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debugsnapshot.c
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debugsnapshot.c
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/* === NP2 debug snapshot === (c) 2020 AZO */
#if defined(SUPPORT_DEBUGSS)
#include <debugsnapshot.h>
#include <dosio.h>
#include <fdd/sxsi.h>
#include <fdd/sxsicd.h>
#include <vram/scrnsave.h>
#include <np2ver.h>
#include <statsave.h>
#if(__LIBRETRO__)
// Nothing
#elif(_MSC_VER)
#include <windows.h>
#else
#include <openssl/sha.h>
#endif
#if defined(_MSC_VER)
#include <crtdbg.h>
#define DBSS_MSG(string) _RPTN(_CRT_WARN, "%s\n", string)
#else
#define DBSS_MSG(string) printf("%s\n", string)
#endif
UINT NP2_DebugSnapshot_Count;
NP2_DebugSnapshot_t tDebugSnapshot;
#if defined(__LIBRETRO__)
static int sha1_calculate(const char *path, char *result);
struct sha1_context
{
unsigned Message_Digest[5]; /* Message Digest (output) */
unsigned Length_Low; /* Message length in bits */
unsigned Length_High; /* Message length in bits */
unsigned char Message_Block[64]; /* 512-bit message blocks */
int Message_Block_Index; /* Index into message block array */
int Computed; /* Is the digest computed? */
int Corrupted; /* Is the message digest corruped? */
};
static void SHA1Reset(struct sha1_context *context);
static int SHA1Result(struct sha1_context *context);
static void SHA1Input(struct sha1_context *context,
const unsigned char *message_array,
unsigned length);
/* SHA-1 implementation. */
/*
* sha1.c
*
* Copyright (C) 1998, 2009
* Paul E. Jones <paulej@packetizer.com>
* All Rights Reserved
*
*****************************************************************************
* $Id: sha1.c 12 2009-06-22 19:34:25Z paulej $
*****************************************************************************
*
* Description:
* This file implements the Secure Hashing Standard as defined
* in FIPS PUB 180-1 published April 17, 1995.
*
* The Secure Hashing Standard, which uses the Secure Hashing
* Algorithm (SHA), produces a 160-bit message digest for a
* given data stream. In theory, it is highly improbable that
* two messages will produce the same message digest. Therefore,
* this algorithm can serve as a means of providing a "fingerprint"
* for a message.
*
* Portability Issues:
* SHA-1 is defined in terms of 32-bit "words". This code was
* written with the expectation that the processor has at least
* a 32-bit machine word size. If the machine word size is larger,
* the code should still function properly. One caveat to that
* is that the input functions taking characters and character
* arrays assume that only 8 bits of information are stored in each
* character.
*
* Caveats:
* SHA-1 is designed to work with messages less than 2^64 bits
* long. Although SHA-1 allows a message digest to be generated for
* messages of any number of bits less than 2^64, this
* implementation only works with messages with a length that is a
* multiple of the size of an 8-bit character.
*
*/
/* Define the circular shift macro */
#define SHA1CircularShift(bits,word) ((((word) << (bits)) & 0xFFFFFFFF) | ((word) >> (32-(bits))))
#if 0
struct sha1_context
{
unsigned Message_Digest[5]; /* Message Digest (output) */
unsigned Length_Low; /* Message length in bits */
unsigned Length_High; /* Message length in bits */
unsigned char Message_Block[64]; /* 512-bit message blocks */
int Message_Block_Index; /* Index into message block array */
int Computed; /* Is the digest computed? */
int Corrupted; /* Is the message digest corruped? */
};
#endif
static void SHA1Reset(struct sha1_context *context)
{
if (!context)
return;
context->Length_Low = 0;
context->Length_High = 0;
context->Message_Block_Index = 0;
context->Message_Digest[0] = 0x67452301;
context->Message_Digest[1] = 0xEFCDAB89;
context->Message_Digest[2] = 0x98BADCFE;
context->Message_Digest[3] = 0x10325476;
context->Message_Digest[4] = 0xC3D2E1F0;
context->Computed = 0;
context->Corrupted = 0;
}
static void SHA1ProcessMessageBlock(struct sha1_context *context)
{
const unsigned K[] = /* Constants defined in SHA-1 */
{
0x5A827999,
0x6ED9EBA1,
0x8F1BBCDC,
0xCA62C1D6
};
int t; /* Loop counter */
unsigned temp; /* Temporary word value */
unsigned W[80]; /* Word sequence */
unsigned A, B, C, D, E; /* Word buffers */
/* Initialize the first 16 words in the array W */
for(t = 0; t < 16; t++)
{
W[t] = ((unsigned) context->Message_Block[t * 4]) << 24;
W[t] |= ((unsigned) context->Message_Block[t * 4 + 1]) << 16;
W[t] |= ((unsigned) context->Message_Block[t * 4 + 2]) << 8;
W[t] |= ((unsigned) context->Message_Block[t * 4 + 3]);
}
for(t = 16; t < 80; t++)
W[t] = SHA1CircularShift(1,W[t-3] ^ W[t-8] ^ W[t-14] ^ W[t-16]);
A = context->Message_Digest[0];
B = context->Message_Digest[1];
C = context->Message_Digest[2];
D = context->Message_Digest[3];
E = context->Message_Digest[4];
for(t = 0; t < 20; t++)
{
temp = SHA1CircularShift(5,A) +
((B & C) | ((~B) & D)) + E + W[t] + K[0];
temp &= 0xFFFFFFFF;
E = D;
D = C;
C = SHA1CircularShift(30,B);
B = A;
A = temp;
}
for(t = 20; t < 40; t++)
{
temp = SHA1CircularShift(5,A) + (B ^ C ^ D) + E + W[t] + K[1];
temp &= 0xFFFFFFFF;
E = D;
D = C;
C = SHA1CircularShift(30,B);
B = A;
A = temp;
}
for(t = 40; t < 60; t++)
{
temp = SHA1CircularShift(5,A) +
((B & C) | (B & D) | (C & D)) + E + W[t] + K[2];
temp &= 0xFFFFFFFF;
E = D;
D = C;
C = SHA1CircularShift(30,B);
B = A;
A = temp;
}
for(t = 60; t < 80; t++)
{
temp = SHA1CircularShift(5,A) + (B ^ C ^ D) + E + W[t] + K[3];
temp &= 0xFFFFFFFF;
E = D;
D = C;
C = SHA1CircularShift(30,B);
B = A;
A = temp;
}
context->Message_Digest[0] =
(context->Message_Digest[0] + A) & 0xFFFFFFFF;
context->Message_Digest[1] =
(context->Message_Digest[1] + B) & 0xFFFFFFFF;
context->Message_Digest[2] =
(context->Message_Digest[2] + C) & 0xFFFFFFFF;
context->Message_Digest[3] =
(context->Message_Digest[3] + D) & 0xFFFFFFFF;
context->Message_Digest[4] =
(context->Message_Digest[4] + E) & 0xFFFFFFFF;
context->Message_Block_Index = 0;
}
static void SHA1PadMessage(struct sha1_context *context)
{
if (!context)
return;
/*
* Check to see if the current message block is too small to hold
* the initial padding bits and length. If so, we will pad the
* block, process it, and then continue padding into a second
* block.
*/
context->Message_Block[context->Message_Block_Index++] = 0x80;
if (context->Message_Block_Index > 55)
{
while(context->Message_Block_Index < 64)
context->Message_Block[context->Message_Block_Index++] = 0;
SHA1ProcessMessageBlock(context);
}
while(context->Message_Block_Index < 56)
context->Message_Block[context->Message_Block_Index++] = 0;
/* Store the message length as the last 8 octets */
context->Message_Block[56] = (context->Length_High >> 24) & 0xFF;
context->Message_Block[57] = (context->Length_High >> 16) & 0xFF;
context->Message_Block[58] = (context->Length_High >> 8) & 0xFF;
context->Message_Block[59] = (context->Length_High) & 0xFF;
context->Message_Block[60] = (context->Length_Low >> 24) & 0xFF;
context->Message_Block[61] = (context->Length_Low >> 16) & 0xFF;
context->Message_Block[62] = (context->Length_Low >> 8) & 0xFF;
context->Message_Block[63] = (context->Length_Low) & 0xFF;
SHA1ProcessMessageBlock(context);
}
static int SHA1Result(struct sha1_context *context)
{
if (context->Corrupted)
return 0;
if (!context->Computed)
{
SHA1PadMessage(context);
context->Computed = 1;
}
return 1;
}
static void SHA1Input(struct sha1_context *context,
const unsigned char *message_array,
unsigned length)
{
if (!length)
return;
if (context->Computed || context->Corrupted)
{
context->Corrupted = 1;
return;
}
while(length-- && !context->Corrupted)
{
context->Message_Block[context->Message_Block_Index++] =
(*message_array & 0xFF);
context->Length_Low += 8;
/* Force it to 32 bits */
context->Length_Low &= 0xFFFFFFFF;
if (context->Length_Low == 0)
{
context->Length_High++;
/* Force it to 32 bits */
context->Length_High &= 0xFFFFFFFF;
if (context->Length_High == 0)
context->Corrupted = 1; /* Message is too long */
}
if (context->Message_Block_Index == 64)
SHA1ProcessMessageBlock(context);
message_array++;
}
}
static int sha1_calculate(const char *path, char *result)
{
struct sha1_context sha;
unsigned char buff[4096];
int rv = 1;
RFILE *fd = filestream_open(path,
RETRO_VFS_FILE_ACCESS_READ,
RETRO_VFS_FILE_ACCESS_HINT_NONE);
if (!fd)
goto error;
buff[0] = '\0';
SHA1Reset(&sha);
do
{
rv = (int)filestream_read(fd, buff, 4096);
if (rv < 0)
goto error;
SHA1Input(&sha, buff, rv);
}while(rv);
if (!SHA1Result(&sha))
goto error;
sprintf(result, "%08X%08X%08X%08X%08X",
sha.Message_Digest[0],
sha.Message_Digest[1],
sha.Message_Digest[2],
sha.Message_Digest[3], sha.Message_Digest[4]);
filestream_close(fd);
return 0;
error:
if (fd)
filestream_close(fd);
return -1;
}
#endif // __LIBRETRO__
#if defined(_MSC_VER)
struct CALCSHA1 {
HCRYPTPROV hProv;
HCRYPTHASH hHash;
};
#endif
HCALCSHA1 calc_sha1_begin(void) {
HCALCSHA1 hRes;
#if defined(__LIBRETRO__)
hRes = (HCALCSHA1)malloc(sizeof(struct sha1_context));
if(hRes) {
SHA1Reset(hRes);
}
#elif defined(_MSC_VER)
struct CALCSHA1 {
HCRYPTPROV hProv;
HCRYPTHASH hHash;
};
hRes = (HCALCSHA1)malloc(sizeof(struct CALCSHA1));
if(hRes) {
if(!CryptAcquireContext(&((struct CALCSHA1*)hRes)->hProv, NULL, NULL, PROV_RSA_AES, CRYPT_VERIFYCONTEXT)) {
CryptReleaseContext(((struct CALCSHA1*)hRes)->hProv, 0);
free(hRes);
hRes = NULL;
}
}
if(hRes) {
if(!CryptCreateHash(((struct CALCSHA1*)hRes)->hProv, CALG_SHA1, 0, 0, &((struct CALCSHA1*)hRes)->hHash)) {
CryptDestroyHash(((struct CALCSHA1*)hRes)->hHash);
CryptReleaseContext(((struct CALCSHA1*)hRes)->hProv, 0);
free(hRes);
hRes = NULL;
}
}
#else
hRes = (HCALCSHA1)malloc(sizeof(SHA_CTX));
if(hRes) {
if(SHA1_Init((SHA_CTX*)hRes) != 1) {
free(hRes);
hRes = NULL;
}
}
#endif
return hRes;
}
void calc_sha1_destruct(HCALCSHA1 hCalc) {
if(hCalc) {
#if defined(_MSC_VER)
CryptDestroyHash(((struct CALCSHA1*)hCalc)->hHash);
CryptReleaseContext(((struct CALCSHA1*)hCalc)->hProv, 0);
#endif
free(hCalc);
}
}
UINT calc_sha1_add(HCALCSHA1 hCalc, const UINT8* pu8Data, const UINT uLen) {
UINT uRes = 0;
if(!hCalc || !pu8Data) {
uRes = 1;
}
if(!uRes && uLen > 0) {
#if defined(__LIBRETRO__)
SHA1Input((struct sha1_context*)hCalc, pu8Data, uLen);
#elif defined(_MSC_VER)
if(!CryptHashData(((struct CALCSHA1*)hCalc)->hHash, pu8Data, uLen, 0)) {
uRes = 2;
CryptDestroyHash(((struct CALCSHA1*)hCalc)->hHash);
CryptReleaseContext(((struct CALCSHA1*)hCalc)->hProv, 0);
free(hCalc);
}
#else
if(SHA1_Update((SHA_CTX*)hCalc, pu8Data, uLen) != 1) {
uRes = 2;
free(hCalc);
}
#endif
}
return uRes;
}
UINT calc_sha1_end(HCALCSHA1 hCalc, UINT8 au8SHA1[20]) {
UINT uRes = 0;
if(!hCalc || !au8SHA1) {
uRes = 1;
}
if(!uRes) {
#if defined(__LIBRETRO__)
if(!SHA1Result((struct sha1_context*)hCalc)) {
uRes = 2;
free(hCalc);
}
}
if(!uRes) {
int i;
for(i = 0; i < 20; i++) {
au8SHA1[i] = ((UINT8*)(((struct sha1_context*)hCalc)->Message_Digest))[(i / 4) * 4 + (3 - (i % 4))];
}
#elif defined(_MSC_VER)
UINT uLen = 20;
if(!CryptGetHashParam(((struct CALCSHA1*)hCalc)->hHash, HP_HASHVAL, au8SHA1, &uLen, 0)) {
uRes = 2;
CryptDestroyHash(((struct CALCSHA1*)hCalc)->hHash);
CryptReleaseContext(((struct CALCSHA1*)hCalc)->hProv, 0);
free(hCalc);
}
}
if(!uRes) {
CryptDestroyHash(((struct CALCSHA1*)hCalc)->hHash);
CryptReleaseContext(((struct CALCSHA1*)hCalc)->hProv, 0);
#else
if(SHA1_Final(au8SHA1, (SHA_CTX*)hCalc) != 1) {
uRes = 2;
free(hCalc);
}
#endif
}
if(!uRes) {
free(hCalc);
}
return uRes;
}
#define CALC_HASH_BUFFERSIZE 0x100000
UINT calc_sha1(UINT8 au8SHA1[20], const OEMCHAR* strFilePath) {
UINT uRes = 0;
FILEH f;
UINT8* pu8Buf;
UINT uLen;
HCALCSHA1 hCalc;
if(!au8SHA1 || !strFilePath) {
uRes = 1;
}
if(!uRes) {
if(strFilePath[0] == '\0') {
uRes = 2;
}
}
if(!uRes) {
hCalc = calc_sha1_begin();
if(!hCalc) {
uRes = 3;
}
}
if(!uRes) {
f = file_open_rb(strFilePath);
if(!f) {
uRes = 4;
calc_sha1_destruct(hCalc);
}
}
if(!uRes) {
pu8Buf = (UINT8*)malloc(CALC_HASH_BUFFERSIZE);
if(!pu8Buf) {
uRes = 5;
calc_sha1_destruct(hCalc);
file_close(f);
}
}
if(!uRes) {
while(uLen = file_read(f, pu8Buf, CALC_HASH_BUFFERSIZE)) {
if(calc_sha1_add(hCalc, pu8Buf, uLen)) {
uRes = 6;
calc_sha1_destruct(hCalc);
file_close(f);
break;
}
}
}
if(!uRes) {
if(calc_sha1_end(hCalc, au8SHA1)) {
uRes = 7;
free(pu8Buf);
file_close(f);
}
}
if(!uRes) {
free(pu8Buf);
file_close(f);
}
return uRes;
}
int debugsnapshot_save(const UINT uNo) {
UINT uRes = 0;
INT iVal;
OEMCHAR* pstrBaseDir;
OEMCHAR strFilePath[MAX_PATH];
SCRNSAVE hScreenSave;
FILEH hFile;
short attr;
memset(&tDebugSnapshot, 0, sizeof(NP2_DebugSnapshot_t));
#if defined(__LIBRETRO__)
milstr_ncpy(tDebugSnapshot.strProgramType, "libretro", sizeof(tDebugSnapshot.strProgramType));
#elif defined(EMSCRIPTEN)
#if defined(SUPPORT_PC9821)
milstr_ncpy(tDebugSnapshot.strProgramType, "Emscripten IA-32", sizeof(tDebugSnapshot.strProgramType));
#else
milstr_ncpy(tDebugSnapshot.strProgramType, "Emscripten", sizeof(tDebugSnapshot.strProgramType));
#endif
#elif defined(NP2_SDL)
#if defined(SUPPORT_PC9821)
milstr_ncpy(tDebugSnapshot.strProgramType, "SDL IA-32", sizeof(tDebugSnapshot.strProgramType));
#else
milstr_ncpy(tDebugSnapshot.strProgramType, "SDL", sizeof(tDebugSnapshot.strProgramType));
#endif
#elif defined(NP2_X)
#if defined(SUPPORT_PC9821)
milstr_ncpy(tDebugSnapshot.strProgramType, "X IA-32", sizeof(tDebugSnapshot.strProgramType));
#else
milstr_ncpy(tDebugSnapshot.strProgramType, "X", sizeof(tDebugSnapshot.strProgramType));
#endif
#elif defined(NP2_WIN)
#if defined(SUPPORT_PC9821)
milstr_ncpy(tDebugSnapshot.strProgramType, "Windows IA-32", sizeof(tDebugSnapshot.strProgramType));
#else
milstr_ncpy(tDebugSnapshot.strProgramType, "Windows", sizeof(tDebugSnapshot.strProgramType));
#endif
#else
milstr_ncpy(tDebugSnapshot.strProgramType, "(unknown)", sizeof(tDebugSnapshot.strProgramType));
#endif
pstrBaseDir = file_getcd(OEMTEXT(DEBUGSS_DIRNAME));
attr = file_attr(pstrBaseDir);
if(attr >= 0) {
if(attr & ~FILEATTR_DIRECTORY) {
DBSS_MSG("[debugss] debugss is not valid directory.");
uRes = 1;
}
} else {
if(file_dircreate(pstrBaseDir) != 0) {
DBSS_MSG("[debugss] could not create debugss directory.");
uRes = 2;
}
}
if(!uRes) {
attr = file_attr(pstrBaseDir);
if(attr >= 0) {
if(attr & FILEATTR_READONLY) {
DBSS_MSG("[debugss] could not create debugss file (read only).");
uRes = 3;
}
} else {
if(attr & FILEATTR_READONLY) {
DBSS_MSG("[debugss] could not create debugss file.");
uRes = 4;
}
}
}
if(!uRes) {
OEMSTRCPY(tDebugSnapshot.strVersion, OEMTEXT(NP2KAI_GIT_TAG) OEMTEXT(" ") OEMTEXT(NP2KAI_GIT_HASH));
OEMSNPRINTF(
tDebugSnapshot.strStatePath, MAX_PATH, OEMTEXT("%s%c%s_%d.state"),
pstrBaseDir,
OEMPATHDIVC,
DEBUGSS_FILENAME,
uNo
);
statsave_save(tDebugSnapshot.strStatePath);
hScreenSave = scrnsave_create();
OEMSNPRINTF(
tDebugSnapshot.strBMPPath, MAX_PATH, OEMTEXT("%s%c%s_%d.bmp"),
pstrBaseDir,
OEMPATHDIVC,
DEBUGSS_FILENAME,
uNo
);
scrnsave_writebmp(hScreenSave, tDebugSnapshot.strBMPPath, 0);
scrnsave_destroy(hScreenSave);
for(iVal = 0; iVal < MAX_FDDFILE; iVal++) {
if(fddfile[iVal].fname[0] != '\0') {
tDebugSnapshot.uFDMount |= (1 << iVal);
tDebugSnapshot.auFDType[iVal] = fddfile[iVal].ftype;
file_cpyname(tDebugSnapshot.astrFDImagePath[iVal], fddfile[iVal].fname, MAX_PATH);
tDebugSnapshot.auFDRO[iVal] = fddfile[iVal].ro;
memcpy(&tDebugSnapshot.auFDInfo[iVal], &fddfile[iVal].inf, sizeof(union fdinfo));
memcpy(tDebugSnapshot.au8FDHash[iVal], fddfile[iVal].hash_sha1, 20);
calc_sha1(tDebugSnapshot.au8FDHash[iVal], fddfile[iVal].fname);
}
}
for(iVal = 0; iVal < SASIHDD_MAX + SCSIHDD_MAX; iVal++) {
if(sxsi_dev[iVal].fname[0] != '\0') {
tDebugSnapshot.uHDCDMount |= (1 << iVal);
tDebugSnapshot.auHDCDType[iVal] = sxsi_dev[iVal].devtype;
file_cpyname(tDebugSnapshot.astrHDCDImagePath[iVal], sxsi_dev[iVal].fname, MAX_PATH);
if(sxsi_dev[iVal].devtype == SXSIDEV_CDROM && (milstr_cmp(sxsi_dev[iVal].fname, OEMTEXT("\\\\.\\")) != 0)) {
if(np2cfg.debugss) {
HCALCSHA1 hCalc;
UINT8 au8Buf[2352];
UINT uTracks, uSectors, uSectorNo, uSize;
CDTRK atTracks = sxsicd_gettrk(&sxsi_dev[iVal], &uTracks);
if(atTracks && uTracks) {
hCalc = calc_sha1_begin();
if(hCalc) {
uSectors = atTracks[uTracks - 1].pos + atTracks[uTracks - 1].sectors;
//printf("CD Sectors: %d\n", uSectors);
for(uSectorNo = 0; uSectorNo < uSectors; uSectorNo++) {
if(sxsicd_readraw_forhash(&sxsi_dev[iVal], uSectorNo, au8Buf, &uSize) == 0) {
calc_sha1_add(hCalc, au8Buf, uSize);
} else {
//printf("Error sector: %d\n", uSectorNo);
}
}
}
calc_sha1_end(hCalc, tDebugSnapshot.au8CDHash[iVal]);
//printf("Hash: ");
// for(uSectorNo = 0; uSectorNo < 20; uSectorNo++) {
//printf("%02x", tDebugSnapshot.au8CDHash[iVal][uSectorNo]);
// }
//printf("\n");
}
} else {
memset(tDebugSnapshot.au8CDHash[iVal], 0, 20);
}
}
}
}
}
if(!uRes) {
memcpy(&tDebugSnapshot.np2cfg, &np2cfg, sizeof(NP2CFG));
memcpy(&tDebugSnapshot.np2oscfg, &np2oscfg, sizeof(NP2OSCFG));
}
if(!uRes) {
OEMSNPRINTF(
strFilePath, MAX_PATH, OEMTEXT("%s%c%s_%d.data"),
pstrBaseDir,
OEMPATHDIVC,
DEBUGSS_FILENAME,
uNo
);
hFile = NULL;
hFile = file_create(strFilePath);
if(!hFile) {
DBSS_MSG("[debugss] could not create debug data file.");
uRes = 10;
}
}
if(!uRes) {
file_write(hFile, &tDebugSnapshot, sizeof(NP2_DebugSnapshot_t));
file_close(hFile);
hFile = NULL;
}
return uRes;
}
int debugsnapshot_load(const UINT uNo) {
UINT uRes = 0;
INT iVal, iVal2;
OEMCHAR* pstrBaseDir;
OEMCHAR strFilePath[MAX_PATH];
OEMCHAR strString[MAX_PATH];
FILEH hFile;
memset(&tDebugSnapshot, 0, sizeof(NP2_DebugSnapshot_t));
pstrBaseDir = file_getcd(OEMTEXT(DEBUGSS_DIRNAME));
iVal = file_attr(pstrBaseDir);
if(iVal == 0) {
DBSS_MSG("[debugss] not found debug directory.");
uRes = 1;
}
if(!uRes) {
OEMSNPRINTF(
strFilePath, MAX_PATH, OEMTEXT("%s%c%s_%d.data"),
pstrBaseDir,
OEMPATHDIVC,
DEBUGSS_FILENAME,
uNo
);
hFile = NULL;
hFile = file_open_rb(strFilePath);
if(!hFile) {
DBSS_MSG("[debugss] could not open debug data file.");
uRes = 3;
} else {
file_read(hFile, &tDebugSnapshot, sizeof(NP2_DebugSnapshot_t));
file_close(hFile);
hFile = NULL;
}
}
if(!uRes) {
#if defined(__LIBRETRO__)
if(milstr_cmp(tDebugSnapshot.strProgramType, "libretro") != 0) {
#elif defined(EMSCRIPTEN)
#if defined(SUPPORT_PC9821)
if(milstr_cmp(tDebugSnapshot.strProgramType, "Emscripten IA-32") != 0) {
#else
if(milstr_cmp(tDebugSnapshot.strProgramType, "Emscripten") != 0) {
#endif
#elif defined(NP2_SDL)
#if defined(SUPPORT_PC9821)
if(milstr_cmp(tDebugSnapshot.strProgramType, "SDL IA-32") != 0) {
#else
if(milstr_cmp(tDebugSnapshot.strProgramType, "SDL") != 0) {
#endif
#elif defined(NP2_X)
#if defined(SUPPORT_PC9821)
if(milstr_cmp(tDebugSnapshot.strProgramType, "X IA-32") != 0) {
#else
if(milstr_cmp(tDebugSnapshot.strProgramType, "X") != 0) {
#endif
#elif defined(NP2_WIN)
#if defined(SUPPORT_PC9821)
if(milstr_cmp(tDebugSnapshot.strProgramType, "Windwos IA-32") != 0) {
#else
if(milstr_cmp(tDebugSnapshot.strProgramType, "Windwos") != 0) {
#endif
#else
if(milstr_cmp(tDebugSnapshot.strProgramType, "(unknown)") == 0) {
#endif
OEMSNPRINTF(
strString, MAX_PATH, OEMTEXT("[debugss] not match program type. : %s"),
tDebugSnapshot.strProgramType
);
DBSS_MSG(strString);
uRes = 3;
} else {
OEMSNPRINTF(
strString, MAX_PATH, OEMTEXT("[debugss] program type: %s"),
tDebugSnapshot.strProgramType
);
DBSS_MSG(strString);
}
}
if(!uRes) {
OEMSNPRINTF(
strString, MAX_PATH, OEMTEXT("[debugss] Debug data ver: %s"),
tDebugSnapshot.strVersion
);
DBSS_MSG(strString);
OEMSNPRINTF(
strString, MAX_PATH, OEMTEXT("[debugss] Program ver: %s"),
OEMTEXT(NP2KAI_GIT_TAG) OEMTEXT(" ") OEMTEXT(NP2KAI_GIT_HASH)
);
DBSS_MSG(strString);
if(milstr_cmp(tDebugSnapshot.strVersion, OEMTEXT(NP2KAI_GIT_TAG) OEMTEXT(" ") OEMTEXT(NP2KAI_GIT_HASH)) != 0) {
DBSS_MSG("[debugss] not match version.");
uRes = 4;
}
}
if(!uRes) {
OEMSNPRINTF(
strString, MAX_PATH, OEMTEXT("[debugss] FDD mount flag is %X."),
tDebugSnapshot.uFDMount
);
DBSS_MSG(strString);
for(iVal = 0; iVal < MAX_FDDFILE; iVal++) {
if(tDebugSnapshot.uFDMount & (1 << iVal)) {
OEMSNPRINTF(
strString, MAX_PATH, OEMTEXT("[debugss] FDD %d info."),
iVal
);
DBSS_MSG(strString);
OEMSNPRINTF(
strString, MAX_PATH, OEMTEXT(" Type: %d"),
tDebugSnapshot.auFDType[iVal]
);
DBSS_MSG(strString);
OEMSNPRINTF(
strString, MAX_PATH, OEMTEXT(" FilePath: %s"),
tDebugSnapshot.astrFDImagePath[iVal]
);
DBSS_MSG(strString);
OEMSNPRINTF(
strString, MAX_PATH, OEMTEXT(" ReadOnly: %d"),
tDebugSnapshot.auFDRO[iVal]
);
DBSS_MSG(strString);
OEMSNPRINTF(strString, MAX_PATH, OEMTEXT("%s"), OEMTEXT(" SHA-1: "));
DBSS_MSG(strString);
strString[0] = '\0';
for(iVal2 = 0; iVal2 < 20; iVal2++) {
OEMSNPRINTF(
strFilePath, MAX_PATH, OEMTEXT("%02x"),
tDebugSnapshot.au8FDHash[iVal][iVal2]
);
milstr_ncat(strString, strFilePath, MAX_PATH);
}
DBSS_MSG(strString);
}
}
OEMSNPRINTF(
strString, MAX_PATH, OEMTEXT("[debugss] HDCDD mount flag is %X."),
tDebugSnapshot.uHDCDMount
);
DBSS_MSG(strString);
for(iVal = 0; iVal < SASIHDD_MAX + SCSIHDD_MAX; iVal++) {
if(tDebugSnapshot.uHDCDMount & (1 << iVal)) {
OEMSNPRINTF(
strString, MAX_PATH, OEMTEXT("[debugss] HDCDD %d info."),
iVal
);
DBSS_MSG(strString);
OEMSNPRINTF(
strString, MAX_PATH, OEMTEXT(" Type: %d"),
tDebugSnapshot.auHDCDType[iVal]
);
DBSS_MSG(strString);
OEMSNPRINTF(
strString, MAX_PATH, OEMTEXT(" FilePath: %s"),
tDebugSnapshot.astrHDCDImagePath[iVal]
);
DBSS_MSG(strString);
if(tDebugSnapshot.auHDCDType[iVal] == SXSIDEV_CDROM) {
OEMSNPRINTF(strString, MAX_PATH, OEMTEXT("%s"), OEMTEXT(" SHA-1: "));
DBSS_MSG(strString);
strString[0] = '\0';
for(iVal2 = 0; iVal2 < 20; iVal2++) {
OEMSNPRINTF(
strFilePath, MAX_PATH, OEMTEXT("%02x"),
tDebugSnapshot.au8CDHash[iVal][iVal2]
);
milstr_ncat(strString, strFilePath, MAX_PATH);
}
DBSS_MSG(strString);
}
}
}
}
if(!uRes) {
memcpy(&np2cfg, &tDebugSnapshot.np2cfg, sizeof(NP2CFG));
memcpy(&np2oscfg, &tDebugSnapshot.np2oscfg, sizeof(NP2OSCFG));
}
if(!uRes) {
statsave_load(tDebugSnapshot.strStatePath);
}
return uRes;
}
#endif // SUPPORT_DEBUGSS