_t m_AllocatedRdramSize;
//Rom Information
// ROM information
bool m_RomMapped;
uint8_t * m_Rom;
uint32_t m_RomSize;
bool m_RomWrittenTo;
uint32_t m_RomWroteValue;
//DDRom Information
// DDRom information
bool m_DDRomMapped;
uint8_t * m_DDRom;
uint32_t m_DDRomSize;
//Current Half line
//Current half line
void UpdateHalfLine();
uint32_t m_HalfLine;
uint32_t m_HalfLineCheck;
@ -207,7 +207,7 @@ private:
mutable char m_strLabelName[100];
//BIG look up table to quickly translate the tlb to real mem address
// Big look up table to quickly translate the TLB to real memory addresses
size_t * m_TLB_ReadMap;
size_t * m_TLB_WriteMap;

View File

@ -165,7 +165,7 @@ void CMempak::ReadFrom(int32_t Control, uint32_t address, uint8_t * data)
else
{
memset(data, 0x00, 0x20);
/* Rumble pack area */
// Rumble pack area
}
}
@ -192,6 +192,6 @@ void CMempak::WriteTo(int32_t Control, uint32_t address, uint8_t * data)
}
else
{
/* Rumble pack area */
// Rumble pack area
}
}

View File

@ -557,7 +557,7 @@ const char * R4300iOpcodeName(uint32_t OpCode, uint32_t PC)
sprintf(CommandName, "ADDI\t%s, %s, 0x%04X", CRegName::GPR[command.rt], CRegName::GPR[command.rs], command.immediate);
break;
case R4300i_ADDIU:
// special case for stack
// Special case for stack
if (command.rt == 29)
{
short imm = (short)command.immediate;

View File

@ -84,7 +84,7 @@ void CPifRam::PifRamRead()
case 0xFD: CurPos = 0x40; break;
case 0xFE: CurPos = 0x40; break;
case 0xFF: break;
case 0xB4: case 0x56: case 0xB8: break; /* ??? */
case 0xB4: case 0x56: case 0xB8: break;
default:
if ((m_PifRam[CurPos] & 0xC0) == 0)
{
@ -109,7 +109,7 @@ void CPifRam::PifRamRead()
{
if (CurPos != 0x27 && bShowPifRamErrors())
{
g_Notify->DisplayError(stdstr_f("Unknown Command in PifRamRead(%X)", m_PifRam[CurPos]).c_str());
g_Notify->DisplayError(stdstr_f("Unknown command in PifRamRead(%X)", m_PifRam[CurPos]).c_str());
}
CurPos = 0x40;
}
@ -132,7 +132,7 @@ void CPifRam::PifRamWrite()
switch (m_PifRam[0x3F])
{
case 0x02:
// format the 'challenge' message into 30 nibbles for X-Scale's CIC code
// Format the 'challenge' message into 30 nibbles for X-Scale's CIC code
{
char Challenge[30], Response[30];
for (int32_t i = 0; i < 15; i++)
@ -174,7 +174,7 @@ void CPifRam::PifRamWrite()
default:
if (bShowPifRamErrors())
{
g_Notify->DisplayError(stdstr_f("Unkown PifRam control: %d", m_PifRam[0x3F]).c_str());
g_Notify->DisplayError(stdstr_f("Unknown PifRam control: %d", m_PifRam[0x3F]).c_str());
}
}
return;
@ -194,7 +194,7 @@ void CPifRam::PifRamWrite()
case 0xFD: CurPos = 0x40; break;
case 0xFE: CurPos = 0x40; break;
case 0xFF: break;
case 0xB4: case 0x56: case 0xB8: break; /* ??? */
case 0xB4: case 0x56: case 0xB8: break; // ???
default:
if ((m_PifRam[CurPos] & 0xC0) == 0)
{
@ -254,7 +254,7 @@ void CPifRam::SI_DMA_READ()
{
if (bShowPifRamErrors())
{
g_Notify->DisplayError(stdstr_f("%s\nSI_DRAM_ADDR_REG not in RDRam space", __FUNCTION__).c_str());
g_Notify->DisplayError(stdstr_f("%s\nSI_DRAM_ADDR_REG not in RDRAM space", __FUNCTION__).c_str());
}
return;
}
@ -354,7 +354,7 @@ void CPifRam::SI_DMA_WRITE()
{
if (bShowPifRamErrors())
{
g_Notify->DisplayError("SI DMA\nSI_DRAM_ADDR_REG not in RDRam space");
g_Notify->DisplayError("SI DMA\nSI_DRAM_ADDR_REG not in RDRAM space");
}
return;
}
@ -388,7 +388,7 @@ void CPifRam::SI_DMA_WRITE()
int32_t count;
char HexData[100], AsciiData[100], Addon[20];
LogMessage("");
LogMessage("\tData DMAed to the Pif Ram:");
LogMessage("\tData DMAed to the PIF RAM:");
LogMessage("\t--------------------------");
for (count = 0; count < 16; count++)
{
@ -440,8 +440,8 @@ void CPifRam::ProcessControllerCommand(int32_t Control, uint8_t * Command)
switch (Command[2])
{
case 0x00: // check
case 0xFF: // reset & check ?
case 0x00: // Check
case 0xFF: // Reset and check?
if ((Command[1] & 0x80) != 0)
{
break;
@ -450,7 +450,7 @@ void CPifRam::ProcessControllerCommand(int32_t Control, uint8_t * Command)
{
if (Command[0] != 1 || Command[1] != 3)
{
g_Notify->DisplayError("What am I meant to do with this Controller Command");
g_Notify->DisplayError("What am I meant to do with this controller command?");
}
}
if (Controllers[Control].Present != 0)
@ -472,12 +472,12 @@ void CPifRam::ProcessControllerCommand(int32_t Control, uint8_t * Command)
Command[1] |= 0x80;
}
break;
case 0x01: // read controller
case 0x01: // Read controller
if (bShowPifRamErrors())
{
if (Command[0] != 1 || Command[1] != 4)
{
g_Notify->DisplayError("What am I meant to do with this Controller Command");
g_Notify->DisplayError("What am I meant to do with this controller command?");
}
}
if (Controllers[Control].Present == false)
@ -485,16 +485,16 @@ void CPifRam::ProcessControllerCommand(int32_t Control, uint8_t * Command)
Command[1] |= 0x80;
}
break;
case 0x02: //read from controller pack
case 0x02: // Read from controller pak
if (LogControllerPak())
{
LogControllerPakData("Read: Before Gettting Results");
LogControllerPakData("Read: before getting results");
}
if (bShowPifRamErrors())
{
if (Command[0] != 3 || Command[1] != 33)
{
g_Notify->DisplayError("What am I meant to do with this Controller Command");
g_Notify->DisplayError("What am I meant to do with this controller command?");
}
}
if (Controllers[Control].Present != 0)
@ -523,19 +523,19 @@ void CPifRam::ProcessControllerCommand(int32_t Control, uint8_t * Command)
}
if (LogControllerPak())
{
LogControllerPakData("Read: After Gettting Results");
LogControllerPakData("Read: after getting results");
}
break;
case 0x03: //write controller pak
case 0x03: // Write controller pak
if (LogControllerPak())
{
LogControllerPakData("Write: Before Processing");
LogControllerPakData("Write: before processing");
}
if (bShowPifRamErrors())
{
if (Command[0] != 35 || Command[1] != 1)
{
g_Notify->DisplayError("What am I meant to do with this Controller Command");
g_Notify->DisplayError("What am I meant to do with this controller command?");
}
}
if (Controllers[Control].Present != 0)
@ -562,7 +562,7 @@ void CPifRam::ProcessControllerCommand(int32_t Control, uint8_t * Command)
}
if (LogControllerPak())
{
LogControllerPakData("Write: After Processing");
LogControllerPakData("Write: after processing");
}
break;
default:
@ -579,19 +579,19 @@ void CPifRam::ReadControllerCommand(int32_t Control, uint8_t * Command)
switch (Command[2])
{
case 0x01: // read controller
case 0x01: // Read controller
if (Controllers[Control].Present != 0)
{
if (bShowPifRamErrors())
{
if (Command[0] != 1 || Command[1] != 4) { g_Notify->DisplayError("What am I meant to do with this Controller Command"); }
if (Command[0] != 1 || Command[1] != 4) { g_Notify->DisplayError("What am I meant to do with this controller command?"); }
}
const uint32_t buttons = g_BaseSystem->GetButtons(Control);
memcpy(&Command[3], &buttons, sizeof(uint32_t));
}
break;
case 0x02: //read from controller pack
case 0x02: // Read from controller pak
if (Controllers[Control].Present != 0)
{
switch (Controllers[Control].Plugin)
@ -600,7 +600,7 @@ void CPifRam::ReadControllerCommand(int32_t Control, uint8_t * Command)
}
}
break;
case 0x03: //write controller pak
case 0x03: // Write controller pak
if (Controllers[Control].Present != 0)
{
switch (Controllers[Control].Plugin)

View File

@ -261,7 +261,7 @@ void CRegisters::Reset()
m_LLBit = 0;
//Reset System Registers
// Reset system registers
memset(m_RDRAM_Interface, 0, sizeof(m_RDRAM_Interface));
memset(m_RDRAM_Registers, 0, sizeof(m_RDRAM_Registers));
memset(m_Mips_Interface, 0, sizeof(m_Mips_Interface));
@ -350,11 +350,11 @@ void CRegisters::DoAddressError(bool DelaySlot, uint32_t BadVaddr, bool FromRead
g_Notify->DisplayError(stdstr_f("AddressError %s Vaddr: %X", FromRead ? "reading" : "writing", BadVaddr).c_str());
if ((STATUS_REGISTER & STATUS_EXL) != 0)
{
g_Notify->DisplayError("EXL set in AddressError Exception");
g_Notify->DisplayError("EXL set in AddressError exception");
}
if ((STATUS_REGISTER & STATUS_ERL) != 0)
{
g_Notify->DisplayError("ERL set in AddressError Exception");
g_Notify->DisplayError("ERL set in AddressError exception");
}
}
@ -406,11 +406,11 @@ void CRegisters::DoBreakException(bool DelaySlot)
{
if ((STATUS_REGISTER & STATUS_EXL) != 0)
{
g_Notify->DisplayError("EXL set in Break Exception");
g_Notify->DisplayError("EXL set in break exception");
}
if ((STATUS_REGISTER & STATUS_ERL) != 0)
{
g_Notify->DisplayError("ERL set in Break Exception");
g_Notify->DisplayError("ERL set in break exception");
}
}
@ -450,11 +450,11 @@ void CRegisters::DoCopUnusableException(bool DelaySlot, int32_t Coprocessor)
{
if ((STATUS_REGISTER & STATUS_EXL) != 0)
{
g_Notify->DisplayError("EXL set in Break Exception");
g_Notify->DisplayError("EXL set in break exception");
}
if ((STATUS_REGISTER & STATUS_ERL) != 0)
{
g_Notify->DisplayError("ERL set in Break Exception");
g_Notify->DisplayError("ERL set in break exception");
}
}
@ -495,7 +495,7 @@ bool CRegisters::DoIntrException(bool DelaySlot)
if (GenerateLog() && LogExceptions() && !LogNoInterrupts())
{
LogMessage("%08X: Interrupt Generated", m_PROGRAM_COUNTER);
LogMessage("%08X: Interrupt generated", m_PROGRAM_COUNTER);
}
CAUSE_REGISTER = FAKE_CAUSE_REGISTER;
@ -548,7 +548,7 @@ void CRegisters::DoTLBReadMiss(bool DelaySlot, uint32_t BadVaddr)
{
if (HaveDebugger())
{
g_Notify->DisplayError(stdstr_f("TLBMiss - EXL Set\nBadVaddr = %X\nAddress Defined: %s", BadVaddr, g_TLB->AddressDefined(BadVaddr) ? "true" : "false").c_str());
g_Notify->DisplayError(stdstr_f("TLBMiss - EXL set\nBadVaddr = %X\nAddress defined: %s", BadVaddr, g_TLB->AddressDefined(BadVaddr) ? "true" : "false").c_str());
}
m_PROGRAM_COUNTER = 0x80000180;
}
@ -586,7 +586,7 @@ void CRegisters::DoTLBWriteMiss(bool DelaySlot, uint32_t BadVaddr)
{
if (HaveDebugger())
{
g_Notify->DisplayError(stdstr_f("TLBMiss - EXL Set\nBadVaddr = %X\nAddress Defined: %s", BadVaddr, g_TLB->AddressDefined(BadVaddr) ? "true" : "false").c_str());
g_Notify->DisplayError(stdstr_f("TLBMiss - EXL set\nBadVaddr = %X\nAddress defined: %s", BadVaddr, g_TLB->AddressDefined(BadVaddr) ? "true" : "false").c_str());
}
m_PROGRAM_COUNTER = 0x80000180;
}
@ -598,11 +598,11 @@ void CRegisters::DoSysCallException(bool DelaySlot)
{
if ((STATUS_REGISTER & STATUS_EXL) != 0)
{
g_Notify->DisplayError("EXL set in SysCall Exception");
g_Notify->DisplayError("EXL set in syscall exception");
}
if ((STATUS_REGISTER & STATUS_ERL) != 0)
{
g_Notify->DisplayError("ERL set in SysCall Exception");
g_Notify->DisplayError("ERL set in syscall exception");
}
}

View File

@ -42,14 +42,14 @@ private:
// CPO register flags
enum
{
//Status Register
// Status register
STATUS_IE = 0x00000001, STATUS_EXL = 0x00000002, STATUS_ERL = 0x00000004,
STATUS_IP0 = 0x00000100, STATUS_IP1 = 0x00000200, STATUS_IP2 = 0x00000400,
STATUS_IP3 = 0x00000800, STATUS_IP4 = 0x00001000, STATUS_IP5 = 0x00002000,
STATUS_IP6 = 0x00004000, STATUS_IP7 = 0x00008000, STATUS_BEV = 0x00400000,
STATUS_FR = 0x04000000, STATUS_CU0 = 0x10000000, STATUS_CU1 = 0x20000000,
//Cause Flags
// Cause flags
CAUSE_EXC_CODE = 0xFF,
CAUSE_IP0 = 0x100,
CAUSE_IP1 = 0x200,
@ -62,55 +62,55 @@ enum
CAUSE_BD = 0x80000000,
// Cause exception ID's
EXC_INT = 0, /* interrupt */
EXC_MOD = 4, /* TLB mod */
EXC_RMISS = 8, /* Read TLB Miss */
EXC_WMISS = 12, /* Write TLB Miss */
EXC_RADE = 16, /* Read Address Error */
EXC_WADE = 20, /* Write Address Error */
EXC_IBE = 24, /* Instruction Bus Error */
EXC_DBE = 28, /* Data Bus Error */
EXC_SYSCALL = 32, /* SYSCALL */
EXC_BREAK = 36, /* BREAKpoint */
EXC_II = 40, /* Illegal Instruction */
EXC_CPU = 44, /* CoProcessor Unusable */
EXC_OV = 48, /* OVerflow */
EXC_TRAP = 52, /* Trap exception */
EXC_VCEI = 56, /* Virt. Coherency on Inst. fetch */
EXC_FPE = 60, /* Floating Point Exception */
EXC_WATCH = 92, /* Watchpoint reference */
EXC_VCED = 124,/* Virt. Coherency on data read */
EXC_INT = 0, // Interrupt
EXC_MOD = 4, // TLB mod
EXC_RMISS = 8, // Read TLB miss
EXC_WMISS = 12, // Write TLB miss
EXC_RADE = 16, // Read address error
EXC_WADE = 20, // Write address error
EXC_IBE = 24, // Instruction bus error
EXC_DBE = 28, // Data bus error
EXC_SYSCALL = 32, // Syscall
EXC_BREAK = 36, // Breakpoint
EXC_II = 40, // Illegal instruction
EXC_CPU = 44, // Co-processor unusable
EXC_OV = 48, // Overflow
EXC_TRAP = 52, // Trap exception
EXC_VCEI = 56, // Virtual coherency on instruction fetch
EXC_FPE = 60, // Floating point exception
EXC_WATCH = 92, // Watchpoint reference
EXC_VCED = 124, // Virtual coherency on data read
};
// Float point control status register flags
enum
{
FPCSR_FS = 0x01000000, /* flush denorm to zero */
FPCSR_C = 0x00800000, /* condition bit */
FPCSR_CE = 0x00020000, /* cause: unimplemented operation */
FPCSR_CV = 0x00010000, /* cause: invalid operation */
FPCSR_CZ = 0x00008000, /* cause: division by zero */
FPCSR_CO = 0x00004000, /* cause: overflow */
FPCSR_CU = 0x00002000, /* cause: underflow */
FPCSR_CI = 0x00001000, /* cause: inexact operation */
FPCSR_EV = 0x00000800, /* enable: invalid operation */
FPCSR_EZ = 0x00000400, /* enable: division by zero */
FPCSR_EO = 0x00000200, /* enable: overflow */
FPCSR_EU = 0x00000100, /* enable: underflow */
FPCSR_EI = 0x00000080, /* enable: inexact operation */
FPCSR_FV = 0x00000040, /* flag: invalid operation */
FPCSR_FZ = 0x00000020, /* flag: division by zero */
FPCSR_FO = 0x00000010, /* flag: overflow */
FPCSR_FU = 0x00000008, /* flag: underflow */
FPCSR_FI = 0x00000004, /* flag: inexact operation */
FPCSR_RM_MASK = 0x00000003, /* rounding mode mask */
FPCSR_RM_RN = 0x00000000, /* round to nearest */
FPCSR_RM_RZ = 0x00000001, /* round to zero */
FPCSR_RM_RP = 0x00000002, /* round to positive infinity */
FPCSR_RM_RM = 0x00000003, /* round to negative infinity */
FPCSR_FS = 0x01000000, // Flush denormalization to zero
FPCSR_C = 0x00800000, // Condition bit
FPCSR_CE = 0x00020000, // Cause: unimplemented operation
FPCSR_CV = 0x00010000, // Cause: invalid operation
FPCSR_CZ = 0x00008000, // Cause: division by zero
FPCSR_CO = 0x00004000, // Cause: overflow
FPCSR_CU = 0x00002000, // Cause: underflow
FPCSR_CI = 0x00001000, // Cause: inexact operation
FPCSR_EV = 0x00000800, // Enable: invalid operation
FPCSR_EZ = 0x00000400, // Enable: division by zero
FPCSR_EO = 0x00000200, // Enable: overflow
FPCSR_EU = 0x00000100, // Enable: underflow
FPCSR_EI = 0x00000080, // Enable: inexact operation
FPCSR_FV = 0x00000040, // Flag: invalid operation
FPCSR_FZ = 0x00000020, // Flag: division by zero
FPCSR_FO = 0x00000010, // Flag: overflow
FPCSR_FU = 0x00000008, // Flag: underflow
FPCSR_FI = 0x00000004, // Flag: inexact operation
FPCSR_RM_MASK = 0x00000003, // Rounding mode mask
FPCSR_RM_RN = 0x00000000, // Round to nearest
FPCSR_RM_RZ = 0x00000001, // Round to zero
FPCSR_RM_RP = 0x00000002, // Round to positive infinity
FPCSR_RM_RM = 0x00000003, // Round to negative infinity
};
//Rdram Registers
// RDRAM registers
class Rdram_InterfaceReg
{
protected:
@ -135,7 +135,7 @@ private:
Rdram_InterfaceReg& operator=(const Rdram_InterfaceReg&);
};
//Mips interface registers
// MIPS interface registers
class Mips_InterfaceReg
{
protected:
@ -155,52 +155,52 @@ private:
Mips_InterfaceReg& operator=(const Mips_InterfaceReg&);
};
//Mips interface flags
// MIPS interface flags
enum
{
MI_MODE_INIT = 0x0080, /* Bit 7: init mode */
MI_MODE_EBUS = 0x0100, /* Bit 8: ebus test mode */
MI_MODE_RDRAM = 0x0200, /* Bit 9: RDRAM reg mode */
MI_MODE_INIT = 0x0080, // Bit 7: Initialization mode
MI_MODE_EBUS = 0x0100, // Bit 8: EBUS test mode
MI_MODE_RDRAM = 0x0200, // Bit 9: RDRAM register mode
MI_CLR_INIT = 0x0080, /* Bit 7: clear init mode */
MI_SET_INIT = 0x0100, /* Bit 8: set init mode */
MI_CLR_EBUS = 0x0200, /* Bit 9: clear ebus test */
MI_SET_EBUS = 0x0400, /* Bit 10: set ebus test mode */
MI_CLR_DP_INTR = 0x0800, /* Bit 11: clear dp interrupt */
MI_CLR_RDRAM = 0x1000, /* Bit 12: clear RDRAM reg */
MI_SET_RDRAM = 0x2000, /* Bit 13: set RDRAM reg mode */
MI_CLR_INIT = 0x0080, // Bit 7: Clear initialization mode
MI_SET_INIT = 0x0100, // Bit 8: Set initialization mode
MI_CLR_EBUS = 0x0200, // Bit 9: Clear EBUS test
MI_SET_EBUS = 0x0400, // Bit 10: Set EBUS test mode
MI_CLR_DP_INTR = 0x0800, // Bit 11: Clear DP interrupt
MI_CLR_RDRAM = 0x1000, // Bit 12: Clear RDRAM register
MI_SET_RDRAM = 0x2000, // Bit 13: Set RDRAM register mode
// Flags for writing to MI_INTR_MASK_REG
MI_INTR_MASK_CLR_SP = 0x0001, /* Bit 0: clear SP mask */
MI_INTR_MASK_SET_SP = 0x0002, /* Bit 1: set SP mask */
MI_INTR_MASK_CLR_SI = 0x0004, /* Bit 2: clear SI mask */
MI_INTR_MASK_SET_SI = 0x0008, /* Bit 3: set SI mask */
MI_INTR_MASK_CLR_AI = 0x0010, /* Bit 4: clear AI mask */
MI_INTR_MASK_SET_AI = 0x0020, /* Bit 5: set AI mask */
MI_INTR_MASK_CLR_VI = 0x0040, /* Bit 6: clear VI mask */
MI_INTR_MASK_SET_VI = 0x0080, /* Bit 7: set VI mask */
MI_INTR_MASK_CLR_PI = 0x0100, /* Bit 8: clear PI mask */
MI_INTR_MASK_SET_PI = 0x0200, /* Bit 9: set PI mask */
MI_INTR_MASK_CLR_DP = 0x0400, /* Bit 10: clear DP mask */
MI_INTR_MASK_SET_DP = 0x0800, /* Bit 11: set DP mask */
MI_INTR_MASK_CLR_SP = 0x0001, // Bit 0: Clear SP mask
MI_INTR_MASK_SET_SP = 0x0002, // Bit 1: Set SP mask
MI_INTR_MASK_CLR_SI = 0x0004, // Bit 2: Clear SI mask
MI_INTR_MASK_SET_SI = 0x0008, // Bit 3: Set SI mask
MI_INTR_MASK_CLR_AI = 0x0010, // Bit 4: Clear AI mask
MI_INTR_MASK_SET_AI = 0x0020, // Bit 5: Set AI mask
MI_INTR_MASK_CLR_VI = 0x0040, // Bit 6: Clear VI mask
MI_INTR_MASK_SET_VI = 0x0080, // Bit 7: Set VI mask
MI_INTR_MASK_CLR_PI = 0x0100, // Bit 8: Clear PI mask
MI_INTR_MASK_SET_PI = 0x0200, // Bit 9: Set PI mask
MI_INTR_MASK_CLR_DP = 0x0400, // Bit 10: Clear DP mask
MI_INTR_MASK_SET_DP = 0x0800, // Bit 11: Set DP mask
// Flags for reading from MI_INTR_MASK_REG
MI_INTR_MASK_SP = 0x01, /* Bit 0: SP intr mask */
MI_INTR_MASK_SI = 0x02, /* Bit 1: SI intr mask */
MI_INTR_MASK_AI = 0x04, /* Bit 2: AI intr mask */
MI_INTR_MASK_VI = 0x08, /* Bit 3: VI intr mask */
MI_INTR_MASK_PI = 0x10, /* Bit 4: PI intr mask */
MI_INTR_MASK_DP = 0x20, /* Bit 5: DP intr mask */
MI_INTR_MASK_SP = 0x01, // Bit 0: SP INTR mask
MI_INTR_MASK_SI = 0x02, // Bit 1: SI INTR mask
MI_INTR_MASK_AI = 0x04, // Bit 2: AI INTR mask
MI_INTR_MASK_VI = 0x08, // Bit 3: VI INTR mask
MI_INTR_MASK_PI = 0x10, // Bit 4: PI INTR mask
MI_INTR_MASK_DP = 0x20, // Bit 5: DP INTR mask
MI_INTR_SP = 0x01, /* Bit 0: SP intr */
MI_INTR_SI = 0x02, /* Bit 1: SI intr */
MI_INTR_AI = 0x04, /* Bit 2: AI intr */
MI_INTR_VI = 0x08, /* Bit 3: VI intr */
MI_INTR_PI = 0x10, /* Bit 4: PI intr */
MI_INTR_DP = 0x20, /* Bit 5: DP intr */
MI_INTR_SP = 0x01, // Bit 0: SP INTR
MI_INTR_SI = 0x02, // Bit 1: SI INTR
MI_INTR_AI = 0x04, // Bit 2: AI INTR
MI_INTR_VI = 0x08, // Bit 3: VI INTR
MI_INTR_PI = 0x10, // Bit 4: PI INTR
MI_INTR_DP = 0x20, // Bit 5: DP INTR
};
//Mips interface registers
// MIPS interface registers
class Video_InterfaceReg
{
protected:
@ -237,7 +237,7 @@ private:
Video_InterfaceReg& operator=(const Video_InterfaceReg&);
};
//Display Processor Control Registers
// Display processor control registers
class DisplayControlReg
{
protected:
@ -261,33 +261,31 @@ private:
enum
{
DPC_CLR_XBUS_DMEM_DMA = 0x0001, /* Bit 0: clear xbus_dmem_dma */
DPC_SET_XBUS_DMEM_DMA = 0x0002, /* Bit 1: set xbus_dmem_dma */
DPC_CLR_FREEZE = 0x0004, /* Bit 2: clear freeze */
DPC_SET_FREEZE = 0x0008, /* Bit 3: set freeze */
DPC_CLR_FLUSH = 0x0010, /* Bit 4: clear flush */
DPC_SET_FLUSH = 0x0020, /* Bit 5: set flush */
DPC_CLR_TMEM_CTR = 0x0040, /* Bit 6: clear tmem ctr */
DPC_CLR_PIPE_CTR = 0x0080, /* Bit 7: clear pipe ctr */
DPC_CLR_CMD_CTR = 0x0100, /* Bit 8: clear cmd ctr */
DPC_CLR_CLOCK_CTR = 0x0200, /* Bit 9: clear clock ctr */
DPC_CLR_XBUS_DMEM_DMA = 0x0001, // Bit 0: Clear xbus_dmem_dma
DPC_SET_XBUS_DMEM_DMA = 0x0002, // Bit 1: Set xbus_dmem_dma
DPC_CLR_FREEZE = 0x0004, // Bit 2: Clear freeze
DPC_SET_FREEZE = 0x0008, // Bit 3: Set freeze
DPC_CLR_FLUSH = 0x0010, // Bit 4: Clear flush
DPC_SET_FLUSH = 0x0020, // Bit 5: Set flush
DPC_CLR_TMEM_CTR = 0x0040, // Bit 6: Clear TMEM CTR
DPC_CLR_PIPE_CTR = 0x0080, // Bit 7: Clear pipe CTR
DPC_CLR_CMD_CTR = 0x0100, // Bit 8: Clear CMD CTR
DPC_CLR_CLOCK_CTR = 0x0200, // Bit 9: Clear clock CTR
DPC_STATUS_XBUS_DMEM_DMA = 0x001, /* Bit 0: xbus_dmem_dma */
DPC_STATUS_FREEZE = 0x002, /* Bit 1: freeze */
DPC_STATUS_FLUSH = 0x004, /* Bit 2: flush */
DPC_STATUS_START_GCLK = 0x008, /* Bit 3: start gclk */
DPC_STATUS_TMEM_BUSY = 0x010, /* Bit 4: tmem busy */
DPC_STATUS_PIPE_BUSY = 0x020, /* Bit 5: pipe busy */
DPC_STATUS_CMD_BUSY = 0x040, /* Bit 6: cmd busy */
DPC_STATUS_CBUF_READY = 0x080, /* Bit 7: cbuf ready */
DPC_STATUS_DMA_BUSY = 0x100, /* Bit 8: dma busy */
DPC_STATUS_END_VALID = 0x200, /* Bit 9: end valid */
DPC_STATUS_START_VALID = 0x400, /* Bit 10: start valid */
DPC_STATUS_XBUS_DMEM_DMA = 0x001, // Bit 0: xbus_dmem_dma
DPC_STATUS_FREEZE = 0x002, // Bit 1: Freeze
DPC_STATUS_FLUSH = 0x004, // Bit 2: Flush
DPC_STATUS_START_GCLK = 0x008, // Bit 3: Start GCLK
DPC_STATUS_TMEM_BUSY = 0x010, // Bit 4: TMEM busy
DPC_STATUS_PIPE_BUSY = 0x020, // Bit 5: Pipe busy
DPC_STATUS_CMD_BUSY = 0x040, // Bit 6: CMD busy
DPC_STATUS_CBUF_READY = 0x080, // Bit 7: CBUF ready
DPC_STATUS_DMA_BUSY = 0x100, // Bit 8: DMA busy
DPC_STATUS_END_VALID = 0x200, // Bit 9: End valid
DPC_STATUS_START_VALID = 0x400, // Bit 10: Start valid
};
/*
//Audio Interface registers;
*/
// Audio interface registers
class AudioInterfaceReg
{
protected:
@ -309,11 +307,11 @@ private:
enum
{
AI_STATUS_FIFO_FULL = 0x80000000, /* Bit 31: full */
AI_STATUS_DMA_BUSY = 0x40000000, /* Bit 30: busy */
AI_STATUS_FIFO_FULL = 0x80000000, // Bit 31: Full
AI_STATUS_DMA_BUSY = 0x40000000, // Bit 30: Busy
};
//Audio Interface registers;
// Audio interface registers
class PeripheralInterfaceReg
{
@ -365,7 +363,7 @@ private:
RDRAMInt_InterfaceReg& operator=(const RDRAMInt_InterfaceReg&);
};
//Signal Processor Interface;
// Signal processor interface
class SigProcessor_InterfaceReg
{
protected:
@ -389,53 +387,53 @@ private:
SigProcessor_InterfaceReg& operator=(const SigProcessor_InterfaceReg&);
};
//Signal Processor interface flags
// Signal processor interface flags
enum
{
SP_CLR_HALT = 0x00001, /* Bit 0: clear halt */
SP_SET_HALT = 0x00002, /* Bit 1: set halt */
SP_CLR_BROKE = 0x00004, /* Bit 2: clear broke */
SP_CLR_INTR = 0x00008, /* Bit 3: clear intr */
SP_SET_INTR = 0x00010, /* Bit 4: set intr */
SP_CLR_SSTEP = 0x00020, /* Bit 5: clear sstep */
SP_SET_SSTEP = 0x00040, /* Bit 6: set sstep */
SP_CLR_INTR_BREAK = 0x00080, /* Bit 7: clear intr on break */
SP_SET_INTR_BREAK = 0x00100, /* Bit 8: set intr on break */
SP_CLR_SIG0 = 0x00200, /* Bit 9: clear signal 0 */
SP_SET_SIG0 = 0x00400, /* Bit 10: set signal 0 */
SP_CLR_SIG1 = 0x00800, /* Bit 11: clear signal 1 */
SP_SET_SIG1 = 0x01000, /* Bit 12: set signal 1 */
SP_CLR_SIG2 = 0x02000, /* Bit 13: clear signal 2 */
SP_SET_SIG2 = 0x04000, /* Bit 14: set signal 2 */
SP_CLR_SIG3 = 0x08000, /* Bit 15: clear signal 3 */
SP_SET_SIG3 = 0x10000, /* Bit 16: set signal 3 */
SP_CLR_SIG4 = 0x20000, /* Bit 17: clear signal 4 */
SP_SET_SIG4 = 0x40000, /* Bit 18: set signal 4 */
SP_CLR_SIG5 = 0x80000, /* Bit 19: clear signal 5 */
SP_SET_SIG5 = 0x100000, /* Bit 20: set signal 5 */
SP_CLR_SIG6 = 0x200000, /* Bit 21: clear signal 6 */
SP_SET_SIG6 = 0x400000, /* Bit 22: set signal 6 */
SP_CLR_SIG7 = 0x800000, /* Bit 23: clear signal 7 */
SP_SET_SIG7 = 0x1000000, /* Bit 24: set signal 7 */
SP_CLR_HALT = 0x00001, // Bit 0: Clear halt
SP_SET_HALT = 0x00002, // Bit 1: Set halt
SP_CLR_BROKE = 0x00004, // Bit 2: Clear broke
SP_CLR_INTR = 0x00008, // Bit 3: Clear INTR
SP_SET_INTR = 0x00010, // Bit 4: Set INTR
SP_CLR_SSTEP = 0x00020, // Bit 5: Clear SSTEP
SP_SET_SSTEP = 0x00040, // Bit 6: Set SSTEP
SP_CLR_INTR_BREAK = 0x00080, // Bit 7: Clear INTR on break
SP_SET_INTR_BREAK = 0x00100, // Bit 8: Set INTR on break
SP_CLR_SIG0 = 0x00200, // Bit 9: Clear signal 0
SP_SET_SIG0 = 0x00400, // Bit 10: Set signal 0
SP_CLR_SIG1 = 0x00800, // Bit 11: Clear signal 1
SP_SET_SIG1 = 0x01000, // Bit 12: Set signal 1
SP_CLR_SIG2 = 0x02000, // Bit 13: Clear signal 2
SP_SET_SIG2 = 0x04000, // Bit 14: Set signal 2
SP_CLR_SIG3 = 0x08000, // Bit 15: Clear signal 3
SP_SET_SIG3 = 0x10000, // Bit 16: Set signal 3
SP_CLR_SIG4 = 0x20000, // Bit 17: Clear signal 4
SP_SET_SIG4 = 0x40000, // Bit 18: Set signal 4
SP_CLR_SIG5 = 0x80000, // Bit 19: Clear signal 5
SP_SET_SIG5 = 0x100000, // Bit 20: Set signal 5
SP_CLR_SIG6 = 0x200000, // Bit 21: Clear signal 6
SP_SET_SIG6 = 0x400000, // Bit 22: Set signal 6
SP_CLR_SIG7 = 0x800000, // Bit 23: Clear signal 7
SP_SET_SIG7 = 0x1000000, // Bit 24: Set signal 7
SP_STATUS_HALT = 0x001, /* Bit 0: halt */
SP_STATUS_BROKE = 0x002, /* Bit 1: broke */
SP_STATUS_DMA_BUSY = 0x004, /* Bit 2: dma busy */
SP_STATUS_DMA_FULL = 0x008, /* Bit 3: dma full */
SP_STATUS_IO_FULL = 0x010, /* Bit 4: io full */
SP_STATUS_SSTEP = 0x020, /* Bit 5: single step */
SP_STATUS_INTR_BREAK = 0x040, /* Bit 6: interrupt on break */
SP_STATUS_SIG0 = 0x080, /* Bit 7: signal 0 set */
SP_STATUS_SIG1 = 0x100, /* Bit 8: signal 1 set */
SP_STATUS_SIG2 = 0x200, /* Bit 9: signal 2 set */
SP_STATUS_SIG3 = 0x400, /* Bit 10: signal 3 set */
SP_STATUS_SIG4 = 0x800, /* Bit 11: signal 4 set */
SP_STATUS_SIG5 = 0x1000, /* Bit 12: signal 5 set */
SP_STATUS_SIG6 = 0x2000, /* Bit 13: signal 6 set */
SP_STATUS_SIG7 = 0x4000, /* Bit 14: signal 7 set */
SP_STATUS_HALT = 0x001, // Bit 0: Halt
SP_STATUS_BROKE = 0x002, // Bit 1: Broke
SP_STATUS_DMA_BUSY = 0x004, // Bit 2: DMA busy
SP_STATUS_DMA_FULL = 0x008, // Bit 3: DMA full
SP_STATUS_IO_FULL = 0x010, // Bit 4: IO full
SP_STATUS_SSTEP = 0x020, // Bit 5: Single step
SP_STATUS_INTR_BREAK = 0x040, // Bit 6: Interrupt on break
SP_STATUS_SIG0 = 0x080, // Bit 7: Signal 0 set
SP_STATUS_SIG1 = 0x100, // Bit 8: Signal 1 set
SP_STATUS_SIG2 = 0x200, // Bit 9: Signal 2 set
SP_STATUS_SIG3 = 0x400, // Bit 10: Signal 3 set
SP_STATUS_SIG4 = 0x800, // Bit 11: Signal 4 set
SP_STATUS_SIG5 = 0x1000, // Bit 12: Signal 5 set
SP_STATUS_SIG6 = 0x2000, // Bit 13: Signal 6 set
SP_STATUS_SIG7 = 0x4000, // Bit 14: Signal 7 set
};
//Peripheral Interface flags
// Peripheral interface flags
enum
{
PI_STATUS_DMA_BUSY = 0x01,
@ -463,7 +461,7 @@ private:
Serial_InterfaceReg& operator=(const Serial_InterfaceReg&);
};
//Serial Interface flags
// Serial interface flags
enum
{
SI_STATUS_DMA_BUSY = 0x0001,
@ -472,7 +470,7 @@ enum
SI_STATUS_INTERRUPT = 0x1000,
};
//Disk Interface
// Disk interface
class Disk_InterfaceReg
{
protected:
@ -508,7 +506,7 @@ private:
Disk_InterfaceReg& operator=(const Disk_InterfaceReg&);
};
//Disk Interface Flags
// Disk interface flags
enum
{
DD_STATUS_DATA_RQ = 0x40000000,
@ -588,7 +586,7 @@ class CRegisters :
public:
CRegisters(CN64System * System, CSystemEvents * SystemEvents);
//General Registers
// General registers
uint32_t m_PROGRAM_COUNTER;
MIPS_DWORD m_GPR[32];
uint32_t m_CP0[33];
@ -603,7 +601,7 @@ public:
float * m_FPR_S[32];
double * m_FPR_D[32];
//Memory Mapped N64 registers
// Memory-mapped N64 registers
uint32_t m_RDRAM_Registers[10];
uint32_t m_SigProcessor_Interface[10];
uint32_t m_Display_ControlReg[10];

View File

@ -50,7 +50,7 @@ const char * SystemEventName(SystemEvent event)
case SysEvent_ResetRecompilerCode: return "SysEvent_ResetRecompilerCode";
}
static char unknown[100];
sprintf(unknown, "unknown(%d)", event);
sprintf(unknown, "Unknown(%d)", event);
return unknown;
}

View File

@ -18,7 +18,7 @@ CSystemTimer::CSystemTimer(CRegisters &Reg, int32_t & NextTimer) :
void CSystemTimer::Reset()
{
//initialise Structure
// Initialize structure
for (int i = 0; i < MaxTimer; i++)
{
m_TimerDetatils[i].Active = false;
@ -51,12 +51,12 @@ void CSystemTimer::SetTimer(TimerType Type, uint32_t Cycles, bool bRelative)
}
else
{
m_TimerDetatils[Type].CyclesToTimer = (int64_t)Cycles - (int64_t)m_NextTimer; //replace the new cycles
m_TimerDetatils[Type].CyclesToTimer = (int64_t)Cycles - (int64_t)m_NextTimer; // Replace the new cycles
}
}
else
{
m_TimerDetatils[Type].CyclesToTimer = (int64_t)Cycles - (int64_t)m_NextTimer; //replace the new cycles
m_TimerDetatils[Type].CyclesToTimer = (int64_t)Cycles - (int64_t)m_NextTimer; // Replace the new cycles
}
FixTimers();
}
@ -120,7 +120,7 @@ void CSystemTimer::FixTimers()
m_TimerDetatils[count].CyclesToTimer += m_NextTimer;
}
//Set Max timer
// Set max timer
m_NextTimer = 0x7FFFFFFF;
// Find the smallest timer left to go

View File

@ -164,7 +164,7 @@ void CTLB::WriteEntry(int index, bool Random)
}
}
//fill in m_tlb entry
// Fill in m_tlb entry
m_tlb[index].PageMask.Value = g_Reg->PAGE_MASK_REGISTER;
m_tlb[index].EntryHi.Value = g_Reg->ENTRYHI_REGISTER;
m_tlb[index].EntryLo0.Value = g_Reg->ENTRYLO0_REGISTER;
@ -176,7 +176,7 @@ void CTLB::WriteEntry(int index, bool Random)
void CTLB::SetupTLB_Entry(int index, bool Random)
{
//Fix up Fast TLB entries
// Fix up fast TLB entries
if (!m_tlb[index].EntryDefined)
{
return;
@ -238,7 +238,7 @@ void CTLB::SetupTLB_Entry(int index, bool Random)
continue;
}
//MAP the new m_tlb entry for reading and writing
// Map the new m_tlb entry for reading and writing
m_FastTlb[FastIndx].ValidEntry = true;
m_CB->TLB_Mapped(m_FastTlb[FastIndx].VSTART, m_FastTlb[FastIndx].Length, m_FastTlb[FastIndx].PHYSSTART, !m_FastTlb[FastIndx].DIRTY);
}

View File

@ -88,7 +88,7 @@ public:
void Reset(bool InvalidateTLB);
//Used by opcodes of the same name to manipulate the tlb (reads the registers)
// Used by opcodes of the same name to manipulate the TLB (reads the registers)
void Probe();
void ReadEntry();
void WriteEntry(int32_t index, bool Random);
@ -124,7 +124,7 @@ private:
bool Probed;
};
friend class CDebugTlb; // enable debug window to read class
friend class CDebugTlb; // Enable debug window to read class
CTLB_CB * const m_CB;

View File

@ -1,9 +1,9 @@
// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// https://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64
// Copyright(C) 2015 Bobby Smiles
// GNU/GPLv2 licensed: https://gnu.org/licenses/gpl-2.0.html
#include "stdafx.h"
#include "GBCart.h"
#include "Transferpak.h"
@ -17,7 +17,7 @@ uint16_t gb_cart_address(unsigned int bank, uint16_t address)
void Transferpak::Init()
{
//Quick check to ensure we dont have a ROM already
// Quick check to ensure we don't have a ROM already
if (tpak.gb_cart.rom == nullptr)
{
memset(&tpak, 0, sizeof(tpak));
@ -38,20 +38,20 @@ void Transferpak::ReadFrom(uint16_t address, uint8_t * data)
{
if ((address >= 0x8000) && (address <= 0x8FFF))
{
//Ensure we actually have a ROM loaded in first.
// Ensure we actually have a ROM loaded in first
if (tpak.gb_cart.rom == nullptr)
{
Init();
}
//Get whether the GB cart is enabled or disabled
// Get whether the Game Boy cart is enabled or disabled
uint8_t value = (tpak.enabled) ? 0x84 : 0x00;
memset(data, value, 0x20);
}
else if ((address >= 0xB000) && (address <= 0xBFFF))
{
// Get the GB Cart access mode
// Get the Game Boy cart access mode
if (tpak.enabled)
{
memset(data, tpak.access_mode, 0x20);
@ -65,7 +65,7 @@ void Transferpak::ReadFrom(uint16_t address, uint8_t * data)
}
else if (address >= 0xC000)
{
// Read the GB Cart
// Read the Game Boy cart
if (tpak.enabled)
{
GBCart::read_gb_cart(&tpak.gb_cart, gb_cart_address(tpak.bank, address), data);
@ -79,13 +79,13 @@ void Transferpak::WriteTo(uint16_t address, uint8_t * data)
if ((address >= 0x8000) && (address <= 0x8FFF))
{
//Ensure we actually have a ROM loaded in first.
// Ensure we actually have a ROM loaded in first
if (tpak.gb_cart.rom == nullptr)
{
Init();
}
//Set whether the gb cart is enabled or disabled.
// Set whether the Game Boy cart is enabled or disabled
switch (*data)
{
case 0xFE:
@ -101,7 +101,7 @@ void Transferpak::WriteTo(uint16_t address, uint8_t * data)
}
else if ((address >= 0xA000) && (address <= 0xAFFF))
{
//Set the bank for the GB Cart
// Set the bank for the Game Boy cart
if (tpak.enabled)
{
tpak.bank = *data;
@ -109,7 +109,7 @@ void Transferpak::WriteTo(uint16_t address, uint8_t * data)
}
else if ((address >= 0xB000) && (address <= 0xBFFF))
{
// Get the GB Cart access mode
// Get the Game Boy cart access mode
if (tpak.enabled)
{
tpak.access_mode_changed = 0x04;
@ -118,13 +118,13 @@ void Transferpak::WriteTo(uint16_t address, uint8_t * data)
if ((*data & 0xFE) != 0)
{
//Unkown tpak write
// Unknown Transfer Pak write
}
}
}
else if (address >= 0xC000)
{
// Write to the GB Cart
// Write to the Game Boy cart
if (tpak.enabled)
{
GBCart::write_gb_cart(&tpak.gb_cart, gb_cart_address(tpak.bank, address), data);

View File

@ -36,11 +36,11 @@ bool CN64Disk::LoadDiskImage(const char * FileLoc)
stdstr ShadowFile = FileLoc;
ShadowFile[ShadowFile.length() - 1] = 'r';
WriteTrace(TraceN64System, TraceDebug, "Attempt to load shadow file.");
WriteTrace(TraceN64System, TraceDebug, "Attempting to load shadow file");
if (!AllocateAndLoadDiskImage(ShadowFile.c_str()))
{
m_isShadowDisk = false;
WriteTrace(TraceN64System, TraceDebug, "Loading Shadow file failed");
WriteTrace(TraceN64System, TraceDebug, "Loading shadow file failed");
UnallocateDiskImage();
if (!AllocateAndLoadDiskImage(FileLoc))
{
@ -60,7 +60,7 @@ bool CN64Disk::LoadDiskImage(const char * FileLoc)
// Get the disk ID from the disk image
if (*(uint32_t *)(&GetDiskAddressID()[0]) != 0)
{
//if not 0x00000000
// If not 0x00000000
RomName[0] = (char)*(GetDiskAddressID() + 3);
RomName[1] = (char)*(GetDiskAddressID() + 2);
RomName[2] = (char)*(GetDiskAddressID() + 1);
@ -69,7 +69,7 @@ bool CN64Disk::LoadDiskImage(const char * FileLoc)
}
else
{
//if 0x00000000 then use a made up one
// If 0x00000000 then use a made up one
RomName[0] = m_DiskIdent[12];
RomName[1] = m_DiskIdent[11];
RomName[2] = m_DiskIdent[10];
@ -102,26 +102,26 @@ bool CN64Disk::SaveDiskImage()
{
DeinitSysDataD64();
//NO NEED TO SAVE IF DISK TYPE IS 6
// No need to save if disk type is 6
if (m_DiskType == 6)
{
m_DiskFile.Close();
WriteTrace(TraceN64System, TraceDebug, "Loaded Disk Type is 6. No RAM area. Shadow file is not needed.");
WriteTrace(TraceN64System, TraceDebug, "Loaded disk type is 6. No RAM area. Shadow file is not needed.");
return true;
}
// Assume the file extension is *.ndd / *.d64
if (m_DiskFormat == DiskFormatMAME || m_isShadowDisk || g_Settings->LoadDword(Setting_DiskSaveType) == SaveDisk_ShadowFile)
{
//Shadow File
// Shadow file
stdstr ShadowFile = m_FileName;
ShadowFile[ShadowFile.length() - 1] = 'r';
WriteTrace(TraceN64System, TraceDebug, "Trying to open %s (Shadow File)", ShadowFile.c_str());
WriteTrace(TraceN64System, TraceDebug, "Trying to open %s (shadow file)", ShadowFile.c_str());
m_DiskFile.Close();
if (!m_DiskFile.Open(ShadowFile.c_str(), CFileBase::modeWrite | CFileBase::modeCreate | CFileBase::modeNoTruncate))
{
WriteTrace(TraceN64System, TraceError, "Failed to open %s (Shadow File)", ShadowFile.c_str());
WriteTrace(TraceN64System, TraceError, "Failed to open %s (shadow file)", ShadowFile.c_str());
return false;
}
@ -137,7 +137,7 @@ bool CN64Disk::SaveDiskImage()
}
else
{
//RAM File
// RAM file
if (m_DiskFileSize <= m_DiskRamAddress || m_DiskRamAddress == 0)
{
m_DiskFile.Close();
@ -149,11 +149,11 @@ bool CN64Disk::SaveDiskImage()
ShadowFile[ShadowFile.length() - 2] = 'a';
ShadowFile[ShadowFile.length() - 3] = 'r';
WriteTrace(TraceN64System, TraceDebug, "Trying to open %s (RAM File)", ShadowFile.c_str());
WriteTrace(TraceN64System, TraceDebug, "Trying to open %s (RAM file)", ShadowFile.c_str());
m_DiskFile.Close();
if (!m_DiskFile.Open(ShadowFile.c_str(), CFileBase::modeWrite | CFileBase::modeCreate | CFileBase::modeNoTruncate))
{
WriteTrace(TraceN64System, TraceError, "Failed to open %s (RAM File)", ShadowFile.c_str());
WriteTrace(TraceN64System, TraceError, "Failed to open %s (RAM file)", ShadowFile.c_str());
return false;
}
@ -180,27 +180,27 @@ void CN64Disk::SwapDiskImage(const char * FileLoc)
bool CN64Disk::IsValidDiskImage(uint8_t Test[0x20])
{
//Basic System Data Check (first 0x20 bytes is enough)
//Disk Type
// Basic system data check (first 0x20 bytes is enough)
// Disk type
if ((Test[0x05] & 0xEF) > 6) return false;
//IPL Load Block
// IPL load block
uint16_t ipl_load_blk = ((Test[0x06] << 8) | Test[0x07]);
if (ipl_load_blk > 0x10C3 || ipl_load_blk == 0x0000) return false;
//IPL Load Address
// IPL load address
uint32_t ipl_load_addr = (Test[0x1C] << 24) | (Test[0x1D] << 16) | (Test[0x1E] << 8) | Test[0x1F];
if (ipl_load_addr < 0x80000000 && ipl_load_addr >= 0x80800000) return false;
//Country Code
// Country code
if (*((uint32_t *)&Test[0]) == 0x16D348E8) { return true; }
else if (*((uint32_t *)&Test[0]) == 0x56EE6322) { return true; }
else if (*((uint32_t *)&Test[0]) == 0x00000000) { return true; }
return false;
}
//Save the settings of the loaded rom, so all loaded settings about rom will be identified with
//this rom
// Save the settings of the loaded ROM, so all loaded settings about ROM will be identified with this ROM
void CN64Disk::SaveDiskSettingID(bool temp)
{
g_Settings->SaveBool(Game_TempLoaded, temp);
@ -242,10 +242,10 @@ bool CN64Disk::AllocateDiskImage(uint32_t DiskFileSize)
WriteTrace(TraceN64System, TraceError, "Failed to allocate memory for disk (size: 0x%X)", DiskFileSize);
return false;
}
uint8_t * Image = (uint8_t *)(((uint64_t)ImageBase.get() + 0xFFF) & ~0xFFF); // start at begining of memory page
uint8_t * Image = (uint8_t *)(((uint64_t)ImageBase.get() + 0xFFF) & ~0xFFF); // Start at beginning of memory page
WriteTrace(TraceN64System, TraceDebug, "Allocated disk memory (%p)", Image);
//save information about the disk loaded
// Save information about the disk loaded
m_DiskImageBase = ImageBase.release();
m_DiskImage = Image;
m_DiskFileSize = DiskFileSize;
@ -262,10 +262,10 @@ bool CN64Disk::AllocateDiskHeader()
WriteTrace(TraceN64System, TraceError, "Failed to allocate memory for disk header forge (size: 0x40)");
return false;
}
uint8_t * Header = (uint8_t *)(((uint64_t)HeaderBase.get() + 0xFFF) & ~0xFFF); // start at begining of memory page
uint8_t * Header = (uint8_t *)(((uint64_t)HeaderBase.get() + 0xFFF) & ~0xFFF); // Start at beginning of memory page
WriteTrace(TraceN64System, TraceDebug, "Allocated disk memory (%p)", Header);
//save information about the disk loaded
// Save information about the disk loaded
m_DiskHeaderBase = HeaderBase.release();
m_DiskHeader = Header;
return true;
@ -302,27 +302,27 @@ bool CN64Disk::AllocateAndLoadDiskImage(const char * FileLoc)
if (!isValidDisk)
{
m_DiskFile.Close();
WriteTrace(TraceN64System, TraceError, "invalid disk image file");
WriteTrace(TraceN64System, TraceError, "Invalid disk image file");
return false;
}
uint32_t DiskFileSize = m_DiskFile.GetLength();
stdstr ext = CPath(FileLoc).GetExtension();
WriteTrace(TraceN64System, TraceDebug, "Successfully Opened, size: 0x%X", DiskFileSize);
WriteTrace(TraceN64System, TraceDebug, "Successfully opened, size: 0x%X", DiskFileSize);
//Check Disk File Format
// Check disk file format
if (((DiskFileSize == MameFormatSize) || (DiskFileSize == SDKFormatSize)) && (ext.compare("ndr") || ext.compare("ndd")))
{
if (DiskFileSize == MameFormatSize)
{
//If Disk is MAME Format (size is constant, it should be the same for every file), then continue
// If disk is MAME Format (size is constant, it should be the same for every file), then continue
m_DiskFormat = DiskFormatMAME;
WriteTrace(TraceN64System, TraceDebug, "Disk File is MAME Format");
WriteTrace(TraceN64System, TraceDebug, "Disk file is MAME format");
}
else
{
//If Disk is SDK format (made with SDK based dumpers like LuigiBlood's, or Nintendo's, size is also constant)
// If disk is SDK format (made with SDK-based dumpers like LuigiBlood's, or Nintendo's, size is also constant)
m_DiskFormat = DiskFormatSDK;
WriteTrace(TraceN64System, TraceDebug, "Disk File is SDK Format");
WriteTrace(TraceN64System, TraceDebug, "Disk file is SDK format");
}
if (!AllocateDiskImage(DiskFileSize))
@ -331,7 +331,7 @@ bool CN64Disk::AllocateAndLoadDiskImage(const char * FileLoc)
return false;
}
//Load the n64 disk to the allocated memory
// Load the N64 disk to the allocated memory
g_Notify->DisplayMessage(5, MSG_LOADING);
m_DiskFile.SeekToBegin();
@ -350,7 +350,7 @@ bool CN64Disk::AllocateAndLoadDiskImage(const char * FileLoc)
}
TotalRead += dwToRead;
//Show Message of how much % wise of the rom has been loaded
// Show message of how much of the ROM has been loaded (as a percentage)
g_Notify->DisplayMessage(0, stdstr_f("%s: %.2f%c", GS(MSG_LOADED), ((float)TotalRead / (float)DiskFileSize) * 100.0f, '%').c_str());
}
@ -370,7 +370,7 @@ bool CN64Disk::AllocateAndLoadDiskImage(const char * FileLoc)
else if ((DiskFileSize > 0x4F08) && (ext.compare("d6r") || ext.compare("d64")))
{
m_DiskFormat = DiskFormatD64;
WriteTrace(TraceN64System, TraceDebug, "Disk File is D64 Format");
WriteTrace(TraceN64System, TraceDebug, "Disk file is D64 format");
m_DiskType = Test[5];
uint16_t ROM_LBA_END = (Test[0xE0] << 8) | Test[0xE1];
@ -400,7 +400,7 @@ bool CN64Disk::AllocateAndLoadDiskImage(const char * FileLoc)
return false;
}
//Allocate File with Max RAM Area size
// Allocate file with maximum size RAM area
WriteTrace(TraceN64System, TraceError, "Allocate D64 ROM %08X + RAM %08X", ROM_SIZE, FULL_RAM_SIZE);
if (!AllocateDiskImage(0x200 + ROM_SIZE + FULL_RAM_SIZE))
{
@ -408,7 +408,7 @@ bool CN64Disk::AllocateAndLoadDiskImage(const char * FileLoc)
return false;
}
//Load the n64 disk to the allocated memory
// Load the N64 disk to the allocated memory
g_Notify->DisplayMessage(5, MSG_LOADING);
m_DiskFile.SeekToBegin();
@ -427,7 +427,7 @@ bool CN64Disk::AllocateAndLoadDiskImage(const char * FileLoc)
}
TotalRead += dwToRead;
//Show Message of how much % wise of the rom has been loaded
// Show message of how much of the ROM has been loaded (as a percentage)
g_Notify->DisplayMessage(0, stdstr_f("%s: %.2f%c", GS(MSG_LOADED), ((float)TotalRead / (float)DiskFileSize) * 100.0f, '%').c_str());
}
@ -446,9 +446,9 @@ bool CN64Disk::AllocateAndLoadDiskImage(const char * FileLoc)
}
else
{
//Else the disk file is invalid
// Otherwise the disk file is invalid
m_DiskFile.Close();
WriteTrace(TraceN64System, TraceError, "Disk File is invalid, unexpected size");
WriteTrace(TraceN64System, TraceError, "Disk file is invalid, unexpected size");
return false;
}
@ -714,14 +714,14 @@ void CN64Disk::DetectSystemArea()
{
if ((m_DiskFormat == DiskFormatMAME) || (m_DiskFormat == DiskFormatSDK))
{
//MAME / SDK (System Area can be handled identically)
// MAME / SDK (system area can be handled identically)
m_DiskSysAddress = 0;
m_DiskIDAddress = DISKID_LBA * 0x4D08;
m_DiskRomAddress = SYSTEM_LBAS * 0x4D08;
//Handle System Data
// Handle system data
const uint16_t sysblocks[4] = { 9, 8, 1, 0 };
//Check if Disk is development disk
// Check if disk is development disk
bool isDevDisk = false;
for (int i = 0; i < 4; i++)
@ -744,10 +744,10 @@ void CN64Disk::DetectSystemArea()
}
}
//Handle Disk ID
// Handle disk ID
for (int i = 2; i > 0; i--)
{
//There are two Disk ID Blocks
// There are two disk ID blocks
if (IsSysSectorGood(DISKID_LBA + i, 0xE8))
{
m_DiskIDAddress = ((DISKID_LBA + i) * 0x4D08);
@ -765,7 +765,7 @@ void CN64Disk::DetectSystemArea()
bool CN64Disk::IsSysSectorGood(uint32_t block, uint32_t sectorsize)
{
//Checks if all sectors are identical (meant only to be used for System Area for MAME and SDK formats)
// Checks if all sectors are identical (meant only to be used for system area for MAME and SDK formats)
for (int j = 1; j < SECTORS_PER_BLOCK; j++)
{
for (uint32_t k = 0; k < sectorsize; k++)
@ -779,13 +779,13 @@ bool CN64Disk::IsSysSectorGood(uint32_t block, uint32_t sectorsize)
if (block < DISKID_LBA)
{
//Check System Data
// Check system data
//System Format
// System format
if (m_DiskImage[(block * 0x4D08) + 4] != 0x10)
return false;
//Disk Format
// Disk format
if ((m_DiskImage[(block * 0x4D08) + 5] & 0xF0) != 0x10)
return false;
@ -797,7 +797,7 @@ bool CN64Disk::IsSysSectorGood(uint32_t block, uint32_t sectorsize)
if ((block & 2) != 0)
alt = 0xA; // Development
//Alternate Tracks Offsets (always the same)
// Alternate tracks offsets (always the same)
for (int i = 0; i < 16; i++)
{
if (m_DiskImage[(block * 0x4D08) + 8 + i] != ((i + 1) * alt))
@ -824,14 +824,14 @@ Country CN64Disk::GetDiskCountryCode()
void CN64Disk::InitSysDataD64()
{
//Else the disk will not work properly.
// Otherwise the disk will not work properly
if (m_DiskFormat != DiskFormatD64)
return;
GetDiskAddressSys()[4 ^ 3] = 0x10;
GetDiskAddressSys()[5 ^ 3] |= 0x10;
//Expand RAM Area for file format consistency
// Expand RAM area for file format consistency
if (m_DiskType < 6)
{
*(uint16_t*)&GetDiskAddressSys()[0xE2 ^ 2] = RAM_START_LBA[m_DiskType] - SYSTEM_LBAS;
@ -927,42 +927,42 @@ uint16_t CN64Disk::LBAToPhys(uint32_t lba)
{
uint8_t * sys_data = GetDiskAddressSys();
//Get Block 0/1 on Disk Track
// Get block 0/1 on disk track
uint8_t block = 1;
if (((lba & 3) == 0) || ((lba & 3) == 3))
block = 0;
//Get Virtual & Physical Disk Zones
// Get virtual and physical disk zones
uint16_t vzone = (uint16_t)LBAToVZone(lba);
uint16_t pzone = VZoneToPZone(vzone, m_DiskType);
//Get Disk Head
// Get disk head
uint16_t head = (7 < pzone);
//Get Disk Zone
// Get disk zone
uint16_t disk_zone = pzone;
if (disk_zone != 0)
disk_zone = pzone - 7;
//Get Virtual Zone LBA start, if Zone 0, it's LBA 0
// Get virtual zone LBA start, if zone 0, it's LBA 0
uint16_t vzone_lba = 0;
if (vzone != 0)
vzone_lba = VZONE_LBA_TBL[m_DiskType][vzone - 1];
//Calculate Physical Track
// Calculate physical track
uint16_t track = (uint16_t)((lba - vzone_lba) >> 1);
// Get the start track from current zone
uint16_t track_zone_start = SCYL_ZONE_TBL[0][pzone];
if (head != 0)
{
//If Head 1, count from the other way around
// If head 1, count from the other way around
track = -track;
track_zone_start = OUTERCYL_TBL[disk_zone - 1];
}
track += SCYL_ZONE_TBL[0][pzone];
//Get the relative offset to defect tracks for the current zone (if Zone 0, then it's 0)
// Get the relative offset to defect tracks for the current zone (if zone 0, then it's 0)
uint16_t defect_offset = 0;
if (pzone != 0)
defect_offset = sys_data[(8 + pzone - 1) ^ 3];

View File

@ -54,11 +54,11 @@ private:
uint16_t LBAToPhys(uint32_t lba);
uint16_t PhysToLBA(uint16_t head, uint16_t track, uint16_t block);
//constant values
// Constant values
enum { ReadFromRomSection = 0x400000, MameFormatSize = 0x0435B0C0, SDKFormatSize = 0x03DEC800,
DiskFormatMAME = 0x0, DiskFormatSDK = 0x1, DiskFormatD64 = 0x2 };
//class variables
// Class variables
CFile m_DiskFile;
uint8_t * m_DiskImage;
uint8_t * m_DiskImageBase;
@ -77,7 +77,7 @@ private:
uint8_t m_DiskType;
bool m_isShadowDisk;
//Disk Defines
// Disk defines
#define MAX_LBA 0x10DB
#define SIZE_LBA MAX_LBA+1
#define SYSTEM_LBAS 24

View File

@ -29,18 +29,18 @@ CN64Rom::~CN64Rom()
bool CN64Rom::AllocateRomImage(uint32_t RomFileSize)
{
WriteTrace(TraceN64System, TraceDebug, "Allocating memory for rom");
WriteTrace(TraceN64System, TraceDebug, "Allocating memory for ROM");
std::unique_ptr<uint8_t> ImageBase(new uint8_t[RomFileSize + 0x2000]);
if (ImageBase.get() == nullptr)
{
SetError(MSG_MEM_ALLOC_ERROR);
WriteTrace(TraceN64System, TraceError, "Failed to allocate memory for rom (size: 0x%X)", RomFileSize);
WriteTrace(TraceN64System, TraceError, "Failed to allocate memory for ROM (size: 0x%X)", RomFileSize);
return false;
}
uint8_t * Image = (uint8_t *)(((uint64_t)ImageBase.get() + 0xFFF) & ~0xFFF); // start at begining of memory page
WriteTrace(TraceN64System, TraceDebug, "Allocated rom memory (%p)", Image);
uint8_t * Image = (uint8_t *)(((uint64_t)ImageBase.get() + 0xFFF) & ~0xFFF); // Start at beginning of memory page
WriteTrace(TraceN64System, TraceDebug, "Allocated ROM memory (%p)", Image);
//save information about the rom loaded
// Save information about the ROM loaded
m_ROMImageBase = ImageBase.release();
m_ROMImage = Image;
m_RomFileSize = RomFileSize;
@ -56,7 +56,7 @@ bool CN64Rom::AllocateAndLoadN64Image(const char * FileLoc, bool LoadBootCodeOnl
return false;
}
//Read the first 4 bytes and make sure it is a valid n64 image
// Read the first 4 bytes and make sure it is a valid N64 image
uint8_t Test[4];
m_RomFile.SeekToBegin();
if (m_RomFile.Read(Test, sizeof(Test)) != sizeof(Test))
@ -68,16 +68,16 @@ bool CN64Rom::AllocateAndLoadN64Image(const char * FileLoc, bool LoadBootCodeOnl
if (!IsValidRomImage(Test))
{
m_RomFile.Close();
WriteTrace(TraceN64System, TraceError, "invalid image file %X %X %X %X", Test[0], Test[1], Test[2], Test[3]);
WriteTrace(TraceN64System, TraceError, "Invalid image file %X %X %X %X", Test[0], Test[1], Test[2], Test[3]);
return false;
}
uint32_t RomFileSize = m_RomFile.GetLength();
WriteTrace(TraceN64System, TraceDebug, "Successfully Opened, size: 0x%X", RomFileSize);
WriteTrace(TraceN64System, TraceDebug, "Successfully opened, size: 0x%X", RomFileSize);
//if loading boot code then just load the first 0x1000 bytes
// If loading boot code then just load the first 0x1000 bytes
if (LoadBootCodeOnly)
{
WriteTrace(TraceN64System, TraceDebug, "loading boot code, so loading the first 0x1000 bytes", RomFileSize);
WriteTrace(TraceN64System, TraceDebug, "Loading boot code, so loading the first 0x1000 bytes", RomFileSize);
RomFileSize = 0x1000;
}
@ -87,7 +87,7 @@ bool CN64Rom::AllocateAndLoadN64Image(const char * FileLoc, bool LoadBootCodeOnl
return false;
}
//Load the n64 rom to the allocated memory
// Load the N64 ROM into the allocated memory
g_Notify->DisplayMessage(5, MSG_LOADING);
m_RomFile.SeekToBegin();
@ -106,7 +106,7 @@ bool CN64Rom::AllocateAndLoadN64Image(const char * FileLoc, bool LoadBootCodeOnl
}
TotalRead += dwToRead;
//Show Message of how much % wise of the rom has been loaded
// Show message of how much of the ROM has been loaded (as a percent)
g_Notify->DisplayMessage(0, stdstr_f("%s: %.2f%c", GS(MSG_LOADED), ((float)TotalRead / (float)RomFileSize) * 100.0f, '%').c_str());
}
@ -121,7 +121,7 @@ bool CN64Rom::AllocateAndLoadN64Image(const char * FileLoc, bool LoadBootCodeOnl
g_Notify->DisplayMessage(5, MSG_BYTESWAP);
ByteSwapRom();
//Protect the memory so that it can not be written to.
// Protect the memory so that it can't be written to
ProtectMemory(m_ROMImage, m_RomFileSize, MEM_READONLY);
return true;
}
@ -137,7 +137,7 @@ bool CN64Rom::AllocateAndLoadZipImage(const char * FileLoc, bool LoadBootCodeOnl
int port = unzGoToFirstFile(file);
bool FoundRom = false;
//scan through all files in zip to a suitable file is found
// Scan through all files in zip until a suitable file is found
while (port == UNZ_OK && !FoundRom)
{
unz_file_info info;
@ -160,7 +160,7 @@ bool CN64Rom::AllocateAndLoadZipImage(const char * FileLoc, bool LoadBootCodeOnl
unzReadCurrentFile(file, Test, sizeof(Test));
if (IsValidRomImage(Test))
{
//Get the size of the rom and try to allocate the memory needed.
// Get the size of the ROM and try to allocate the memory needed
uint32_t RomFileSize = info.uncompressed_size;
if (LoadBootCodeOnly)
{
@ -173,7 +173,7 @@ bool CN64Rom::AllocateAndLoadZipImage(const char * FileLoc, bool LoadBootCodeOnl
return false;
}
//Load the n64 rom to the allocated memory
// Load the N64 ROM into the allocated memory
g_Notify->DisplayMessage(5, MSG_LOADING);
memcpy(m_ROMImage, Test, 4);
@ -192,7 +192,7 @@ bool CN64Rom::AllocateAndLoadZipImage(const char * FileLoc, bool LoadBootCodeOnl
}
TotalRead += dwRead;
//Show Message of how much % wise of the rom has been loaded
// Show message of how much of the ROM has been loaded (as a percent)
g_Notify->DisplayMessage(5, stdstr_f("%s: %.2f%c", GS(MSG_LOADED), ((float)TotalRead / (float)RomFileSize) * 100.0f, '%').c_str());
}
dwRead = TotalRead + 4;
@ -209,7 +209,7 @@ bool CN64Rom::AllocateAndLoadZipImage(const char * FileLoc, bool LoadBootCodeOnl
g_Notify->DisplayMessage(5, MSG_BYTESWAP);
ByteSwapRom();
//Protect the memory so that it can not be written to.
// Protect the memory so that it can't be written to
ProtectMemory(m_ROMImage, m_RomFileSize, MEM_READONLY);
}
unzCloseCurrentFile(file);
@ -278,9 +278,9 @@ CICChip CN64Rom::GetCicChipID(uint8_t * RomData, uint64_t * CRC)
case 0x000000D6497E414B: return CIC_NUS_6103;
case 0x0000011A49F60E96: return CIC_NUS_6105;
case 0x000000D6D5BE5580: return CIC_NUS_6106;
case 0x000001053BC19870: return CIC_NUS_5167; //64DD CONVERSION CIC
case 0x000001053BC19870: return CIC_NUS_5167; // 64DD conversion CIC
case 0x000000D2E53EF008: return CIC_NUS_8303; // 64DD IPL
case 0x000000D2E53EF39F: return CIC_NUS_DDTL; //64DD IPL TOOL
case 0x000000D2E53EF39F: return CIC_NUS_DDTL; // 64DD IPL tool
case 0x000000D2E53E5DDA: return CIC_NUS_DDUS; // 64DD IPL US (different CIC)
default:
return CIC_UNKNOWN;
@ -459,7 +459,7 @@ void CN64Rom::CleanRomName(char * RomName, bool byteswap)
}
}
//truncate all the spaces at the end of the string
// Truncate all the spaces at the end of the string
for (int count = 19; count >= 0; count--)
{
if (RomName[count] == ' ')
@ -476,7 +476,7 @@ void CN64Rom::CleanRomName(char * RomName, bool byteswap)
}
RomName[20] = '\0';
//remove all /,\,: from the string
// Remove all special characters from the string
for (int count = 0; count < (int)strlen(RomName); count++)
{
switch (RomName[count])
@ -507,7 +507,7 @@ bool CN64Rom::LoadN64Image(const char * FileLoc, bool LoadBootCodeOnly)
{
stdstr FullPath = FileLoc;
//this should be a 7zip file
// This should be a 7-zip file
char * SubFile = strstr(const_cast<char*>(FullPath.c_str()), "?");
if (SubFile != nullptr)
{
@ -517,7 +517,7 @@ bool CN64Rom::LoadN64Image(const char * FileLoc, bool LoadBootCodeOnly)
//else load first found file until dialog is implemented
//{
// Pop up a dialog and select file
//allocate memory for sub name and copy selected file name to var
// Allocate memory for sub name and copy selected file name to variable
//}
C7zip ZipFile(FullPath.c_str());
@ -540,9 +540,9 @@ bool CN64Rom::LoadN64Image(const char * FileLoc, bool LoadBootCodeOnly)
}
}
//Get the size of the rom and try to allocate the memory needed.
// Get the size of the ROM and try to allocate the memory needed
uint32_t RomFileSize = (uint32_t)f->Size;
//if loading boot code then just load the first 0x1000 bytes
// If loading boot code then just load the first 0x1000 bytes
if (LoadBootCodeOnly) { RomFileSize = 0x1000; }
if (!AllocateRomImage(RomFileSize))
@ -551,7 +551,7 @@ bool CN64Rom::LoadN64Image(const char * FileLoc, bool LoadBootCodeOnly)
return false;
}
//Load the n64 rom to the allocated memory
// Load the N64 ROM to the allocated memory
g_Notify->DisplayMessage(5, MSG_LOADING);
if (!ZipFile.GetFile(i, m_ROMImage, RomFileSize))
{
@ -574,7 +574,7 @@ bool CN64Rom::LoadN64Image(const char * FileLoc, bool LoadBootCodeOnly)
g_Notify->DisplayMessage(5, MSG_BYTESWAP);
ByteSwapRom();
//Protect the memory so that it can not be written to.
// Protect the memory so that it can't be written to
ProtectMemory(m_ROMImage, m_RomFileSize, MEM_READONLY);
Loaded7zFile = true;
break;
@ -607,7 +607,7 @@ bool CN64Rom::LoadN64Image(const char * FileLoc, bool LoadBootCodeOnly)
}
char RomName[260];
//Get the header from the rom image
// Get the header from the ROM image
memcpy(&RomName[0], (void *)(m_ROMImage + 0x20), 20);
CN64Rom::CleanRomName(RomName);
@ -625,7 +625,7 @@ bool CN64Rom::LoadN64Image(const char * FileLoc, bool LoadBootCodeOnly)
if (!LoadBootCodeOnly)
{
//Calculate files MD5
// Calculate files MD5 checksum
m_MD5 = MD5((const unsigned char *)m_ROMImage, m_RomFileSize).hex_digest();
WriteTrace(TraceN64System, TraceDebug, "MD5: %s", m_MD5.c_str());
}
@ -636,7 +636,7 @@ bool CN64Rom::LoadN64Image(const char * FileLoc, bool LoadBootCodeOnly)
if (IsLoadedRomDDIPL())
{
//Handle CRC differently if 64DD IPL
// Handle CRC differently if it is a 64DD IPL
CRC1 = (*(uint16_t *)(&m_ROMImage[0x608]) << 16) | *(uint16_t *)(&m_ROMImage[0x60C]);
CRC2 = (*(uint16_t *)(&m_ROMImage[0x638]) << 16) | *(uint16_t *)(&m_ROMImage[0x63C]);
}
@ -677,13 +677,13 @@ bool CN64Rom::LoadN64Image(const char * FileLoc, bool LoadBootCodeOnly)
}
else if (!IsLoadedRomDDIPL())
{
g_Settings->SaveString(Game_GameName, m_RomName.c_str()); //Use Base Game's Save File if loaded in combo
g_Settings->SaveString(Game_GameName, m_RomName.c_str()); // Use base games save file if loaded in combo
}
}
if (g_Settings->LoadBool(Game_CRC_Recalc))
{
//Calculate ROM Header CRC
// Calculate ROM header CRC
CalculateRomCrc();
}
@ -703,7 +703,7 @@ bool CN64Rom::LoadN64ImageIPL(const char * FileLoc, bool LoadBootCodeOnly)
{
stdstr FullPath = FileLoc;
//this should be a 7zip file
// This should be a 7-zip file
char * SubFile = strstr(const_cast<char*>(FullPath.c_str()), "?");
if (SubFile != nullptr)
{
@ -713,7 +713,7 @@ bool CN64Rom::LoadN64ImageIPL(const char * FileLoc, bool LoadBootCodeOnly)
//else load first found file until dialog is implemented
//{
// Pop up a dialog and select file
//allocate memory for sub name and copy selected file name to var
// Allocate memory for sub name and copy selected file name to variable
//}
C7zip ZipFile(FullPath.c_str());
@ -736,9 +736,9 @@ bool CN64Rom::LoadN64ImageIPL(const char * FileLoc, bool LoadBootCodeOnly)
}
}
//Get the size of the rom and try to allocate the memory needed.
// Get the size of the ROM and try to allocate the memory needed
uint32_t RomFileSize = (uint32_t)f->Size;
//if loading boot code then just load the first 0x1000 bytes
// If loading boot code then just load the first 0x1000 bytes
if (LoadBootCodeOnly) { RomFileSize = 0x1000; }
if (!AllocateRomImage(RomFileSize))
@ -747,7 +747,7 @@ bool CN64Rom::LoadN64ImageIPL(const char * FileLoc, bool LoadBootCodeOnly)
return false;
}
//Load the n64 rom to the allocated memory
// Load the N64 ROM to the allocated memory
g_Notify->DisplayMessage(5, MSG_LOADING);
if (!ZipFile.GetFile(i, m_ROMImage, RomFileSize))
{
@ -770,7 +770,7 @@ bool CN64Rom::LoadN64ImageIPL(const char * FileLoc, bool LoadBootCodeOnly)
g_Notify->DisplayMessage(5, MSG_BYTESWAP);
ByteSwapRom();
//Protect the memory so that it can not be written to.
// Protect the memory so that it can't be written to
ProtectMemory(m_ROMImage, m_RomFileSize, MEM_READONLY);
Loaded7zFile = true;
break;
@ -801,7 +801,7 @@ bool CN64Rom::LoadN64ImageIPL(const char * FileLoc, bool LoadBootCodeOnly)
}
char RomName[260];
//Get the header from the rom image
// Get the header from the ROM image
memcpy(&RomName[0], (void *)(m_ROMImage + 0x20), 20);
CN64Rom::CleanRomName(RomName);
if (strlen(RomName) == 0)
@ -817,7 +817,7 @@ bool CN64Rom::LoadN64ImageIPL(const char * FileLoc, bool LoadBootCodeOnly)
if (!LoadBootCodeOnly)
{
//Calculate files MD5
// Calculate files MD5 checksum
m_MD5 = MD5((const unsigned char *)m_ROMImage, m_RomFileSize).hex_digest();
WriteTrace(TraceN64System, TraceDebug, "MD5: %s", m_MD5.c_str());
}
@ -828,7 +828,7 @@ bool CN64Rom::LoadN64ImageIPL(const char * FileLoc, bool LoadBootCodeOnly)
if (IsLoadedRomDDIPL())
{
//Handle CRC differently if 64DD IPL
// Handle CRC differently if it is a 64DD IPL
CRC1 = (*(uint16_t *)(&m_ROMImage[0x608]) << 16) | *(uint16_t *)(&m_ROMImage[0x60C]);
CRC2 = (*(uint16_t *)(&m_ROMImage[0x638]) << 16) | *(uint16_t *)(&m_ROMImage[0x63C]);
}
@ -854,15 +854,15 @@ bool CN64Rom::LoadN64ImageIPL(const char * FileLoc, bool LoadBootCodeOnly)
if (g_Settings->LoadBool(Game_CRC_Recalc))
{
//Calculate ROM Header CRC
// Calculate ROM header CRC
CalculateRomCrc();
}
return true;
}
//Save the settings of the loaded rom, so all loaded settings about rom will be identified with
//this rom
// Save the settings of the loaded ROM, so all loaded settings about ROM will be identified with this ROM
void CN64Rom::SaveRomSettingID(bool temp)
{
g_Settings->SaveBool(Game_TempLoaded, temp);

View File

@ -27,7 +27,7 @@ public:
bool IsPal();
void UnallocateRomImage();
//Get a message id for the reason that you failed to load the rom
// Get a message ID for the reason that you failed to load the ROM
LanguageStringID GetError() const { return m_ErrorMsg; }
static CICChip GetCicChipID(uint8_t * RomData, uint64_t * CRC = nullptr);
static void CleanRomName(char * RomName, bool byteswap = true);
@ -43,10 +43,10 @@ private:
static void NotificationCB(const char * Status, CN64Rom * _this);
//constant values
// Constant values
enum { ReadFromRomSection = 0x400000 };
//class variables
// Class variables
CFile m_RomFile;
uint8_t * m_ROMImage;
uint8_t * m_ROMImageBase;

View File

@ -67,12 +67,12 @@ CN64System::CN64System(CPlugins * Plugins, uint32_t randomizer_seed, bool SavesR
if (!m_MMU_VM.Initialize(SyncSystem))
{
WriteTrace(TraceN64System, TraceWarning, "MMU failed to Initialize");
WriteTrace(TraceN64System, TraceWarning, "MMU failed to initialize");
WriteTrace(TraceN64System, TraceDebug, "Done");
return;
}
WriteTrace(TraceN64System, TraceDebug, "Reseting Plugins");
WriteTrace(TraceN64System, TraceDebug, "Resetting plugins");
g_Notify->DisplayMessage(5, MSG_PLUGIN_INIT);
m_Plugins->CreatePlugins();
bool bRes = m_Plugins->Initiate(this);
@ -98,7 +98,7 @@ CN64System::CN64System(CPlugins * Plugins, uint32_t randomizer_seed, bool SavesR
{
g_Notify->BreakPoint(__FILE__, __LINE__);
}
g_Notify->DisplayMessage(5, "Copy Plugins");
g_Notify->DisplayMessage(5, "Copy plugins");
g_Plugins->CopyPlugins(g_Settings->LoadStringVal(Directory_PluginSync));
m_SyncPlugins = new CPlugins(Directory_PluginSync, true);
m_SyncPlugins->SetRenderWindows(g_Plugins->SyncWindow(), nullptr);
@ -154,14 +154,14 @@ CN64System::~CN64System()
void CN64System::ExternalEvent(SystemEvent action)
{
WriteTrace(TraceN64System, TraceDebug, "action: %s", SystemEventName(action));
WriteTrace(TraceN64System, TraceDebug, "Action: %s", SystemEventName(action));
if (action == SysEvent_LoadMachineState &&
!g_Settings->LoadBool(GameRunning_CPU_Running) &&
g_BaseSystem != nullptr &&
g_BaseSystem->LoadState())
{
WriteTrace(TraceN64System, TraceDebug, "ignore event, manualy loaded save");
WriteTrace(TraceN64System, TraceDebug, "Ignore event, manually loaded save");
return;
}
@ -170,7 +170,7 @@ void CN64System::ExternalEvent(SystemEvent action)
g_BaseSystem != nullptr &&
g_BaseSystem->SaveState())
{
WriteTrace(TraceN64System, TraceDebug, "ignore event, manualy saved event");
WriteTrace(TraceN64System, TraceDebug, "Ignore event, manually saved event");
return;
}
@ -228,7 +228,7 @@ void CN64System::ExternalEvent(SystemEvent action)
}
break;
case SysEvent_ResumeCPU_FromMenu:
// always resume if from menu
// Always resume if from menu
m_hPauseEvent.Trigger();
break;
case SysEvent_ResumeCPU_AppGainedFocus:
@ -305,24 +305,24 @@ bool CN64System::LoadFileImage(const char * FileLoc)
g_Settings->SaveDword(Game_CurrentSaveState, g_Settings->LoadDefaultDword(Game_CurrentSaveState));
if (g_Settings->LoadBool(GameRunning_LoadingInProgress))
{
WriteTrace(TraceN64System, TraceError, "game loading is in progress, can not load new file");
WriteTrace(TraceN64System, TraceError, "Game loading is in progress, cannot load new file");
return false;
}
//Mark the rom as loading
WriteTrace(TraceN64System, TraceDebug, "Mark Rom as loading");
// Mark the ROM as loading
WriteTrace(TraceN64System, TraceDebug, "Mark ROM as loading");
g_Settings->SaveString(Game_File, "");
g_Settings->SaveBool(GameRunning_LoadingInProgress, true);
//Try to load the passed N64 rom
// Try to load the passed N64 ROM
if (g_Rom == nullptr)
{
WriteTrace(TraceN64System, TraceDebug, "Allocating global rom object");
WriteTrace(TraceN64System, TraceDebug, "Allocating global ROM object");
g_Rom = new CN64Rom();
}
else
{
WriteTrace(TraceN64System, TraceDebug, "Use existing global rom object");
WriteTrace(TraceN64System, TraceDebug, "Use existing global ROM object");
}
WriteTrace(TraceN64System, TraceDebug, "Loading \"%s\"", FileLoc);
@ -351,7 +351,7 @@ bool CN64System::LoadFileImage(const char * FileLoc)
g_Settings->SaveString(Game_File, FileLoc);
}
g_Settings->SaveBool(GameRunning_LoadingInProgress, false);
WriteTrace(TraceN64System, TraceDebug, "Finished Loading (GoodName: %s)", g_Settings->LoadStringVal(Rdb_GoodName).c_str());
WriteTrace(TraceN64System, TraceDebug, "Finished loading (GoodName: %s)", g_Settings->LoadStringVal(Rdb_GoodName).c_str());
}
else
{
@ -375,20 +375,20 @@ bool CN64System::LoadFileImageIPL(const char * FileLoc)
return false;
}
//Mark the rom as loading
WriteTrace(TraceN64System, TraceDebug, "Mark DDRom as loading");
// Mark the N64DD IPL as loading
WriteTrace(TraceN64System, TraceDebug, "Mark N64DD IPL as loading");
//g_Settings->SaveString(Game_File, "");
g_Settings->SaveBool(GameRunning_LoadingInProgress, true);
//Try to load the passed N64 DDrom
// Try to load the passed N64DD IPL
if (g_DDRom == nullptr)
{
WriteTrace(TraceN64System, TraceDebug, "Allocating global DDrom object");
WriteTrace(TraceN64System, TraceDebug, "Allocating global N64DD IPL object");
g_DDRom = new CN64Rom();
}
else
{
WriteTrace(TraceN64System, TraceDebug, "Use existing global DDrom object");
WriteTrace(TraceN64System, TraceDebug, "Use existing global N64DD IPL object");
}
WriteTrace(TraceN64System, TraceDebug, "Loading \"%s\"", FileLoc);
@ -437,20 +437,20 @@ bool CN64System::LoadDiskImage(const char * FileLoc, const bool Expansion)
return false;
}
//Mark the rom as loading
WriteTrace(TraceN64System, TraceDebug, "Mark Disk as loading");
// Mark the disk as loading
WriteTrace(TraceN64System, TraceDebug, "Mark disk as loading");
//g_Settings->SaveString(Game_File, "");
g_Settings->SaveBool(GameRunning_LoadingInProgress, true);
//Try to load the passed N64 Disk
// Try to load the passed N64 disk
if (g_Disk == nullptr)
{
WriteTrace(TraceN64System, TraceDebug, "Allocating global Disk object");
WriteTrace(TraceN64System, TraceDebug, "Allocating global disk object");
g_Disk = new CN64Disk();
}
else
{
WriteTrace(TraceN64System, TraceDebug, "Use existing global Disk object");
WriteTrace(TraceN64System, TraceDebug, "Use existing global disk object");
}
WriteTrace(TraceN64System, TraceDebug, "Loading \"%s\"", FileLoc);
@ -478,7 +478,7 @@ bool CN64System::LoadDiskImage(const char * FileLoc, const bool Expansion)
bool CN64System::RunFileImage(const char * FileLoc)
{
//Uninitialize g_Disk and g_DDRom to prevent exception when ending emulation of a regular ROM after playing 64DD content previously.
// Uninitialize g_Disk and g_DDRom to prevent exception when ending emulation of a regular ROM after playing 64DD content previously
if (g_Disk != nullptr)
{
g_Disk->UnallocateDiskImage();
@ -517,7 +517,7 @@ bool CN64System::RunDiskImage(const char * FileLoc)
return false;
}
//Select IPL ROM depending on Disk Country Code
// Select IPL ROM depending on disk country code
if (!SelectAndLoadFileImageIPL(g_Disk->GetCountry(), false))
{
return false;
@ -539,7 +539,7 @@ bool CN64System::RunDiskComboImage(const char * FileLoc, const char * FileLocDis
return false;
}
//Select IPL ROM depending on Disk Country Code
// Select IPL ROM depending on disk country code
if (!SelectAndLoadFileImageIPL(g_Disk->GetCountry(), true))
{
return false;
@ -558,7 +558,7 @@ void CN64System::RunLoadedImage(void)
{
if (g_Settings->LoadBool(Setting_AutoStart) != 0)
{
WriteTrace(TraceN64System, TraceDebug, "Automattically starting rom");
WriteTrace(TraceN64System, TraceDebug, "Automatically starting ROM");
g_BaseSystem->StartEmulation(true);
}
}
@ -605,7 +605,7 @@ bool CN64System::SelectAndLoadFileImageIPL(Country country, bool combo)
IPLROMError = MSG_TOOL_IPL_REQUIRED;
if (combo && !CPath(g_Settings->LoadStringVal(File_DiskIPLTOOLPath).c_str()).Exists())
{
//Development IPL is not needed for combo ROM + Disk loading
// Development IPL is not needed for combo ROM + disk loading
if (CPath(g_Settings->LoadStringVal(File_DiskIPLPath).c_str()).Exists())
IPLROMPathSetting = File_DiskIPLPath;
else if (CPath(g_Settings->LoadStringVal(File_DiskIPLUSAPath).c_str()).Exists())
@ -660,14 +660,14 @@ bool CN64System::EmulationStarting(CThread * thread)
if (g_BaseSystem->SetActiveSystem(true))
{
g_BaseSystem->m_thread = thread;
WriteTrace(TraceN64System, TraceDebug, "Setting up N64 system done");
WriteTrace(TraceN64System, TraceDebug, "Setting up N64 system is done");
g_Settings->SaveBool(GameRunning_LoadingInProgress, false);
try
{
WriteTrace(TraceN64System, TraceDebug, "Game starting");
g_BaseSystem->StartEmulation2(false);
WriteTrace(TraceN64System, TraceDebug, "Game Done");
//PLACE TO ADD 64DD SAVING CODE
WriteTrace(TraceN64System, TraceDebug, "Game done");
// TODO: Add 64DD saving code?
if (g_Disk != nullptr)
{
g_Disk->SaveDiskImage();
@ -715,7 +715,7 @@ void CN64System::StartEmulation2(bool NewThread)
WriteTrace(TraceN64System, TraceDebug, "Setting system as active");
if (!m_Plugins->Reset(this) || !m_Plugins->initilized())
{
WriteTrace(TraceN64System, TraceWarning, "can not run, plugins not initlized");
WriteTrace(TraceN64System, TraceWarning, "Can't run, plugins not initialized");
g_Settings->SaveBool(GameRunning_LoadingInProgress, false);
g_Notify->DisplayError(MSG_PLUGIN_NOT_INIT);
}
@ -732,9 +732,9 @@ void CN64System::StartEmulation2(bool NewThread)
}
else
{
//mark the emulation as starting and fix up menus
// Mark the emulation as starting and fix up menus
g_Notify->DisplayMessage(2, MSG_EMULATION_STARTED);
WriteTrace(TraceN64System, TraceDebug, "Start Executing CPU");
WriteTrace(TraceN64System, TraceDebug, "Start executing CPU");
ExecuteCPU();
}
WriteTrace(TraceN64System, TraceDebug, "Done");
@ -969,7 +969,7 @@ void CN64System::InitRegisters(bool bPostPif, CMipsMemoryVM & MMU)
{
m_Reg.Reset();
//COP0 Registers
// COP0 registers
m_Reg.RANDOM_REGISTER = 0x1F;
m_Reg.COUNT_REGISTER = 0x5000;
m_Reg.MI_VERSION_REG = 0x02020102;
@ -982,9 +982,9 @@ void CN64System::InitRegisters(bool bPostPif, CMipsMemoryVM & MMU)
m_Reg.CONFIG_REGISTER = 0x0006E463;
m_Reg.STATUS_REGISTER = 0x34000000;
//64DD Registers
// N64DD registers
//Start 64DD in Reset State and Motor Not Spinning
// Start N64DD in reset state and motor not spinning
m_Reg.ASIC_STATUS = DD_STATUS_RST_STATE | DD_STATUS_MTR_N_SPIN;
m_Reg.ASIC_ID_REG = 0x00030000;
if (g_DDRom && (g_DDRom->CicChipID() == CIC_NUS_DDTL || (g_Disk && g_Disk->GetCountry() == Country_Unknown)))
@ -1074,7 +1074,7 @@ void CN64System::InitRegisters(bool bPostPif, CMipsMemoryVM & MMU)
case CIC_NUS_DDUS:
case CIC_NUS_DDTL:
default:
//no specific values
// No specific values
break;
}
m_Reg.m_GPR[20].DW = 0x0000000000000001;
@ -1089,8 +1089,8 @@ void CN64System::InitRegisters(bool bPostPif, CMipsMemoryVM & MMU)
m_Reg.m_GPR[22].DW = 0x000000000000003F;
break;
case CIC_NUS_8303: // 64DD IPL CIC
case CIC_NUS_DDTL: //64DD IPL TOOL CIC
case CIC_NUS_5167: //64DD CONVERSION CIC
case CIC_NUS_DDTL: // 64DD IPL tool CIC
case CIC_NUS_5167: // 64DD conversion CIC
m_Reg.m_GPR[22].DW = 0x00000000000000DD;
break;
case CIC_NUS_DDUS: // 64DD US IPL CIC
@ -1153,7 +1153,7 @@ void CN64System::InitRegisters(bool bPostPif, CMipsMemoryVM & MMU)
else
{
m_Reg.m_PROGRAM_COUNTER = 0xBFC00000;
/* PIF_Ram[36] = 0x00; PIF_Ram[39] = 0x3F; //common pif ram start values
/* PIF_Ram[36] = 0x00; PIF_Ram[39] = 0x3F; // Common PIF RAM start values
switch (g_Rom->CicChipID()) {
case CIC_NUS_6101: PIF_Ram[37] = 0x06; PIF_Ram[38] = 0x3F; break;
@ -1170,7 +1170,7 @@ void CN64System::ExecuteCPU()
{
WriteTrace(TraceN64System, TraceDebug, "Start");
//reset code
// Reset code
g_Settings->SaveBool(GameRunning_CPU_Paused, false);
g_Settings->SaveBool(GameRunning_CPU_Running, true);
g_Notify->DisplayMessage(2, MSG_EMULATION_STARTED);
@ -1205,7 +1205,7 @@ void CN64System::ExecuteCPU()
}
WriteTrace(TraceN64System, TraceDebug, "CPU finished executing");
CpuStopped();
WriteTrace(TraceN64System, TraceDebug, "Notifing plugins rom is done");
WriteTrace(TraceN64System, TraceDebug, "Notifying plugins ROM is done");
m_Plugins->RomClosed();
if (m_SyncCPU)
{
@ -1438,7 +1438,7 @@ void CN64System::DumpSyncErrors(CN64System * SecondCPU)
CLog Error;
Error.Open(ErrorFile);
Error.Log("Errors:\r\n");
Error.Log("Register, Recompiler, Interpter\r\n");
Error.Log("Register, Recompiler, Interpreter\r\n");
#ifdef TEST_SP_TRACKING
if (m_CurrentSP != GPR[29].UW[0])
{
@ -1552,7 +1552,7 @@ void CN64System::DumpSyncErrors(CN64System * SecondCPU)
{
if (Rdram[z] != Rdram2[z])
{
Error.LogF("Rdram[%X]: %X %X\r\n", z << 2, Rdram[z], Rdram2[z]);
Error.LogF("RDRAM[%X]: %X %X\r\n", z << 2, Rdram[z], Rdram2[z]);
}
}
@ -1561,7 +1561,7 @@ void CN64System::DumpSyncErrors(CN64System * SecondCPU)
{
if (Imem[z] != Imem2[z])
{
Error.LogF("Imem[%X]: %X %X\r\n", z << 2, Imem[z], Imem2[z]);
Error.LogF("IMEM[%X]: %X %X\r\n", z << 2, Imem[z], Imem2[z]);
}
}
uint32_t * Dmem = (uint32_t *)m_MMU_VM.Dmem(), *Dmem2 = (uint32_t *)SecondCPU->m_MMU_VM.Dmem();
@ -1569,15 +1569,15 @@ void CN64System::DumpSyncErrors(CN64System * SecondCPU)
{
if (Dmem[z] != Dmem2[z])
{
Error.LogF("Dmem[%X]: %X %X\r\n", z << 2, Dmem[z], Dmem2[z]);
Error.LogF("DMEM[%X]: %X %X\r\n", z << 2, Dmem[z], Dmem2[z]);
}
}
Error.Log("\r\n");
Error.Log("Information:\r\n");
Error.Log("\r\n");
Error.LogF("PROGRAM_COUNTER,0x%X\r\n", m_Reg.m_PROGRAM_COUNTER);
Error.LogF("Current Timer,0x%X\r\n", m_NextTimer);
Error.LogF("Timer Type,0x%X\r\n", m_SystemTimer.CurrentType());
Error.LogF("Current timer,0x%X\r\n", m_NextTimer);
Error.LogF("Timer type,0x%X\r\n", m_SystemTimer.CurrentType());
Error.Log("\r\n");
for (int i = 0; i < (sizeof(m_LastSuccessSyncPC) / sizeof(m_LastSuccessSyncPC[0])); i++)
{
@ -1610,7 +1610,7 @@ void CN64System::DumpSyncErrors(CN64System * SecondCPU)
count < 10 ? 7 : 6, " ", *(m_Reg.m_FPR_D[count]), *(SecondCPU->m_Reg.m_FPR_D[count]));
}
Error.Log("\r\n");
Error.LogF("Rounding Model, 0x%08X, 0x%08X\r\n", m_Reg.m_RoundingModel, SecondCPU->m_Reg.m_RoundingModel);
Error.LogF("Rounding model, 0x%08X, 0x%08X\r\n", m_Reg.m_RoundingModel, SecondCPU->m_Reg.m_RoundingModel);
Error.Log("\r\n");
for (count = 0; count < 32; count++)
{
@ -1661,7 +1661,7 @@ void CN64System::DumpSyncErrors(CN64System * SecondCPU)
}
}
Error.Log("\r\n");
Error.Log("Code at Last Sync PC:\r\n");
Error.Log("Code at last sync PC:\r\n");
for (count = 0; count < 50; count++)
{
uint32_t OpcodeValue, Addr = m_LastSuccessSyncPC[0] + (count << 2);
@ -1672,7 +1672,7 @@ void CN64System::DumpSyncErrors(CN64System * SecondCPU)
}
}
g_Notify->DisplayError("Sync Error");
g_Notify->DisplayError("Sync error");
g_Notify->BreakPoint(__FILE__, __LINE__);
}
@ -1683,7 +1683,7 @@ bool CN64System::SaveState()
// if (!m_SystemTimer.SaveAllowed()) { return false; }
if ((m_Reg.STATUS_REGISTER & STATUS_EXL) != 0)
{
WriteTrace(TraceN64System, TraceDebug, "Done - STATUS_EXL set, can not save");
WriteTrace(TraceN64System, TraceDebug, "Done - STATUS_EXL set, can't save");
return false;
}
@ -1715,7 +1715,7 @@ bool CN64System::SaveState()
CPath ZipFile(SaveFile);
ZipFile.SetNameExtension(stdstr_f("%s.zip", ZipFile.GetNameExtension().c_str()).c_str());
//Make sure the target dir exists
// Make sure the target directory exists
if (!SaveFile.DirectoryExists())
{
SaveFile.DirectoryCreate();
@ -1742,7 +1742,7 @@ bool CN64System::SaveState()
zipWriteInFileInZip(file, &RdramSize, sizeof(uint32_t));
if (g_Settings->LoadBool(Setting_EnableDisk) && g_Disk)
{
//Keep Base ROM Information (64DD IPL / Compatible Game ROM)
// Keep base ROM information (64DD IPL / compatible game ROM)
zipWriteInFileInZip(file, &g_Rom->GetRomAddress()[0x10], 0x20);
zipWriteInFileInZip(file, g_Disk->GetDiskAddressID(), 0x20);
}
@ -1776,13 +1776,13 @@ bool CN64System::SaveState()
zipOpenNewFileInZip(file, ExtraInfo.GetNameExtension().c_str(), nullptr, nullptr, 0, nullptr, 0, nullptr, Z_DEFLATED, Z_DEFAULT_COMPRESSION);
//Extra Info v2
// Extra info v2
zipWriteInFileInZip(file, &SaveID_2, sizeof(SaveID_2));
//Disk Interface Info
// Disk interface info
zipWriteInFileInZip(file, m_Reg.m_DiskInterface, sizeof(uint32_t) * 22);
//System Timers Info
// System timers info
m_SystemTimer.SaveData(file);
zipCloseFileInZip(file);
@ -1812,7 +1812,7 @@ bool CN64System::SaveState()
hSaveFile.Write(&RdramSize, sizeof(uint32_t));
if (g_Settings->LoadBool(Setting_EnableDisk) && g_Disk)
{
//Keep Base ROM Information (64DD IPL / Compatible Game ROM)
// Keep base ROM information (64DD IPL / compatible game ROM)
hSaveFile.Write(&g_Rom->GetRomAddress()[0x10], 0x20);
hSaveFile.Write(g_Disk->GetDiskAddressID(), 0x20);
}
@ -1847,13 +1847,13 @@ bool CN64System::SaveState()
CFile hExtraInfo(ExtraInfo, CFileBase::modeWrite | CFileBase::modeCreate);
if (hExtraInfo.IsOpen())
{
//Extra Info v2
// Extra info v2
hExtraInfo.Write(&SaveID_2, sizeof(uint32_t));
//Disk Interface Info
// Disk interface info
hExtraInfo.Write(m_Reg.m_DiskInterface, sizeof(uint32_t) * 22);
//System Timers Info
// System timers info
m_SystemTimer.SaveData(hExtraInfo);
hExtraInfo.Close();
}
@ -1954,7 +1954,7 @@ bool CN64System::LoadState(const char * FileName)
if (g_Settings->LoadDword(Setting_AutoZipInstantSave) || _stricmp(SaveFile.GetExtension().c_str(), ".zip") == 0)
{
//If ziping save add .zip on the end
// If zipping save add .zip on the end
if (!SaveFile.Exists() && _stricmp(SaveFile.GetExtension().c_str(), ".zip") != 0)
{
SaveFile.SetNameExtension(stdstr_f("%s.zip", SaveFile.GetNameExtension().c_str()).c_str());
@ -1993,7 +1993,7 @@ bool CN64System::LoadState(const char * FileName)
unzReadCurrentFile(file, LoadHeader, 0x40);
if (g_Settings->LoadBool(Setting_EnableDisk) && g_Disk)
{
//Base ROM Information (64DD IPL / Compatible Game ROM) & Disk Info Check
// Base ROM information (64DD IPL / compatible game ROM) and disk info check
if ((memcmp(LoadHeader, &g_Rom->GetRomAddress()[0x10], 0x20) != 0 ||
memcmp(&LoadHeader[0x20], g_Disk->GetDiskAddressID(), 0x20) != 0) &&
!g_Notify->AskYesNoQuestion(g_Lang->GetString(MSG_SAVE_STATE_HEADER).c_str()))
@ -2043,21 +2043,21 @@ bool CN64System::LoadState(const char * FileName)
}
if (LoadedZipFile && Value == SaveID_1 && port == UNZ_OK)
{
//Extra Info v1
//System Timers Info
// Extra info v1
// System timers info
m_SystemTimer.LoadData(file);
}
if (LoadedZipFile && Value == SaveID_2 && port == UNZ_OK)
{
//Extra Info v2 (Project64 2.4)
//Disk Interface Info
// Extra info v2 (Project64 2.4)
// Disk interface info
unzReadCurrentFile(file, m_Reg.m_DiskInterface, sizeof(uint32_t) * 22);
//Recover Disk Seek Address (if the save state is done while loading/saving data)
// Recover disk seek address (if the save state is done while loading/saving data)
if (g_Disk)
DiskBMReadWrite(false);
//System Timers Info
// System timers info
m_SystemTimer.LoadData(file);
}
unzCloseCurrentFile(file);
@ -2088,7 +2088,7 @@ bool CN64System::LoadState(const char * FileName)
hSaveFile.Read(LoadHeader, 0x40);
if (g_Settings->LoadBool(Setting_EnableDisk) && g_Disk)
{
//Base ROM Information (64DD IPL / Compatible Game ROM) & Disk Info Check
// Base ROM information (64DD IPL / compatible game ROM) and disk info check
if ((memcmp(LoadHeader, &g_Rom->GetRomAddress()[0x10], 0x20) != 0 ||
memcmp(&LoadHeader[0x20], g_Disk->GetDiskAddressID(), 0x20) != 0) &&
!g_Notify->AskYesNoQuestion(g_Lang->GetString(MSG_SAVE_STATE_HEADER).c_str()))
@ -2138,22 +2138,22 @@ bool CN64System::LoadState(const char * FileName)
CFile hExtraInfo(ExtraInfo, CFileBase::modeRead);
if (hExtraInfo.IsOpen())
{
//Extra Info version check
// Extra info version check
hExtraInfo.Read(&Value, sizeof(Value));
if (Value != SaveID_1 && Value != SaveID_2)
hExtraInfo.SeekToBegin();
//Disk Interface Info
// Disk interface info
if (Value == SaveID_2)
{
hExtraInfo.Read(m_Reg.m_DiskInterface, sizeof(uint32_t) * 22);
//Recover Disk Seek Address (if the save state is done while loading/saving data)
// Recover disk seek address (if the save state is done while loading/saving data)
if (g_Disk)
DiskBMReadWrite(false);
}
//System Timers Info
// System timers info
m_SystemTimer.LoadData(hExtraInfo);
hExtraInfo.Close();
@ -2185,7 +2185,7 @@ bool CN64System::LoadState(const char * FileName)
}
g_Plugins->Audio()->DacrateChanged(SystemType());
//Fix Random Register
// Fix random register
while ((int)m_Reg.RANDOM_REGISTER < (int)m_Reg.WIRED_REGISTER)
{
m_Reg.RANDOM_REGISTER += 32 - m_Reg.WIRED_REGISTER;
@ -2288,14 +2288,14 @@ void CN64System::RunRSP()
__except_try()
{
WriteTrace(TraceRSP, TraceDebug, "do cycles - starting");
WriteTrace(TraceRSP, TraceDebug, "Do cycles - starting");
g_Plugins->RSP()->DoRspCycles(100);
WriteTrace(TraceRSP, TraceDebug, "do cycles - Done");
WriteTrace(TraceRSP, TraceDebug, "Do cycles - done");
}
__except_catch()
{
WriteTrace(TraceRSP, TraceError, "exception generated");
g_Notify->FatalError("CN64System::RunRSP()\nUnknown memory action\n\nEmulation stop");
WriteTrace(TraceRSP, TraceError, "Exception generated");
g_Notify->FatalError("CN64System::RunRSP()\nUnknown memory action\n\nEmulation stopping");
}
if (Task == 1 && bDelayDP() && ((m_Reg.m_GfxIntrReg & MI_INTR_DP) != 0))
@ -2328,7 +2328,7 @@ void CN64System::RunRSP()
{
m_RspBroke = true;
}
WriteTrace(TraceRSP, TraceDebug, "check interrupts");
WriteTrace(TraceRSP, TraceDebug, "Check interrupts");
g_Reg->CheckInterrupts();
}
}
@ -2381,13 +2381,13 @@ void CN64System::RefreshScreen()
__except_try()
{
WriteTrace(TraceGFXPlugin, TraceDebug, "UpdateScreen Starting");
WriteTrace(TraceGFXPlugin, TraceDebug, "UpdateScreen starting");
g_Plugins->Gfx()->UpdateScreen();
if (g_Debugger != nullptr && HaveDebugger())
{
g_Debugger->FrameDrawn();
}
WriteTrace(TraceGFXPlugin, TraceDebug, "UpdateScreen Done");
WriteTrace(TraceGFXPlugin, TraceDebug, "UpdateScreen done");
}
__except_catch()
{

View File

@ -27,7 +27,7 @@ class CPlugins;
class CRSP_Plugin;
class CRecompiler;
//#define TEST_SP_TRACKING //track the SP to make sure all ops pick it up fine
//#define TEST_SP_TRACKING // Track the SP to make sure all ops pick it up fine
class CN64System :
public CLogging,
@ -56,7 +56,7 @@ public:
static void CloseSystem(void);
void CloseCpu();
void ExternalEvent(SystemEvent action); //covers gui interacting and timers etc..
void ExternalEvent(SystemEvent action); // Covers GUI interactions and timers etc.
void StartEmulation(bool NewThread);
void EndEmulation();
void AlterSpeed(const CSpeedLimiter::ESpeedChange SpeedChange) { m_Limiter.AlterSpeed(SpeedChange); }
@ -83,7 +83,7 @@ public:
#ifdef TEST_SP_TRACKING
uint32_t m_CurrentSP;
#endif
//For Sync CPU
// For sync CPU
void UpdateSyncCPU(CN64System * const SecondCPU, uint32_t const Cycles);
void SyncCPU(CN64System * const SecondCPU);
void SyncCPUPC(CN64System * const SecondCPU);
@ -101,7 +101,7 @@ private:
friend class CRecompiler;
friend class CMipsMemoryVM;
//Used for loading and potentially executing the CPU in its own thread.
// Used for loading and potentially executing the CPU in its own thread
static void StartEmulationThread(CThread * thread);
static bool EmulationStarting(CThread * thread);
static void StartEmulationThead();
@ -114,7 +114,7 @@ private:
void InitRegisters(bool bPostPif, CMipsMemoryVM & MMU);
void DisplayRSPListCount();
//CPU Methods
// CPU methods
void ExecuteRecompiler();
void ExecuteInterpret();
void ExecuteSyncCPU();
@ -130,12 +130,12 @@ private:
CPlugins * const m_Plugins; // The plugin container
CPlugins * m_SyncPlugins;
CN64System * m_SyncCPU;
CMipsMemoryVM m_MMU_VM; //Memory of the n64
CMipsMemoryVM m_MMU_VM; // Memory of the N64
CTLB m_TLB;
CRegisters m_Reg;
CMempak m_Mempak;
CFramePerSecond m_FPS;
CProfiling m_CPU_Usage; //used to track the cpu usage
CProfiling m_CPU_Usage; // Used to track the CPU usage
CRecompiler * m_Recomp;
CAudio m_Audio;
CSpeedLimiter m_Limiter;
@ -155,24 +155,24 @@ private:
bool m_SyncSystem;
CRandom m_Random;
//When Syncing cores this is the PC where it last Sync'ed correctly
// When syncing cores this is the PC where it last synced correctly
uint32_t m_LastSuccessSyncPC[10];
int32_t m_CyclesToSkip;
//Handle to the cpu thread
// Handle to the CPU thread
CThread * m_thread;
// Handle to pause mutex
SyncEvent m_hPauseEvent;
//No of Alist and Dlist sent to the RSP
// Number of Alist and Dlist sent to the RSP
uint32_t m_AlistCount, m_DlistCount, m_UnknownCount;
//list of function that have been called .. used in profiling
// List of function that have been called (used in profiling)
FUNC_CALLS m_FunctionCalls;
//list of Save State File IDs
const uint32_t SaveID_0 = 0x23D8A6C8; //Main Save State Info (*.pj)
const uint32_t SaveID_1 = 0x56D2CD23; //Extra Data v1 (System Timing) Info (*.dat)
const uint32_t SaveID_2 = 0x750A6BEB; //Extra Data v2 (Timing + Disk Registers) (*.dat)
// List of save state file IDs
const uint32_t SaveID_0 = 0x23D8A6C8; // Main save state info (*.pj)
const uint32_t SaveID_1 = 0x56D2CD23; // Extra data v1 (system timing) info (*.dat)
const uint32_t SaveID_2 = 0x750A6BEB; // Extra data v2 (timing + disk registers) (*.dat)
};

View File

@ -2,12 +2,13 @@
#include <stdint.h>
/*
* The limits of COP1 extend to native SSE2 register capabilities, but for
* now this is only being included to dodge the MSVC inline asm for x86.
*
* As better cross-platform methods of handling FP precision are implemented
* for non-Intel-architecture builds, this #include may become obsolete.
The limits of COP1 extend to native SSE2 register capabilities, but for
now this is only being included to dodge the MSVC inline assembler for x86.
As better cross-platform methods of handling floating point precision are implemented
for non-Intel-architecture builds, this #include may become obsolete.
*/
#if defined(__i386) || defined(__x86_64__) || defined(_M_X64)
#include <emmintrin.h>
#endif

View File

@ -10,11 +10,11 @@ public:
void RecordTime(PROFILE_TIMERS timer, uint32_t time);
uint64_t NonCPUTime(void);
//recording timing against current timer, returns the address of the timer stopped
// Recording timing against the current timer, returns the address of the timer stopped
PROFILE_TIMERS StartTimer(PROFILE_TIMERS TimerType);
PROFILE_TIMERS StopTimer();
//Display the CPU Usage
// Display the CPU usage
void ShowCPU_Usage();
void ResetTimers(void);

View File

@ -94,7 +94,7 @@ union Arm32Opcode
uint32_t Hex;
uint8_t Ascii[4];
// uint16 + uint16 type instuction
// uint16 + uint16 type instruction
struct
{
unsigned rn : 4;

View File

@ -16,9 +16,8 @@ CArmOps::ArmReg CArmOps::m_LastStoreReg;
uint16_t CArmOps::m_PopRegisters = 0;
uint16_t CArmOps::m_PushRegisters = 0;
/**************************************************************************
* Logging Functions *
**************************************************************************/
// Logging functions
void CArmOps::WriteArmComment(const char * Comment)
{
CPU_Message("");
@ -126,7 +125,7 @@ void CArmOps::AddConstToArmReg(ArmReg DestReg, ArmReg SourceReg, uint32_t Const)
if (DestReg == SourceReg && Const == 0)
{
//ignore
// Ignore
}
else if ((Const & 0xFFFFFFF8) == 0 && DestReg <= 7 && SourceReg <= 7)
{
@ -836,7 +835,7 @@ void CArmOps::PushArmReg(uint16_t Registers)
{
if (Registers == m_PopRegisters)
{
CPU_Message("%s: Ignoring Push/Pop", __FUNCTION__);
CPU_Message("%s: Ignoring push/pop", __FUNCTION__);
m_PopRegisters = 0;
PreOpCheck(Arm_Unknown, false, __FILE__, __LINE__);
return;
@ -1373,7 +1372,7 @@ void CArmOps::XorConstToArmReg(ArmReg DestReg, uint32_t value)
if (value == 0)
{
//ignore
// Ignore
}
else if (CanThumbCompressConst(value))
{

View File

@ -144,7 +144,7 @@ public:
};
protected:
//Logging Functions
// Logging functions
static void WriteArmComment(const char * Comment);
static void WriteArmLabel(const char * Label);

View File

@ -166,7 +166,8 @@ void CArmRecompilerOps::Compile_TrapCompare(TRAP_COMPARE CompareType)
}
}
/************************** Branch functions ************************/
// Branch functions
void CArmRecompilerOps::Compile_BranchCompare(BRANCH_COMPARE CompareType)
{
switch (CompareType)
@ -643,7 +644,7 @@ void CArmRecompilerOps::BNE_Compare()
if (m_Section->m_Jump.FallThrough)
{
Jump = *g_RecompPos;
BranchLabel8(ArmBranch_Notequal, "continue");
BranchLabel8(ArmBranch_Notequal, "Continue");
}
else
{
@ -721,7 +722,7 @@ void CArmRecompilerOps::BNE_Compare()
if (m_Section->m_Jump.FallThrough)
{
Jump = *g_RecompPos;
BranchLabel8(ArmBranch_Notequal, "continue");
BranchLabel8(ArmBranch_Notequal, "Continue");
}
else
{
@ -810,7 +811,7 @@ void CArmRecompilerOps::BNE_Compare()
if (m_Section->m_Jump.FallThrough)
{
Jump = *g_RecompPos;
BranchLabel8(ArmBranch_Notequal, "continue");
BranchLabel8(ArmBranch_Notequal, "Continue");
}
else
{
@ -885,7 +886,7 @@ void CArmRecompilerOps::BNE_Compare()
if (m_Section->m_Jump.FallThrough)
{
Jump = *g_RecompPos;
BranchLabel8(ArmBranch_Notequal, "continue");
BranchLabel8(ArmBranch_Notequal, "Continue");
}
else
{
@ -980,7 +981,7 @@ void CArmRecompilerOps::BEQ_Compare()
if (m_Section->m_Cont.FallThrough)
{
Jump = *g_RecompPos;
BranchLabel8(ArmBranch_Notequal, "continue");
BranchLabel8(ArmBranch_Notequal, "Continue");
}
else
{
@ -1057,7 +1058,7 @@ void CArmRecompilerOps::BEQ_Compare()
if (m_Section->m_Cont.FallThrough)
{
Jump = *g_RecompPos;
BranchLabel8(ArmBranch_Notequal, "continue");
BranchLabel8(ArmBranch_Notequal, "Continue");
}
else
{
@ -1141,7 +1142,7 @@ void CArmRecompilerOps::BEQ_Compare()
if (m_Section->m_Cont.FallThrough)
{
Jump = *g_RecompPos;
BranchLabel8(ArmBranch_Notequal, "continue");
BranchLabel8(ArmBranch_Notequal, "Continue");
}
else
{
@ -1204,7 +1205,7 @@ void CArmRecompilerOps::BEQ_Compare()
if (m_Section->m_Cont.FallThrough)
{
Jump = *g_RecompPos;
BranchLabel8(ArmBranch_Notequal, "continue");
BranchLabel8(ArmBranch_Notequal, "Continue");
}
else
{
@ -1328,12 +1329,12 @@ void CArmRecompilerOps::BGTZ_Compare()
BranchLabel20(ArmBranch_LessThan, m_Section->m_Cont.BranchLabel.c_str());
m_Section->m_Cont.LinkLocation = (uint32_t *)(*g_RecompPos - 4);
Jump = *g_RecompPos;
BranchLabel8(ArmBranch_GreaterThan, "continue");
BranchLabel8(ArmBranch_GreaterThan, "Continue");
}
else if (m_Section->m_Cont.FallThrough)
{
Jump = *g_RecompPos;
BranchLabel8(ArmBranch_LessThan, "continue");
BranchLabel8(ArmBranch_LessThan, "Continue");
BranchLabel20(ArmBranch_GreaterThan, m_Section->m_Jump.BranchLabel.c_str());
m_Section->m_Jump.LinkLocation = (uint32_t *)(*g_RecompPos - 4);
}
@ -1829,7 +1830,8 @@ void CArmRecompilerOps::COP1_BCT_Compare()
}
}
/************************* OpCode functions *************************/
// Opcode functions
void CArmRecompilerOps::J()
{
if (m_NextInstruction == NORMAL)
@ -2335,8 +2337,8 @@ void CArmRecompilerOps::LW(bool ResultSigned, bool bRecordLLBit)
if (g_System->bFastSP() && m_Opcode.rt == 29)
{
g_Notify->BreakPoint(__FILE__, __LINE__);
/*ResetX86Protection();
ResetMemoryStack();*/
//ResetX86Protection();
//ResetMemoryStack();
}
}
@ -3671,7 +3673,7 @@ void CArmRecompilerOps::SPECIAL_SLT()
MoveConstToArmReg(useRdReg ? GetMipsRegMapLo(m_Opcode.rd) : UnknownArmReg, (uint16_t)0);
CPU_Message("");
CPU_Message(" Continue:");
CPU_Message(" continue:");
SetJump8(JumpContinue, *g_RecompPos);
if (!useRdReg)
{
@ -3754,7 +3756,7 @@ void CArmRecompilerOps::SPECIAL_SLT()
MoveConstToArmReg(useRdReg ? GetMipsRegMapLo(m_Opcode.rd) : TempRegRt, (uint16_t)1);
MoveConstToArmReg(useRdReg ? GetMipsRegMapLo(m_Opcode.rd) : TempRegRt, (uint16_t)0);
CPU_Message("");
CPU_Message(" Continue:");
CPU_Message(" continue:");
SetJump8(JumpContinue, *g_RecompPos);
if (!useRdReg)
{
@ -3923,7 +3925,8 @@ void CArmRecompilerOps::SPECIAL_DSRA32()
}
}
/************************** COP0 functions **************************/
// COP0 functions
void CArmRecompilerOps::COP0_MF()
{
if (m_Opcode.rt != 0) { UnMap_GPR(m_Opcode.rt, true); }
@ -3959,12 +3962,12 @@ void CArmRecompilerOps::COP0_MT()
case 5: // PageMask
case 10: // Entry Hi
case 12: // Status
case 13: //cause
case 13: // Cause
case 14: // EPC
case 16: // Config
case 18: // WatchLo
case 19: // WatchHi
case 28: //Tag lo
case 28: // Tag Lo
case 29: // Tag Hi
case 30: // ErrEPC
if (g_Settings->LoadBool(Game_32Bit))
@ -4080,7 +4083,8 @@ void CArmRecompilerOps::COP0_CO_ERET()
m_NextInstruction = END_BLOCK;
}
/************************** COP1 functions **************************/
// COP1 functions
void CArmRecompilerOps::COP1_MF()
{
CompileCop1Test();
@ -5053,14 +5057,14 @@ void CArmRecompilerOps::SyncRegState(const CRegInfo & SyncTo)
else if (MemStackReg == x86_Unknown)
{
UnMap_X86reg(TargetStackReg);
CPU_Message(" regcache: allocate %s as Memory Stack", x86_Name(TargetStackReg));
CPU_Message(" regcache: allocate %s as memory stack", x86_Name(TargetStackReg));
m_RegWorkingSet.SetX86Mapped(TargetStackReg, CRegInfo::Stack_Mapped);
MoveVariableToX86reg(&g_Recompiler->MemoryStackPos(), "MemoryStack", TargetStackReg);
}
else
{
UnMap_X86reg(TargetStackReg);
CPU_Message(" regcache: change allocation of Memory Stack from %s to %s", x86_Name(MemStackReg), x86_Name(TargetStackReg));
CPU_Message(" regcache: change allocation of memory stack from %s to %s", x86_Name(MemStackReg), x86_Name(TargetStackReg));
m_RegWorkingSet.SetX86Mapped(TargetStackReg, CRegInfo::Stack_Mapped);
m_RegWorkingSet.SetX86Mapped(MemStackReg, CRegInfo::NotMapped);
MoveX86RegToX86Reg(MemStackReg, TargetStackReg);
@ -5103,12 +5107,12 @@ void CArmRecompilerOps::SyncRegState(const CRegInfo & SyncTo)
case CRegInfo::STATE_CONST_32_SIGN:
if (GetMipsRegLo(i) != SyncTo.GetMipsRegLo(i))
{
CPU_Message("Value of const is different Reg %d (%s) Value: 0x%08X to 0x%08X", i, CRegName::GPR[i], GetMipsRegLo(i), SyncTo.GetMipsRegLo(i));
CPU_Message("Value of constant is different register %d (%s) Value: 0x%08X to 0x%08X", i, CRegName::GPR[i], GetMipsRegLo(i), SyncTo.GetMipsRegLo(i));
g_Notify->BreakPoint(__FILE__, __LINE__);
}
continue;
default:
CPU_Message("Unhandled Reg state %d\nin SyncRegState", GetMipsRegState(i));
CPU_Message("Unhandled register state %d\nin SyncRegState", GetMipsRegState(i));
g_Notify->BreakPoint(__FILE__, __LINE__);
}
}
@ -5258,7 +5262,7 @@ void CArmRecompilerOps::SyncRegState(const CRegInfo & SyncTo)
case CRegInfo::STATE_CONST_32_SIGN:
if (!g_System->b32BitCore() && GetMipsRegLo_S(i) < 0)
{
CPU_Message("Sign Problems in SyncRegState\nSTATE_MAPPED_32_ZERO");
CPU_Message("Sign problems in SyncRegState\nSTATE_MAPPED_32_ZERO");
CPU_Message("%s: %X", CRegName::GPR[i], GetMipsRegLo_S(i));
g_Notify->BreakPoint(__FILE__, __LINE__);
}
@ -5503,7 +5507,7 @@ bool CArmRecompilerOps::InheritParentInfo()
return true;
}
//Multiple Parents
// Multiple parents
BLOCK_PARENT_LIST ParentList;
CCodeSection::SECTION_LIST::iterator iter;
for (iter = m_Section->m_ParentSection.begin(); iter != m_Section->m_ParentSection.end(); iter++)
@ -5576,7 +5580,7 @@ bool CArmRecompilerOps::InheritParentInfo()
FirstParent = 0;
}
//Link First Parent to start
// Link first parent to start
CCodeSection * Parent = ParentList[FirstParent].Parent;
CJumpInfo * JumpInfo = ParentList[FirstParent].JumpInfo;
@ -5610,7 +5614,7 @@ bool CArmRecompilerOps::InheritParentInfo()
}
JumpInfo->FallThrough = false;
//determine loop reg usage
// Determine loop register usage
if (m_Section->m_InLoop && ParentList.size() > 1)
{
if (!SetupRegisterForLoop(m_Section->m_BlockInfo, m_Section->m_RegEnter)) { return false; }
@ -5632,7 +5636,7 @@ bool CArmRecompilerOps::InheritParentInfo()
if (m_RegWorkingSet.GetRoundingModel() != RegSet->GetRoundingModel()) { m_RegWorkingSet.SetRoundingModel(CRegInfo::RoundUnknown); }
//Find Parent MapRegState
// Find parent MapRegState
/*MemoryStackPos = x86_Unknown;
for (i2 = 0; i2 < sizeof(x86_Registers) / sizeof(x86_Registers[0]); i2++)
{
@ -5644,7 +5648,7 @@ bool CArmRecompilerOps::InheritParentInfo()
}
if (MemoryStackPos == x86_Unknown)
{
// if the memory stack position is not mapped then unmap it
// If the memory stack position is not mapped then unmap it
x86Reg MemStackReg = Get_MemoryStack();
if (MemStackReg != x86_Unknown)
{
@ -5686,7 +5690,7 @@ bool CArmRecompilerOps::InheritParentInfo()
}
break;
default:
CPU_Message("Unknown CPU State(%d) in InheritParentInfo", GetMipsRegState(i2));
CPU_Message("Unknown CPU state(%d) in InheritParentInfo", GetMipsRegState(i2));
g_Notify->BreakPoint(__FILE__, __LINE__);
}
}
@ -5729,7 +5733,7 @@ bool CArmRecompilerOps::InheritParentInfo()
}
break;
default:
CPU_Message("Unknown CPU State(%d) in InheritParentInfo", RegSet->GetMipsRegState(i2));
CPU_Message("Unknown CPU state(%d) in InheritParentInfo", RegSet->GetMipsRegState(i2));
g_Notify->BreakPoint(__FILE__, __LINE__);
break;
}
@ -5828,7 +5832,7 @@ bool CArmRecompilerOps::InheritParentInfo()
}
break;
default:
WriteTrace(TraceRecompiler, TraceError, "Unhandled Reg state %d\nin InheritParentInfo", GetMipsRegState(i2));
WriteTrace(TraceRecompiler, TraceError, "Unhandled register state %d\nin InheritParentInfo", GetMipsRegState(i2));
g_Notify->BreakPoint(__FILE__, __LINE__);
}
}
@ -5966,7 +5970,7 @@ void CArmRecompilerOps::UpdateSyncCPU(CRegInfo & RegSet, uint32_t Cycles)
{
return;
}
WriteArmComment("Updating Sync CPU");
WriteArmComment("Updating sync CPU");
RegSet.BeforeCallDirect();
MoveConstToArmReg(Arm_R2, Cycles);
MoveConstToArmReg(Arm_R1, (uint32_t)g_SyncSystem, "g_SyncSystem");
@ -5980,7 +5984,7 @@ void CArmRecompilerOps::UpdateCounters(CRegInfo & RegSet, bool CheckTimer, bool
if (RegSet.GetBlockCycleCount() != 0)
{
UpdateSyncCPU(RegSet, RegSet.GetBlockCycleCount());
WriteArmComment("Update Counter");
WriteArmComment("Update counter");
ArmReg NextTimerReg = RegSet.Map_Variable(CArmRegInfo::VARIABLE_NEXT_TIMER);
ArmReg TempReg = RegSet.Map_TempReg(Arm_Any, -1, false);
@ -6133,7 +6137,7 @@ void CArmRecompilerOps::SW_Const(uint32_t Value, uint32_t VAddr)
default:
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("%s\ntrying to store %08X in %08X?", __FUNCTION__, Value, VAddr).c_str());
g_Notify->DisplayError(stdstr_f("%s\nTrying to store %08X in %08X?", __FUNCTION__, Value, VAddr).c_str());
}
}
break;
@ -6169,10 +6173,10 @@ void CArmRecompilerOps::SW_Const(uint32_t Value, uint32_t VAddr)
case 0x0404001C: MoveConstToVariable(0, &g_Reg->SP_SEMAPHORE_REG, "SP_SEMAPHORE_REG"); break;
case 0x04080000: MoveConstToVariable(Value & 0xFFC, &g_Reg->SP_PC_REG, "SP_PC_REG"); break;
default:
CPU_Message(" Should be moving %X in to %08X ?!?", Value, VAddr);
CPU_Message(" should be moving %X in to %08X ?", Value, VAddr);
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("%s\ntrying to store %08X in %08X?", __FUNCTION__, Value, VAddr).c_str());
g_Notify->DisplayError(stdstr_f("%s\nTrying to store %08X in %08X?", __FUNCTION__, Value, VAddr).c_str());
}
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
@ -6191,7 +6195,7 @@ void CArmRecompilerOps::SW_Const(uint32_t Value, uint32_t VAddr)
default:
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("%s\ntrying to store %08X in %08X?", __FUNCTION__, Value, VAddr).c_str());
g_Notify->DisplayError(stdstr_f("%s\nTrying to store %08X in %08X?", __FUNCTION__, Value, VAddr).c_str());
}
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
@ -6303,10 +6307,10 @@ void CArmRecompilerOps::SW_Const(uint32_t Value, uint32_t VAddr)
}
break;
default:
CPU_Message(" Should be moving %X in to %08X ?!?", Value, VAddr);
CPU_Message(" should be moving %X in to %08X ?", Value, VAddr);
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("%s\ntrying to store %08X in %08X?", __FUNCTION__, Value, VAddr).c_str());
g_Notify->DisplayError(stdstr_f("%s\nTrying to store %08X in %08X?", __FUNCTION__, Value, VAddr).c_str());
}
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
@ -6324,7 +6328,7 @@ void CArmRecompilerOps::SW_Const(uint32_t Value, uint32_t VAddr)
CompareArmRegToArmReg(TempReg, TempValueReg);
uint8_t * Jump = *g_RecompPos;
BranchLabel8(ArmBranch_Equal, "continue");
BranchLabel8(ArmBranch_Equal, "Continue");
m_RegWorkingSet.BeforeCallDirect();
ArmReg VariableReg = TempValueReg != Arm_R1 ? Arm_R1 : Arm_R2;
@ -6349,7 +6353,7 @@ void CArmRecompilerOps::SW_Const(uint32_t Value, uint32_t VAddr)
CompareArmRegToArmReg(TempReg, TempValueReg);
uint8_t * Jump = *g_RecompPos;
BranchLabel8(ArmBranch_Equal, "continue");
BranchLabel8(ArmBranch_Equal, "Continue");
MoveArmRegToVariable(TempValueReg, &g_Reg->VI_WIDTH_REG, "VI_WIDTH_REG");
m_RegWorkingSet.BeforeCallDirect();
@ -6357,7 +6361,7 @@ void CArmRecompilerOps::SW_Const(uint32_t Value, uint32_t VAddr)
m_RegWorkingSet.AfterCallDirect();
FlushPopArmReg();
CPU_Message("");
CPU_Message(" Continue:");
CPU_Message(" continue:");
SetJump8(Jump, *g_RecompPos);
}
break;
@ -6379,15 +6383,15 @@ void CArmRecompilerOps::SW_Const(uint32_t Value, uint32_t VAddr)
case 0x04400030: MoveConstToVariable(Value, &g_Reg->VI_X_SCALE_REG, "VI_X_SCALE_REG"); break;
case 0x04400034: MoveConstToVariable(Value, &g_Reg->VI_Y_SCALE_REG, "VI_Y_SCALE_REG"); break;
default:
CPU_Message(" Should be moving %X in to %08X ?!?", Value, VAddr);
CPU_Message(" should be moving %X in to %08X ?", Value, VAddr);
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("%s\ntrying to store %08X in %08X?", __FUNCTION__, Value, VAddr).c_str());
g_Notify->DisplayError(stdstr_f("%s\nTrying to store %08X in %08X?", __FUNCTION__, Value, VAddr).c_str());
}
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
break;
case 0x04500000: /* AI registers */
case 0x04500000: // AI registers
switch (PAddr)
{
case 0x04500000: MoveConstToVariable(Value, &g_Reg->AI_DRAM_ADDR_REG, "AI_DRAM_ADDR_REG"); break;
@ -6408,7 +6412,7 @@ void CArmRecompilerOps::SW_Const(uint32_t Value, uint32_t VAddr)
break;
case 0x04500008: MoveConstToVariable((Value & 1), &g_Reg->AI_CONTROL_REG, "AI_CONTROL_REG"); break;
case 0x0450000C:
/* Clear Interrupt */;
// Clear interrupt
AndConstToVariable(&g_Reg->MI_INTR_REG, "MI_INTR_REG", (uint32_t)~MI_INTR_AI);
AndConstToVariable(&g_Reg->m_AudioIntrReg, "m_AudioIntrReg", (uint32_t)~MI_INTR_AI);
m_RegWorkingSet.BeforeCallDirect();
@ -6426,10 +6430,10 @@ void CArmRecompilerOps::SW_Const(uint32_t Value, uint32_t VAddr)
break;
case 0x04500014: MoveConstToVariable(Value, &g_Reg->AI_BITRATE_REG, "AI_BITRATE_REG"); break;
default:
CPU_Message(" Should be moving %X in to %08X ?!?", Value, VAddr);
CPU_Message(" should be moving %X in to %08X ?", Value, VAddr);
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("%s\ntrying to store %08X in %08X?", __FUNCTION__, Value, VAddr).c_str());
g_Notify->DisplayError(stdstr_f("%s\nTrying to store %08X in %08X?", __FUNCTION__, Value, VAddr).c_str());
}
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
@ -6475,10 +6479,10 @@ void CArmRecompilerOps::SW_Const(uint32_t Value, uint32_t VAddr)
case 0x0460002C: MoveConstToVariable((Value & 0xFF), &g_Reg->PI_BSD_DOM2_PGS_REG, "PI_BSD_DOM2_PGS_REG"); break;
case 0x04600030: MoveConstToVariable((Value & 0xFF), &g_Reg->PI_BSD_DOM2_RLS_REG, "PI_BSD_DOM2_RLS_REG"); break;
default:
CPU_Message(" Should be moving %X in to %08X ?!?", Value, VAddr);
CPU_Message(" should be moving %X in to %08X ?", Value, VAddr);
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("%s\ntrying to store %08X in %08X?", __FUNCTION__, Value, VAddr).c_str());
g_Notify->DisplayError(stdstr_f("%s\nTrying to store %08X in %08X?", __FUNCTION__, Value, VAddr).c_str());
}
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
@ -6491,10 +6495,10 @@ void CArmRecompilerOps::SW_Const(uint32_t Value, uint32_t VAddr)
case 0x04700008: MoveConstToVariable(Value, &g_Reg->RI_CURRENT_LOAD_REG, "RI_CURRENT_LOAD_REG"); break;
case 0x0470000C: MoveConstToVariable(Value, &g_Reg->RI_SELECT_REG, "RI_SELECT_REG"); break;
default:
CPU_Message(" Should be moving %X in to %08X ?!?", Value, VAddr);
CPU_Message(" should be moving %X in to %08X ?", Value, VAddr);
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("%s\ntrying to store %08X in %08X?", __FUNCTION__, Value, VAddr).c_str());
g_Notify->DisplayError(stdstr_f("%s\nTrying to store %08X in %08X?", __FUNCTION__, Value, VAddr).c_str());
}
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
@ -6532,16 +6536,16 @@ void CArmRecompilerOps::SW_Const(uint32_t Value, uint32_t VAddr)
m_RegWorkingSet.AfterCallDirect();
break;
default:
CPU_Message(" Should be moving %X in to %08X ?!?", Value, VAddr);
CPU_Message(" should be moving %X in to %08X ?", Value, VAddr);
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("%s\ntrying to store %08X in %08X?", __FUNCTION__, Value, VAddr).c_str());
g_Notify->DisplayError(stdstr_f("%s\nTrying to store %08X in %08X?", __FUNCTION__, Value, VAddr).c_str());
}
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
break;
case 0x05000000:
//64DD Registers
// 64DD registers
if (g_Settings->LoadBool(Setting_EnableDisk))
{
switch (PAddr)
@ -6552,10 +6556,10 @@ void CArmRecompilerOps::SW_Const(uint32_t Value, uint32_t VAddr)
m_RegWorkingSet.AfterCallDirect();
break;
default:
CPU_Message(" Should be moving %X in to %08X ?!?", Value, VAddr);
CPU_Message(" should be moving %X in to %08X ?", Value, VAddr);
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("%s\ntrying to store %08X in %08X?", __FUNCTION__, Value, VAddr).c_str());
g_Notify->DisplayError(stdstr_f("%s\nTrying to store %08X in %08X?", __FUNCTION__, Value, VAddr).c_str());
}
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
@ -6574,10 +6578,10 @@ void CArmRecompilerOps::SW_Const(uint32_t Value, uint32_t VAddr)
m_RegWorkingSet.AfterCallDirect();
break;
default:
CPU_Message(" Should be moving %X in to %08X ?!?", Value, VAddr);
CPU_Message(" should be moving %X in to %08X ?", Value, VAddr);
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("%s\ntrying to store %08X in %08X?", __FUNCTION__, Value, VAddr).c_str());
g_Notify->DisplayError(stdstr_f("%s\nTrying to store %08X in %08X?", __FUNCTION__, Value, VAddr).c_str());
}
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
@ -6641,10 +6645,10 @@ void CArmRecompilerOps::SW_Register(ArmReg Reg, uint32_t VAddr)
case 0x03F8000C: break;
case 0x03F80014: break;
default:
CPU_Message(" Should be moving %s in to %08X ?!?", ArmRegName(Reg), VAddr);
CPU_Message(" should be moving %s in to %08X ?", ArmRegName(Reg), VAddr);
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("%s\ntrying to store in %08X?", __FUNCTION__, VAddr).c_str());
g_Notify->DisplayError(stdstr_f("%s\nTrying to store in %08X?", __FUNCTION__, VAddr).c_str());
}
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
@ -6689,10 +6693,10 @@ void CArmRecompilerOps::SW_Register(ArmReg Reg, uint32_t VAddr)
}
else
{
CPU_Message(" Should be moving %s in to %08X ?!?", ArmRegName(Reg), VAddr);
CPU_Message(" should be moving %s in to %08X ?", ArmRegName(Reg), VAddr);
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("%s\ntrying to store in %08X?", __FUNCTION__, VAddr).c_str());
g_Notify->DisplayError(stdstr_f("%s\nTrying to store in %08X?", __FUNCTION__, VAddr).c_str());
}
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
@ -6732,10 +6736,10 @@ void CArmRecompilerOps::SW_Register(ArmReg Reg, uint32_t VAddr)
m_RegWorkingSet.AfterCallDirect();
break;
default:
CPU_Message(" Should be moving %s in to %08X ?!?", ArmRegName(Reg), VAddr);
CPU_Message(" should be moving %s in to %08X ?", ArmRegName(Reg), VAddr);
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("%s\ntrying to store in %08X?", __FUNCTION__, VAddr).c_str());
g_Notify->DisplayError(stdstr_f("%s\nTrying to store in %08X?", __FUNCTION__, VAddr).c_str());
}
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
@ -6750,7 +6754,7 @@ void CArmRecompilerOps::SW_Register(ArmReg Reg, uint32_t VAddr)
CompareArmRegToArmReg(TempReg, Reg);
uint8_t * Jump = *g_RecompPos;
BranchLabel8(ArmBranch_Equal, "continue");
BranchLabel8(ArmBranch_Equal, "Continue");
MoveArmRegToVariable(Reg, &g_Reg->VI_STATUS_REG, "VI_STATUS_REG");
m_RegWorkingSet.BeforeCallDirect();
@ -6758,7 +6762,7 @@ void CArmRecompilerOps::SW_Register(ArmReg Reg, uint32_t VAddr)
m_RegWorkingSet.AfterCallDirect();
FlushPopArmReg();
CPU_Message("");
CPU_Message(" Continue:");
CPU_Message(" continue:");
SetJump8(Jump, *g_RecompPos);
}
break;
@ -6782,7 +6786,7 @@ void CArmRecompilerOps::SW_Register(ArmReg Reg, uint32_t VAddr)
m_RegWorkingSet.AfterCallDirect();
FlushPopArmReg();
CPU_Message("");
CPU_Message(" Continue:");
CPU_Message(" continue:");
SetJump8(Jump, *g_RecompPos);
}
break;
@ -6804,14 +6808,14 @@ void CArmRecompilerOps::SW_Register(ArmReg Reg, uint32_t VAddr)
case 0x04400030: MoveArmRegToVariable(Reg, &g_Reg->VI_X_SCALE_REG, "VI_X_SCALE_REG"); break;
case 0x04400034: MoveArmRegToVariable(Reg, &g_Reg->VI_Y_SCALE_REG, "VI_Y_SCALE_REG"); break;
default:
CPU_Message(" Should be moving %s in to %08X ?!?", ArmRegName(Reg), VAddr);
CPU_Message(" should be moving %s in to %08X ?", ArmRegName(Reg), VAddr);
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("%s\ntrying to store in %08X?", __FUNCTION__, VAddr).c_str());
g_Notify->DisplayError(stdstr_f("%s\nTrying to store in %08X?", __FUNCTION__, VAddr).c_str());
}
}
break;
case 0x04500000: /* AI registers */
case 0x04500000: // AI registers
switch (PAddr) {
case 0x04500000: MoveArmRegToVariable(Reg, &g_Reg->AI_DRAM_ADDR_REG, "AI_DRAM_ADDR_REG"); break;
case 0x04500004:
@ -6835,7 +6839,7 @@ void CArmRecompilerOps::SW_Register(ArmReg Reg, uint32_t VAddr)
MoveArmRegToVariable(Reg, &g_Reg->AI_CONTROL_REG, "AI_CONTROL_REG");
AndConstToVariable(&g_Reg->AI_CONTROL_REG, "AI_CONTROL_REG", 1);
case 0x0450000C:
/* Clear Interrupt */;
// Clear interrupt
AndConstToVariable(&g_Reg->MI_INTR_REG, "MI_INTR_REG", (uint32_t)~MI_INTR_AI);
AndConstToVariable(&g_Reg->m_AudioIntrReg, "m_AudioIntrReg", (uint32_t)~MI_INTR_AI);
m_RegWorkingSet.BeforeCallDirect();
@ -6859,7 +6863,7 @@ void CArmRecompilerOps::SW_Register(ArmReg Reg, uint32_t VAddr)
MoveArmRegToVariable(Reg, PAddr + g_MMU->Rdram(), stdstr_f("RDRAM + %X", PAddr).c_str());
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("%s\ntrying to store in %08X?", __FUNCTION__, VAddr).c_str());
g_Notify->DisplayError(stdstr_f("%s\nTrying to store in %08X?", __FUNCTION__, VAddr).c_str());
}
}
break;
@ -6896,7 +6900,7 @@ void CArmRecompilerOps::SW_Register(ArmReg Reg, uint32_t VAddr)
case 0x04600010:
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("%s\ntrying to store in %08X?", __FUNCTION__, VAddr).c_str());
g_Notify->DisplayError(stdstr_f("%s\nTrying to store in %08X?", __FUNCTION__, VAddr).c_str());
}
AndConstToVariable(&g_Reg->MI_INTR_REG, "MI_INTR_REG", (uint32_t)~MI_INTR_PI);
m_RegWorkingSet.BeforeCallDirect();
@ -6937,10 +6941,10 @@ void CArmRecompilerOps::SW_Register(ArmReg Reg, uint32_t VAddr)
AndConstToVariable(&g_Reg->PI_BSD_DOM2_RLS_REG, "PI_BSD_DOM2_RLS_REG", 0xFF);
break;
default:
CPU_Message(" Should be moving %s in to %08X ?!?", ArmRegName(Reg), VAddr);
CPU_Message(" should be moving %s in to %08X ?", ArmRegName(Reg), VAddr);
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("%s\ntrying to store in %08X?", __FUNCTION__, VAddr).c_str());
g_Notify->DisplayError(stdstr_f("%s\nTrying to store in %08X?", __FUNCTION__, VAddr).c_str());
}
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
@ -6953,10 +6957,10 @@ void CArmRecompilerOps::SW_Register(ArmReg Reg, uint32_t VAddr)
case 0x0470000C: MoveArmRegToVariable(Reg, &g_Reg->RI_SELECT_REG, "RI_SELECT_REG"); break;
case 0x04700010: MoveArmRegToVariable(Reg, &g_Reg->RI_REFRESH_REG, "RI_REFRESH_REG"); break;
default:
CPU_Message(" Should be moving %s in to %08X ?!?", ArmRegName(Reg), VAddr);
CPU_Message(" should be moving %s in to %08X ?", ArmRegName(Reg), VAddr);
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("%s\ntrying to store in %08X?", __FUNCTION__, VAddr).c_str());
g_Notify->DisplayError(stdstr_f("%s\nTrying to store in %08X?", __FUNCTION__, VAddr).c_str());
}
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
@ -6988,16 +6992,16 @@ void CArmRecompilerOps::SW_Register(ArmReg Reg, uint32_t VAddr)
m_RegWorkingSet.AfterCallDirect();
break;
default:
CPU_Message(" Should be moving %s in to %08X ?!?", ArmRegName(Reg), VAddr);
CPU_Message(" should be moving %s in to %08X ?", ArmRegName(Reg), VAddr);
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("%s\ntrying to store in %08X?", __FUNCTION__, VAddr).c_str());
g_Notify->DisplayError(stdstr_f("%s\nTrying to store in %08X?", __FUNCTION__, VAddr).c_str());
}
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
break;
case 0x05000000:
//64DD Registers
// 64DD registers
if (g_Settings->LoadBool(Setting_EnableDisk))
{
switch (PAddr)
@ -7040,10 +7044,10 @@ void CArmRecompilerOps::SW_Register(ArmReg Reg, uint32_t VAddr)
MoveArmRegToVariable(Reg, PAddr + g_MMU->Rdram(), stdstr_f("RDRAM + %X", PAddr).c_str());
break;
default:
CPU_Message(" Should be moving %s in to %08X ?!?", ArmRegName(Reg), VAddr);
CPU_Message(" should be moving %s in to %08X ?", ArmRegName(Reg), VAddr);
if (ShowUnhandledMemory())
{
g_Notify->DisplayError(stdstr_f("%s\ntrying to store in %08X?", __FUNCTION__, VAddr).c_str());
g_Notify->DisplayError(stdstr_f("%s\nTrying to store in %08X?", __FUNCTION__, VAddr).c_str());
}
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
@ -7084,7 +7088,7 @@ void CArmRecompilerOps::LB_KnownAddress(ArmReg Reg, uint32_t VAddr, bool SignExt
SignExtendByte(Reg);
break;
default:
CPU_Message(" Should be loading from %08X ?!?", VAddr);
CPU_Message(" should be loading from %08X ?", VAddr);
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
}
@ -7157,7 +7161,7 @@ void CArmRecompilerOps::LW_KnownAddress(ArmReg Reg, uint32_t VAddr)
{
g_Notify->DisplayError(stdstr_f("%s\nFailed to translate address: %08X", __FUNCTION__, VAddr).c_str());
}
CPU_Message(" Should be loading from %08X ?!?", VAddr);
CPU_Message(" should be loading from %08X ?", VAddr);
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
break;
@ -7180,7 +7184,7 @@ void CArmRecompilerOps::LW_KnownAddress(ArmReg Reg, uint32_t VAddr)
default:
MoveConstToArmReg(Reg, (uint32_t)0);
if (ShowUnhandledMemory()) { g_Notify->DisplayError(stdstr_f("%s\nFailed to translate address: %08X", __FUNCTION__, VAddr).c_str()); }
CPU_Message(" Should be loading from %08X ?!?", VAddr);
CPU_Message(" should be loading from %08X ?", VAddr);
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
break;
@ -7200,11 +7204,11 @@ void CArmRecompilerOps::LW_KnownAddress(ArmReg Reg, uint32_t VAddr)
default:
MoveConstToArmReg(Reg, (uint32_t)0);
if (ShowUnhandledMemory()) { g_Notify->DisplayError(stdstr_f("%s\nFailed to translate address: %08X", __FUNCTION__, VAddr).c_str()); }
CPU_Message(" Should be loading from %08X ?!?", VAddr);
CPU_Message(" should be loading from %08X ?", VAddr);
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
break;
case 0x04500000: /* AI registers */
case 0x04500000: // AI registers
switch (PAddr)
{
case 0x04500004:
@ -7257,7 +7261,7 @@ void CArmRecompilerOps::LW_KnownAddress(ArmReg Reg, uint32_t VAddr)
default:
MoveConstToArmReg(Reg, (uint32_t)0);
if (ShowUnhandledMemory()) { g_Notify->DisplayError(stdstr_f("%s\nFailed to translate address: %08X", __FUNCTION__, VAddr).c_str()); }
CPU_Message(" Should be loading from %08X ?!?", VAddr);
CPU_Message(" should be loading from %08X ?", VAddr);
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
break;
@ -7283,7 +7287,7 @@ void CArmRecompilerOps::LW_KnownAddress(ArmReg Reg, uint32_t VAddr)
{
g_Notify->DisplayError(stdstr_f("%s\nFailed to translate address: %08X", __FUNCTION__, VAddr).c_str());
}
CPU_Message(" Should be loading from %08X ?!?", VAddr);
CPU_Message(" should be loading from %08X ?", VAddr);
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
break;
@ -7298,7 +7302,7 @@ void CArmRecompilerOps::LW_KnownAddress(ArmReg Reg, uint32_t VAddr)
{
g_Notify->DisplayError(stdstr_f("%s\nFailed to translate address: %08X", __FUNCTION__, VAddr).c_str());
}
CPU_Message(" Should be loading from %08X ?!?", VAddr);
CPU_Message(" should be loading from %08X ?", VAddr);
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
break;
@ -7313,12 +7317,12 @@ void CArmRecompilerOps::LW_KnownAddress(ArmReg Reg, uint32_t VAddr)
{
g_Notify->DisplayError(stdstr_f("%s\nFailed to translate address: %08X", __FUNCTION__, VAddr).c_str());
}
CPU_Message(" Should be loading from %08X ?!?", VAddr);
CPU_Message(" should be loading from %08X ?", VAddr);
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
break;
case 0x05000000:
//64DD Registers
// 64DD registers
if (g_Settings->LoadBool(Setting_EnableDisk))
{
switch (PAddr)
@ -7353,7 +7357,7 @@ void CArmRecompilerOps::LW_KnownAddress(ArmReg Reg, uint32_t VAddr)
{
g_Notify->DisplayError(stdstr_f("%s\nFailed to translate address: %08X", __FUNCTION__, VAddr).c_str());
}
CPU_Message(" Should be loading from %08X ?!?", VAddr);
CPU_Message(" should be loading from %08X ?", VAddr);
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
}
@ -7375,11 +7379,11 @@ void CArmRecompilerOps::LW_KnownAddress(ArmReg Reg, uint32_t VAddr)
if ((PAddr & 0xF0000000) == 0x10000000 && (PAddr - 0x10000000) < g_Rom->GetRomSize())
{
uint32_t RomOffset = PAddr - 0x10000000;
MoveVariableToArmReg(RomOffset + g_Rom->GetRomAddress(), stdstr_f("ROM + %X", RomOffset).c_str(), Reg); // read from rom
MoveVariableToArmReg(RomOffset + g_Rom->GetRomAddress(), stdstr_f("ROM + %X", RomOffset).c_str(), Reg); // Read from ROM
}
else
{
CPU_Message(" Should be loading from %08X ?!?", VAddr);
CPU_Message(" should be loading from %08X ?", VAddr);
if (HaveDebugger()) { g_Notify->BreakPoint(__FILE__, __LINE__); }
}
}

View File

@ -12,10 +12,10 @@ class CArmRecompilerOps :
public:
CArmRecompilerOps();
/*************************** Trap functions *************************/
// Trap functions
void Compile_TrapCompare(TRAP_COMPARE CompareType);
/************************** Branch functions ************************/
// Branch functions
void Compile_BranchCompare(BRANCH_COMPARE CompareType);
void Compile_Branch(BRANCH_COMPARE CompareType, BRANCH_TYPE BranchType, bool Link);
void Compile_BranchLikely(BRANCH_COMPARE CompareType, bool Link);
@ -28,7 +28,7 @@ public:
void COP1_BCF_Compare();
void COP1_BCT_Compare();
/************************* OpCode functions *************************/
// Opcode functions
void J ();
void JAL ();
void ADDI ();
@ -67,7 +67,7 @@ public:
void SDC1 ();
void SD ();
/********************** R4300i OpCodes: Special **********************/
// R4300i opcodes: Special
void SPECIAL_SLL ();
void SPECIAL_SRL ();
void SPECIAL_SRA ();
@ -113,18 +113,18 @@ public:
void SPECIAL_DSRL32 ();
void SPECIAL_DSRA32 ();
/************************** COP0 functions **************************/
// COP0 functions
void COP0_MF ();
void COP0_MT ();
/************************** COP0 CO functions ***********************/
// COP0 CO functions
void COP0_CO_TLBR ();
void COP0_CO_TLBWI ();
void COP0_CO_TLBWR ();
void COP0_CO_TLBP ();
void COP0_CO_ERET ();
/************************** COP1 functions **************************/
// COP1 functions
void COP1_MF ();
void COP1_DMF ();
void COP1_CF ();
@ -132,7 +132,7 @@ public:
void COP1_DMT ();
void COP1_CT ();
/************************** COP1: S functions ************************/
// COP1: S functions
void COP1_S_ADD ();
void COP1_S_SUB ();
void COP1_S_MUL ();
@ -154,7 +154,7 @@ public:
void COP1_S_CVT_L ();
void COP1_S_CMP ();
/************************** COP1: D functions ************************/
// COP1: D functions
void COP1_D_ADD ();
void COP1_D_SUB ();
void COP1_D_MUL ();
@ -176,15 +176,15 @@ public:
void COP1_D_CVT_L ();
void COP1_D_CMP ();
/************************** COP1: W functions ************************/
// COP1: W functions
void COP1_W_CVT_S ();
void COP1_W_CVT_D ();
/************************** COP1: L functions ************************/
// COP1: L functions
void COP1_L_CVT_S ();
void COP1_L_CVT_D ();
/************************** Other functions **************************/
// Other functions
void UnknownOpcode ();
private:
@ -220,7 +220,7 @@ private:
void CompileExecuteBP(void);
void CompileExecuteDelaySlotBP(void);
/********* Helper Functions *********/
// Helper functions
typedef CRegInfo::REG_STATE REG_STATE;
static inline REG_STATE GetMipsRegState(int32_t Reg) { return m_RegWorkingSet.GetMipsRegState(Reg); }

View File

@ -265,7 +265,7 @@ void CArmRegInfo::Map_GPR_32bit(int32_t MipsReg, bool SignValue, int32_t MipsReg
{
if (Is64Bit(MipsReg))
{
CPU_Message(" regcache: unallocate %s from high 32bit of %s", ArmRegName(GetMipsRegMapHi(MipsReg)), CRegName::GPR_Hi[MipsReg]);
CPU_Message(" regcache: unallocate %s from high 32-bit of %s", ArmRegName(GetMipsRegMapHi(MipsReg)), CRegName::GPR_Hi[MipsReg]);
SetArmRegMapOrder(GetMipsRegMapHi(MipsReg), 0);
SetArmRegMapped(GetMipsRegMapHi(MipsReg), NotMapped);
SetArmRegProtected(GetMipsRegMapHi(MipsReg), false);
@ -327,7 +327,7 @@ void CArmRegInfo::Map_GPR_64bit(int32_t MipsReg, int32_t MipsRegToLoad)
if (MipsReg == 0)
{
if (HaveDebugger()) { g_Notify->DisplayError("Map_GPR_64bit\n\nWhy are you trying to map reg 0"); }
if (HaveDebugger()) { g_Notify->DisplayError("Map_GPR_64bit\n\nWhy are you trying to map register 0?"); }
g_Notify->BreakPoint(__FILE__, __LINE__);
return;
}
@ -466,7 +466,7 @@ void CArmRegInfo::UnMap_GPR(uint32_t MipsReg, bool WriteBackValue)
{
if (HaveDebugger())
{
g_Notify->DisplayError(stdstr_f("%s\n\nWhy are you trying to unmap reg 0", __FUNCTION__).c_str());
g_Notify->DisplayError(stdstr_f("%s\n\nWhy are you trying to unmap register 0?", __FUNCTION__).c_str());
}
return;
}
@ -502,7 +502,7 @@ void CArmRegInfo::WriteBack_GPR(uint32_t MipsReg, bool Unmapping)
{
if (HaveDebugger())
{
g_Notify->DisplayError(stdstr_f("%s\n\nWhy are you trying to unmap reg 0", __FUNCTION__).c_str());
g_Notify->DisplayError(stdstr_f("%s\n\nWhy are you trying to unmap register 0?", __FUNCTION__).c_str());
}
return;
}
@ -597,7 +597,7 @@ void CArmRegInfo::WriteBackRegisters()
g_Notify->BreakPoint(__FILE__, __LINE__);
break;
default:
CPU_Message("%s: Unknown State: %d reg %d (%s)", __FUNCTION__, GetMipsRegState(count), count, CRegName::GPR[count]);
CPU_Message("%s: Unknown state: %d reg %d (%s)", __FUNCTION__, GetMipsRegState(count), count, CRegName::GPR[count]);
g_Notify->BreakPoint(__FILE__, __LINE__);
}
}
@ -701,7 +701,7 @@ bool CArmRegInfo::UnMap_ArmReg(ArmReg Reg)
}
else if (GetArmRegMapped(Reg) == Temp_Mapped)
{
CPU_Message(" regcache: unallocate %s from temp storage", ArmRegName(Reg));
CPU_Message(" regcache: unallocate %s from temporary storage", ArmRegName(Reg));
SetArmRegMapped(Reg, NotMapped);
return true;
}
@ -901,11 +901,11 @@ CArmOps::ArmReg CArmRegInfo::Map_TempReg(ArmReg Reg, int32_t MipsReg, bool LoadH
}
if (MipsReg < 0)
{
CPU_Message(" regcache: allocate %s as temp storage", ArmRegName(Reg));
CPU_Message(" regcache: allocate %s as temporary storage", ArmRegName(Reg));
}
else
{
CPU_Message(" regcache: allocate %s as temp storage (%s)", ArmRegName(Reg), LoadHiWord ? CRegName::GPR_Hi[MipsReg] : CRegName::GPR_Lo[MipsReg]);
CPU_Message(" regcache: allocate %s as temporary storage (%s)", ArmRegName(Reg), LoadHiWord ? CRegName::GPR_Hi[MipsReg] : CRegName::GPR_Lo[MipsReg]);
if (GprReg == Arm_Unknown)
{
g_Notify->BreakPoint(__FILE__, __LINE__);

View File

@ -10,7 +10,7 @@ class CArmRegInfo :
private CSystemRegisters
{
public:
//enums
// Enums
enum REG_MAPPED
{
NotMapped = 0,

View File

@ -1,17 +1,14 @@
/****************************************************************************
* *
* Project64 - A Nintendo 64 emulator. *
* http://www.pj64-emu.com/ *
* Copyright (C) 2012 Project64. All rights reserved. *
* *
* License: *
* GNU/GPLv2 http://www.gnu.org/licenses/gpl-2.0.html *
* *
****************************************************************************/
/*
Project64 - A Nintendo 64 emulator
https://www.pj64-emu.com/
Copyright (C) 2012-2021 Project64. All rights reserved.
License:
GNU/GPLv2 http://www.gnu.org/licenses/gpl-2.0.html
*/
#define GLOBAL_FUNCTION(name) \
.align 2; \
.globl name; \
.global name; \
.hidden name; \
.type name, %function; \
name

View File

@ -26,7 +26,7 @@ m_RecompilerOps(nullptr),
m_Test(1)
{
#if defined(__arm__) || defined(_M_ARM)
// make sure function starts at odd address so that the system knows it is thumb mode
// Make sure function starts at an odd address so that the system knows it is in thumb mode
if (((uint32_t)m_CompiledLocation % 2) == 0)
{
m_CompiledLocation+=1;
@ -264,7 +264,7 @@ bool CCodeBlock::CreateBlockLinkage(CCodeSection * EnterSection)
{
CPU_Message("%s: End Block", __FUNCTION__);
CurrentSection->m_EndSection = true;
// find other sections that need compiling
// Find other sections that need compiling
break;
}
@ -745,11 +745,11 @@ bool CCodeBlock::AnalyzeInstruction(uint32_t PC, uint32_t & TargetPC, uint32_t &
bool CCodeBlock::Compile()
{
CPU_Message("====== Code Block ======");
CPU_Message("====== Code block ======");
CPU_Message("Native entry point: %X", CompiledLocation());
CPU_Message("Start of Block: %X", VAddrEnter());
CPU_Message("No of Sections: %d", NoOfSections());
CPU_Message("====== recompiled code ======");
CPU_Message("Start of block: %X", VAddrEnter());
CPU_Message("Number of sections: %d", NoOfSections());
CPU_Message("====== Recompiled code ======");
m_RecompilerOps->EnterCodeBlock();
if (g_System->bLinkBlocks())

View File

@ -46,10 +46,10 @@ private:
bool & EndBlock, bool & PermLoop);
uint32_t m_VAddrEnter;
uint32_t m_VAddrFirst; // the address of the first opcode in the block
uint32_t m_VAddrLast; // the address of the first opcode in the block
uint8_t* m_CompiledLocation; // What address is this compiled at
uint8_t* m_CompiledLocationEnd; // What address is this compiled at
uint32_t m_VAddrFirst; // The address of the first opcode in the block
uint32_t m_VAddrLast; // The address of the first opcode in the block
uint8_t* m_CompiledLocation; // What address is this compiled at?
uint8_t* m_CompiledLocationEnd; // What address is this compiled at?
typedef std::map<uint32_t, CCodeSection *> SectionMap;
typedef std::list<CCodeSection *> SectionList;

View File

@ -187,7 +187,7 @@ void CCodeSection::GenerateSectionLinkage()
{
g_Notify->BreakPoint(__FILE__, __LINE__);
#ifdef legacycode
//Handle Fall througth
// Handle fall-through
uint8_t * Jump = nullptr;
for (i = 0; i < 2; i ++)
{
@ -243,7 +243,7 @@ void CCodeSection::GenerateSectionLinkage()
// MoveConstToVariable(DELAY_SLOT,&m_NextInstruction,"m_NextInstruction");
PushImm32(stdstr_f("0x%08X",m_RecompilerOps->GetCurrentPC() + 4).c_str(),m_RecompilerOps->GetCurrentPC() + 4);
// check if there is an existing section
// Check if there is an existing section
MoveConstToX86reg((uint32_t)g_Recompiler,x86_ECX);
Call_Direct(AddressOf(&CRecompiler::CompileDelaySlot), "CRecompiler::CompileDelaySlot");
@ -253,7 +253,7 @@ void CCodeSection::GenerateSectionLinkage()
#endif
}
// Handle Perm Loop
// Handle permanent loop
if (m_RecompilerOps->GetCurrentPC() == m_Jump.TargetPC && (m_Cont.FallThrough == false))
{
if (!DelaySlotEffectsJump(m_RecompilerOps->GetCurrentPC()))
@ -826,7 +826,7 @@ bool CCodeSection::GenerateNativeCode(uint32_t Test)
break;
case JUMP:
case END_BLOCK:
// Do nothing, block will end
// Do nothing, the block will end
break;
default:
CPU_Message("m_RecompilerOps->GetNextStepType() = %d", m_RecompilerOps->GetNextStepType());
@ -874,7 +874,7 @@ void CCodeSection::AddParent(CCodeSection * Parent)
return;
}
// check to see if we already have the parent in the list
// Check to see if we already have the parent in the list
for (SECTION_LIST::iterator iter = m_ParentSection.begin(); iter != m_ParentSection.end(); iter++)
{
if (*iter == Parent)
@ -896,7 +896,7 @@ void CCodeSection::AddParent(CCodeSection * Parent)
}
else
{
g_Notify->DisplayError("How are these sections joined?????");
g_Notify->DisplayError("How are these sections joined?");
}
}
else
@ -1192,26 +1192,27 @@ void CCodeSection::DisplaySectionInformation()
if (g_System->bLinkBlocks())
{
CPU_Message("Jump Address: 0x%08X", m_Jump.JumpPC);
CPU_Message("Jump Target Address: 0x%08X", m_Jump.TargetPC);
CPU_Message("Jump address: 0x%08X", m_Jump.JumpPC);
CPU_Message("Jump target address: 0x%08X", m_Jump.TargetPC);
if (m_JumpSection != nullptr)
{
CPU_Message("Jump Section: %d", m_JumpSection->m_SectionID);
CPU_Message("Jump section: %d", m_JumpSection->m_SectionID);
}
else
{
CPU_Message("Jump Section: None");
CPU_Message("Jump section: None");
}
CPU_Message("Continue Address: 0x%08X", m_Cont.JumpPC);
CPU_Message("Continue Target Address: 0x%08X", m_Cont.TargetPC);
if (m_ContinueSection != nullptr) {
CPU_Message("Continue Section: %d", m_ContinueSection->m_SectionID);
CPU_Message("Continue address: 0x%08X", m_Cont.JumpPC);
CPU_Message("Continue target address: 0x%08X", m_Cont.TargetPC);
if (m_ContinueSection != nullptr)
{
CPU_Message("Continue section: %d", m_ContinueSection->m_SectionID);
}
else
{
CPU_Message("Continue Section: None");
CPU_Message("Continue section: None");
}
CPU_Message("In Loop: %s", m_InLoop ? "Yes" : "No");
CPU_Message("In loop: %s", m_InLoop ? "Yes" : "No");
}
CPU_Message("=======================");
}

View File

@ -27,7 +27,7 @@ public:
void AddParent(CCodeSection * Parent);
void SwitchParent(CCodeSection * OldParent, CCodeSection * NewParent);
/* Block Connection info */
// Block connection info
SECTION_LIST m_ParentSection;
CCodeBlock * const m_BlockInfo;
const uint32_t m_SectionID;
@ -35,8 +35,8 @@ public:
uint32_t m_EndPC;
CCodeSection * m_ContinueSection;
CCodeSection * m_JumpSection;
bool m_EndSection; // if this section does not link
bool m_LinkAllowed; // are other sections allowed to find block to link to it
bool m_EndSection; // If this section does not link, are other sections allowed to find block to link to it?
bool m_LinkAllowed;
uint32_t m_Test;
uint32_t m_Test2;
uint8_t * m_CompiledLocation;
@ -44,10 +44,10 @@ public:
bool m_DelaySlot;
CRecompilerOps * & m_RecompilerOps;
/* Register Info */
// Register info
CRegInfo m_RegEnter;
/* Jump Info */
// Jump info
CJumpInfo m_Jump;
CJumpInfo m_Cont;

View File

@ -23,7 +23,7 @@ struct CExitInfo
CRegInfo ExitRegSet;
EXIT_REASON reason;
STEP_TYPE NextInstruction;
uint32_t * JumpLoc; //32bit jump
uint32_t * JumpLoc; // 32-bit jump
};
typedef std::list<CExitInfo> EXIT_LIST;

View File

@ -16,7 +16,7 @@ CCompiledFunc::CCompiledFunc( const CCodeBlock & CodeBlock ) :
m_MemLocation[1] = CodeBlock.MemLocation(1);
#if defined(__arm__) || defined(_M_ARM)
// make sure function starts at odd address so that the system knows it is thumb mode
// Make sure function starts at an odd address so that the system knows it is in thumb mode
if ((((uint32_t)m_Function) % 2) == 0)
{
m_Function = (Func)(((uint32_t)m_Function) + 1);

View File

@ -8,7 +8,6 @@ public:
typedef void (*Func)();
//Get Private Information
const uint32_t EnterPC () const { return m_EnterPC; }
const uint32_t MinPC () const { return m_MinPC; }
const uint32_t MaxPC () const { return m_MaxPC; }

View File

@ -16,13 +16,13 @@ CFunctionMap::~CFunctionMap()
bool CFunctionMap::AllocateMemory()
{
WriteTrace(TraceRecompiler, TraceDebug, "start");
WriteTrace(TraceRecompiler, TraceDebug, "Start");
if (LookUpMode() == FuncFind_VirtualLookup && m_FunctionTable == nullptr)
{
m_FunctionTable = new PCCompiledFunc_TABLE[0x100000];
if (m_FunctionTable == nullptr)
{
WriteTrace(TraceRecompiler, TraceError, "failed to allocate function table");
WriteTrace(TraceRecompiler, TraceError, "Failed to allocate function table");
g_Notify->FatalError(MSG_MEM_ALLOC_ERROR);
return false;
}
@ -33,7 +33,7 @@ bool CFunctionMap::AllocateMemory()
m_JumpTable = new PCCompiledFunc[RdramSize() >> 2];
if (m_JumpTable == nullptr)
{
WriteTrace(TraceRecompiler, TraceError, "failed to allocate jump table");
WriteTrace(TraceRecompiler, TraceError, "Failed to allocate jump table");
g_Notify->FatalError(MSG_MEM_ALLOC_ERROR);
return false;
}
@ -66,7 +66,7 @@ void CFunctionMap::CleanBuffers()
void CFunctionMap::Reset(bool bAllocate)
{
WriteTrace(TraceRecompiler, TraceDebug, "start (bAllocate: %s)", bAllocate ? "true" : "false");
WriteTrace(TraceRecompiler, TraceDebug, "Start (bAllocate: %s)", bAllocate ? "true" : "false");
CleanBuffers();
if (bAllocate && (g_System->LookUpMode() == FuncFind_VirtualLookup || g_System->LookUpMode() == FuncFind_PhysicalLookup))
{

View File

@ -14,7 +14,7 @@ struct CJumpInfo
uint32_t * LinkLocation2;
bool FallThrough;
bool PermLoop;
bool DoneDelaySlot; //maybe deletable
bool DoneDelaySlot;
CRegInfo RegSet;
EXIT_REASON ExitReason;
};

View File

@ -235,7 +235,7 @@ bool LoopAnalysis::CheckLoopRegisterUsage(CCodeSection * Section)
g_Notify->BreakPoint(__FILE__, __LINE__);
#ifdef legacycode
if (m_Command.Hex == 0x00000001) { break; }
g_Notify->DisplayError("Unhandled R4300i OpCode in FillSectionInfo 5\n%s",
g_Notify->DisplayError("Unhandled R4300i opcode in FillSectionInfo 5\n%s",
R4300iOpcodeName(m_Command.Hex, m_PC));
#endif
m_NextInstruction = END_BLOCK;
@ -366,7 +366,7 @@ bool LoopAnalysis::CheckLoopRegisterUsage(CCodeSection * Section)
g_Notify->BreakPoint(__FILE__, __LINE__);
#ifdef legacycode
if (m_Command.Hex == 0x0407000D) { break; }
g_Notify->DisplayError("Unhandled R4300i OpCode in FillSectionInfo 4\n%s",
g_Notify->DisplayError("Unhandled R4300i opcode in FillSectionInfo 4\n%s",
R4300iOpcodeName(m_Command.Hex, m_PC));
m_NextInstruction = END_BLOCK;
m_PC -= 4;
@ -542,14 +542,14 @@ bool LoopAnalysis::CheckLoopRegisterUsage(CCodeSection * Section)
case R4300i_COP0_CO_TLBP: break;
case R4300i_COP0_CO_ERET: m_NextInstruction = END_BLOCK; break;
default:
g_Notify->DisplayError(stdstr_f("Unhandled R4300i OpCode in FillSectionInfo\n%s", R4300iOpcodeName(m_Command.Hex, m_PC)).c_str());
g_Notify->DisplayError(stdstr_f("Unhandled R4300i opcode in FillSectionInfo\n%s", R4300iOpcodeName(m_Command.Hex, m_PC)).c_str());
m_NextInstruction = END_BLOCK;
m_PC -= 4;
}
}
else
{
g_Notify->DisplayError(stdstr_f("Unhandled R4300i OpCode in FillSectionInfo 3\n%s", R4300iOpcodeName(m_Command.Hex, m_PC)).c_str());
g_Notify->DisplayError(stdstr_f("Unhandled R4300i opcode in FillSectionInfo 3\n%s", R4300iOpcodeName(m_Command.Hex, m_PC)).c_str());
m_NextInstruction = END_BLOCK;
m_PC -= 4;
}
@ -627,7 +627,7 @@ bool LoopAnalysis::CheckLoopRegisterUsage(CCodeSection * Section)
case R4300i_COP1_W: break;
case R4300i_COP1_L: break;
default:
g_Notify->DisplayError(stdstr_f("Unhandled R4300i OpCode in FillSectionInfo 2\n%s", R4300iOpcodeName(m_Command.Hex, m_PC)).c_str());
g_Notify->DisplayError(stdstr_f("Unhandled R4300i opcode in FillSectionInfo 2\n%s", R4300iOpcodeName(m_Command.Hex, m_PC)).c_str());
m_NextInstruction = END_BLOCK;
m_PC -= 4;
}
@ -727,7 +727,7 @@ bool LoopAnalysis::CheckLoopRegisterUsage(CCodeSection * Section)
if (m_Command.Hex == 0xF1F3F5F7) { break; }
if (m_Command.Hex == 0xC1200000) { break; }
if (m_Command.Hex == 0x4C5A5353) { break; }
g_Notify->DisplayError(stdstr_f("Unhandled R4300i OpCode in FillSectionInfo 1\n%s\n%X", R4300iOpcodeName(m_Command.Hex, m_PC), m_Command.Hex).c_str());
g_Notify->DisplayError(stdstr_f("Unhandled R4300i opcode in FillSectionInfo 1\n%s\n%X", R4300iOpcodeName(m_Command.Hex, m_PC), m_Command.Hex).c_str());
}
CPU_Message(" %s state: %X value: %X", CRegName::GPR[5], m_Reg.GetMipsRegState(5), m_Reg.GetMipsRegLo(5));

View File

@ -26,7 +26,7 @@ private:
void SetJumpRegSet(CCodeSection * Section, const CRegInfo &Reg);
void SetContinueRegSet(CCodeSection * Section, const CRegInfo &Reg);
/********************** R4300i OpCodes: Special **********************/
// R4300i opcodes: Special
void SPECIAL_SLL();
void SPECIAL_SRL();
void SPECIAL_SRA();

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