BOOL PSPrintDC::OutputCoord(DocCoord& Coord, EPSAccuracy Accuracy)
{
// We need a view to scale the coords.
ERROR2IF(pView == NULL, FALSE, "No view attached to PostScript DC!");
WinCoord PSCoord = TransformCoord(Coord);
// Output to PostScript stream.
BOOL Ok = (OutputValue(PSCoord.x) && OutputValue(PSCoord.y));
return Ok;
}
STDMETHODIMP AitEncoder::Initialize(IStream *pIStream, WICBitmapEncoderCacheOption cacheOption)
{
HRESULT result = E_INVALIDARG;
if (pIStream)
{
result = S_OK;
stream = pIStream;
if (SUCCEEDED(result))
{
result = VerifyFactory();
}
// Remember the position of the header for later reference
if (SUCCEEDED(result))
{
LARGE_INTEGER zero = { 0 };
result = stream->Seek(zero, STREAM_SEEK_CUR, &headerPos);
}
// Write the header with a placeholder for the number of frames
if (SUCCEEDED(result))
{
BeginBlock(stream, "AIT", 0xFFFFFFFF);
OutputValue(stream, (UINT)0);
result = EndBlock(stream);
}
}
return result;
}
BOOL PSPrintDC::OutputUserSpaceValue(MILLIPOINT n, EPSAccuracy Accuracy)
{
// We need a view to scale the value.
ERROR2IF(pView == NULL, FALSE, "No view attached to PostScript DC!");
// Use pixel size to scale to device units.
n /= PixelSize;
// Output as device units
return OutputValue(n);
}
static HRESULT BeginBlock(IStream *stream, LPCSTR name, UINT frameNum)
{
HRESULT result = S_OK;
if (NULL == stream)
{
result = E_INVALIDARG;
}
// Remember where we are
if (SUCCEEDED(result))
{
LARGE_INTEGER zero = { 0 };
result = stream->Seek(zero, STREAM_SEEK_CUR, &lastBlockPos);
}
// The number of bytes is stored as zero for now. The function EndBlock will write the
// correct value later.
UINT numBytes = 0;
// Output the name
if (SUCCEEDED(result))
{
result = OutputValues(stream, name, 4);
}
// Output the frame number
if (SUCCEEDED(result))
{
result = OutputValue(stream, frameNum);
}
// Output the size
if (SUCCEEDED(result))
{
result = OutputValue(stream, numBytes);
}
return result;
}
static HRESULT OutputBitmapPalette(IStream *stream, UINT frameNum, IWICPalette *palette)
{
HRESULT result = E_INVALIDARG;
if (stream && palette)
{
UINT colorCount = 0;
WICColor *colors = NULL;
result = S_OK;
if (SUCCEEDED(result))
{
result = palette->GetColorCount(&colorCount);
}
if (colorCount > 0)
{
if (SUCCEEDED(result))
{
colors = new WICColor[colorCount];
if (NULL == colors)
{
result = E_OUTOFMEMORY;
}
}
if (SUCCEEDED(result))
{
UINT cActualColors = 0;
result = palette->GetColors(colorCount, colors, &cActualColors);
}
if (SUCCEEDED(result))
{
BeginBlock(stream, "PAL", frameNum);
OutputValue(stream, colorCount);
OutputValues(stream, colors, colorCount);
result = EndBlock(stream);
}
if (colors)
{
delete[] colors;
}
}
}
return result;
}
static HRESULT OutputColorContext(IStream *stream, UINT frameNum, UINT colorContextCount, IWICColorContext **colorContext)
{
HRESULT result = E_INVALIDARG;
if (stream && colorContext)
{
BeginBlock(stream, "COL", frameNum);
for(int i = 0; i < colorContextCount; i++)
{
UINT numBytes = 0;
BYTE *bytes = NULL;
result = S_OK;
if (SUCCEEDED(result))
{
result = colorContext[i]->GetProfileBytes(0, NULL, &numBytes);
}
if (numBytes > 0)
{
if (SUCCEEDED(result))
{
bytes = new BYTE[numBytes];
if (NULL == bytes)
{
result = E_OUTOFMEMORY;
}
}
if (SUCCEEDED(result))
{
result = colorContext[i]->GetProfileBytes(numBytes, bytes, &numBytes);
}
if (SUCCEEDED(result))
{
OutputValue(stream, numBytes);
OutputValues(stream, bytes, numBytes);
}
if (bytes)
{
delete[] bytes;
}
}
}
result = EndBlock(stream);
}
return result;
}
static HRESULT EndBlock(IStream *stream)
{
HRESULT result = S_OK;
if (NULL == stream)
{
result = E_INVALIDARG;
}
// Remember where we are
ULARGE_INTEGER curPos = { 0 };
if (SUCCEEDED(result))
{
LARGE_INTEGER zero = { 0 };
result = stream->Seek(zero, STREAM_SEEK_CUR, &curPos);
}
// Move to where the size of the last block is stored
if (SUCCEEDED(result))
{
LARGE_INTEGER newPos;
newPos.QuadPart = static_cast<LONGLONG>(lastBlockPos.QuadPart) + 2*sizeof(UINT);
result = stream->Seek(newPos, STREAM_SEEK_SET, NULL);
}
// Store the size
if (SUCCEEDED(result))
{
UINT size = static_cast<UINT>(curPos.QuadPart - lastBlockPos.QuadPart) - 3*sizeof(UINT);
result = OutputValue(stream, size);
}
// Move back to where we should be
if (SUCCEEDED(result))
{
LARGE_INTEGER cp;
cp.QuadPart = static_cast<LONGLONG>(curPos.QuadPart);
result = stream->Seek(cp, STREAM_SEEK_SET, NULL);
}
return result;
}
STDMETHODIMP AitEncoder::Commit()
{
HRESULT result = E_UNEXPECTED;
if (stream)
{
ULARGE_INTEGER curPos = { 0 };
result = S_OK;
// Go back and insert the number of frames
// Remember this position
if (SUCCEEDED(result))
{
LARGE_INTEGER zero = { 0 };
result = stream->Seek(zero, STREAM_SEEK_CUR, NULL);
}
// Seek to the numFrames member of the header
if (SUCCEEDED(result))
{
LARGE_INTEGER pos;
pos.QuadPart = static_cast<LONGLONG>(headerPos.QuadPart) + 3*sizeof(UINT);
result = stream->Seek(pos, STREAM_SEEK_SET, NULL);
}
// Write the proper value
if (SUCCEEDED(result))
{
UINT numFrames = frames.size();
result = OutputValue(stream, numFrames);
}
// Seek back to where we were
if (SUCCEEDED(result))
{
LARGE_INTEGER pos;
pos.QuadPart = static_cast<LONGLONG>(curPos.QuadPart);
result = stream->Seek(pos, STREAM_SEEK_SET, NULL);
}
if (SUCCEEDED(result) && (NULL != destPalette))
{
result = OutputBitmapPalette(stream, 0xFFFFFFFF, destPalette);
}
if (SUCCEEDED(result) && (UINT)colorContexts.size() != 0)
{
IWICColorContext** ppIColorContext = new IWICColorContext*[colorContexts.size()];
for (int i = 0; i < (UINT)colorContexts.size(); i++)
{
ppIColorContext[i] = colorContexts[i];
}
result = OutputColorContext(stream, 0xFFFFFFFF, colorContexts.size(), (IWICColorContext**)ppIColorContext);
delete[] ppIColorContext;
}
if (SUCCEEDED(result) && (NULL != destThumbnail))
{
result = OutputBitmapSource(stream, "THU", 0xFFFFFFFF, 0, 0, destThumbnail);
}
if (SUCCEEDED(result) && (NULL != destPreview))
{
result = OutputBitmapSource(stream, "PRE", 0xFFFFFFFF, 0, 0, destPreview);
}
}
return result;
}
int main(int argc, const char* argv[]){
if(argc < 3){
fprintf(stderr, "Usage: %s buffer_size stack_depth\n", argv[0]);
return 1;
}
/* Read arguments. */
char* endptr;
unsigned buffsize = strtol(argv[1], &endptr, 10);
unsigned depth = strtol(argv[2], &endptr, 10);
/* Read json from std input. */
FD_Reader reader(0);
uint32_t *pstack = new uint32_t[depth];
BNJ::PullParser parser(depth, pstack);
/* Initialize parsing session. buffer is I/O scratch space. */
uint8_t *buffer = new uint8_t[buffsize];
parser.Begin(buffer, buffsize, &reader);
int ret = 0;
try{
/* Begin a tree walk. */
bool running = true;
while(running){
switch(parser.Pull()){
/* Stop when there is no more data. */
case BNJ::PullParser::ST_NO_DATA:
running = false;
break;
/* Parser pulled a datum. */
case BNJ::PullParser::ST_DATUM:
OutputValue(parser);
break;
case BNJ::PullParser::ST_MAP:
fprintf(stdout, "map open '{'\n");
break;
case BNJ::PullParser::ST_LIST:
fprintf(stdout, "array open '['\n");
break;
case BNJ::PullParser::ST_ASCEND_MAP:
fprintf(stdout, "map close '}'\n");
break;
case BNJ::PullParser::ST_ASCEND_LIST:
fprintf(stdout, "array close ']'\n");
break;
default:
break;
}
}
}
catch(const std::exception& e){
fprintf(stderr, "Runtime Error: %s\n", e.what());
ret = 1;
}
delete [] buffer;
delete [] pstack;
return ret;
}
static HRESULT OutputBitmapSource(IStream *stream, LPCSTR name, UINT frameNum,
double dpiX, double dpiY,
IWICBitmapSource *source)
{
HRESULT result = E_INVALIDARG;
if (stream && source)
{
UINT width = 0, height = 0;
UINT stride = 0;
WICPixelFormatGUID pixelFormat;
BYTE *pixels = NULL;
result = S_OK;
// Retrieve the dimensions of the source
if (SUCCEEDED(result))
{
result = source->GetSize(&width, &height);
}
// Optionally retrieve the resolution
if (SUCCEEDED(result) && (dpiX == 0 || dpiY == 0))
{
result = source->GetResolution(&dpiX, &dpiY);
}
// Get the pixel format
if (SUCCEEDED(result))
{
result = source->GetPixelFormat(&pixelFormat);
}
// Get the stride
if (SUCCEEDED(result))
{
stride = GetScanlineStride(width, pixelFormat);
if (stride < 1)
{
result = E_UNEXPECTED;
}
}
// Allocate the pixels
if (SUCCEEDED(result))
{
pixels = new BYTE[stride * height];
if (NULL == pixels)
{
result = E_OUTOFMEMORY;
}
}
// Get the pixels
if (SUCCEEDED(result))
{
WICRect rct;
rct.X = 0;
rct.Y = 0;
rct.Width = width;
rct.Height = height;
result = source->CopyPixels(&rct, stride, stride * height, pixels);
}
// Output everything
if (SUCCEEDED(result))
{
BeginBlock(stream, name, frameNum);
OutputValue(stream, width);
OutputValue(stream, height);
OutputValue(stream, dpiX);
OutputValue(stream, dpiY);
OutputValue(stream, stride);
OutputValue(stream, pixelFormat);
OutputValues(stream, pixels, stride*height);
result = EndBlock(stream);
}
if (pixels)
{
delete[] pixels;
}
}
return result;
}
int proc_file(char *rqfile)
{
char afn[256], rfn[256];
FILE *afp = NULL, *rfp = NULL;
char ibuf[2048];
int ilen, len, ret = 0;
char amode[8] = "";
char atest[100] = "";
int akeysz=0;
unsigned char iVec[20], aKey[40];
int dir = -1, err = 0, step = 0;
unsigned char plaintext[2048];
unsigned char ciphertext[2048];
char *rp;
EVP_CIPHER_CTX ctx;
int numkeys=1;
if (!rqfile || !(*rqfile))
{
printf("No req file\n");
return -1;
}
strcpy(afn, rqfile);
if ((afp = fopen(afn, "r")) == NULL)
{
printf("Cannot open file: %s, %s\n",
afn, strerror(errno));
return -1;
}
strcpy(rfn,afn);
rp=strstr(rfn,"req/");
assert(rp);
memcpy(rp,"rsp",3);
rp = strstr(rfn, ".req");
memcpy(rp, ".rsp", 4);
if ((rfp = fopen(rfn, "w")) == NULL)
{
printf("Cannot open file: %s, %s\n",
rfn, strerror(errno));
fclose(afp);
afp = NULL;
return -1;
}
while (!err && (fgets(ibuf, sizeof(ibuf), afp)) != NULL)
{
ilen = strlen(ibuf);
/* printf("step=%d ibuf=%s",step,ibuf);*/
if(step == 3 && !strcmp(amode,"ECB"))
{
memset(iVec, 0, sizeof(iVec));
step = (dir)? 4: 5; /* no ivec for ECB */
}
switch (step)
{
case 0: /* read preamble */
if (ibuf[0] == '\n')
{ /* end of preamble */
if (*amode == '\0')
{
printf("Missing Mode\n");
err = 1;
}
else
{
fputs(ibuf, rfp);
++ step;
}
}
else if (ibuf[0] != '#')
{
printf("Invalid preamble item: %s\n", ibuf);
err = 1;
}
else
{ /* process preamble */
char *xp, *pp = ibuf+2;
int n;
if(*amode)
{ /* insert current time & date */
time_t rtim = time(0);
fprintf(rfp, "# %s", ctime(&rtim));
}
else
{
fputs(ibuf, rfp);
if(!strncmp(pp,"INVERSE ",8) || !strncmp(pp,"DES ",4)
|| !strncmp(pp,"TDES ",5)
|| !strncmp(pp,"PERMUTATION ",12)
|| !strncmp(pp,"SUBSTITUTION ",13)
|| !strncmp(pp,"VARIABLE ",9))
{
/* get test type */
if(!strncmp(pp,"DES ",4))
pp+=4;
else if(!strncmp(pp,"TDES ",5))
pp+=5;
xp = strchr(pp, ' ');
n = xp-pp;
strncpy(atest, pp, n);
atest[n] = '\0';
/* get mode */
xp = strrchr(pp, ' '); /* get mode" */
n = strlen(xp+1)-1;
strncpy(amode, xp+1, n);
amode[n] = '\0';
/* amode[3] = '\0'; */
printf("Test=%s, Mode=%s\n",atest,amode);
}
}
}
break;
case 1: /* [ENCRYPT] | [DECRYPT] */
if(ibuf[0] == '\n')
break;
if (ibuf[0] == '[')
{
fputs(ibuf, rfp);
++step;
if (strncasecmp(ibuf, "[ENCRYPT]", 9) == 0)
dir = 1;
else if (strncasecmp(ibuf, "[DECRYPT]", 9) == 0)
dir = 0;
else
{
printf("Invalid keyword: %s\n", ibuf);
err = 1;
}
break;
}
else if (dir == -1)
{
err = 1;
printf("Missing ENCRYPT/DECRYPT keyword\n");
break;
}
else
step = 2;
case 2: /* KEY = xxxx */
if(*ibuf == '\n')
{
fputs(ibuf, rfp);
break;
}
if(!strncasecmp(ibuf,"COUNT = ",8))
{
fputs(ibuf, rfp);
break;
}
if(!strncasecmp(ibuf,"COUNT=",6))
{
fputs(ibuf, rfp);
break;
}
if(!strncasecmp(ibuf,"NumKeys = ",10))
{
numkeys=atoi(ibuf+10);
break;
}
fputs(ibuf, rfp);
if(!strncasecmp(ibuf,"KEY = ",6))
{
akeysz=64;
len = hex2bin((char*)ibuf+6, strlen(ibuf+6)-1, aKey);
if (len < 0)
{
printf("Invalid KEY\n");
err=1;
break;
}
PrintValue("KEY", aKey, len);
++step;
}
else if(!strncasecmp(ibuf,"KEYs = ",7))
{
akeysz=64*3;
len=hex2bin(ibuf+7,strlen(ibuf+7)-1,aKey);
if(len != 8)
{
printf("Invalid KEY\n");
err=1;
break;
}
memcpy(aKey+8,aKey,8);
memcpy(aKey+16,aKey,8);
ibuf[4]='\0';
PrintValue("KEYs",aKey,len);
++step;
}
else if(!strncasecmp(ibuf,"KEY",3))
{
int n=ibuf[3]-'1';
akeysz=64*3;
len=hex2bin(ibuf+7,strlen(ibuf+7)-1,aKey+n*8);
if(len != 8)
{
printf("Invalid KEY\n");
err=1;
break;
}
ibuf[4]='\0';
PrintValue(ibuf,aKey,len);
if(n == 2)
++step;
}
else
{
printf("Missing KEY\n");
err = 1;
}
break;
case 3: /* IV = xxxx */
fputs(ibuf, rfp);
if (strncasecmp(ibuf, "IV = ", 5) != 0)
{
printf("Missing IV\n");
err = 1;
}
else
{
len = hex2bin((char*)ibuf+5, strlen(ibuf+5)-1, iVec);
if (len < 0)
{
printf("Invalid IV\n");
err =1;
break;
}
PrintValue("IV", iVec, len);
step = (dir)? 4: 5;
}
break;
case 4: /* PLAINTEXT = xxxx */
fputs(ibuf, rfp);
if (strncasecmp(ibuf, "PLAINTEXT = ", 12) != 0)
{
printf("Missing PLAINTEXT\n");
err = 1;
}
else
{
int nn = strlen(ibuf+12);
if(!strcmp(amode,"CFB1"))
len=bint2bin(ibuf+12,nn-1,plaintext);
else
len=hex2bin(ibuf+12, nn-1,plaintext);
if (len < 0)
{
printf("Invalid PLAINTEXT: %s", ibuf+12);
err =1;
break;
}
if (len >= sizeof(plaintext))
{
printf("Buffer overflow\n");
}
PrintValue("PLAINTEXT", (unsigned char*)plaintext, len);
if (strcmp(atest, "Monte") == 0) /* Monte Carlo Test */
{
do_mct(amode,akeysz,numkeys,aKey,iVec,dir,plaintext,len,rfp);
}
else
{
assert(dir == 1);
ret = DESTest(&ctx, amode, akeysz, aKey, iVec,
dir, /* 0 = decrypt, 1 = encrypt */
ciphertext, plaintext, len);
OutputValue("CIPHERTEXT",ciphertext,len,rfp,
!strcmp(amode,"CFB1"));
}
step = 6;
}
break;
case 5: /* CIPHERTEXT = xxxx */
fputs(ibuf, rfp);
if (strncasecmp(ibuf, "CIPHERTEXT = ", 13) != 0)
{
printf("Missing KEY\n");
err = 1;
}
else
{
if(!strcmp(amode,"CFB1"))
len=bint2bin(ibuf+13,strlen(ibuf+13)-1,ciphertext);
else
len = hex2bin(ibuf+13,strlen(ibuf+13)-1,ciphertext);
if (len < 0)
{
printf("Invalid CIPHERTEXT\n");
err =1;
break;
}
PrintValue("CIPHERTEXT", ciphertext, len);
if (strcmp(atest, "Monte") == 0) /* Monte Carlo Test */
{
do_mct(amode, akeysz, numkeys, aKey, iVec,
dir, ciphertext, len, rfp);
}
else
{
assert(dir == 0);
ret = DESTest(&ctx, amode, akeysz, aKey, iVec,
dir, /* 0 = decrypt, 1 = encrypt */
plaintext, ciphertext, len);
OutputValue("PLAINTEXT",(unsigned char *)plaintext,len,rfp,
!strcmp(amode,"CFB1"));
}
step = 6;
}
break;
case 6:
if (ibuf[0] != '\n')
{
err = 1;
printf("Missing terminator\n");
}
else if (strcmp(atest, "MCT") != 0)
{ /* MCT already added terminating nl */
fputs(ibuf, rfp);
}
step = 1;
break;
}
}
if (rfp)
fclose(rfp);
if (afp)
fclose(afp);
return err;
}
BOOL PrintComponent::WriteEPSComments(EPSFilter *pFilter)
{
// Graeme (23-5-00) - Neither AI nor ArtWorks files need the print control entries, so
// just return TRUE to avoid problems.
if ( !pFilter->NeedsPrintComponents () )
{
return TRUE;
}
ERROR2IF ( pPrCtrl == NULL, FALSE,
"No print control to output in PrintComponent::WriteEPSComments()" );
// Set up the export DC ptr
pExportDC = pFilter->GetExportDC();
ERROR2IF(pExportDC == NULL,FALSE,"Export DC is NULL in PrintComponent::WriteEPSComments()");
BOOL ok = TRUE;
if (ok) ok = OutputValue(PCTOKEN_SECTIONNAME, PC_SECTION_VERSION);
if (ok) ok = OutputValue(PCTOKEN_WHOLESPREAD, pPrCtrl->IsWholeSpread());
if (ok) ok = OutputValue(PCTOKEN_SCALE, pPrCtrl->GetScale());
if (ok) ok = OutputValue(PCTOKEN_ORIENTATION, pPrCtrl->GetPrintOrient());
if (ok) ok = OutputValue(PCTOKEN_FITTYPE, pPrCtrl->GetFitType());
if (ok) ok = OutputValue(PCTOKEN_TOPMARGIN, pPrCtrl->GetTopMargin());
if (ok) ok = OutputValue(PCTOKEN_LEFTMARGIN, pPrCtrl->GetLeftMargin());
if (ok) ok = OutputValue(PCTOKEN_WIDTH, pPrCtrl->GetWidth());
if (ok) ok = OutputValue(PCTOKEN_HEIGHT, pPrCtrl->GetHeight());
if (ok) ok = OutputValue(PCTOKEN_ROWS, pPrCtrl->GetRows());
if (ok) ok = OutputValue(PCTOKEN_COLUMNS, pPrCtrl->GetColumns());
if (ok) ok = OutputValue(PCTOKEN_GUTTER, pPrCtrl->GetGutter());
if (ok) ok = OutputValue(PCTOKEN_LAYERS, pPrCtrl->GetPrintLayers());
if (ok) ok = OutputValue(PCTOKEN_PSLEVEL, pPrCtrl->GetPSLevel());
if (ok) ok = OutputValue(PCTOKEN_BITMAPRESMETHOD, pPrCtrl->GetBitmapResMethod());
// We only need to output the bitmap DPI if the user has selected 'manual' bitmap DPI
// Auto DPI will calculated the DPI automatically ( surprise, surprise - Cilla 'ere!)
// This also means that the printer's DPI is not needed before saving, hence avoiding any unnecessary
// delays.
if (ok)
{
if (pPrCtrl->GetBitmapResMethod() == BITMAPRES_MANUAL)
ok = OutputValue(PCTOKEN_DOTSPERINCH, pPrCtrl->GetDotsPerInch());
else
ok = OutputValue(PCTOKEN_DOTSPERINCH, 150);
}
if (ok) ok = OutputValue(PCTOKEN_COLLATED, pPrCtrl->IsCollated());
if (ok) ok = OutputValue(PCTOKEN_NUMCOPIES, pPrCtrl->GetNumCopies());
if (ok) ok = OutputValue(PCTOKEN_PRINTTOFILE, pPrCtrl->GetPrintToFile());
if (ok) ok = OutputValue(PCTOKEN_OBJPRINTRANGE, pPrCtrl->GetObjPrintRange());
if (ok) ok = OutputValue(PCTOKEN_DPSPRINTRANGE, pPrCtrl->GetDPSPrintRange());
if (ok) ok = OutputValue(PCTOKEN_ALLTEXTASSHAPES, pPrCtrl->GetTextOptions());
// if (ok) ok = OutputValue(PCTOKEN_PRINTMETHOD, pPrCtrl->GetPrintMethod());
// reset the DC ptr to NULL (ready for next time)
pExportDC = NULL;
return ok;
}
static int proc_file(char *rqfile, char *rspfile)
{
char afn[256], rfn[256];
FILE *afp = NULL, *rfp = NULL;
char ibuf[2048];
char tbuf[2048];
int ilen, len, ret = 0;
char algo[8] = "";
char amode[8] = "";
char atest[8] = "";
int akeysz = 0;
unsigned char iVec[20], aKey[40];
int dir = -1, err = 0, step = 0;
unsigned char plaintext[2048];
unsigned char ciphertext[2048];
char *rp;
EVP_CIPHER_CTX ctx;
FIPS_cipher_ctx_init(&ctx);
if (!rqfile || !(*rqfile))
{
printf("No req file\n");
return -1;
}
strcpy(afn, rqfile);
if ((afp = fopen(afn, "r")) == NULL)
{
printf("Cannot open file: %s, %s\n",
afn, strerror(errno));
return -1;
}
if (!rspfile)
{
strcpy(rfn,afn);
rp=strstr(rfn,"req/");
#ifdef OPENSSL_SYS_WIN32
if (!rp)
rp=strstr(rfn,"req\\");
#endif
assert(rp);
memcpy(rp,"rsp",3);
rp = strstr(rfn, ".req");
memcpy(rp, ".rsp", 4);
rspfile = rfn;
}
if ((rfp = fopen(rspfile, "w")) == NULL)
{
printf("Cannot open file: %s, %s\n",
rfn, strerror(errno));
fclose(afp);
afp = NULL;
return -1;
}
while (!err && (fgets(ibuf, sizeof(ibuf), afp)) != NULL)
{
tidy_line(tbuf, ibuf);
ilen = strlen(ibuf);
/* printf("step=%d ibuf=%s",step,ibuf); */
switch (step)
{
case 0: /* read preamble */
if (ibuf[0] == '\n')
{ /* end of preamble */
if ((*algo == '\0') ||
(*amode == '\0') ||
(akeysz == 0))
{
printf("Missing Algorithm, Mode or KeySize (%s/%s/%d)\n",
algo,amode,akeysz);
err = 1;
}
else
{
fputs(ibuf, rfp);
++ step;
}
}
else if (ibuf[0] != '#')
{
printf("Invalid preamble item: %s\n", ibuf);
err = 1;
}
else
{ /* process preamble */
char *xp, *pp = ibuf+2;
int n;
if (akeysz)
{ /* insert current time & date */
time_t rtim = time(0);
fprintf(rfp, "# %s", ctime(&rtim));
}
else
{
fputs(ibuf, rfp);
if (strncmp(pp, "AESVS ", 6) == 0)
{
strcpy(algo, "AES");
/* get test type */
pp += 6;
xp = strchr(pp, ' ');
n = xp-pp;
strncpy(atest, pp, n);
atest[n] = '\0';
/* get mode */
xp = strrchr(pp, ' '); /* get mode" */
n = strlen(xp+1)-1;
strncpy(amode, xp+1, n);
amode[n] = '\0';
/* amode[3] = '\0'; */
if (VERBOSE)
printf("Test = %s, Mode = %s\n", atest, amode);
}
else if (strncasecmp(pp, "Key Length : ", 13) == 0)
{
akeysz = atoi(pp+13);
if (VERBOSE)
printf("Key size = %d\n", akeysz);
}
}
}
break;
case 1: /* [ENCRYPT] | [DECRYPT] */
if (ibuf[0] == '[')
{
fputs(ibuf, rfp);
++step;
if (strncasecmp(ibuf, "[ENCRYPT]", 9) == 0)
dir = 1;
else if (strncasecmp(ibuf, "[DECRYPT]", 9) == 0)
dir = 0;
else
{
printf("Invalid keyword: %s\n", ibuf);
err = 1;
}
break;
}
else if (dir == -1)
{
err = 1;
printf("Missing ENCRYPT/DECRYPT keyword\n");
break;
}
else
step = 2;
case 2: /* KEY = xxxx */
fputs(ibuf, rfp);
if(*ibuf == '\n')
break;
if(!strncasecmp(ibuf,"COUNT = ",8))
break;
if (strncasecmp(ibuf, "KEY = ", 6) != 0)
{
printf("Missing KEY\n");
err = 1;
}
else
{
len = hex2bin((char*)ibuf+6, aKey);
if (len < 0)
{
printf("Invalid KEY\n");
err =1;
break;
}
PrintValue("KEY", aKey, len);
if (strcmp(amode, "ECB") == 0)
{
memset(iVec, 0, sizeof(iVec));
step = (dir)? 4: 5; /* no ivec for ECB */
}
else
++step;
}
break;
case 3: /* IV = xxxx */
fputs(ibuf, rfp);
if (strncasecmp(ibuf, "IV = ", 5) != 0)
{
printf("Missing IV\n");
err = 1;
}
else
{
len = hex2bin((char*)ibuf+5, iVec);
if (len < 0)
{
printf("Invalid IV\n");
err =1;
break;
}
PrintValue("IV", iVec, len);
step = (dir)? 4: 5;
}
break;
case 4: /* PLAINTEXT = xxxx */
fputs(ibuf, rfp);
if (strncasecmp(ibuf, "PLAINTEXT = ", 12) != 0)
{
printf("Missing PLAINTEXT\n");
err = 1;
}
else
{
int nn = strlen(ibuf+12);
if(!strcmp(amode,"CFB1"))
len=bint2bin(ibuf+12,nn-1,plaintext);
else
len=hex2bin(ibuf+12, plaintext);
if (len < 0)
{
printf("Invalid PLAINTEXT: %s", ibuf+12);
err =1;
break;
}
if (len >= (int)sizeof(plaintext))
{
printf("Buffer overflow\n");
}
PrintValue("PLAINTEXT", (unsigned char*)plaintext, len);
if (strcmp(atest, "MCT") == 0) /* Monte Carlo Test */
{
if(do_mct(amode, akeysz, aKey, iVec,
dir, (unsigned char*)plaintext, len,
rfp) < 0)
EXIT(1);
}
else
{
ret = AESTest(&ctx, amode, akeysz, aKey, iVec,
dir, /* 0 = decrypt, 1 = encrypt */
plaintext, ciphertext, len);
OutputValue("CIPHERTEXT",ciphertext,len,rfp,
!strcmp(amode,"CFB1"));
}
step = 6;
}
break;
case 5: /* CIPHERTEXT = xxxx */
fputs(ibuf, rfp);
if (strncasecmp(ibuf, "CIPHERTEXT = ", 13) != 0)
{
printf("Missing KEY\n");
err = 1;
}
else
{
if(!strcmp(amode,"CFB1"))
len=bint2bin(ibuf+13,strlen(ibuf+13)-1,ciphertext);
else
len = hex2bin(ibuf+13,ciphertext);
if (len < 0)
{
printf("Invalid CIPHERTEXT\n");
err =1;
break;
}
PrintValue("CIPHERTEXT", ciphertext, len);
if (strcmp(atest, "MCT") == 0) /* Monte Carlo Test */
{
do_mct(amode, akeysz, aKey, iVec,
dir, ciphertext, len, rfp);
}
else
{
ret = AESTest(&ctx, amode, akeysz, aKey, iVec,
dir, /* 0 = decrypt, 1 = encrypt */
plaintext, ciphertext, len);
OutputValue("PLAINTEXT",(unsigned char *)plaintext,len,rfp,
!strcmp(amode,"CFB1"));
}
step = 6;
}
break;
case 6:
if (ibuf[0] != '\n')
{
err = 1;
printf("Missing terminator\n");
}
else if (strcmp(atest, "MCT") != 0)
{ /* MCT already added terminating nl */
fputs(ibuf, rfp);
}
step = 1;
break;
}
}
if (rfp)
fclose(rfp);
if (afp)
fclose(afp);
return err;
}
static void pqg(FILE *in, FILE *out)
{
char buf[1024];
char lbuf[1024];
char *keyword, *value;
int dsa2, L, N;
const EVP_MD *md = NULL;
while(fgets(buf,sizeof buf,in) != NULL)
{
if (!parse_line(&keyword, &value, lbuf, buf))
{
fputs(buf,out);
continue;
}
if(!strcmp(keyword,"[mod"))
{
fputs(buf,out);
if (!parse_mod(value, &dsa2, &L, &N, &md))
{
fprintf(stderr, "Mod Parse Error\n");
exit (1);
}
}
else if(!strcmp(keyword,"N"))
{
int n=atoi(value);
while(n--)
{
unsigned char seed[EVP_MAX_MD_SIZE];
DSA *dsa;
int counter;
unsigned long h;
dsa = FIPS_dsa_new();
if (!dsa2 && !dsa_builtin_paramgen(dsa, L, N, md,
NULL, 0, seed,
&counter, &h, NULL))
{
fprintf(stderr, "Parameter Generation error\n");
exit(1);
}
if (dsa2 && dsa_builtin_paramgen2(dsa, L, N, md,
NULL, 0, seed,
&counter, &h, NULL) <= 0)
{
fprintf(stderr, "Parameter Generation error\n");
exit(1);
}
do_bn_print_name(out, "P",dsa->p);
do_bn_print_name(out, "Q",dsa->q);
do_bn_print_name(out, "G",dsa->g);
OutputValue("Seed",seed, M_EVP_MD_size(md), out, 0);
fprintf(out, "c = %d\n",counter);
fprintf(out, "H = %lx\n\n",h);
}
}
else
fputs(buf,out);
}
}
static int do_mct(char *amode,
int akeysz, unsigned char *aKey,unsigned char *iVec,
int dir, unsigned char *text, int len,
FILE *rfp)
{
int ret = 0;
unsigned char key[101][32];
unsigned char iv[101][AES_BLOCK_SIZE];
unsigned char ptext[1001][32];
unsigned char ctext[1001][32];
unsigned char ciphertext[64+4];
int i, j, n, n1, n2;
int imode = 0, nkeysz = akeysz/8;
EVP_CIPHER_CTX ctx;
FIPS_cipher_ctx_init(&ctx);
if (len > 32)
{
printf("\n>>>> Length exceeds 32 for %s %d <<<<\n\n",
amode, akeysz);
return -1;
}
for (imode = 0; imode < 6; ++imode)
if (strcmp(amode, t_mode[imode]) == 0)
break;
if (imode == 6)
{
printf("Unrecognized mode: %s\n", amode);
return -1;
}
memcpy(key[0], aKey, nkeysz);
if (iVec)
memcpy(iv[0], iVec, AES_BLOCK_SIZE);
if (dir == XENCRYPT)
memcpy(ptext[0], text, len);
else
memcpy(ctext[0], text, len);
for (i = 0; i < 100; ++i)
{
/* printf("Iteration %d\n", i); */
if (i > 0)
{
fprintf(rfp,"COUNT = %d\n",i);
OutputValue("KEY",key[i],nkeysz,rfp,0);
if (imode != ECB) /* ECB */
OutputValue("IV",iv[i],AES_BLOCK_SIZE,rfp,0);
/* Output Ciphertext | Plaintext */
OutputValue(t_tag[dir^1],dir ? ptext[0] : ctext[0],len,rfp,
imode == CFB1);
}
for (j = 0; j < 1000; ++j)
{
switch (imode)
{
case ECB:
if (j == 0)
{ /* set up encryption */
ret = AESTest(&ctx, amode, akeysz, key[i], NULL,
dir, /* 0 = decrypt, 1 = encrypt */
ptext[j], ctext[j], len);
if (dir == XENCRYPT)
memcpy(ptext[j+1], ctext[j], len);
else
memcpy(ctext[j+1], ptext[j], len);
}
else
{
if (dir == XENCRYPT)
{
FIPS_cipher(&ctx, ctext[j], ptext[j], len);
memcpy(ptext[j+1], ctext[j], len);
}
else
{
FIPS_cipher(&ctx, ptext[j], ctext[j], len);
memcpy(ctext[j+1], ptext[j], len);
}
}
break;
case CBC:
case OFB:
case CFB128:
if (j == 0)
{
ret = AESTest(&ctx, amode, akeysz, key[i], iv[i],
dir, /* 0 = decrypt, 1 = encrypt */
ptext[j], ctext[j], len);
if (dir == XENCRYPT)
memcpy(ptext[j+1], iv[i], len);
else
memcpy(ctext[j+1], iv[i], len);
}
else
{
if (dir == XENCRYPT)
{
FIPS_cipher(&ctx, ctext[j], ptext[j], len);
memcpy(ptext[j+1], ctext[j-1], len);
}
else
{
FIPS_cipher(&ctx, ptext[j], ctext[j], len);
memcpy(ctext[j+1], ptext[j-1], len);
}
}
break;
case CFB8:
if (j == 0)
{
ret = AESTest(&ctx, amode, akeysz, key[i], iv[i],
dir, /* 0 = decrypt, 1 = encrypt */
ptext[j], ctext[j], len);
}
else
{
if (dir == XENCRYPT)
FIPS_cipher(&ctx, ctext[j], ptext[j], len);
else
FIPS_cipher(&ctx, ptext[j], ctext[j], len);
}
if (dir == XENCRYPT)
{
if (j < 16)
memcpy(ptext[j+1], &iv[i][j], len);
else
memcpy(ptext[j+1], ctext[j-16], len);
}
else
{
if (j < 16)
memcpy(ctext[j+1], &iv[i][j], len);
else
memcpy(ctext[j+1], ptext[j-16], len);
}
break;
case CFB1:
if(j == 0)
{
#if 0
/* compensate for wrong endianness of input file */
if(i == 0)
ptext[0][0]<<=7;
#endif
ret = AESTest(&ctx,amode,akeysz,key[i],iv[i],dir,
ptext[j], ctext[j], len);
}
else
{
if (dir == XENCRYPT)
FIPS_cipher(&ctx, ctext[j], ptext[j], len);
else
FIPS_cipher(&ctx, ptext[j], ctext[j], len);
}
if(dir == XENCRYPT)
{
if(j < 128)
sb(ptext[j+1],0,gb(iv[i],j));
else
sb(ptext[j+1],0,gb(ctext[j-128],0));
}
else
{
if(j < 128)
sb(ctext[j+1],0,gb(iv[i],j));
else
sb(ctext[j+1],0,gb(ptext[j-128],0));
}
break;
}
}
--j; /* reset to last of range */
/* Output Ciphertext | Plaintext */
OutputValue(t_tag[dir],dir ? ctext[j] : ptext[j],len,rfp,
imode == CFB1);
fprintf(rfp, "\n"); /* add separator */
/* Compute next KEY */
if (dir == XENCRYPT)
{
if (imode == CFB8)
{ /* ct = CT[j-15] || CT[j-14] || ... || CT[j] */
for (n1 = 0, n2 = nkeysz-1; n1 < nkeysz; ++n1, --n2)
ciphertext[n1] = ctext[j-n2][0];
}
else if(imode == CFB1)
{
for(n1=0,n2=akeysz-1 ; n1 < akeysz ; ++n1,--n2)
sb(ciphertext,n1,gb(ctext[j-n2],0));
}
else
switch (akeysz)
{
case 128:
memcpy(ciphertext, ctext[j], 16);
break;
case 192:
memcpy(ciphertext, ctext[j-1]+8, 8);
memcpy(ciphertext+8, ctext[j], 16);
break;
case 256:
memcpy(ciphertext, ctext[j-1], 16);
memcpy(ciphertext+16, ctext[j], 16);
break;
}
}
else
{
if (imode == CFB8)
{ /* ct = CT[j-15] || CT[j-14] || ... || CT[j] */
for (n1 = 0, n2 = nkeysz-1; n1 < nkeysz; ++n1, --n2)
ciphertext[n1] = ptext[j-n2][0];
}
else if(imode == CFB1)
{
for(n1=0,n2=akeysz-1 ; n1 < akeysz ; ++n1,--n2)
sb(ciphertext,n1,gb(ptext[j-n2],0));
}
else
switch (akeysz)
{
case 128:
memcpy(ciphertext, ptext[j], 16);
break;
case 192:
memcpy(ciphertext, ptext[j-1]+8, 8);
memcpy(ciphertext+8, ptext[j], 16);
break;
case 256:
memcpy(ciphertext, ptext[j-1], 16);
memcpy(ciphertext+16, ptext[j], 16);
break;
}
}
/* Compute next key: Key[i+1] = Key[i] xor ct */
for (n = 0; n < nkeysz; ++n)
key[i+1][n] = key[i][n] ^ ciphertext[n];
/* Compute next IV and text */
if (dir == XENCRYPT)
{
switch (imode)
{
case ECB:
memcpy(ptext[0], ctext[j], AES_BLOCK_SIZE);
break;
case CBC:
case OFB:
case CFB128:
memcpy(iv[i+1], ctext[j], AES_BLOCK_SIZE);
memcpy(ptext[0], ctext[j-1], AES_BLOCK_SIZE);
break;
case CFB8:
/* IV[i+1] = ct */
for (n1 = 0, n2 = 15; n1 < 16; ++n1, --n2)
iv[i+1][n1] = ctext[j-n2][0];
ptext[0][0] = ctext[j-16][0];
break;
case CFB1:
for(n1=0,n2=127 ; n1 < 128 ; ++n1,--n2)
sb(iv[i+1],n1,gb(ctext[j-n2],0));
ptext[0][0]=ctext[j-128][0]&0x80;
break;
}
}
else
{
switch (imode)
{
case ECB:
memcpy(ctext[0], ptext[j], AES_BLOCK_SIZE);
break;
case CBC:
case OFB:
case CFB128:
memcpy(iv[i+1], ptext[j], AES_BLOCK_SIZE);
memcpy(ctext[0], ptext[j-1], AES_BLOCK_SIZE);
break;
case CFB8:
for (n1 = 0, n2 = 15; n1 < 16; ++n1, --n2)
iv[i+1][n1] = ptext[j-n2][0];
ctext[0][0] = ptext[j-16][0];
break;
case CFB1:
for(n1=0,n2=127 ; n1 < 128 ; ++n1,--n2)
sb(iv[i+1],n1,gb(ptext[j-n2],0));
ctext[0][0]=ptext[j-128][0]&0x80;
break;
}
}
}
return ret;
}
int main(int argc,char **argv)
{
FILE *in, *out;
DRBG_CTX *dctx = NULL;
TEST_ENT t;
int r, nid = 0;
int pr = 0;
char buf[2048], lbuf[2048];
unsigned char randout[2048];
char *keyword = NULL, *value = NULL;
unsigned char *ent = NULL, *nonce = NULL, *pers = NULL, *adin = NULL;
long entlen, noncelen, perslen, adinlen;
int df = 0;
int randoutlen = 0;
int gen = 0;
fips_algtest_init();
if (argc == 3)
{
in = fopen(argv[1], "r");
if (!in)
{
fprintf(stderr, "Error opening input file\n");
exit(1);
}
out = fopen(argv[2], "w");
if (!out)
{
fprintf(stderr, "Error opening output file\n");
exit(1);
}
}
else if (argc == 1)
{
in = stdin;
out = stdout;
}
else
{
fprintf(stderr,"%s (infile outfile)\n",argv[0]);
exit(1);
}
while (fgets(buf, sizeof(buf), in) != NULL)
{
fputs(buf, out);
if (strlen(buf) > 4 && !strncmp(buf, "[SHA-", 5))
{
nid = parse_md(buf);
if (nid == NID_undef)
exit(1);
}
if (strlen(buf) > 12 && !strncmp(buf, "[AES-", 5))
{
nid = parse_aes(buf, &df);
if (nid == NID_undef)
exit(1);
}
if (!parse_line(&keyword, &value, lbuf, buf))
continue;
if (!strcmp(keyword, "[PredictionResistance"))
{
if (!strcmp(value, "True]"))
pr = 1;
else if (!strcmp(value, "False]"))
pr = 0;
else
exit(1);
}
if (!strcmp(keyword, "EntropyInput"))
{
ent = hex2bin_m(value, &entlen);
t.ent = ent;
t.entlen = entlen;
}
if (!strcmp(keyword, "Nonce"))
{
nonce = hex2bin_m(value, &noncelen);
t.nonce = nonce;
t.noncelen = noncelen;
}
if (!strcmp(keyword, "PersonalizationString"))
{
pers = hex2bin_m(value, &perslen);
dctx = FIPS_drbg_new(nid, df | DRBG_FLAG_TEST);
if (!dctx)
exit (1);
FIPS_drbg_set_callbacks(dctx, test_entropy, 0, 0,
test_nonce, 0);
FIPS_drbg_set_app_data(dctx, &t);
randoutlen = (int)FIPS_drbg_get_blocklength(dctx);
r = FIPS_drbg_instantiate(dctx, pers, perslen);
if (!r)
{
fprintf(stderr, "Error instantiating DRBG\n");
exit(1);
}
OPENSSL_free(pers);
OPENSSL_free(ent);
OPENSSL_free(nonce);
ent = nonce = pers = NULL;
gen = 0;
}
if (!strcmp(keyword, "AdditionalInput"))
{
adin = hex2bin_m(value, &adinlen);
if (pr)
continue;
r = FIPS_drbg_generate(dctx, randout, randoutlen, 0, 0,
adin, adinlen);
if (!r)
{
fprintf(stderr, "Error generating DRBG bits\n");
exit(1);
}
if (!r)
exit(1);
OPENSSL_free(adin);
adin = NULL;
gen++;
}
if (pr)
{
if (!strcmp(keyword, "EntropyInputPR"))
{
ent = hex2bin_m(value, &entlen);
t.ent = ent;
t.entlen = entlen;
r = FIPS_drbg_generate(dctx,
randout, randoutlen,
0, 1, adin, adinlen);
if (!r)
{
fprintf(stderr,
"Error generating DRBG bits\n");
exit(1);
}
OPENSSL_free(adin);
OPENSSL_free(ent);
adin = ent = NULL;
gen++;
}
}
if (!strcmp(keyword, "EntropyInputReseed"))
{
ent = hex2bin_m(value, &entlen);
t.ent = ent;
t.entlen = entlen;
}
if (!strcmp(keyword, "AdditionalInputReseed"))
{
adin = hex2bin_m(value, &adinlen);
FIPS_drbg_reseed(dctx, adin, adinlen);
OPENSSL_free(ent);
OPENSSL_free(adin);
ent = adin = NULL;
}
if (gen == 2)
{
OutputValue("ReturnedBits", randout, randoutlen,
out, 0);
FIPS_drbg_free(dctx);
dctx = NULL;
gen = 0;
}
}
return 0;
}
static void pqg(FILE *in, FILE *out)
{
char buf[1024];
char lbuf[1024];
char *keyword, *value;
int dsa2, L, N;
const EVP_MD *md = NULL;
BIGNUM *p = NULL, *q = NULL;
enum pqtype { PQG_NONE, PQG_PQ, PQG_G, PQG_GCANON}
pqg_type = PQG_NONE;
int seedlen=-1, idxlen, idx = -1;
unsigned char seed[1024], idtmp[1024];
while(fgets(buf,sizeof buf,in) != NULL)
{
if (buf[0] == '[')
{
if (strstr(buf, "Probable"))
pqg_type = PQG_PQ;
else if (strstr(buf, "Unverifiable"))
pqg_type = PQG_G;
else if (strstr(buf, "Canonical"))
pqg_type = PQG_GCANON;
}
if (!parse_line(&keyword, &value, lbuf, buf))
{
fputs(buf,out);
continue;
}
if (strcmp(keyword, "Num"))
fputs(buf,out);
if(!strcmp(keyword,"[mod"))
{
if (!parse_mod(value, &dsa2, &L, &N, &md))
{
fprintf(stderr, "Mod Parse Error\n");
exit (1);
}
}
else if(!strcmp(keyword,"N")
|| (!strcmp(keyword, "Num") && pqg_type == PQG_PQ))
{
int n=atoi(value);
while(n--)
{
DSA *dsa;
int counter;
unsigned long h;
dsa = FIPS_dsa_new();
if (!dsa2 && !dsa_builtin_paramgen(dsa, L, N, md,
NULL, 0, seed,
&counter, &h, NULL))
{
fprintf(stderr, "Parameter Generation error\n");
exit(1);
}
if (dsa2 && dsa_builtin_paramgen2(dsa, L, N, md,
NULL, 0, -1, seed,
&counter, &h, NULL) <= 0)
{
fprintf(stderr, "Parameter Generation error\n");
exit(1);
}
do_bn_print_name(out, "P",dsa->p);
do_bn_print_name(out, "Q",dsa->q);
if (!dsa2)
do_bn_print_name(out, "G",dsa->g);
OutputValue(dsa2 ? "domain_parameter_seed" : "Seed",
seed, M_EVP_MD_size(md), out, 0);
if (!dsa2)
{
fprintf(out, "c = %d" RESP_EOL, counter);
fprintf(out, "H = %lx" RESP_EOL RESP_EOL,h);
}
else
{
fprintf(out, "counter = %d" RESP_EOL RESP_EOL, counter);
}
FIPS_dsa_free(dsa);
}
}
else if(!strcmp(keyword,"P"))
p=hex2bn(value);
else if(!strcmp(keyword,"Q"))
q=hex2bn(value);
else if(!strcmp(keyword,"domain_parameter_seed"))
seedlen = hex2bin(value, seed);
else if(!strcmp(keyword,"firstseed"))
seedlen = hex2bin(value, seed);
else if(!strcmp(keyword,"pseed"))
seedlen += hex2bin(value, seed + seedlen);
else if(!strcmp(keyword,"qseed"))
seedlen += hex2bin(value, seed + seedlen);
else if(!strcmp(keyword,"index"))
{
idxlen = hex2bin(value, idtmp);
if (idxlen != 1)
{
fprintf(stderr, "Index value error\n");
exit (1);
}
idx = idtmp[0];
}
if ((idx >= 0 && pqg_type == PQG_GCANON) || (q && pqg_type == PQG_G))
{
DSA *dsa;
dsa = FIPS_dsa_new();
dsa->p = p;
dsa->q = q;
p = q = NULL;
if (dsa_builtin_paramgen2(dsa, L, N, md,
seed, seedlen, idx, NULL,
NULL, NULL, NULL) <= 0)
{
fprintf(stderr, "Parameter Generation error\n");
exit(1);
}
do_bn_print_name(out, "G",dsa->g);
FIPS_dsa_free(dsa);
idx = -1;
}
}
}
int main(int argc,char **argv)
#endif
{
FILE *in, *out;
DRBG_CTX *dctx = NULL;
TEST_ENT t;
int r, nid = 0;
int pr = 0;
char buf[2048], lbuf[2048];
unsigned char randout[2048];
char *keyword = NULL, *value = NULL;
unsigned char *ent = NULL, *nonce = NULL, *pers = NULL, *adin = NULL;
long entlen, noncelen, perslen, adinlen;
int df = 0;
enum dtype { DRBG_NONE, DRBG_CTR, DRBG_HASH, DRBG_HMAC, DRBG_DUAL_EC }
drbg_type = DRBG_NONE;
int randoutlen = 0;
int gen = 0;
fips_algtest_init();
if (argc == 3)
{
in = fopen(argv[1], "r");
if (!in)
{
fprintf(stderr, "Error opening input file\n");
exit(1);
}
out = fopen(argv[2], "w");
if (!out)
{
fprintf(stderr, "Error opening output file\n");
exit(1);
}
}
else if (argc == 1)
{
in = stdin;
out = stdout;
}
else
{
fprintf(stderr,"%s (infile outfile)\n",argv[0]);
exit(1);
}
while (fgets(buf, sizeof(buf), in) != NULL)
{
fputs(buf, out);
if (drbg_type == DRBG_NONE)
{
if (strstr(buf, "CTR_DRBG"))
drbg_type = DRBG_CTR;
else if (strstr(buf, "Hash_DRBG"))
drbg_type = DRBG_HASH;
else if (strstr(buf, "HMAC_DRBG"))
drbg_type = DRBG_HMAC;
else if (strstr(buf, "Dual_EC_DRBG"))
drbg_type = DRBG_DUAL_EC;
else
continue;
}
if (strlen(buf) > 4 && !strncmp(buf, "[SHA-", 5))
{
nid = dparse_md(buf);
if (nid == NID_undef)
exit(1);
if (drbg_type == DRBG_HMAC)
{
switch (nid)
{
case NID_sha1:
nid = NID_hmacWithSHA1;
break;
case NID_sha224:
nid = NID_hmacWithSHA224;
break;
case NID_sha256:
nid = NID_hmacWithSHA256;
break;
case NID_sha384:
nid = NID_hmacWithSHA384;
break;
case NID_sha512:
nid = NID_hmacWithSHA512;
break;
default:
exit(1);
}
}
}
if (strlen(buf) > 12 && !strncmp(buf, "[AES-", 5))
{
nid = parse_aes(buf, &df);
if (nid == NID_undef)
exit(1);
}
if (strlen(buf) > 12 && !strncmp(buf, "[P-", 3))
{
nid = parse_ec(buf);
if (nid == NID_undef)
exit(1);
}
if (!parse_line(&keyword, &value, lbuf, buf))
continue;
if (!strcmp(keyword, "[PredictionResistance"))
{
if (!strcmp(value, "True]"))
pr = 1;
else if (!strcmp(value, "False]"))
pr = 0;
else
exit(1);
}
if (!strcmp(keyword, "EntropyInput"))
{
ent = hex2bin_m(value, &entlen);
t.ent = ent;
t.entlen = entlen;
}
if (!strcmp(keyword, "Nonce"))
{
nonce = hex2bin_m(value, &noncelen);
t.nonce = nonce;
t.noncelen = noncelen;
}
if (!strcmp(keyword, "PersonalizationString"))
{
pers = hex2bin_m(value, &perslen);
if (nid == 0)
{
fprintf(stderr, "DRBG type not recognised!\n");
exit (1);
}
dctx = FIPS_drbg_new(nid, df | DRBG_FLAG_TEST);
if (!dctx)
exit (1);
FIPS_drbg_set_callbacks(dctx, test_entropy, 0, 0,
test_nonce, 0);
FIPS_drbg_set_app_data(dctx, &t);
randoutlen = (int)FIPS_drbg_get_blocklength(dctx);
r = FIPS_drbg_instantiate(dctx, pers, perslen);
if (!r)
{
fprintf(stderr, "Error instantiating DRBG\n");
exit(1);
}
OPENSSL_free(pers);
OPENSSL_free(ent);
OPENSSL_free(nonce);
ent = nonce = pers = NULL;
gen = 0;
}
if (!strcmp(keyword, "AdditionalInput"))
{
adin = hex2bin_m(value, &adinlen);
if (pr)
continue;
r = FIPS_drbg_generate(dctx, randout, randoutlen, 0,
adin, adinlen);
if (!r)
{
fprintf(stderr, "Error generating DRBG bits\n");
exit(1);
}
if (!r)
exit(1);
OPENSSL_free(adin);
adin = NULL;
gen++;
}
if (pr)
{
if (!strcmp(keyword, "EntropyInputPR"))
{
ent = hex2bin_m(value, &entlen);
t.ent = ent;
t.entlen = entlen;
r = FIPS_drbg_generate(dctx,
randout, randoutlen,
1, adin, adinlen);
if (!r)
{
fprintf(stderr,
"Error generating DRBG bits\n");
exit(1);
}
OPENSSL_free(adin);
OPENSSL_free(ent);
adin = ent = NULL;
gen++;
}
}
if (!strcmp(keyword, "EntropyInputReseed"))
{
ent = hex2bin_m(value, &entlen);
t.ent = ent;
t.entlen = entlen;
}
if (!strcmp(keyword, "AdditionalInputReseed"))
{
adin = hex2bin_m(value, &adinlen);
FIPS_drbg_reseed(dctx, adin, adinlen);
OPENSSL_free(ent);
OPENSSL_free(adin);
ent = adin = NULL;
}
if (gen == 2)
{
OutputValue("ReturnedBits", randout, randoutlen,
out, 0);
FIPS_drbg_free(dctx);
dctx = NULL;
gen = 0;
}
}
return 0;
}
static void vst(FILE *in, FILE *out)
{
unsigned char *key = NULL;
unsigned char *v = NULL;
unsigned char *dt = NULL;
unsigned char ret[16];
char buf[1024];
char lbuf[1024];
uint8_t seed[1024];
char *keyword, *value;
long i, keylen;
struct session_op session = {
.rng = CRYPTO_ANSI_CPRNG,
.key = seed
};
struct crypt_op op = {
.dst = ret,
.len = 16
};
keylen = 0;
while(fgets(buf,sizeof buf,in) != NULL)
{
fputs(buf,out);
if(!strncmp(buf,"[AES 128-Key]", 13))
keylen = 16;
else if(!strncmp(buf,"[AES 192-Key]", 13))
keylen = 24;
else if(!strncmp(buf,"[AES 256-Key]", 13))
keylen = 32;
if (!parse_line(&keyword, &value, lbuf, buf))
continue;
if(!strcmp(keyword,"Key"))
{
key=hex2bin_m(value,&i);
if (i != keylen)
{
fprintf(stderr, "Invalid key length, expecting %ld\n", keylen);
return;
}
}
else if(!strcmp(keyword,"DT"))
{
dt=hex2bin_m(value,&i);
if (i != 16)
{
fprintf(stderr, "Invalid DT length\n");
return;
}
}
else if(!strcmp(keyword,"V"))
{
v=hex2bin_m(value,&i);
if (i != 16)
{
fprintf(stderr, "Invalid V length\n");
return;
}
if (!key || !dt)
{
fprintf(stderr, "Missing key or DT\n");
return;
}
session.keylen = build_seed(seed, v, key, dt, keylen);
if (session.keylen > sizeof(seed)/sizeof(*seed)) {
fprintf(stderr, "Seed buffer overrun\n");
return;
}
if (!cryptodev_op(session,op))
{
fprintf(stderr, "Error getting PRNG value\n");
return;
}
OutputValue("R", ret, 16, out, 0);
OPENSSL_free(key);
key = NULL;
OPENSSL_free(dt);
dt = NULL;
OPENSSL_free(v);
v = NULL;
}
}
}
static void mct(FILE *in, FILE *out)
{
unsigned char *key = NULL;
unsigned char *v = NULL;
unsigned char *dt = NULL;
unsigned char ret[16];
char buf[1024];
char lbuf[1024];
uint8_t seed[1024];
char *keyword, *value;
long i, keylen;
int cryptofd;
struct session_op session = {
.rng = CRYPTO_ANSI_CPRNG,
.key = seed
};
struct crypt_op op = {
.dst = ret,
.len = 16
};
keylen = 0;
while(fgets(buf,sizeof buf,in) != NULL)
{
fputs(buf,out);
if(!strncmp(buf,"[AES 128-Key]", 13))
keylen = 16;
else if(!strncmp(buf,"[AES 192-Key]", 13))
keylen = 24;
else if(!strncmp(buf,"[AES 256-Key]", 13))
keylen = 32;
if (!parse_line(&keyword, &value, lbuf, buf))
continue;
if(!strcmp(keyword,"Key"))
{
key=hex2bin_m(value,&i);
if (i != keylen)
{
fprintf(stderr, "Invalid key length, expecting %ld\n", keylen);
return;
}
}
else if(!strcmp(keyword,"DT"))
{
dt=hex2bin_m(value,&i);
if (i != 16)
{
fprintf(stderr, "Invalid DT length\n");
return;
}
}
else if(!strcmp(keyword,"V"))
{
v=hex2bin_m(value,&i);
if (i != 16)
{
fprintf(stderr, "Invalid V length\n");
return;
}
if (!key || !dt)
{
fprintf(stderr, "Missing key or DT\n");
return;
}
session.keylen = build_seed(seed, v, key, dt, keylen);
if (session.keylen > sizeof(seed)/sizeof(*seed)) {
fprintf(stderr, "Seed buffer overrun\n");
return;
}
cryptodev_start_session(&session, &cryptofd);
for (i = 0; i < 10000; i++)
{
if (cryptodev_session_op(session, cryptofd, op) <= 0)
{
fprintf(stderr, "Error getting PRNG value\n");
return;
}
}
cryptodev_end_session(session, cryptofd);
OutputValue("R", ret, 16, out, 0);
OPENSSL_free(key);
key = NULL;
OPENSSL_free(dt);
dt = NULL;
OPENSSL_free(v);
v = NULL;
}
}
}
#ifdef FIPS_ALGVS
int fips_rngvs_main(int argc, char **argv)
#else
int main(int argc, char **argv)
#endif
{
FILE *in, *out;
if (argc == 4)
{
in = fopen(argv[2], "r");
if (!in)
{
fprintf(stderr, "Error opening input file\n");
exit(1);
}
out = fopen(argv[3], "w");
if (!out)
{
fprintf(stderr, "Error opening output file\n");
exit(1);
}
}
else if (argc == 2)
{
in = stdin;
out = stdout;
}
else
{
fprintf(stderr,"%s [mct|vst]\n",argv[0]);
exit(1);
}
if(!strcmp(argv[1],"mct"))
mct(in, out);
else if(!strcmp(argv[1],"vst"))
vst(in, out);
else
{
fprintf(stderr,"Don't know how to %s.\n",argv[1]);
exit(1);
}
if (argc == 4)
{
fclose(in);
fclose(out);
}
return 0;
}
HeapTuple
_rserv_log_()
#endif
{
Trigger *trigger; /* to get trigger name */
int nargs; /* # of args specified in CREATE TRIGGER */
char **args; /* argument: argnum */
Relation rel; /* triggered relation */
HeapTuple tuple; /* tuple to return */
HeapTuple newtuple = NULL; /* tuple to return */
TupleDesc tupdesc; /* tuple description */
int keynum;
char *key;
char *okey;
char *newkey = NULL;
int deleted;
char sql[8192];
char outbuf[8192];
char oidbuf[64];
int ret;
/* Called by trigger manager ? */
if (!CurrentTriggerData)
/* internal error */
elog(ERROR, "_rserv_log_: triggers are not initialized");
/* Should be called for ROW trigger */
if (TRIGGER_FIRED_FOR_STATEMENT(CurrentTriggerData->tg_event))
/* internal error */
elog(ERROR, "_rserv_log_: can't process STATEMENT events");
tuple = CurrentTriggerData->tg_trigtuple;
trigger = CurrentTriggerData->tg_trigger;
nargs = trigger->tgnargs;
args = trigger->tgargs;
if (nargs != 1) /* odd number of arguments! */
/* internal error */
elog(ERROR, "_rserv_log_: need in *one* argument");
keynum = atoi(args[0]);
if (keynum < 0 && keynum != ObjectIdAttributeNumber)
/* internal error */
elog(ERROR, "_rserv_log_: invalid keynum %d", keynum);
rel = CurrentTriggerData->tg_relation;
tupdesc = rel->rd_att;
deleted = (TRIGGER_FIRED_BY_DELETE(CurrentTriggerData->tg_event)) ?
1 : 0;
if (TRIGGER_FIRED_BY_UPDATE(CurrentTriggerData->tg_event))
newtuple = CurrentTriggerData->tg_newtuple;
#ifndef PG_FUNCTION_INFO_V1
/*
* Setting CurrentTriggerData to NULL prevents direct calls to trigger
* functions in queries. Normally, trigger functions have to be called
* by trigger manager code only.
*/
CurrentTriggerData = NULL;
#endif
/* Connect to SPI manager */
if ((ret = SPI_connect()) < 0)
/* internal error */
elog(ERROR, "_rserv_log_: SPI_connect returned %d", ret);
if (keynum == ObjectIdAttributeNumber)
{
snprintf(oidbuf, sizeof(oidbuf), "%u", HeapTupleGetOid(tuple));
key = oidbuf;
}
else
key = SPI_getvalue(tuple, tupdesc, keynum);
if (key == NULL)
ereport(ERROR,
(errcode(ERRCODE_NOT_NULL_VIOLATION),
errmsg("key must be not null")));
if (newtuple && keynum != ObjectIdAttributeNumber)
{
newkey = SPI_getvalue(newtuple, tupdesc, keynum);
if (newkey == NULL)
ereport(ERROR,
(errcode(ERRCODE_NOT_NULL_VIOLATION),
errmsg("key must be not null")));
if (strcmp(newkey, key) == 0)
newkey = NULL;
else
deleted = 1; /* old key was deleted */
}
if (strpbrk(key, "\\ \n'"))
okey = OutputValue(key, outbuf, sizeof(outbuf));
else
okey = key;
snprintf(sql, 8192, "update _RSERV_LOG_ set logid = %d, logtime = now(), "
"deleted = %d where reloid = %u and key = '%s'",
GetCurrentTransactionId(), deleted, rel->rd_id, okey);
if (debug)
elog(DEBUG4, "sql: %s", sql);
ret = SPI_exec(sql, 0);
if (ret < 0)
ereport(ERROR,
(errcode(ERRCODE_TRIGGERED_ACTION_EXCEPTION),
errmsg("SPI_exec(update) returned %d", ret)));
/*
* If no tuple was UPDATEd then do INSERT...
*/
if (SPI_processed > 1)
ereport(ERROR,
(errcode(ERRCODE_TRIGGERED_ACTION_EXCEPTION),
errmsg("duplicate tuples")));
else if (SPI_processed == 0)
{
snprintf(sql, 8192, "insert into _RSERV_LOG_ "
"(reloid, logid, logtime, deleted, key) "
"values (%u, %d, now(), %d, '%s')",
rel->rd_id, GetCurrentTransactionId(),
deleted, okey);
if (debug)
elog(DEBUG4, "sql: %s", sql);
ret = SPI_exec(sql, 0);
if (ret < 0)
ereport(ERROR,
(errcode(ERRCODE_TRIGGERED_ACTION_EXCEPTION),
errmsg("SPI_exec(insert) returned %d", ret)));
}
if (okey != key && okey != outbuf)
pfree(okey);
if (newkey)
{
if (strpbrk(newkey, "\\ \n'"))
okey = OutputValue(newkey, outbuf, sizeof(outbuf));
else
okey = newkey;
snprintf(sql, 8192, "insert into _RSERV_LOG_ "
"(reloid, logid, logtime, deleted, key) "
"values (%u, %d, now(), 0, '%s')",
rel->rd_id, GetCurrentTransactionId(), okey);
if (debug)
elog(DEBUG4, "sql: %s", sql);
ret = SPI_exec(sql, 0);
if (ret < 0)
ereport(ERROR,
(errcode(ERRCODE_TRIGGERED_ACTION_EXCEPTION),
errmsg("SPI_exec returned %d", ret)));
if (okey != newkey && okey != outbuf)
pfree(okey);
}
SPI_finish();
#ifdef PG_FUNCTION_INFO_V1
return (PointerGetDatum(tuple));
#else
return (tuple);
#endif
}
void do_mct(char *amode,
int akeysz, int numkeys, unsigned char *akey,unsigned char *ivec,
int dir, unsigned char *text, int len,
FILE *rfp)
{
int i,imode;
unsigned char nk[4*8]; /* longest key+8 */
unsigned char text0[8];
for (imode=0 ; imode < 6 ; ++imode)
if(!strcmp(amode,t_mode[imode]))
break;
if (imode == 6)
{
printf("Unrecognized mode: %s\n", amode);
EXIT(1);
}
for(i=0 ; i < 400 ; ++i)
{
int j;
int n;
EVP_CIPHER_CTX ctx;
int kp=akeysz/64;
unsigned char old_iv[8];
fprintf(rfp,"\nCOUNT = %d\n",i);
if(kp == 1)
OutputValue("KEY",akey,8,rfp,0);
else
for(n=0 ; n < kp ; ++n)
{
fprintf(rfp,"KEY%d",n+1);
OutputValue("",akey+n*8,8,rfp,0);
}
if(imode != ECB)
OutputValue("IV",ivec,8,rfp,0);
OutputValue(t_tag[dir^1],text,len,rfp,imode == CFB1);
/* compensate for endianness */
if(imode == CFB1)
text[0]<<=7;
memcpy(text0,text,8);
for(j=0 ; j < 10000 ; ++j)
{
unsigned char old_text[8];
memcpy(old_text,text,8);
if(j == 0)
{
memcpy(old_iv,ivec,8);
DESTest(&ctx,amode,akeysz,akey,ivec,dir,text,text,len);
}
else
{
memcpy(old_iv,ctx.iv,8);
EVP_Cipher(&ctx,text,text,len);
}
if(j == 9999)
{
OutputValue(t_tag[dir],text,len,rfp,imode == CFB1);
/* memcpy(ivec,text,8); */
}
/* DebugValue("iv",ctx.iv,8); */
/* accumulate material for the next key */
shiftin(nk,text,Sizes[imode]);
/* DebugValue("nk",nk,24);*/
if((dir && (imode == CFB1 || imode == CFB8 || imode == CFB64
|| imode == CBC)) || imode == OFB)
memcpy(text,old_iv,8);
if(!dir && (imode == CFB1 || imode == CFB8 || imode == CFB64))
{
/* the test specifies using the output of the raw DES operation
which we don't have, so reconstruct it... */
for(n=0 ; n < 8 ; ++n)
text[n]^=old_text[n];
}
}
for(n=0 ; n < 8 ; ++n)
akey[n]^=nk[16+n];
for(n=0 ; n < 8 ; ++n)
akey[8+n]^=nk[8+n];
for(n=0 ; n < 8 ; ++n)
akey[16+n]^=nk[n];
if(numkeys < 3)
memcpy(&akey[2*8],akey,8);
if(numkeys < 2)
memcpy(&akey[8],akey,8);
DES_set_odd_parity((DES_cblock *)akey);
DES_set_odd_parity((DES_cblock *)(akey+8));
DES_set_odd_parity((DES_cblock *)(akey+16));
memcpy(ivec,ctx.iv,8);
/* pointless exercise - the final text doesn't depend on the
initial text in OFB mode, so who cares what it is? (Who
designed these tests?) */
if(imode == OFB)
for(n=0 ; n < 8 ; ++n)
text[n]=text0[n]^old_iv[n];
}
}
