Windows2000/private/ntos/w32/ntgdi/icm/adobe/jan99/dll32/getcrd.c

#include "generic.h"
#include "stdio.h"
#pragma code_seg(_ICMSEG)

char ICMSEG BeginString[] = "<";
char ICMSEG EndString[] = ">";
char ICMSEG BeginArray[] = "[";
char ICMSEG EndArray[] = "]";
char ICMSEG BeginFunction[] = "{";
char ICMSEG EndFunction[] = "}bind ";
char ICMSEG BeginDict[] = "<<";
char ICMSEG EndDict[] = ">>";
char ICMSEG BlackPoint[] = "[0 0 0]";
char ICMSEG DictType[] = "/ColorRenderingType 1 ";
char ICMSEG IntentType[] = "/RenderingIntent ";
char ICMSEG IntentPer[] = "/Perceptual";
char ICMSEG IntentSat[] = "/Saturation";
char ICMSEG IntentACol[] = "/AbsoluteColorimetric";
char ICMSEG IntentRCol[] = "/RelativeColorimetric";

char ICMSEG WhitePointTag[] = "/WhitePoint ";
char ICMSEG BlackPointTag[] = "/BlackPoint ";
char ICMSEG RangePQRTag[] = "/RangePQR ";
char ICMSEG TransformPQRTag[] = "/TransformPQR ";
char ICMSEG MatrixPQRTag[] = "/MatrixPQR ";

char ICMSEG RangeABCTag[] = "/RangeABC ";
char ICMSEG MatrixATag[] = "/MatrixA ";
char ICMSEG MatrixABCTag[] = "/MatrixABC ";
char ICMSEG EncodeABCTag[] = "/EncodeABC ";
char ICMSEG RangeLMNTag[] = "/RangeLMN ";
char ICMSEG MatrixLMNTag[] = "/MatrixLMN ";
char ICMSEG EncodeLMNTag[] = "/EncodeLMN ";
char ICMSEG RenderTableTag[] = "/RenderTable ";
char ICMSEG CIEBasedATag[] = "/CIEBasedA ";
char ICMSEG CIEBasedABCTag[] = "/CIEBasedABC ";
char ICMSEG CIEBasedDEFGTag[] = "/CIEBasedDEFG ";
char ICMSEG CIEBasedDEFTag[] = "/CIEBasedDEF ";
char ICMSEG DecodeATag[] = "/DecodeA ";
char ICMSEG DecodeABCTag[] = "/DecodeABC ";
char ICMSEG DecodeLMNTag[] = "/DecodeLMN ";
char ICMSEG DeviceRGBTag[] = "/DeviceRGB ";
char ICMSEG DeviceCMYKTag[] = "/DeviceCMYK ";
char ICMSEG DeviceGrayTag[] = "/DeviceGray ";
char ICMSEG TableTag[] = "/Table ";
char ICMSEG DecodeDEFGTag[] = "/DecodeDEFG ";
char ICMSEG DecodeDEFTag[] = "/DecodeDEF ";

char ICMSEG NullOp[] = "";
char ICMSEG DupOp[] = "dup ";
char ICMSEG UserDictOp[] = "userdict ";
char ICMSEG GlobalDictOp[] = "globaldict ";
char ICMSEG CurrentGlobalOp[] = "currentglobal ";
char ICMSEG SetGlobalOp[] = "setglobal ";
char ICMSEG DefOp[] = "def ";
char ICMSEG BeginOp[] = "begin ";
char ICMSEG EndOp[] = "end ";
char ICMSEG TrueOp[] = "true ";
char ICMSEG FalseOp[] = "false ";
char ICMSEG MulOp[] = "mul ";
char ICMSEG DivOp[] = "div ";

char ICMSEG NewLine[] = "\n";
char ICMSEG Slash[] = "/";
char ICMSEG Space[] = " ";
char ICMSEG CRDBegin[] = "%** CRD Begin ";
char ICMSEG CRDEnd[] = "%** CRD End ";
char ICMSEG CieBasedDEFGBegin[] = "%** CieBasedDEFG CSA Begin ";
char ICMSEG CieBasedDEFBegin[] = "%** CieBasedDEF CSA Begin ";
char ICMSEG CieBasedABCBegin[] = "%** CieBasedABC CSA Begin ";
char ICMSEG CieBasedABegin[] = "%** CieBasedA CSA Begin ";
char ICMSEG CieBasedDEFGEnd[] = "%** CieBasedDEFG CSA End ";
char ICMSEG CieBasedDEFEnd[] = "%** CieBasedDEF CSA End ";
char ICMSEG CieBasedABCEnd[] = "%** CieBasedABC CSA End ";
char ICMSEG CieBasedAEnd[] = "%** CieBasedA CSA End ";
char ICMSEG RangeABC[] = "[ 0 1 0 1 0 1 ] ";
char ICMSEG RangeLMN[] = "[ 0 2 0 2 0 2 ] ";
char ICMSEG Identity[] = "[1 0 0 0 1 0 0 0 1]";
char ICMSEG RangeABC_Lab[] = "[0 100 -128 127 -128 127]";

/********** This PostScript code clips incoming value between 0.0 and 1.0
   Use:   x <clip>   --   <clipped x>                                   */
char ICMSEG Clip01[] = "dup 1.0 ge{pop 1.0}{dup 0.0 lt{pop 0.0}if}ifelse ";
char ICMSEG DecodeA3[] = "256 div exp ";
char ICMSEG DecodeA3Rev[] = "256 div 1.0 exch div exp ";
char ICMSEG DecodeABCArray[] = "DecodeABC_";
char ICMSEG InputArray[] = "Inp_";
char ICMSEG OutputArray[] = "Out_";
char ICMSEG PreViewInArray[] = "IPV_";
char ICMSEG PreViewOutArray[] = "OPV_";

char ICMSEG AdobeCSA[] = "[ /CIEBasedABC << /DecodeLMN [\n\
{dup 0.03928 le {12.92321 div}{0.055 add 1.055 div 2.4 exp}ifelse} bind dup dup ]\n\
/MatrixLMN [0.412457 0.212673 0.019334 0.357576 0.715152 0.119192 0.180437 0.072175 0.950301]\n\
/WhitePoint [ 0.9505 1 1.0890 ] >> ]";

char ICMSEG AdobeCRD[] = " /RangePQR [ -0.5 2 -0.5 2 -0.5 2 ]\n\
/MatrixPQR [0.8951 -0.7502  0.0389 0.2664  1.7135 -0.0685 -0.1614  0.0367  1.0296]\n\
/TransformPQR [{exch pop exch 3 get mul exch pop exch 3 get div} bind\n\
{exch pop exch 4 get mul exch pop exch 4 get div} bind\n\
{exch pop exch 5 get mul exch pop exch 5 get div} bind]\n\
/MatrixLMN [3.240449 -0.969265  0.055643 -1.537136  1.876011 -0.204026 -0.498531  0.041556  1.057229]\n\
/EncodeABC [{dup 0.00304 le {12.92321 mul}{1 2.4 div exp 1.055 mul 0.055 sub}ifelse} bind dup dup]\n\
/WhitePoint[0.9505 1 1.0890] >>";

// This PostScript segment takes value in range from 0.0 to 1.0 and
//  interpolates the result using array supplied.
//   x [array]  -- <interpolated value>

char ICMSEG IndexArray16b[] = \
" dup length 1 sub 3 -1 roll mul dup dup floor cvi \
exch ceiling cvi 3 index exch get 32768 add 4 -1 roll 3 -1 roll get 32768 add \
dup 3 1 roll sub 3 -1 roll dup floor cvi sub mul add ";

char ICMSEG IndexArray[] = \
" dup length 1 sub 3 -1 roll mul dup dup floor cvi \
exch ceiling cvi 3 index exch get 4 -1 roll 3 -1 roll get \
dup 3 1 roll sub 3 -1 roll dup floor cvi sub mul add ";

char ICMSEG TestingDEFG[] = \
"/SupportDEFG? {/CIEBasedDEFG /ColorSpaceFamily resourcestatus { pop pop languagelevel 3 ge}{false} ifelse} def";

char ICMSEG SupportDEFG_S[] = "SupportDEFG? { ";
char ICMSEG NotSupportDEFG_S[] = "SupportDEFG? not { ";
char ICMSEG SupportDEFG_E[] = "}if ";

char ICMSEG StartClip[] = "dup 1.0 le{dup 0.0 ge{";
char ICMSEG EndClip[] = "}if}if ";

char ICMSEG Scale8[] = "255 div ";
char ICMSEG Scale16[] = "65535 div ";
char ICMSEG Scale16XYZ[] = "32768 div ";
char ICMSEG TFunction8[] = "exch 255 mul round cvi get 255 div ";
char ICMSEG TFunction8XYZ[] = "exch 255 mul round cvi get 128 div ";
char ICMSEG MatrixABCLab[] = "[1 1 1 1 0 0 0 0 -1]";
char ICMSEG DecodeABCLab1[] = "[{16 add 116 div} bind {500 div} bind {200 div} bind]";
char ICMSEG DecodeALab[] = " 50 mul 16 add 116 div ";
char ICMSEG DecodeLMNLab[] = \
"dup 0.206897 ge{dup dup mul mul}{0.137931 sub 0.128419 mul} ifelse ";

char ICMSEG RangeLMNLab[] = "[0 1 0 1 0 1]";
char ICMSEG EncodeLMNLab[] = "\
dup 0.008856 le{7.787 mul 0.13793 add}{0.3333 exp}ifelse ";

char ICMSEG MatrixABCLabCRD[] = "[0 500 0 116 -500 200 0 0 -200]";
char ICMSEG MatrixABCXYZCRD[] = "[0 1 0 1 0 0 0 0 1]";
char ICMSEG EncodeABCLab1[] = "16 sub 100 div ";
char ICMSEG EncodeABCLab2[] = "128 add 255 div ";

char ICMSEG   RangePQR[] = "[ -0.07 2.2 -0.02 1.4 -0.2 4.8 ]";
char ICMSEG   MatrixPQR[] = "[0.8951 -0.7502 0.0389 0.2664 1.7135 -0.0685 -0.1614 0.0367 1.0296]";

char *TransformPQR[3] = {
"exch pop exch 3 get mul exch pop exch 3 get div ",
"exch pop exch 4 get mul exch pop exch 4 get div ",
"exch pop exch 5 get mul exch pop exch 5 get div "};

#define SRGBCRC 0x678175D2L

#pragma optimize("",off)

/*
*                               CreateLutCRD
*  function:
*    this is the function which creates the Color Rendering Dictionary (CRD)
*    from the data supplied in the ColorProfile's LUT8 or LUT16 tag.
*  prototype:
*       SINT EXTERN CreateLutCRD(
*                          CHANDLE      cp,
*                          SINT         Index,
*                          MEMPTR       lpMem,
*                          BOOL         AllowBinary)
*  parameters:
*       cp          --  Color Profile handle
*       Index       --  Index of the tag
*       lpMem       --  Pointer to the memory block
*       AllowBinary --  1: binary CRD allowed,  0: only ascii CRD allowed.

*  returns:
*       SINT        --  !=0 if the function was successful,
*                         0 otherwise.
*                       Returns number of bytes required/transferred
*/

SINT EXTERN
CreateLutCRD(CHANDLE cp, SINT Index, MEMPTR lpMem, DWORD InputIntent, BOOL AllowBinary)
{
    SINT nInputCh, nOutputCh, nGrids;
    SINT nInputTable, nOutputTable, nNumbers;
    CSIG Tag, PCS;
    CSIG IntentSig;

    SINT Ret;
    SINT i, j;
    MEMPTR lpTable;

    SFLOAT IlluminantWP[3];
    SFLOAT MediaWP[3];
    MEMPTR Buff = NULL;
    SINT MemSize = 0;
    MEMPTR lpOldMem = lpMem;
    char PublicArrayName[TempBfSize];
    HGLOBAL hMem;
    MEMPTR lpLineStart;
    // Check if we can generate the CRD
    if (!GetCPTagSig(cp, Index, (LPCSIG)& IntentSig) ||
        !GetCPElementType(cp, Index, (LPCSIG)& Tag) ||
        ((Tag != icSigLut8Type) && (Tag != icSigLut16Type)) ||
        !GetCPConnSpace(cp, (LPCSIG)& PCS) ||
        !GetCPElementSize(cp, Index, (LPSINT)& MemSize) ||
        !MemAlloc(MemSize, (HGLOBAL FAR *)&hMem, (LPMEMPTR)& Buff) ||
        !GetCPElement(cp, Index, Buff, MemSize)) {
        if (NULL != Buff) {
            MemFree(hMem);
        }
        return (0);
    }
    GetCLUTinfo(Tag, Buff, &nInputCh, &nOutputCh,
                &nGrids, &nInputTable, &nOutputTable, &i);
    // Level 2 printers support only tri-component CIEBasedABC input,
    // but can have either 3 or 4 output channels.
    if (((nOutputCh != 3) &&
        (nOutputCh != 4)) ||
         (nInputCh != 3)) {
        SetCPLastError(CP_POSTSCRIPT_ERR);
        MemFree(hMem);
        return (0);
    }
    Ret = nInputCh * nInputTable * 6 +
        nOutputCh * nOutputTable * 6 +  // Number of INT bytes
        nOutputCh * nGrids * nGrids * nGrids * 2 +  // LUT HEX bytes
        nInputCh * (lstrlen(IndexArray) +
                    lstrlen(StartClip) +
                    lstrlen(EndClip)) +
        nOutputCh * (lstrlen(IndexArray) +
                     lstrlen(StartClip) +
                     lstrlen(EndClip)) +
        2048;                           // + other PS stuff

    if (lpMem == NULL)                  // This is a size request
    {
        MemFree(hMem);
        return (Ret);
    }
    //  Get all necessary params from the header
    //  GetCPRenderIntent (cp, (LPCSIG) & Intent);  // Get Intent
    GetCPWhitePoint(cp, (LPSFLOAT)& IlluminantWP);          // .. Illuminant

 // Support absolute whitePoint
    if (InputIntent == icAbsoluteColorimetric) {
        if (!GetCPMediaWhitePoint(cp, (LPSFLOAT)& MediaWP)) // .. Media WhitePoint
        {
            MediaWP[0] = IlluminantWP[0];
            MediaWP[1] = IlluminantWP[1];
            MediaWP[2] = IlluminantWP[2];
        }
    }

    //******** Define golbal array used in EncodeABC and RenderTaber
    GetPublicArrayName(cp, IntentSig, PublicArrayName);
    lpMem += WriteNewLineObject(lpMem, CRDBegin);

    lpMem += EnableGlobalDict(lpMem);
    lpMem += BeginGlobalDict(lpMem);

    lpMem += CreateInputArray(lpMem, nInputCh, nInputTable,
        (MEMPTR)PublicArrayName, Tag, Buff, AllowBinary, NULL);

    i = nInputTable * nInputCh +
        nGrids * nGrids * nGrids * nOutputCh;
    lpMem += CreateOutputArray(lpMem, nOutputCh, nOutputTable, i,
        (MEMPTR)PublicArrayName, Tag, Buff, AllowBinary, NULL);

    lpMem += EndGlobalDict(lpMem);

    //************* Start writing  CRD  ****************************
    lpMem += WriteNewLineObject(lpMem, BeginDict);    // Begin dictionary
    lpMem += WriteObject(lpMem, DictType); // Dictionary type

    lpMem += WriteNewLineObject(lpMem, IntentType); // RenderingIntent
    switch (InputIntent) {
    case icPerceptual:
        lpMem += WriteObject(lpMem, IntentPer);
        break;

    case icSaturation:
        lpMem += WriteObject(lpMem, IntentSat);
        break;

    case icRelativeColorimetric:
        lpMem += WriteObject(lpMem, IntentRCol);
        break;

    case icAbsoluteColorimetric:
        lpMem += WriteObject(lpMem, IntentACol);
        break;
    }

    //********** Send Black/White Point.
    lpMem += SendCRDBWPoint(lpMem, IlluminantWP);

    //********** Send PQR - used for Absolute Colorimetric *****
    lpMem += SendCRDPQR(lpMem, InputIntent, IlluminantWP);

    //********** Send LMN - For Absolute Colorimetric use WhitePoint's XYZs
    lpMem += SendCRDLMN(lpMem, InputIntent, IlluminantWP, MediaWP, PCS);

    // ******** Create MatrixABC and  EncodeABC  stuff
    lpMem += SendCRDABC(lpMem, PublicArrayName,
                        PCS, nInputCh, Buff, NULL, Tag, AllowBinary);

    //********** /RenderTable
    lpMem += WriteNewLineObject(lpMem, RenderTableTag);
    lpMem += WriteObject(lpMem, BeginArray);

    lpMem += WriteInt(lpMem, nGrids);  // Send down Na
    lpMem += WriteInt(lpMem, nGrids);  // Send down Nb
    lpMem += WriteInt(lpMem, nGrids);  // Send down Nc

    lpLineStart = lpMem;
    lpMem += WriteNewLineObject(lpMem, BeginArray);
    nNumbers = nGrids * nGrids * nOutputCh;
    for (i = 0; i < nGrids; i++)        // Na strings should be sent
    {
        lpMem += WriteObject(lpMem, NewLine);
        lpLineStart = lpMem;
        if (Tag == icSigLut8Type) {
            lpTable = (MEMPTR)(((lpcpLut8Type)Buff)->lut.data) +
                nInputTable * nInputCh +
                nNumbers * i;
        } else {
            lpTable = (MEMPTR)(((lpcpLut16Type)Buff)->lut.data) +
                2 * nInputTable * nInputCh +
                2 * nNumbers * i;
        }
        if (!AllowBinary)               // Output ASCII CRD
        {
            lpMem += WriteObject(lpMem, BeginString);
            if (Tag == icSigLut8Type)
                lpMem += WriteHexBuffer(lpMem, lpTable, lpLineStart, nNumbers);
            else {
                for (j = 0; j < nNumbers; j++) {
                    lpMem += WriteHex(lpMem, ui16toSINT(lpTable) / 256);
                    lpTable += sizeof(icUInt16Number);
                    if (((SINT)(lpMem - lpLineStart)) > MAX_LINELENG) {
                        lpLineStart = lpMem;
                        lpMem += WriteObject(lpMem, NewLine);
                    }
                }
            }
            lpMem += WriteObject(lpMem, EndString);
        } else {                               // Output BINARY CRD
            lpMem += WriteStringToken(lpMem, 143, nNumbers);
            if (Tag == icSigLut8Type)
                lpMem += WriteByteString(lpMem, lpTable, nNumbers);
            else
                lpMem += WriteInt2ByteString(lpMem, lpTable, nNumbers);
        }
    }

    lpMem += WriteObject(lpMem, EndArray); // End array
    lpMem += WriteInt(lpMem, nOutputCh);   // Send down m

 //********** Send Output Table.
    lpMem += SendCRDOutputTable(lpMem, PublicArrayName,
                                nOutputCh, Tag, FALSE, AllowBinary);

    lpMem += WriteObject(lpMem, EndArray); // End array
    lpMem += WriteObject(lpMem, EndDict);  // End dictionary definition

    lpMem += WriteNewLineObject(lpMem, CRDEnd);

    // Testing Convert binary to ascii
    //    i = ConvertBinaryData2Ascii(lpOldMem, (SINT)(lpMem - lpOldMem), Ret);
    //    lpMem = lpOldMem + i;
    // Testing Convert binary to ascii

    MemFree(hMem);
    return ((SINT)((unsigned long)(lpMem - lpOldMem)));
}
/*
*                               GetRevCurve
*  function:
*  prototype:
*       BOOL  GetRevCurve(
*                          MEMPTR       Buff,
*                          MEMPTR       lpRevCurve)
*  parameters:
*       Buff        --
*       lpRevCurve  --
*  returns:
*       BOOL        --  TRUE:  successful,
*                       FALSE: otherwise.
*/

BOOL
GetRevCurve(MEMPTR lpBuff, MEMPTR lpCurve, MEMPTR lpRevCurve)
{
    SINT i, j, nCount;
    MEMPTR lpTable;
    PUSHORT lpInput, lpOutput;
    SFLOAT fTemp;
    SINT iBegin, iEnd, iTemp;
    nCount = ui32toSINT(((lpcpCurveType)lpBuff)->curve.count);
    lpTable = (MEMPTR)(((lpcpCurveType)lpBuff)->curve.data);
    lpOutput = (PUSHORT)lpRevCurve;
    lpInput = (PUSHORT)lpCurve;

    for (i = 0; i < nCount; i++) {
        lpInput[i] = (USHORT)(ui16toSINT(lpTable));
        lpTable += sizeof(icUInt16Number);
    }

    j = nCount * REVCURVE_RATIO;
    for (i = 0; i < j; i++) {
        fTemp = (SFLOAT)i * 65535 / (j - 1);
        lpOutput[i] = (fTemp < 65535) ? (USHORT)fTemp : (USHORT)65535;
    }

    for (i = 0; i < j; i++) {
        iBegin = 0;
        iEnd = nCount - 1;
        for (;;) {
            if ((iEnd - iBegin) <= 1)
                break;
            iTemp = (iEnd + iBegin) / 2;
            if (lpOutput[i] < lpInput[iTemp])
                iEnd = iTemp;
            else
                iBegin = iTemp;
        }
        if (lpOutput[i] <= lpInput[iBegin])
            fTemp = (SFLOAT)iBegin;
        else if (lpOutput[i] >= lpInput[iEnd])
            fTemp = (SFLOAT)iEnd;
        else {
            fTemp = ((SFLOAT)(lpInput[iEnd] - lpOutput[i])) /
                (lpOutput[i] - lpInput[iBegin]);
            fTemp = (iBegin * fTemp + iEnd) / (fTemp + 1);
        }
        fTemp = (fTemp / (nCount - 1)) * 65535;
        lpOutput[i] = (fTemp < 65535) ? (USHORT)fTemp : (USHORT)65535;
    }

    return TRUE;
}
/*
*                               CreateMonoCRD
*  function:
*    this is the function which creates the Color Rendering Dictionary (CRD)
*    from the data supplied in the GrayTRC tag.
*  prototype:
*       BOOL EXTERN CreateMonoCRD(
*                          CHANDLE      cp,
*                          SINT         Index,
*                          MEMPTR       lpMem)
*  parameters:
*       cp          --  Color Profile handle
*       Index       --  Index of the tag
*       lpMem       --  Pointer to the memory block
*  returns:
*       SINT        --  !=0 if the function was successful,
*                         0 otherwise.
*                       Returns number of bytes required/transferred
*/
//  According to the spec this tag-based function only converts from
//  Device to PCS, so we need to create an inverse function to perform
//  PCS->device conversion. By definition the CRD is only
//  for XYZ->DeviceRGB/CMYK conversion.
SINT EXTERN
CreateMonoCRD(CHANDLE cp, SINT Index, MEMPTR lpMem, DWORD InputIntent)
{
    SINT nCount;
    CSIG Tag, PCS;

    MEMPTR Buff = NULL;
    SINT MemSize = 0;
    MEMPTR lpOldMem = lpMem;
    MEMPTR lpCurve, lpRevCurve;
    HGLOBAL hRevCurve;
    SINT Ret = 0;
    HGLOBAL hMem;
    SINT i;
    MEMPTR lpTable;
    SFLOAT IlluminantWP[3];
    SFLOAT MediaWP[3];
    MEMPTR lpLineStart;
    // Check if we can generate the CRD
    if (!GetCPElementType(cp, Index, (LPCSIG)& Tag) ||
        (Tag != icSigCurveType) ||
        !GetCPConnSpace(cp, (LPCSIG)& PCS) ||
        !GetCPElementSize(cp, Index, (LPSINT)& MemSize) ||
        !MemAlloc(MemSize, (HGLOBAL FAR *)&hMem, (LPMEMPTR)& Buff) ||
        !GetCPElement(cp, Index, Buff, MemSize)) {
        if (NULL != Buff) {
            MemFree(hMem);
        }
        return (0);
    }
    nCount = ui32toSINT(((lpcpCurveType)Buff)->curve.count);

    // Estimate the memory size required to hold CRD
    // SRGB98
    Ret = nCount * 6 * REVCURVE_RATIO + // Number of INT elements
        2048;                           // + other PS stuff
    if (lpMem == NULL)                  // This is a size request
    {
        MemFree(hMem);
        return (Ret);
    }
    if (!MemAlloc(nCount * 2 * (REVCURVE_RATIO + 1),
        (HGLOBAL FAR *) &hRevCurve, (LPMEMPTR)& lpRevCurve)) {
        MemFree(hMem);
        return (FALSE);
    }
    lpCurve = lpRevCurve + 2 * REVCURVE_RATIO * nCount;
    GetRevCurve(Buff, lpCurve, lpRevCurve);

    //   GetCPCMMType (cp, (LPCSIG) & Intent);   // Get Intent
    GetCPWhitePoint(cp, (LPSFLOAT)& IlluminantWP);          // .. Illuminant

 // Support absolute whitePoint
    if (InputIntent == icAbsoluteColorimetric) {
        if (!GetCPMediaWhitePoint(cp, (LPSFLOAT)& MediaWP)) // .. Media WhitePoint
        {
            MediaWP[0] = IlluminantWP[0];
            MediaWP[1] = IlluminantWP[1];
            MediaWP[2] = IlluminantWP[2];
        }
    }

    //************* Start writing  CRD  ****************************
    lpMem += WriteNewLineObject(lpMem, BeginDict);    // Begin dictionary
    lpMem += WriteObject(lpMem, DictType); // Dictionary type

    lpMem += WriteNewLineObject(lpMem, IntentType); // RenderingIntent
    switch (InputIntent) {
    case icPerceptual:
        lpMem += WriteObject(lpMem, IntentPer);
        break;

    case icSaturation:
        lpMem += WriteObject(lpMem, IntentSat);
        break;

    case icRelativeColorimetric:
        lpMem += WriteObject(lpMem, IntentRCol);
        break;

    case icAbsoluteColorimetric:
        lpMem += WriteObject(lpMem, IntentACol);
        break;
    }

    //********** Send Black/White Point.
    lpMem += SendCRDBWPoint(lpMem, IlluminantWP);

    //********** /TransformPQR
    lpMem += SendCRDPQR(lpMem, InputIntent, IlluminantWP);

    //********** /MatrixLMN
    lpMem += SendCRDLMN(lpMem, InputIntent, IlluminantWP, MediaWP, PCS);

    //********** /MatrixABC
    if (PCS == icSigXYZData) {   // Switch ABC to BAC, since we want to output B which is converted from Y.
        lpMem += WriteNewLineObject(lpMem, MatrixABCTag);
        lpMem += WriteObject(lpMem, MatrixABCXYZCRD);
    } else if (PCS == icSigLabData) {
        lpMem += WriteNewLineObject(lpMem, MatrixABCTag);
        lpMem += WriteObject(lpMem, MatrixABCLabCRD);
    }
    //********** /EncodeABC
    if (nCount != 0) {
        lpMem += WriteObject(lpMem, NewLine);
        lpLineStart = lpMem;
        lpMem += WriteObject(lpMem, EncodeABCTag);
        lpMem += WriteObject(lpMem, BeginArray);
        lpMem += WriteObject(lpMem, BeginFunction);
        if (nCount == 1)                // Gamma supplied in ui16 format
        {
            lpTable = (MEMPTR)(((lpcpCurveType)Buff)->curve.data);
            lpMem += WriteInt(lpMem, ui16toSINT(lpTable));
            lpMem += WriteObject(lpMem, DecodeA3Rev);
        } else {
            if (PCS == icSigLabData) {
                lpMem += WriteObject(lpMem, EncodeABCLab1);
            }
            lpMem += WriteObject(lpMem, StartClip);
            lpMem += WriteObject(lpMem, BeginArray);
            for (i = 0; i < nCount * REVCURVE_RATIO; i++) {
                lpMem += WriteInt(lpMem, (SINT)(*((PUSHORT)lpRevCurve)));
                lpRevCurve += sizeof(icUInt16Number);
                if (((SINT)(lpMem - lpLineStart)) > MAX_LINELENG) {
                    lpLineStart = lpMem;
                    lpMem += WriteObject(lpMem, NewLine);
                }
            }
            lpMem += WriteObject(lpMem, EndArray);
            lpLineStart = lpMem;
            lpMem += WriteNewLineObject(lpMem, IndexArray);
            lpMem += WriteObject(lpMem, Scale16);
            lpMem += WriteObject(lpMem, EndClip);
        }
        lpMem += WriteObject(lpMem, EndFunction);
        lpMem += WriteObject(lpMem, DupOp);
        lpMem += WriteObject(lpMem, DupOp);
        lpMem += WriteObject(lpMem, EndArray);
    }
    lpMem += WriteObject(lpMem, EndDict);  // End dictionary definition

    MemFree(hRevCurve);
    MemFree(hMem);
    return ((SINT)((unsigned long)(lpMem - lpOldMem)));
}

// SRGB98 start
BOOL
GetTRCElementSize(CHANDLE cp, CSIG icSigXTRCTag, LPSINT pIndex, LPSINT pTRCSize)
{
    CSIG Tag;

    if (!GetCPTagIndex(cp, icSigXTRCTag, (LPSINT)pIndex) ||
        !GetCPElementType(cp, *pIndex, (LPCSIG)& Tag) ||
        !(Tag == icSigCurveType) ||
        !GetCPElementSize(cp, *pIndex, (LPSINT)pTRCSize)) {
        return FALSE;
    }
    return TRUE;
}

BOOL
DoesTRCAndColorantTagExist(CHANDLE cp)
{
    if (DoesCPTagExist(cp, icSigRedColorantTag) &&
        DoesCPTagExist(cp, icSigRedTRCTag) &&
        DoesCPTagExist(cp, icSigGreenColorantTag) &&
        DoesCPTagExist(cp, icSigGreenTRCTag) &&
        DoesCPTagExist(cp, icSigBlueColorantTag) &&
        DoesCPTagExist(cp, icSigBlueTRCTag)) {
        return TRUE;
    }

    return FALSE;
}

static SINT
CreateRevArray(CHANDLE cp, MEMPTR lpMem, MEMPTR lpBuff,
               MEMPTR lpRevCurve, CSIG CPTag, BOOL AllowBinary)
{
    SINT i, nCount;
    SINT MemSize = 0;
    MEMPTR lpOldMem, lpLineStart;
    MEMPTR lpCurve;

    lpOldMem = lpMem;

    lpLineStart = lpMem;
    nCount = ui32toSINT(((lpcpCurveType)lpBuff)->curve.count);
    if (nCount > 1) {
        lpMem += WriteNewLineObject(lpMem, Slash);
        lpMem += WriteObject(lpMem, InputArray);
        lpMem += WriteInt(lpMem, (SINT)CPTag);

        lpCurve = lpRevCurve + 2 * REVCURVE_RATIO * nCount;
        GetRevCurve(lpBuff, lpCurve, lpRevCurve);

        if (!AllowBinary)           // Output ASCII DATA
        {
            lpMem += WriteObject(lpMem, BeginArray);
            for (i = 0; i < nCount * REVCURVE_RATIO; i++) {
                lpMem += WriteInt(lpMem, (SINT)(*((PUSHORT)lpRevCurve)));
                lpRevCurve += sizeof(icUInt16Number);
                if (((SINT)(lpMem - lpLineStart)) > MAX_LINELENG) {
                    lpLineStart = lpMem;
                    lpMem += WriteObject(lpMem, NewLine);
                }
            }
            lpMem += WriteObject(lpMem, EndArray);
        } else {                           // Output BINARY DATA
            lpMem += WriteHNAToken(lpMem, 149, nCount);
            lpMem += WriteIntStringU2S_L(lpMem, lpRevCurve, nCount);
        }
    }
    lpMem += WriteObject(lpMem, DefOp);
    return ((SINT)(lpMem - lpOldMem));
}

static SINT
SendRevArray(CHANDLE cp, MEMPTR lpMem, MEMPTR lpBuff,
             CSIG CPTag, BOOL AllowBinary)
{
    SINT nCount;
    MEMPTR lpOldMem;
    MEMPTR lpTable;

    lpOldMem = lpMem;
    lpMem += WriteObject(lpMem, BeginFunction);
    nCount = ui32toSINT(((lpcpCurveType)lpBuff)->curve.count);
    if (nCount != 0) {
        if (nCount == 1)            // Gamma supplied in ui16 format
        {
            lpTable = (MEMPTR)(((lpcpCurveType)lpBuff)->curve.data);
            lpMem += WriteInt(lpMem, ui16toSINT(lpTable));
            lpMem += WriteObject(lpMem, DecodeA3Rev);
        } else {
            lpMem += WriteObject(lpMem, StartClip);
            lpMem += WriteObject(lpMem, InputArray);
            lpMem += WriteInt(lpMem, (SINT)CPTag);

            if (!AllowBinary)       // Output ASCII CS
            {
                lpMem += WriteObject(lpMem, IndexArray);
            } else {                       // Output BINARY CS
                lpMem += WriteObject(lpMem, IndexArray16b);
            }
            lpMem += WriteObject(lpMem, Scale16);
            lpMem += WriteObject(lpMem, EndClip);
        }
    }
    lpMem += WriteObject(lpMem, EndFunction);
    return ((SINT)(lpMem - lpOldMem));
}

SINT
CreateColorantArray(CHANDLE cp, double FAR *lpArray, CSIG CPTag)
{
    SINT i, Index;
    MEMPTR lpTable;
    MEMPTR Buff = NULL;
    SINT MemSize = 0;
    HGLOBAL hBuff;

    if (GetCPTagIndex(cp, CPTag, (LPSINT)& Index) &&
        GetCPElementSize(cp, Index, (LPSINT)& MemSize) &&
        MemAlloc(MemSize, (HGLOBAL FAR *)&hBuff, (LPMEMPTR)& Buff) &&
        GetCPElement(cp, Index, Buff, MemSize)) {
        lpTable = (MEMPTR) & (((lpcpXYZType)Buff)->data);
        for (i = 0; i < 3; i++) {
            *lpArray++ = (SFLOAT)si16f16toSFLOAT(lpTable);
            lpTable += sizeof(icS15Fixed16Number);
        }
        MemFree(hBuff);
    }
    return (TRUE);
}


/*
*                           IsSRGB
*  function: check if the profile is sRGB

*  parameters:
*       cp          --  Color Profile handle

*  returns:
*       BOOL        --  TRUE if the profile is sRGB
*                       FALSE otherwise.
*/
BOOL FAR IsSRGB(CHANDLE cp)
{
    BOOL    match = FALSE;
    SINT    RedTRCIndex, GreenTRCIndex, BlueTRCIndex, RedCIndex, GreenCIndex, BlueCIndex;
    SINT    MemSize;
    SINT    RedTRCSize = 0, GreenTRCSize = 0, BlueTRCSize = 0, RedCSize = 0, GreenCSize = 0, BlueCSize = 0;
    HGLOBAL hMem;
    MEMPTR  lpRed = NULL, lpGreen, lpBlue, lpRedC, lpGreenC, lpBlueC;
    DWORD   crc;

    if (GetCPTagIndex(cp, icSigRedTRCTag, &RedTRCIndex) &&
        GetCPElementSize(cp, RedTRCIndex, &RedTRCSize) &&

        GetCPTagIndex(cp, icSigGreenTRCTag, &GreenTRCIndex) &&
        GetCPElementSize(cp, GreenTRCIndex, &GreenTRCSize) &&

        GetCPTagIndex(cp, icSigBlueTRCTag, &BlueTRCIndex) &&
        GetCPElementSize(cp, BlueTRCIndex, &BlueTRCSize) &&

        GetCPTagIndex(cp, icSigRedColorantTag, &RedCIndex) &&
        GetCPElementSize(cp, RedCIndex, &RedCSize) &&

        GetCPTagIndex(cp, icSigGreenColorantTag, &GreenCIndex) &&
        GetCPElementSize(cp, GreenCIndex, &GreenCSize) &&

        GetCPTagIndex(cp, icSigBlueColorantTag, &BlueCIndex) &&
        GetCPElementSize(cp, BlueCIndex, &BlueCSize)) {
        MemSize = RedTRCSize + GreenTRCSize + BlueTRCSize + RedCSize + GreenCSize + BlueCSize;

        if ((MemSize == 6240) && // #bytes in sRGBColorTags
            MemAlloc(MemSize, (HGLOBAL FAR *)&hMem, (LPMEMPTR)&lpRed)) {
            lpGreen = lpRed + RedTRCSize;
            lpBlue = lpGreen + GreenTRCSize;
            lpRedC = lpBlue + BlueTRCSize;
            lpGreenC = lpRedC + RedCSize;
            lpBlueC = lpGreenC + GreenCSize;

            if (GetCPElement(cp, RedTRCIndex, lpRed, RedTRCSize) &&
                GetCPElement(cp, GreenTRCIndex, lpGreen, GreenTRCSize) &&
                GetCPElement(cp, BlueTRCIndex, lpBlue, BlueTRCSize) &&
                GetCPElement(cp, RedCIndex, lpRedC, RedCSize) &&
                GetCPElement(cp, GreenCIndex, lpGreenC, GreenCSize) &&
                GetCPElement(cp, BlueCIndex, lpBlueC, BlueCSize)) {
                crc = crc32(lpRed, 6240);
                match = (crc == SRGBCRC);
            }
            MemFree(hMem);
        }
    }
    return (match);
}

/*
*                           CreateMatrixCRD
*  function:
*    this is the function which creates the Color Rendering Dictionary (CRD)
*    from the data supplied in the redTRC, greenTRC, blueTRA, redColorant,
*    greenColorant and BlueColorant tags
*  prototype:
*       BOOL EXTERN CreateMatrixCRD(
*                          CHANDLE      cp,
*                          MEMPTR       lpMem,
*                          BOOL         AllowBinary)
*  parameters:
*       cp          --  Color Profile handle
*       lpMem       --  Pointer to the memory block
*       AllowBinary --
*  returns:
*       SINT        --  !=0 if the function was successful,
*                         0 otherwise.
*                       Returns number of bytes required/transferred
*/
// With matrix/TRC model, only the CIEXYZ encoding of the PCS can be used.
// So, we don't need to worry about CIELAB.
SINT EXTERN
CreateMatrixCRD(CHANDLE cp, MEMPTR lpMem, DWORD InputIntent, BOOL AllowBinary)
{
    SINT RedTRCIndex, GreenTRCIndex, BlueTRCIndex;
    SINT i, MemSize;
    SINT nRedCount, nGreenCount, nBlueCount;
    MEMPTR lpRed = NULL, lpGreen, lpBlue;
    SINT RedTRCSize = 0, GreenTRCSize = 0, BlueTRCSize = 0;
    MEMPTR lpOldMem = lpMem;
    MEMPTR lpRevCurve;
    HGLOBAL hRevCurve;
    SINT Ret = 0;
    HGLOBAL hMem;
    SFLOAT IlluminantWP[3];
    double Colorant[9];
    double RevColorant[9];

    // Check if we can generate the CRD
    if (!GetTRCElementSize(cp, icSigRedTRCTag, &RedTRCIndex, &RedTRCSize) ||
        !GetTRCElementSize(cp, icSigGreenTRCTag, &GreenTRCIndex, &GreenTRCSize) ||
        !GetTRCElementSize(cp, icSigBlueTRCTag, &BlueTRCIndex, &BlueTRCSize)) {
        return 0;
    }
    MemSize = RedTRCSize + GreenTRCSize + BlueTRCSize;
    if (!MemAlloc(MemSize, (HGLOBAL FAR *)&hMem, (LPMEMPTR)& lpRed))
        return 0;

    lpGreen = lpRed + RedTRCSize;
    lpBlue = lpGreen + GreenTRCSize;
    if (!GetCPElement(cp, RedTRCIndex, lpRed, RedTRCSize) ||
        !GetCPElement(cp, GreenTRCIndex, lpGreen, GreenTRCSize) ||
        !GetCPElement(cp, BlueTRCIndex, lpBlue, BlueTRCSize)) {
        MemFree(hMem);
        return (0);
    }
    nRedCount = ui32toSINT(((lpcpCurveType)lpRed)->curve.count);
    nGreenCount = ui32toSINT(((lpcpCurveType)lpGreen)->curve.count);
    nBlueCount = ui32toSINT(((lpcpCurveType)lpBlue)->curve.count);

    // Estimate the memory size required to hold CRD
    Ret = (nRedCount + nGreenCount + nBlueCount) * 6 * REVCURVE_RATIO +
        2048;                // Number of INT elements + other PS stuff
    if (lpMem == NULL)       // This is a size request
    {
        MemFree(hMem);
        return (Ret);
    }

    if (!MemAlloc(nRedCount * 2 * (REVCURVE_RATIO + 1),
        (HGLOBAL FAR *) &hRevCurve, (LPMEMPTR)& lpRevCurve)) {
        MemFree(hMem);
        return (0);
    }

    if (IsSRGB(cp)) {
        lpMem += WriteNewLineObject(lpMem, CRDBegin);
        lpMem += WriteNewLineObject(lpMem, BeginDict);    // Begin dictionary
        lpMem += WriteObject(lpMem, DictType); // Dictionary type
        lpMem += WriteNewLineObject(lpMem, IntentType); // RenderingIntent
        switch (InputIntent) {
        case icPerceptual:
            lpMem += WriteObject(lpMem, IntentPer);
            break;

        case icSaturation:
            lpMem += WriteObject(lpMem, IntentSat);
            break;

        case icRelativeColorimetric:
            lpMem += WriteObject(lpMem, IntentRCol);
            break;

        case icAbsoluteColorimetric:
            lpMem += WriteObject(lpMem, IntentACol);
            break;
        }
        lpMem += WriteNewLineObject(lpMem, AdobeCRD);
        lpMem += WriteNewLineObject(lpMem, CRDEnd);
    } else {
        lpMem += EnableGlobalDict(lpMem);
        lpMem += BeginGlobalDict(lpMem);

        lpMem += CreateRevArray(cp, lpMem, lpRed, lpRevCurve, icSigRedTRCTag, AllowBinary);
        lpMem += CreateRevArray(cp, lpMem, lpGreen, lpRevCurve, icSigGreenTRCTag, AllowBinary);
        lpMem += CreateRevArray(cp, lpMem, lpBlue, lpRevCurve, icSigBlueTRCTag, AllowBinary);

        lpMem += EndGlobalDict(lpMem);

        //   GetCPCMMType (cp, (LPCSIG) & Intent);   // Get Intent
        GetCPWhitePoint(cp, (LPSFLOAT)& IlluminantWP);          // .. Illuminant

     //************* Start writing  CRD  ****************************
        lpMem += WriteNewLineObject(lpMem, CRDBegin);

        lpMem += WriteNewLineObject(lpMem, BeginDict);    // Begin dictionary
        lpMem += WriteObject(lpMem, DictType); // Dictionary type

        lpMem += WriteNewLineObject(lpMem, IntentType); // RenderingIntent
        switch (InputIntent) {
        case icPerceptual:
            lpMem += WriteObject(lpMem, IntentPer);
            break;

        case icSaturation:
            lpMem += WriteObject(lpMem, IntentSat);
            break;

        case icRelativeColorimetric:
            lpMem += WriteObject(lpMem, IntentRCol);
            break;

        case icAbsoluteColorimetric:
            lpMem += WriteObject(lpMem, IntentACol);
            break;
        }

        //********** Send Black/White Point.
        lpMem += SendCRDBWPoint(lpMem, IlluminantWP);

        //********** /TransformPQR
        lpMem += SendCRDPQR(lpMem, InputIntent, IlluminantWP);

        //********** /MatrixLMN
        CreateColorantArray(cp, &Colorant[0], icSigRedColorantTag);
        CreateColorantArray(cp, &Colorant[3], icSigGreenColorantTag);
        CreateColorantArray(cp, &Colorant[6], icSigBlueColorantTag);
        InvertMatrix(Colorant, RevColorant);

        lpMem += WriteNewLineObject(lpMem, MatrixLMNTag);

        lpMem += WriteObject(lpMem, BeginArray);
        for (i = 0; i < 9; i++) {
            lpMem += WriteFloat(lpMem, (SFLOAT)RevColorant[i]);
        }
        lpMem += WriteObject(lpMem, EndArray);

        //********** /EncodeABC
        lpMem += WriteNewLineObject(lpMem, EncodeABCTag);
        lpMem += WriteObject(lpMem, BeginArray);

        lpMem += WriteObject(lpMem, NewLine);
        lpMem += SendRevArray(cp, lpMem, lpRed, icSigRedTRCTag, AllowBinary);
        lpMem += WriteObject(lpMem, NewLine);
        lpMem += SendRevArray(cp, lpMem, lpGreen, icSigGreenTRCTag, AllowBinary);
        lpMem += WriteObject(lpMem, NewLine);
        lpMem += SendRevArray(cp, lpMem, lpBlue, icSigBlueTRCTag, AllowBinary);
        lpMem += WriteNewLineObject(lpMem, EndArray);

        lpMem += WriteObject(lpMem, EndDict);  // End dictionary definition

        lpMem += WriteNewLineObject(lpMem, CRDEnd);
    }
    MemFree(hRevCurve);
    MemFree(hMem);
    return ((SINT)((unsigned long)(lpMem - lpOldMem)));
}
// SRGB98 End

BOOL EXTERN
GetPS2ColorRenderingDictionary(
    CHANDLE cp,
    DWORD Intent,
    MEMPTR lpMem,
    LPDWORD lpcbSize,
    BOOL AllowBinary)
{
    SINT Index;
    SINT Ret, Size;
    CSIG icSigPs2CRDx, icSigBToAx;

    if (!cp)
        return FALSE;

    if ((lpMem == NULL) || (*lpcbSize == 0)) {
        lpMem = NULL;
        *lpcbSize = 0;
    }
    Ret = 0;
    Size = (SINT)* lpcbSize;

    switch (Intent) {
    case icPerceptual:
        icSigPs2CRDx = icSigPs2CRD0Tag;
        icSigBToAx = icSigBToA0Tag;
        break;

    case icRelativeColorimetric:
        icSigPs2CRDx = icSigPs2CRD1Tag;
        icSigBToAx = icSigBToA1Tag;
        break;

    case icSaturation:
        icSigPs2CRDx = icSigPs2CRD2Tag;
        icSigBToAx = icSigBToA2Tag;
        break;

    case icAbsoluteColorimetric:
        icSigPs2CRDx = icSigPs2CRD3Tag;
        icSigBToAx = icSigBToA1Tag;
        break;

    default:
        *lpcbSize = (DWORD)Ret;
        return (Ret > 0);
    }

    if (
        (DoesCPTagExist(cp, icSigPs2CRDx) &&
         GetCPTagIndex(cp, icSigPs2CRDx, (LPSINT)& Index) &&
         GetCPElementDataSize(cp, Index, (LPSINT)& Ret) &&
         ((Size == 0) ||
          GetCPElementData(cp, Index, lpMem, Size)) &&
          (Ret = Convert2Ascii(cp, Index, lpMem, Size, Ret, AllowBinary))
         ) ||
         (DoesCPTagExist(cp, icSigBToAx) &&
          GetCPTagIndex(cp, icSigBToAx, (LPSINT)& Index) &&
          (Ret = CreateLutCRD(cp, Index, lpMem, Intent, AllowBinary))
          ) ||
        // SRGB98 Support Windows 98 sRGB icc profile.
        // Create CRD from TRC and Colorant Tags.
          (DoesTRCAndColorantTagExist(cp) &&
        (Ret = CreateMatrixCRD(cp, lpMem, Intent, AllowBinary))
           ) ||
           (DoesCPTagExist(cp, icSigGrayTRCTag) &&
            GetCPTagIndex(cp, icSigGrayTRCTag, (LPSINT)& Index) &&
            (Ret = CreateMonoCRD(cp, Index, lpMem, Intent))
            )
        ) {
    }

    *lpcbSize = (DWORD)Ret;
    return (Ret > 0);
}