//---------------------------------------------------------------------------------
//
//  Little Color Management System
//  Copyright (c) 1998-2020 Marti Maria Saguer
//
// Permission is hereby granted, free of charge, to any person obtaining
// a copy of this software and associated documentation files (the "Software"),
// to deal in the Software without restriction, including without limitation
// the rights to use, copy, modify, merge, publish, distribute, sublicense,
// and/or sell copies of the Software, and to permit persons to whom the Software
// is furnished to do so, subject to the following conditions:
//
// The above copyright notice and this permission notice shall be included in
// all copies or substantial portions of the Software.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
// EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO
// THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
// NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE
// LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION
// OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
// WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
//
//---------------------------------------------------------------------------------
//
 
#include "lcms2_internal.h"
 
 
// IT8.7 / CGATS.17-200x handling -----------------------------------------------------------------------------
 
 
#define MAXID        128     // Max length of identifier
#define MAXSTR      1024     // Max length of string
#define MAXTABLES    255     // Max Number of tables in a single stream
#define MAXINCLUDE    20     // Max number of nested includes
 
#define DEFAULT_DBL_FORMAT  "%.10g" // Double formatting
 
#ifdef CMS_IS_WINDOWS_
#    include <io.h>
#    define DIR_CHAR    '\\'
#else
#    define DIR_CHAR    '/'
#endif
 
 
// Symbols
typedef enum {
 
        SUNDEFINED,
        SINUM,      // Integer
        SDNUM,      // Real
        SIDENT,     // Identifier
        SSTRING,    // string
        SCOMMENT,   // comment
        SEOLN,      // End of line
        SEOF,       // End of stream
        SSYNERROR,  // Syntax error found on stream
 
        // Keywords
 
        SBEGIN_DATA,
        SBEGIN_DATA_FORMAT,
        SEND_DATA,
        SEND_DATA_FORMAT,
        SKEYWORD,
        SDATA_FORMAT_ID,
        SINCLUDE
 
    } SYMBOL;
 
 
// How to write the value
typedef enum {
 
        WRITE_UNCOOKED,
        WRITE_STRINGIFY,
        WRITE_HEXADECIMAL,
        WRITE_BINARY,
        WRITE_PAIR
 
    } WRITEMODE;
 
// Linked list of variable names
typedef struct _KeyVal {
 
        struct _KeyVal*  Next;
        char*            Keyword;       // Name of variable
        struct _KeyVal*  NextSubkey;    // If key is a dictionary, points to the next item
        char*            Subkey;        // If key is a dictionary, points to the subkey name
        char*            Value;         // Points to value
        WRITEMODE        WriteAs;       // How to write the value
 
   } KEYVALUE;
 
 
// Linked list of memory chunks (Memory sink)
typedef struct _OwnedMem {
 
        struct _OwnedMem* Next;
        void *            Ptr;          // Point to value
 
   } OWNEDMEM;
 
// Suballocator
typedef struct _SubAllocator {
 
         cmsUInt8Number* Block;
         cmsUInt32Number BlockSize;
         cmsUInt32Number Used;
 
    } SUBALLOCATOR;
 
// Table. Each individual table can hold properties and rows & cols
typedef struct _Table {
 
        char SheetType[MAXSTR];               // The first row of the IT8 (the type)
 
        int            nSamples, nPatches;    // Cols, Rows
        int            SampleID;              // Pos of ID
 
        KEYVALUE*      HeaderList;            // The properties
 
        char**         DataFormat;            // The binary stream descriptor
        char**         Data;                  // The binary stream
 
    } TABLE;
 
// File stream being parsed
typedef struct _FileContext {
        char           FileName[cmsMAX_PATH];    // File name if being read from file
        FILE*          Stream;                   // File stream or NULL if holded in memory
    } FILECTX;
 
// This struct hold all information about an open IT8 handler.
typedef struct {
 
 
        cmsUInt32Number  TablesCount;                     // How many tables in this stream
        cmsUInt32Number  nTable;                          // The actual table
 
        TABLE Tab[MAXTABLES];
 
        // Memory management
        OWNEDMEM*      MemorySink;            // The storage backend
        SUBALLOCATOR   Allocator;             // String suballocator -- just to keep it fast
 
        // Parser state machine
        SYMBOL             sy;                // Current symbol
        int                ch;                // Current character
 
        cmsInt32Number     inum;              // integer value
        cmsFloat64Number   dnum;              // real value
 
        char           id[MAXID];             // identifier
        char           str[MAXSTR];           // string
 
        // Allowed keywords & datasets. They have visibility on whole stream
        KEYVALUE*      ValidKeywords;
        KEYVALUE*      ValidSampleID;
 
        char*          Source;                // Points to loc. being parsed
        cmsInt32Number lineno;                // line counter for error reporting
 
        FILECTX*       FileStack[MAXINCLUDE]; // Stack of files being parsed
        cmsInt32Number IncludeSP;             // Include Stack Pointer
 
        char*          MemoryBlock;           // The stream if holded in memory
 
        char           DoubleFormatter[MAXID];// Printf-like 'cmsFloat64Number' formatter
 
        cmsContext    ContextID;              // The threading context
 
   } cmsIT8;
 
 
// The stream for save operations
typedef struct {
 
        FILE* stream;   // For save-to-file behaviour
 
        cmsUInt8Number* Base;
        cmsUInt8Number* Ptr;        // For save-to-mem behaviour
        cmsUInt32Number Used;
        cmsUInt32Number Max;
 
    } SAVESTREAM;
 
 
// ------------------------------------------------------ cmsIT8 parsing routines
 
 
// A keyword
typedef struct {
 
        const char *id;
        SYMBOL sy;
 
   } KEYWORD;
 
// The keyword->symbol translation table. Sorting is required.
static const KEYWORD TabKeys[] = {
 
        {"$INCLUDE",               SINCLUDE},   // This is an extension!
        {".INCLUDE",               SINCLUDE},   // This is an extension!
 
        {"BEGIN_DATA",             SBEGIN_DATA },
        {"BEGIN_DATA_FORMAT",      SBEGIN_DATA_FORMAT },
        {"DATA_FORMAT_IDENTIFIER", SDATA_FORMAT_ID},
        {"END_DATA",               SEND_DATA},
        {"END_DATA_FORMAT",        SEND_DATA_FORMAT},
        {"KEYWORD",                SKEYWORD}
        };
 
#define NUMKEYS (sizeof(TabKeys)/sizeof(KEYWORD))
 
// Predefined properties
 
// A property
typedef struct {
        const char *id;    // The identifier
        WRITEMODE as;      // How is supposed to be written
    } PROPERTY;
 
static PROPERTY PredefinedProperties[] = {
 
        {"NUMBER_OF_FIELDS", WRITE_UNCOOKED},    // Required - NUMBER OF FIELDS
        {"NUMBER_OF_SETS",   WRITE_UNCOOKED},    // Required - NUMBER OF SETS
        {"ORIGINATOR",       WRITE_STRINGIFY},   // Required - Identifies the specific system, organization or individual that created the data file.
        {"FILE_DESCRIPTOR",  WRITE_STRINGIFY},   // Required - Describes the purpose or contents of the data file.
        {"CREATED",          WRITE_STRINGIFY},   // Required - Indicates date of creation of the data file.
        {"DESCRIPTOR",       WRITE_STRINGIFY},   // Required  - Describes the purpose or contents of the data file.
        {"DIFFUSE_GEOMETRY", WRITE_STRINGIFY},   // The diffuse geometry used. Allowed values are "sphere" or "opal".
        {"MANUFACTURER",     WRITE_STRINGIFY},
        {"MANUFACTURE",      WRITE_STRINGIFY},   // Some broken Fuji targets does store this value
        {"PROD_DATE",        WRITE_STRINGIFY},   // Identifies year and month of production of the target in the form yyyy:mm.
        {"SERIAL",           WRITE_STRINGIFY},   // Uniquely identifies individual physical target.
 
        {"MATERIAL",         WRITE_STRINGIFY},    // Identifies the material on which the target was produced using a code
                                                  // uniquely identifying th e material. This is intend ed to be used for IT8.7
                                                  // physical targets only (i.e . IT8.7/1 a nd IT8.7/2).
 
        {"INSTRUMENTATION",  WRITE_STRINGIFY},    // Used to report the specific instrumentation used (manufacturer and
                                                  // model number) to generate the data reported. This data will often
                                                  // provide more information about the particular data collected than an
                                                  // extensive list of specific details. This is particularly important for
                                                  // spectral data or data derived from spectrophotometry.
 
        {"MEASUREMENT_SOURCE", WRITE_STRINGIFY},  // Illumination used for spectral measurements. This data helps provide
                                                  // a guide to the potential for issues of paper fluorescence, etc.
 
        {"PRINT_CONDITIONS", WRITE_STRINGIFY},     // Used to define the characteristics of the printed sheet being reported.
                                                   // Where standard conditions have been defined (e.g., SWOP at nominal)
                                                   // named conditions may suffice. Otherwise, detailed information is
                                                   // needed.
 
        {"SAMPLE_BACKING",   WRITE_STRINGIFY},     // Identifies the backing material used behind the sample during
                                                   // measurement. Allowed values are "black", "white", or {"na".
                                                  
        {"CHISQ_DOF",        WRITE_STRINGIFY},     // Degrees of freedom associated with the Chi squared statistic
                                                   // below properties are new in recent specs:
 
        {"MEASUREMENT_GEOMETRY", WRITE_STRINGIFY}, // The type of measurement, either reflection or transmission, should be indicated
                                                   // along with details of the geometry and the aperture size and shape. For example,
                                                   // for transmission measurements it is important to identify 0/diffuse, diffuse/0,
                                                   // opal or integrating sphere, etc. For reflection it is important to identify 0/45,
                                                   // 45/0, sphere (specular included or excluded), etc.
 
       {"FILTER",            WRITE_STRINGIFY},     // Identifies the use of physical filter(s) during measurement. Typically used to
                                                   // denote the use of filters such as none, D65, Red, Green or Blue.
                                                  
       {"POLARIZATION",      WRITE_STRINGIFY},     // Identifies the use of a physical polarization filter during measurement. Allowed
                                                   // values are {"yes", "white", "none" or "na".
 
       {"WEIGHTING_FUNCTION", WRITE_PAIR},         // Indicates such functions as: the CIE standard observer functions used in the
                                                   // calculation of various data parameters (2 degree and 10 degree), CIE standard
                                                   // illuminant functions used in the calculation of various data parameters (e.g., D50,
                                                   // D65, etc.), density status response, etc. If used there shall be at least one
                                                   // name-value pair following the WEIGHTING_FUNCTION tag/keyword. The first attribute
                                                   // in the set shall be {"name" and shall identify the particular parameter used.
                                                   // The second shall be {"value" and shall provide the value associated with that name.
                                                   // For ASCII data, a string containing the Name and Value attribute pairs shall follow
                                                   // the weighting function keyword. A semi-colon separates attribute pairs from each
                                                   // other and within the attribute the name and value are separated by a comma.
 
       {"COMPUTATIONAL_PARAMETER", WRITE_PAIR},    // Parameter that is used in computing a value from measured data. Name is the name
                                                   // of the calculation, parameter is the name of the parameter used in the calculation
                                                   // and value is the value of the parameter.
                                                   
       {"TARGET_TYPE",        WRITE_STRINGIFY},    // The type of target being measured, e.g. IT8.7/1, IT8.7/3, user defined, etc.
                                                  
       {"COLORANT",           WRITE_STRINGIFY},    // Identifies the colorant(s) used in creating the target.
                                                  
       {"TABLE_DESCRIPTOR",   WRITE_STRINGIFY},    // Describes the purpose or contents of a data table.
                                                  
       {"TABLE_NAME",         WRITE_STRINGIFY}     // Provides a short name for a data table.
};
 
#define NUMPREDEFINEDPROPS (sizeof(PredefinedProperties)/sizeof(PROPERTY))
 
 
// Predefined sample types on dataset
static const char* PredefinedSampleID[] = {
        "SAMPLE_ID",      // Identifies sample that data represents
        "STRING",         // Identifies label, or other non-machine readable value.
                          // Value must begin and end with a " symbol
 
        "CMYK_C",         // Cyan component of CMYK data expressed as a percentage
        "CMYK_M",         // Magenta component of CMYK data expressed as a percentage
        "CMYK_Y",         // Yellow component of CMYK data expressed as a percentage
        "CMYK_K",         // Black component of CMYK data expressed as a percentage
        "D_RED",          // Red filter density
        "D_GREEN",        // Green filter density
        "D_BLUE",         // Blue filter density
        "D_VIS",          // Visual filter density
        "D_MAJOR_FILTER", // Major filter d ensity
        "RGB_R",          // Red component of RGB data
        "RGB_G",          // Green component of RGB data
        "RGB_B",          // Blue com ponent of RGB data
        "SPECTRAL_NM",    // Wavelength of measurement expressed in nanometers
        "SPECTRAL_PCT",   // Percentage reflectance/transmittance
        "SPECTRAL_DEC",   // Reflectance/transmittance
        "XYZ_X",          // X component of tristimulus data
        "XYZ_Y",          // Y component of tristimulus data
        "XYZ_Z",          // Z component of tristimulus data
        "XYY_X",          // x component of chromaticity data
        "XYY_Y",          // y component of chromaticity data
        "XYY_CAPY",       // Y component of tristimulus data
        "LAB_L",          // L* component of Lab data
        "LAB_A",          // a* component of Lab data
        "LAB_B",          // b* component of Lab data
        "LAB_C",          // C*ab component of Lab data
        "LAB_H",          // hab component of Lab data
        "LAB_DE",         // CIE dE
        "LAB_DE_94",      // CIE dE using CIE 94
        "LAB_DE_CMC",     // dE using CMC
        "LAB_DE_2000",    // CIE dE using CIE DE 2000
        "MEAN_DE",        // Mean Delta E (LAB_DE) of samples compared to batch average
                          // (Used for data files for ANSI IT8.7/1 and IT8.7/2 targets)
        "STDEV_X",        // Standard deviation of X (tristimulus data)
        "STDEV_Y",        // Standard deviation of Y (tristimulus data)
        "STDEV_Z",        // Standard deviation of Z (tristimulus data)
        "STDEV_L",        // Standard deviation of L*
        "STDEV_A",        // Standard deviation of a*
        "STDEV_B",        // Standard deviation of b*
        "STDEV_DE",       // Standard deviation of CIE dE
        "CHI_SQD_PAR"};   // The average of the standard deviations of L*, a* and b*. It is
                          // used to derive an estimate of the chi-squared parameter which is
                          // recommended as the predictor of the variability of dE
 
#define NUMPREDEFINEDSAMPLEID (sizeof(PredefinedSampleID)/sizeof(char *))
 
//Forward declaration of some internal functions
static void* AllocChunk(cmsIT8* it8, cmsUInt32Number size);
 
// Checks whatever c is a separator
static
cmsBool isseparator(int c)
{
    return (c == ' ') || (c == '\t') ; 
}
 
// Checks whatever c is a valid identifier char
static
cmsBool ismiddle(int c)
{
   return (!isseparator(c) && (c != '#') && (c !='\"') && (c != '\'') && (c > 32) && (c < 127));
}
 
// Checks whatsever c is a valid identifier middle char.
static
cmsBool isidchar(int c)
{
   return isalnum(c) || ismiddle(c);
}
 
// Checks whatsever c is a valid identifier first char.
static
cmsBool isfirstidchar(int c)
{
     return !isdigit(c) && ismiddle(c);
}
 
// Guess whether the supplied path looks like an absolute path
static
cmsBool isabsolutepath(const char *path)
{
    char ThreeChars[4];
 
    if(path == NULL)
        return FALSE;
    if (path[0] == 0)
        return FALSE;
 
    strncpy(ThreeChars, path, 3);
    ThreeChars[3] = 0;
 
    if(ThreeChars[0] == DIR_CHAR)
        return TRUE;
 
#ifdef  CMS_IS_WINDOWS_
    if (isalpha((int) ThreeChars[0]) && ThreeChars[1] == ':')
        return TRUE;
#endif
    return FALSE;
}
 
 
// Makes a file path based on a given reference path
// NOTE: this function doesn't check if the path exists or even if it's legal
static
cmsBool BuildAbsolutePath(const char *relPath, const char *basePath, char *buffer, cmsUInt32Number MaxLen)
{
    char *tail;
    cmsUInt32Number len;
 
    // Already absolute?
    if (isabsolutepath(relPath)) {
 
        strncpy(buffer, relPath, MaxLen);
        buffer[MaxLen-1] = 0;
        return TRUE;
    }
 
    // No, search for last
    strncpy(buffer, basePath, MaxLen);
    buffer[MaxLen-1] = 0;
 
    tail = strrchr(buffer, DIR_CHAR);
    if (tail == NULL) return FALSE;    // Is not absolute and has no separators??
 
    len = (cmsUInt32Number) (tail - buffer);
    if (len >= MaxLen) return FALSE;
 
    // No need to assure zero terminator over here
    strncpy(tail + 1, relPath, MaxLen - len);
 
    return TRUE;
}
 
 
// Make sure no exploit is being even tried
static
const char* NoMeta(const char* str)
{
    if (strchr(str, '%') != NULL)
        return "**** CORRUPTED FORMAT STRING ***";
 
    return str;
}
 
// Syntax error
static
cmsBool SynError(cmsIT8* it8, const char *Txt, ...)
{
    char Buffer[256], ErrMsg[1024];
    va_list args;
 
    va_start(args, Txt);
    vsnprintf(Buffer, 255, Txt, args);
    Buffer[255] = 0;
    va_end(args);
 
    snprintf(ErrMsg, 1023, "%s: Line %d, %s", it8->FileStack[it8 ->IncludeSP]->FileName, it8->lineno, Buffer);
    ErrMsg[1023] = 0;
    it8->sy = SSYNERROR;
    cmsSignalError(it8 ->ContextID, cmsERROR_CORRUPTION_DETECTED, "%s", ErrMsg);
    return FALSE;
}
 
// Check if current symbol is same as specified. issue an error else.
static
cmsBool Check(cmsIT8* it8, SYMBOL sy, const char* Err)
{
        if (it8 -> sy != sy)
                return SynError(it8, NoMeta(Err));
        return TRUE;
}
 
// Read Next character from stream
static
void NextCh(cmsIT8* it8)
{
    if (it8 -> FileStack[it8 ->IncludeSP]->Stream) {
 
        it8 ->ch = fgetc(it8 ->FileStack[it8 ->IncludeSP]->Stream);
 
        if (feof(it8 -> FileStack[it8 ->IncludeSP]->Stream))  {
 
            if (it8 ->IncludeSP > 0) {
 
                fclose(it8 ->FileStack[it8->IncludeSP--]->Stream);
                it8 -> ch = ' ';                            // Whitespace to be ignored
 
            } else
                it8 ->ch = 0;   // EOF
        }
    }
    else {
        it8->ch = *it8->Source;
        if (it8->ch) it8->Source++;
    }
}
 
 
// Try to see if current identifier is a keyword, if so return the referred symbol
static
SYMBOL BinSrchKey(const char *id)
{
    int l = 1;
    int r = NUMKEYS;
    int x, res;
 
    while (r >= l)
    {
        x = (l+r)/2;
        res = cmsstrcasecmp(id, TabKeys[x-1].id);
        if (res == 0) return TabKeys[x-1].sy;
        if (res < 0) r = x - 1;
        else l = x + 1;
    }
 
    return SUNDEFINED;
}
 
 
// 10 ^n
static
cmsFloat64Number xpow10(int n)
{
    return pow(10, (cmsFloat64Number) n);
}
 
 
//  Reads a Real number, tries to follow from integer number
static
void ReadReal(cmsIT8* it8, cmsInt32Number inum)
{
    it8->dnum = (cmsFloat64Number)inum;
 
    while (isdigit(it8->ch)) {
 
        it8->dnum = (cmsFloat64Number)it8->dnum * 10.0 + (cmsFloat64Number)(it8->ch - '0');
        NextCh(it8);
    }
 
    if (it8->ch == '.') {        // Decimal point
 
        cmsFloat64Number frac = 0.0;      // fraction
        int prec = 0;                     // precision
 
        NextCh(it8);               // Eats dec. point
 
        while (isdigit(it8->ch)) {
 
            frac = frac * 10.0 + (cmsFloat64Number)(it8->ch - '0');
            prec++;
            NextCh(it8);
        }
 
        it8->dnum = it8->dnum + (frac / xpow10(prec));
    }
 
    // Exponent, example 34.00E+20
    if (toupper(it8->ch) == 'E') {
 
        cmsInt32Number e;
        cmsInt32Number sgn;
 
        NextCh(it8); sgn = 1;
 
        if (it8->ch == '-') {
 
            sgn = -1; NextCh(it8);
        }
        else
            if (it8->ch == '+') {
 
                sgn = +1;
                NextCh(it8);
            }
 
        e = 0;
        while (isdigit(it8->ch)) {
 
            cmsInt32Number digit = (it8->ch - '0');
 
            if ((cmsFloat64Number)e * 10.0 + (cmsFloat64Number)digit < (cmsFloat64Number)+2147483647.0)
                e = e * 10 + digit;
 
            NextCh(it8);
        }
 
        e = sgn*e;
        it8->dnum = it8->dnum * xpow10(e);
    }
}
 
// Parses a float number
// This can not call directly atof because it uses locale dependent
// parsing, while CCMX files always use . as decimal separator
static
cmsFloat64Number ParseFloatNumber(const char *Buffer)
{
    cmsFloat64Number dnum = 0.0;
    int sign = 1;
 
    // keep safe
    if (Buffer == NULL) return 0.0;
 
    if (*Buffer == '-' || *Buffer == '+') {
 
        sign = (*Buffer == '-') ? -1 : 1;
        Buffer++;
    }
 
 
    while (*Buffer && isdigit((int)*Buffer)) {
 
        dnum = dnum * 10.0 + (*Buffer - '0');
        if (*Buffer) Buffer++;
    }
 
    if (*Buffer == '.') {
 
        cmsFloat64Number frac = 0.0;      // fraction
        int prec = 0;                     // precision
 
        if (*Buffer) Buffer++;
 
        while (*Buffer && isdigit((int)*Buffer)) {
 
            frac = frac * 10.0 + (*Buffer - '0');
            prec++;
            if (*Buffer) Buffer++;
        }
 
        dnum = dnum + (frac / xpow10(prec));
    }
 
    // Exponent, example 34.00E+20
    if (*Buffer && toupper(*Buffer) == 'E') {
 
        int e;
        int sgn;
 
        if (*Buffer) Buffer++;
        sgn = 1;
 
        if (*Buffer == '-') {
 
            sgn = -1;
            if (*Buffer) Buffer++;
        }
        else
            if (*Buffer == '+') {
 
                sgn = +1;
                if (*Buffer) Buffer++;
            }
 
        e = 0;
        while (*Buffer && isdigit((int)*Buffer)) {
 
            cmsInt32Number digit = (*Buffer - '0');
 
            if ((cmsFloat64Number)e * 10.0 + digit < (cmsFloat64Number)+2147483647.0)
                e = e * 10 + digit;
 
            if (*Buffer) Buffer++;
        }
 
        e = sgn*e;
        dnum = dnum * xpow10(e);
    }
 
    return sign * dnum;
}
 
 
// Reads next symbol
static
void InSymbol(cmsIT8* it8)
{
    CMSREGISTER char *idptr;
    CMSREGISTER int k;
    SYMBOL key;
    int sng;
    
    do {
 
        while (isseparator(it8->ch))
            NextCh(it8);
 
        if (isfirstidchar(it8->ch)) {          // Identifier
 
            k = 0;
            idptr = it8->id;
 
            do {
 
                if (++k < MAXID) *idptr++ = (char) it8->ch;
 
                NextCh(it8);
 
            } while (isidchar(it8->ch));
 
            *idptr = '\0';
 
 
            key = BinSrchKey(it8->id);
            if (key == SUNDEFINED) it8->sy = SIDENT;
            else it8->sy = key;
 
        }
        else                         // Is a number?
            if (isdigit(it8->ch) || it8->ch == '.' || it8->ch == '-' || it8->ch == '+')
            {
                int sign = 1;
 
                if (it8->ch == '-') {
                    sign = -1;
                    NextCh(it8);
                }
 
                it8->inum = 0;
                it8->sy   = SINUM;
 
                if (it8->ch == '0') {          // 0xnnnn (Hexa) or 0bnnnn (Binary)
 
                    NextCh(it8);
                    if (toupper(it8->ch) == 'X') {
 
                        int j;
 
                        NextCh(it8);
                        while (isxdigit(it8->ch))
                        {
                            it8->ch = toupper(it8->ch);
                            if (it8->ch >= 'A' && it8->ch <= 'F')  j = it8->ch -'A'+10;
                            else j = it8->ch - '0';
 
                            if ((cmsFloat64Number) it8->inum * 16.0 + (cmsFloat64Number) j > (cmsFloat64Number)+2147483647.0)
                            {
                                SynError(it8, "Invalid hexadecimal number");
                                return;
                            }
 
                            it8->inum = it8->inum * 16 + j;
                            NextCh(it8);
                        }
                        return;
                    }
 
                    if (toupper(it8->ch) == 'B') {  // Binary
 
                        int j;
 
                        NextCh(it8);
                        while (it8->ch == '0' || it8->ch == '1')
                        {
                            j = it8->ch - '0';
 
                            if ((cmsFloat64Number) it8->inum * 2.0 + j > (cmsFloat64Number)+2147483647.0)
                            {
                                SynError(it8, "Invalid binary number");
                                return;
                            }
 
                            it8->inum = it8->inum * 2 + j;
                            NextCh(it8);
                        }
                        return;
                    }
                }
 
 
                while (isdigit(it8->ch)) {
 
                    cmsInt32Number digit = (it8->ch - '0');
 
                    if ((cmsFloat64Number) it8->inum * 10.0 + (cmsFloat64Number) digit > (cmsFloat64Number) +2147483647.0) {
                        ReadReal(it8, it8->inum);
                        it8->sy = SDNUM;
                        it8->dnum *= sign;
                        return;
                    }
 
                    it8->inum = it8->inum * 10 + digit;
                    NextCh(it8);
                }
 
                if (it8->ch == '.') {
 
                    ReadReal(it8, it8->inum);
                    it8->sy = SDNUM;
                    it8->dnum *= sign;
                    return;
                }
 
                it8 -> inum *= sign;
 
                // Special case. Numbers followed by letters are taken as identifiers
 
                if (isidchar(it8 ->ch)) {
 
                    if (it8 ->sy == SINUM) {
 
                        snprintf(it8->id, 127, "%d", it8->inum);
                    }
                    else {
 
                        snprintf(it8->id, 127, it8 ->DoubleFormatter, it8->dnum);
                    }
 
                    k = (int) strlen(it8 ->id);
                    idptr = it8 ->id + k;
                    do {
 
                        if (++k < MAXID) *idptr++ = (char) it8->ch;
 
                        NextCh(it8);
 
                    } while (isidchar(it8->ch));
 
                    *idptr = '\0';
                    it8->sy = SIDENT;
                }
                return;
 
            }
            else
                switch ((int) it8->ch) {
 
        // EOF marker -- ignore it
        case '\x1a':
            NextCh(it8);
            break;
 
        // Eof stream markers
        case 0:
        case -1:
            it8->sy = SEOF;
            break;
 
 
        // Next line
        case '\r':
            NextCh(it8);
            if (it8 ->ch == '\n') 
                NextCh(it8);
            it8->sy = SEOLN;
            it8->lineno++;
            break;
 
        case '\n':
            NextCh(it8);
            it8->sy = SEOLN;
            it8->lineno++;
            break;
 
        // Comment
        case '#':
            NextCh(it8);
            while (it8->ch && it8->ch != '\n' && it8->ch != '\r')
                NextCh(it8);
 
            it8->sy = SCOMMENT;
            break;
 
        // String.
        case '\'':
        case '\"':
            idptr = it8->str;
            sng = it8->ch;
            k = 0;
            NextCh(it8);
 
            while (k < (MAXSTR-1) && it8->ch != sng) {
 
                if (it8->ch == '\n'|| it8->ch == '\r') k = MAXSTR+1;
                else {
                    *idptr++ = (char) it8->ch;
                    NextCh(it8);
                    k++;
                }
            }
 
            it8->sy = SSTRING;
            *idptr = '\0';
            NextCh(it8);
            break;
 
 
        default:
            SynError(it8, "Unrecognized character: 0x%x", it8 ->ch);
            return;
            }
 
    } while (it8->sy == SCOMMENT);
 
    // Handle the include special token
 
    if (it8 -> sy == SINCLUDE) {
 
                FILECTX* FileNest;
 
                if(it8 -> IncludeSP >= (MAXINCLUDE-1)) {
 
                    SynError(it8, "Too many recursion levels");
                    return;
                }
 
                InSymbol(it8);
                if (!Check(it8, SSTRING, "Filename expected")) return;
 
                FileNest = it8 -> FileStack[it8 -> IncludeSP + 1];
                if(FileNest == NULL) {
 
                    FileNest = it8 ->FileStack[it8 -> IncludeSP + 1] = (FILECTX*)AllocChunk(it8, sizeof(FILECTX));
                    //if(FileNest == NULL)
                    //  TODO: how to manage out-of-memory conditions?
                }
 
                if (BuildAbsolutePath(it8->str,
                                      it8->FileStack[it8->IncludeSP]->FileName,
                                      FileNest->FileName, cmsMAX_PATH-1) == FALSE) {
                    SynError(it8, "File path too long");
                    return;
                }
 
                FileNest->Stream = fopen(FileNest->FileName, "rt");
                if (FileNest->Stream == NULL) {
 
                        SynError(it8, "File %s not found", FileNest->FileName);
                        return;
                }
                it8->IncludeSP++;
 
                it8 ->ch = ' ';
                InSymbol(it8);
    }
 
}
 
// Checks end of line separator
static
cmsBool CheckEOLN(cmsIT8* it8)
{
        if (!Check(it8, SEOLN, "Expected separator")) return FALSE;
        while (it8 -> sy == SEOLN)
                        InSymbol(it8);
        return TRUE;
 
}
 
// Skip a symbol
 
static
void Skip(cmsIT8* it8, SYMBOL sy)
{
        if (it8->sy == sy && it8->sy != SEOF)
                        InSymbol(it8);
}
 
 
// Skip multiple EOLN
static
void SkipEOLN(cmsIT8* it8)
{
    while (it8->sy == SEOLN) {
             InSymbol(it8);
    }
}
 
 
// Returns a string holding current value
static
cmsBool GetVal(cmsIT8* it8, char* Buffer, cmsUInt32Number max, const char* ErrorTitle)
{
    switch (it8->sy) {
 
    case SEOLN:   // Empty value
                  Buffer[0]=0;
                  break;
    case SIDENT:  strncpy(Buffer, it8->id, max);
                  Buffer[max-1]=0;
                  break;
    case SINUM:   snprintf(Buffer, max, "%d", it8 -> inum); break;
    case SDNUM:   snprintf(Buffer, max, it8->DoubleFormatter, it8 -> dnum); break;
    case SSTRING: strncpy(Buffer, it8->str, max);
                  Buffer[max-1] = 0;
                  break;
 
 
    default:
         return SynError(it8, "%s", ErrorTitle);
    }
 
    Buffer[max] = 0;
    return TRUE;
}
 
// ---------------------------------------------------------- Table
 
static
TABLE* GetTable(cmsIT8* it8)
{
   if ((it8 -> nTable >= it8 ->TablesCount)) {
 
           SynError(it8, "Table %d out of sequence", it8 -> nTable);
           return it8 -> Tab;
   }
 
   return it8 ->Tab + it8 ->nTable;
}
 
// ---------------------------------------------------------- Memory management
 
 
// Frees an allocator and owned memory
void CMSEXPORT cmsIT8Free(cmsHANDLE hIT8)
{
   cmsIT8* it8 = (cmsIT8*) hIT8;
 
    if (it8 == NULL)
        return;
 
    if (it8->MemorySink) {
 
        OWNEDMEM* p;
        OWNEDMEM* n;
 
        for (p = it8->MemorySink; p != NULL; p = n) {
 
            n = p->Next;
            if (p->Ptr) _cmsFree(it8 ->ContextID, p->Ptr);
            _cmsFree(it8 ->ContextID, p);
        }
    }
 
    if (it8->MemoryBlock)
        _cmsFree(it8 ->ContextID, it8->MemoryBlock);
 
    _cmsFree(it8 ->ContextID, it8);
}
 
 
// Allocates a chunk of data, keep linked list
static
void* AllocBigBlock(cmsIT8* it8, cmsUInt32Number size)
{
    OWNEDMEM* ptr1;
    void* ptr = _cmsMallocZero(it8->ContextID, size);
 
    if (ptr != NULL) {
 
        ptr1 = (OWNEDMEM*) _cmsMallocZero(it8 ->ContextID, sizeof(OWNEDMEM));
 
        if (ptr1 == NULL) {
 
            _cmsFree(it8 ->ContextID, ptr);
            return NULL;
        }
 
        ptr1-> Ptr        = ptr;
        ptr1-> Next       = it8 -> MemorySink;
        it8 -> MemorySink = ptr1;
    }
 
    return ptr;
}
 
 
// Suballocator.
static
void* AllocChunk(cmsIT8* it8, cmsUInt32Number size)
{
    cmsUInt32Number Free = it8 ->Allocator.BlockSize - it8 ->Allocator.Used;
    cmsUInt8Number* ptr;
 
    size = _cmsALIGNMEM(size);
 
    if (size > Free) {
 
        if (it8 -> Allocator.BlockSize == 0)
 
                it8 -> Allocator.BlockSize = 20*1024;
        else
                it8 ->Allocator.BlockSize *= 2;
 
        if (it8 ->Allocator.BlockSize < size)
                it8 ->Allocator.BlockSize = size;
 
        it8 ->Allocator.Used = 0;
        it8 ->Allocator.Block = (cmsUInt8Number*)  AllocBigBlock(it8, it8 ->Allocator.BlockSize);
    }
 
    ptr = it8 ->Allocator.Block + it8 ->Allocator.Used;
    it8 ->Allocator.Used += size;
 
    return (void*) ptr;
 
}
 
 
// Allocates a string
static
char *AllocString(cmsIT8* it8, const char* str)
{
    cmsUInt32Number Size = (cmsUInt32Number) strlen(str)+1;
    char *ptr;
 
 
    ptr = (char *) AllocChunk(it8, Size);
    if (ptr) strncpy (ptr, str, Size-1);
 
    return ptr;
}
 
// Searches through linked list
 
static
cmsBool IsAvailableOnList(KEYVALUE* p, const char* Key, const char* Subkey, KEYVALUE** LastPtr)
{
    if (LastPtr) *LastPtr = p;
 
    for (;  p != NULL; p = p->Next) {
 
        if (LastPtr) *LastPtr = p;
 
        if (*Key != '#') { // Comments are ignored
 
            if (cmsstrcasecmp(Key, p->Keyword) == 0)
                break;
        }
    }
 
    if (p == NULL)
        return FALSE;
 
    if (Subkey == 0)
        return TRUE;
 
    for (; p != NULL; p = p->NextSubkey) {
 
        if (p ->Subkey == NULL) continue;
 
        if (LastPtr) *LastPtr = p;
 
        if (cmsstrcasecmp(Subkey, p->Subkey) == 0)
            return TRUE;
    }
 
    return FALSE;
}
 
 
 
// Add a property into a linked list
static
KEYVALUE* AddToList(cmsIT8* it8, KEYVALUE** Head, const char *Key, const char *Subkey, const char* xValue, WRITEMODE WriteAs)
{
    KEYVALUE* p;
    KEYVALUE* last;
 
 
    // Check if property is already in list
 
    if (IsAvailableOnList(*Head, Key, Subkey, &p)) {
 
        // This may work for editing properties
 
        //     return SynError(it8, "duplicate key <%s>", Key);
    }
    else {
 
        last = p;
 
        // Allocate the container
        p = (KEYVALUE*) AllocChunk(it8, sizeof(KEYVALUE));
        if (p == NULL)
        {
            SynError(it8, "AddToList: out of memory");
            return NULL;
        }
 
        // Store name and value
        p->Keyword = AllocString(it8, Key);
        p->Subkey = (Subkey == NULL) ? NULL : AllocString(it8, Subkey);
 
        // Keep the container in our list
        if (*Head == NULL) {
            *Head = p;
        }
        else
        {
            if (Subkey != NULL && last != NULL) {
 
                last->NextSubkey = p;
 
                // If Subkey is not null, then last is the last property with the same key,
                // but not necessarily is the last property in the list, so we need to move
                // to the actual list end
                while (last->Next != NULL)
                         last = last->Next;
            }
 
            if (last != NULL) last->Next = p;
        }
 
        p->Next    = NULL;
        p->NextSubkey = NULL;
    }
 
    p->WriteAs = WriteAs;
 
    if (xValue != NULL) {
 
        p->Value   = AllocString(it8, xValue);
    }
    else {
        p->Value   = NULL;
    }
 
    return p;
}
 
static
KEYVALUE* AddAvailableProperty(cmsIT8* it8, const char* Key, WRITEMODE as)
{
    return AddToList(it8, &it8->ValidKeywords, Key, NULL, NULL, as);
}
 
 
static
KEYVALUE* AddAvailableSampleID(cmsIT8* it8, const char* Key)
{
    return AddToList(it8, &it8->ValidSampleID, Key, NULL, NULL, WRITE_UNCOOKED);
}
 
 
static
void AllocTable(cmsIT8* it8)
{
    TABLE* t;
 
    t = it8 ->Tab + it8 ->TablesCount;
 
    t->HeaderList = NULL;
    t->DataFormat = NULL;
    t->Data       = NULL;
 
    it8 ->TablesCount++;
}
 
 
cmsInt32Number CMSEXPORT cmsIT8SetTable(cmsHANDLE  IT8, cmsUInt32Number nTable)
{
     cmsIT8* it8 = (cmsIT8*) IT8;
 
     if (nTable >= it8 ->TablesCount) {
 
         if (nTable == it8 ->TablesCount) {
 
             AllocTable(it8);
         }
         else {
             SynError(it8, "Table %d is out of sequence", nTable);
             return -1;
         }
     }
 
     it8 ->nTable = nTable;
 
     return (cmsInt32Number) nTable;
}
 
 
 
// Init an empty container
cmsHANDLE  CMSEXPORT cmsIT8Alloc(cmsContext ContextID)
{
    cmsIT8* it8;
    cmsUInt32Number i;
 
    it8 = (cmsIT8*) _cmsMallocZero(ContextID, sizeof(cmsIT8));
    if (it8 == NULL) return NULL;
 
    AllocTable(it8);
 
    it8->MemoryBlock = NULL;
    it8->MemorySink  = NULL;
 
    it8 ->nTable = 0;
 
    it8->ContextID = ContextID;
    it8->Allocator.Used = 0;
    it8->Allocator.Block = NULL;
    it8->Allocator.BlockSize = 0;
 
    it8->ValidKeywords = NULL;
    it8->ValidSampleID = NULL;
 
    it8 -> sy = SUNDEFINED;
    it8 -> ch = ' ';
    it8 -> Source = NULL;
    it8 -> inum = 0;
    it8 -> dnum = 0.0;
 
    it8->FileStack[0] = (FILECTX*)AllocChunk(it8, sizeof(FILECTX));
    it8->IncludeSP   = 0;
    it8 -> lineno = 1;
 
    strcpy(it8->DoubleFormatter, DEFAULT_DBL_FORMAT);
    cmsIT8SetSheetType((cmsHANDLE) it8, "CGATS.17");
 
    // Initialize predefined properties & data
 
    for (i=0; i < NUMPREDEFINEDPROPS; i++)
            AddAvailableProperty(it8, PredefinedProperties[i].id, PredefinedProperties[i].as);
 
    for (i=0; i < NUMPREDEFINEDSAMPLEID; i++)
            AddAvailableSampleID(it8, PredefinedSampleID[i]);
 
 
   return (cmsHANDLE) it8;
}
 
 
const char* CMSEXPORT cmsIT8GetSheetType(cmsHANDLE hIT8)
{
        return GetTable((cmsIT8*) hIT8)->SheetType;
}
 
cmsBool CMSEXPORT cmsIT8SetSheetType(cmsHANDLE hIT8, const char* Type)
{
        TABLE* t = GetTable((cmsIT8*) hIT8);
 
        strncpy(t ->SheetType, Type, MAXSTR-1);
        t ->SheetType[MAXSTR-1] = 0;
        return TRUE;
}
 
cmsBool CMSEXPORT cmsIT8SetComment(cmsHANDLE hIT8, const char* Val)
{
    cmsIT8* it8 = (cmsIT8*) hIT8;
 
    if (!Val) return FALSE;
    if (!*Val) return FALSE;
 
    return AddToList(it8, &GetTable(it8)->HeaderList, "# ", NULL, Val, WRITE_UNCOOKED) != NULL;
}
 
// Sets a property
cmsBool CMSEXPORT cmsIT8SetPropertyStr(cmsHANDLE hIT8, const char* Key, const char *Val)
{
    cmsIT8* it8 = (cmsIT8*) hIT8;
 
    if (!Val) return FALSE;
    if (!*Val) return FALSE;
 
    return AddToList(it8, &GetTable(it8)->HeaderList, Key, NULL, Val, WRITE_STRINGIFY) != NULL;
}
 
cmsBool CMSEXPORT cmsIT8SetPropertyDbl(cmsHANDLE hIT8, const char* cProp, cmsFloat64Number Val)
{
    cmsIT8* it8 = (cmsIT8*) hIT8;
    char Buffer[1024];
 
    snprintf(Buffer, 1023, it8->DoubleFormatter, Val);
 
    return AddToList(it8, &GetTable(it8)->HeaderList, cProp, NULL, Buffer, WRITE_UNCOOKED) != NULL;
}
 
cmsBool CMSEXPORT cmsIT8SetPropertyHex(cmsHANDLE hIT8, const char* cProp, cmsUInt32Number Val)
{
    cmsIT8* it8 = (cmsIT8*) hIT8;
    char Buffer[1024];
 
    snprintf(Buffer, 1023, "%u", Val);
 
    return AddToList(it8, &GetTable(it8)->HeaderList, cProp, NULL, Buffer, WRITE_HEXADECIMAL) != NULL;
}
 
cmsBool CMSEXPORT cmsIT8SetPropertyUncooked(cmsHANDLE hIT8, const char* Key, const char* Buffer)
{
    cmsIT8* it8 = (cmsIT8*) hIT8;
 
    return AddToList(it8, &GetTable(it8)->HeaderList, Key, NULL, Buffer, WRITE_UNCOOKED) != NULL;
}
 
cmsBool CMSEXPORT cmsIT8SetPropertyMulti(cmsHANDLE hIT8, const char* Key, const char* SubKey, const char *Buffer)
{
    cmsIT8* it8 = (cmsIT8*) hIT8;
 
    return AddToList(it8, &GetTable(it8)->HeaderList, Key, SubKey, Buffer, WRITE_PAIR) != NULL;
}
 
// Gets a property
const char* CMSEXPORT cmsIT8GetProperty(cmsHANDLE hIT8, const char* Key)
{
    cmsIT8* it8 = (cmsIT8*) hIT8;
    KEYVALUE* p;
 
    if (IsAvailableOnList(GetTable(it8) -> HeaderList, Key, NULL, &p))
    {
        return p -> Value;
    }
    return NULL;
}
 
 
cmsFloat64Number CMSEXPORT cmsIT8GetPropertyDbl(cmsHANDLE hIT8, const char* cProp)
{
    const char *v = cmsIT8GetProperty(hIT8, cProp);
 
    if (v == NULL) return 0.0;
 
    return ParseFloatNumber(v);
}
 
const char* CMSEXPORT cmsIT8GetPropertyMulti(cmsHANDLE hIT8, const char* Key, const char *SubKey)
{
    cmsIT8* it8 = (cmsIT8*) hIT8;
    KEYVALUE* p;
 
    if (IsAvailableOnList(GetTable(it8) -> HeaderList, Key, SubKey, &p)) {
        return p -> Value;
    }
    return NULL;
}
 
// ----------------------------------------------------------------- Datasets
 
 
static
void AllocateDataFormat(cmsIT8* it8)
{
    TABLE* t = GetTable(it8);
 
    if (t -> DataFormat) return;    // Already allocated
 
    t -> nSamples  = (int) cmsIT8GetPropertyDbl(it8, "NUMBER_OF_FIELDS");
 
    if (t -> nSamples <= 0) {
 
        SynError(it8, "AllocateDataFormat: Unknown NUMBER_OF_FIELDS");
        t -> nSamples = 10;
        }
 
    t -> DataFormat = (char**) AllocChunk (it8, ((cmsUInt32Number) t->nSamples + 1) * sizeof(char *));
    if (t->DataFormat == NULL) {
 
        SynError(it8, "AllocateDataFormat: Unable to allocate dataFormat array");
    }
 
}
 
static
const char *GetDataFormat(cmsIT8* it8, int n)
{
    TABLE* t = GetTable(it8);
 
    if (t->DataFormat)
        return t->DataFormat[n];
 
    return NULL;
}
 
static
cmsBool SetDataFormat(cmsIT8* it8, int n, const char *label)
{
    TABLE* t = GetTable(it8);
 
    if (!t->DataFormat)
        AllocateDataFormat(it8);
 
    if (n > t -> nSamples) {
        SynError(it8, "More than NUMBER_OF_FIELDS fields.");
        return FALSE;
    }
 
    if (t->DataFormat) {
        t->DataFormat[n] = AllocString(it8, label);
    }
 
    return TRUE;
}
 
 
cmsBool CMSEXPORT cmsIT8SetDataFormat(cmsHANDLE  h, int n, const char *Sample)
{
    cmsIT8* it8 = (cmsIT8*)h;
    return SetDataFormat(it8, n, Sample);
}
 
// A safe atoi that returns 0 when NULL input is given
static
cmsInt32Number satoi(const char* b)
{
    if (b == NULL) return 0;
    return atoi(b);
}
 
// Convert to binary
static
const char* satob(const char* v)
{
    cmsUInt32Number x;
    static char buf[33];
    char *s = buf + 33;
    
    if (v == NULL) return "0";
    
    x = atoi(v);
    *--s = 0;
    if (!x) *--s = '0';
    for (; x; x /= 2) *--s = '0' + x%2;
    
    return s;
}
 
 
static
void AllocateDataSet(cmsIT8* it8)
{
    TABLE* t = GetTable(it8);
 
    if (t -> Data) return;    // Already allocated
 
    t-> nSamples   = satoi(cmsIT8GetProperty(it8, "NUMBER_OF_FIELDS"));
    t-> nPatches   = satoi(cmsIT8GetProperty(it8, "NUMBER_OF_SETS"));
 
    if (t -> nSamples < 0 || t->nSamples > 0x7ffe || t->nPatches < 0 || t->nPatches > 0x7ffe)
    {
        SynError(it8, "AllocateDataSet: too much data");
    }
    else {
        // Some dumb analizers warns of possible overflow here, just take a look couple of lines above.
        t->Data = (char**)AllocChunk(it8, ((cmsUInt32Number)t->nSamples + 1) * ((cmsUInt32Number)t->nPatches + 1) * sizeof(char*));
        if (t->Data == NULL) {
 
            SynError(it8, "AllocateDataSet: Unable to allocate data array");
        }
    }
 
}
 
static
char* GetData(cmsIT8* it8, int nSet, int nField)
{
    TABLE* t = GetTable(it8);
    int nSamples    = t -> nSamples;
    int nPatches    = t -> nPatches;
 
    if (nSet >= nPatches || nField >= nSamples)
        return NULL;
 
    if (!t->Data) return NULL;
    return t->Data [nSet * nSamples + nField];
}
 
static
cmsBool SetData(cmsIT8* it8, int nSet, int nField, const char *Val)
{
    TABLE* t = GetTable(it8);
 
    if (!t->Data)
        AllocateDataSet(it8);
 
    if (!t->Data) return FALSE;
 
    if (nSet > t -> nPatches || nSet < 0) {
 
            return SynError(it8, "Patch %d out of range, there are %d patches", nSet, t -> nPatches);
    }
 
    if (nField > t ->nSamples || nField < 0) {
            return SynError(it8, "Sample %d out of range, there are %d samples", nField, t ->nSamples);
 
    }
 
    t->Data [nSet * t -> nSamples + nField] = AllocString(it8, Val);
    return TRUE;
}
 
 
// --------------------------------------------------------------- File I/O
 
 
// Writes a string to file
static
void WriteStr(SAVESTREAM* f, const char *str)
{
    cmsUInt32Number len;
 
    if (str == NULL)
        str = " ";
 
    // Length to write
    len = (cmsUInt32Number) strlen(str);
    f ->Used += len;
 
 
    if (f ->stream) {   // Should I write it to a file?
 
        if (fwrite(str, 1, len, f->stream) != len) {
            cmsSignalError(0, cmsERROR_WRITE, "Write to file error in CGATS parser");
            return;
        }
 
    }
    else {  // Or to a memory block?
 
        if (f ->Base) {   // Am I just counting the bytes?
 
            if (f ->Used > f ->Max) {
 
                 cmsSignalError(0, cmsERROR_WRITE, "Write to memory overflows in CGATS parser");
                 return;
            }
 
            memmove(f ->Ptr, str, len);
            f->Ptr += len;
        }
 
    }
}
 
 
// Write formatted
 
static
void Writef(SAVESTREAM* f, const char* frm, ...)
{
    char Buffer[4096];
    va_list args;
 
    va_start(args, frm);
    vsnprintf(Buffer, 4095, frm, args);
    Buffer[4095] = 0;
    WriteStr(f, Buffer);
    va_end(args);
 
}
 
// Writes full header
static
void WriteHeader(cmsIT8* it8, SAVESTREAM* fp)
{
    KEYVALUE* p;
    TABLE* t = GetTable(it8);
 
    // Writes the type
    WriteStr(fp, t->SheetType);
    WriteStr(fp, "\n");
 
    for (p = t->HeaderList; (p != NULL); p = p->Next)
    {
        if (*p ->Keyword == '#') {
 
            char* Pt;
 
            WriteStr(fp, "#\n# ");
            for (Pt = p ->Value; *Pt; Pt++) {
 
 
                Writef(fp, "%c", *Pt);
 
                if (*Pt == '\n') {
                    WriteStr(fp, "# ");
                }
            }
 
            WriteStr(fp, "\n#\n");
            continue;
        }
 
 
        if (!IsAvailableOnList(it8-> ValidKeywords, p->Keyword, NULL, NULL)) {
 
#ifdef CMS_STRICT_CGATS
            WriteStr(fp, "KEYWORD\t\"");
            WriteStr(fp, p->Keyword);
            WriteStr(fp, "\"\n");
#endif
 
            AddAvailableProperty(it8, p->Keyword, WRITE_UNCOOKED);
        }
 
        WriteStr(fp, p->Keyword);
        if (p->Value) {
 
            switch (p ->WriteAs) {
 
            case WRITE_UNCOOKED:
                    Writef(fp, "\t%s", p ->Value);
                    break;
 
            case WRITE_STRINGIFY:
                    Writef(fp, "\t\"%s\"", p->Value );
                    break;
 
            case WRITE_HEXADECIMAL:
                    Writef(fp, "\t0x%X", satoi(p ->Value));
                    break;
 
            case WRITE_BINARY:
                    Writef(fp, "\t0b%s", satob(p ->Value));
                    break;
 
            case WRITE_PAIR:
                    Writef(fp, "\t\"%s,%s\"", p->Subkey, p->Value);
                    break;
 
            default: SynError(it8, "Unknown write mode %d", p ->WriteAs);
                     return;
            }
        }
 
        WriteStr (fp, "\n");
    }
 
}
 
 
// Writes the data format
static
void WriteDataFormat(SAVESTREAM* fp, cmsIT8* it8)
{
    int i, nSamples;
    TABLE* t = GetTable(it8);
 
    if (!t -> DataFormat) return;
 
       WriteStr(fp, "BEGIN_DATA_FORMAT\n");
       WriteStr(fp, " ");
       nSamples = satoi(cmsIT8GetProperty(it8, "NUMBER_OF_FIELDS"));
 
       for (i = 0; i < nSamples; i++) {
 
              WriteStr(fp, t->DataFormat[i]);
              WriteStr(fp, ((i == (nSamples-1)) ? "\n" : "\t"));
          }
 
       WriteStr (fp, "END_DATA_FORMAT\n");
}
 
 
// Writes data array
static
void WriteData(SAVESTREAM* fp, cmsIT8* it8)
{
       int  i, j;
       TABLE* t = GetTable(it8);
 
       if (!t->Data) return;
 
       WriteStr (fp, "BEGIN_DATA\n");
 
       t->nPatches = satoi(cmsIT8GetProperty(it8, "NUMBER_OF_SETS"));
 
       for (i = 0; i < t-> nPatches; i++) {
 
              WriteStr(fp, " ");
 
              for (j = 0; j < t->nSamples; j++) {
 
                     char *ptr = t->Data[i*t->nSamples+j];
 
                     if (ptr == NULL) WriteStr(fp, "\"\"");
                     else {
                         // If value contains whitespace, enclose within quote
 
                         if (strchr(ptr, ' ') != NULL) {
 
                             WriteStr(fp, "\"");
                             WriteStr(fp, ptr);
                             WriteStr(fp, "\"");
                         }
                         else
                            WriteStr(fp, ptr);
                     }
 
                     WriteStr(fp, ((j == (t->nSamples-1)) ? "\n" : "\t"));
              }
       }
       WriteStr (fp, "END_DATA\n");
}
 
 
 
// Saves whole file
cmsBool CMSEXPORT cmsIT8SaveToFile(cmsHANDLE hIT8, const char* cFileName)
{
    SAVESTREAM sd;
    cmsUInt32Number i;
    cmsIT8* it8 = (cmsIT8*) hIT8;
 
    memset(&sd, 0, sizeof(sd));
 
    sd.stream = fopen(cFileName, "wt");
    if (!sd.stream) return FALSE;
 
    for (i=0; i < it8 ->TablesCount; i++) {
 
            cmsIT8SetTable(hIT8, i);
            WriteHeader(it8, &sd);
            WriteDataFormat(&sd, it8);
            WriteData(&sd, it8);
    }
 
    if (fclose(sd.stream) != 0) return FALSE;
 
    return TRUE;
}
 
 
// Saves to memory
cmsBool CMSEXPORT cmsIT8SaveToMem(cmsHANDLE hIT8, void *MemPtr, cmsUInt32Number* BytesNeeded)
{
    SAVESTREAM sd;
    cmsUInt32Number i;
    cmsIT8* it8 = (cmsIT8*) hIT8;
 
    memset(&sd, 0, sizeof(sd));
 
    sd.stream = NULL;
    sd.Base   = (cmsUInt8Number*)  MemPtr;
    sd.Ptr    = sd.Base;
 
    sd.Used = 0;
 
    if (sd.Base)
        sd.Max  = *BytesNeeded;     // Write to memory?
    else
        sd.Max  = 0;                // Just counting the needed bytes
 
    for (i=0; i < it8 ->TablesCount; i++) {
 
        cmsIT8SetTable(hIT8, i);
        WriteHeader(it8, &sd);
        WriteDataFormat(&sd, it8);
        WriteData(&sd, it8);
    }
 
    sd.Used++;  // The \0 at the very end
 
    if (sd.Base)
        *sd.Ptr = 0;
 
    *BytesNeeded = sd.Used;
 
    return TRUE;
}
 
 
// -------------------------------------------------------------- Higher level parsing
 
static
cmsBool DataFormatSection(cmsIT8* it8)
{
    int iField = 0;
    TABLE* t = GetTable(it8);
 
    InSymbol(it8);   // Eats "BEGIN_DATA_FORMAT"
    CheckEOLN(it8);
 
    while (it8->sy != SEND_DATA_FORMAT &&
        it8->sy != SEOLN &&
        it8->sy != SEOF &&
        it8->sy != SSYNERROR)  {
 
            if (it8->sy != SIDENT) {
 
                return SynError(it8, "Sample type expected");
            }
 
            if (!SetDataFormat(it8, iField, it8->id)) return FALSE;
            iField++;
 
            InSymbol(it8);
            SkipEOLN(it8);
       }
 
       SkipEOLN(it8);
       Skip(it8, SEND_DATA_FORMAT);
       SkipEOLN(it8);
 
       if (iField != t ->nSamples) {
           SynError(it8, "Count mismatch. NUMBER_OF_FIELDS was %d, found %d\n", t ->nSamples, iField);
 
 
       }
 
       return TRUE;
}
 
 
 
static
cmsBool DataSection (cmsIT8* it8)
{
    int  iField = 0;
    int  iSet   = 0;
    char Buffer[256];
    TABLE* t = GetTable(it8);
 
    InSymbol(it8);   // Eats "BEGIN_DATA"
    CheckEOLN(it8);
 
    if (!t->Data)
        AllocateDataSet(it8);
 
    while (it8->sy != SEND_DATA && it8->sy != SEOF)
    {
        if (iField >= t -> nSamples) {
            iField = 0;
            iSet++;
 
        }
 
        if (it8->sy != SEND_DATA && it8->sy != SEOF) {
 
            if (!GetVal(it8, Buffer, 255, "Sample data expected"))
                return FALSE;
 
            if (!SetData(it8, iSet, iField, Buffer))
                return FALSE;
 
            iField++;
 
            InSymbol(it8);
            SkipEOLN(it8);
        }
    }
 
    SkipEOLN(it8);
    Skip(it8, SEND_DATA);
    SkipEOLN(it8);
 
    // Check for data completion.
 
    if ((iSet+1) != t -> nPatches)
        return SynError(it8, "Count mismatch. NUMBER_OF_SETS was %d, found %d\n", t ->nPatches, iSet+1);
 
    return TRUE;
}
 
 
 
 
static
cmsBool HeaderSection(cmsIT8* it8)
{
    char VarName[MAXID];
    char Buffer[MAXSTR];
    KEYVALUE* Key;
 
        while (it8->sy != SEOF &&
               it8->sy != SSYNERROR &&
               it8->sy != SBEGIN_DATA_FORMAT &&
               it8->sy != SBEGIN_DATA) {
 
 
        switch (it8 -> sy) {
 
        case SKEYWORD:
                InSymbol(it8);
                if (!GetVal(it8, Buffer, MAXSTR-1, "Keyword expected")) return FALSE;
                if (!AddAvailableProperty(it8, Buffer, WRITE_UNCOOKED)) return FALSE;
                InSymbol(it8);
                break;
 
 
        case SDATA_FORMAT_ID:
                InSymbol(it8);
                if (!GetVal(it8, Buffer, MAXSTR-1, "Keyword expected")) return FALSE;
                if (!AddAvailableSampleID(it8, Buffer)) return FALSE;
                InSymbol(it8);
                break;
 
 
        case SIDENT:
            strncpy(VarName, it8->id, MAXID - 1);
            VarName[MAXID - 1] = 0;
 
            if (!IsAvailableOnList(it8->ValidKeywords, VarName, NULL, &Key)) {
 
#ifdef CMS_STRICT_CGATS
                return SynError(it8, "Undefined keyword '%s'", VarName);
#else
                Key = AddAvailableProperty(it8, VarName, WRITE_UNCOOKED);
                if (Key == NULL) return FALSE;
#endif
            }
 
            InSymbol(it8);
            if (!GetVal(it8, Buffer, MAXSTR - 1, "Property data expected")) return FALSE;
 
            if (Key->WriteAs != WRITE_PAIR) {
                AddToList(it8, &GetTable(it8)->HeaderList, VarName, NULL, Buffer,
                    (it8->sy == SSTRING) ? WRITE_STRINGIFY : WRITE_UNCOOKED);
            }
            else {
                const char *Subkey;
                char *Nextkey;
                if (it8->sy != SSTRING)
                    return SynError(it8, "Invalid value '%s' for property '%s'.", Buffer, VarName);
 
                // chop the string as a list of "subkey, value" pairs, using ';' as a separator
                for (Subkey = Buffer; Subkey != NULL; Subkey = Nextkey)
                {
                    char *Value, *temp;
 
                    //  identify token pair boundary
                    Nextkey = (char*)strchr(Subkey, ';');
                    if (Nextkey)
                        *Nextkey++ = '\0';
 
                    // for each pair, split the subkey and the value
                    Value = (char*)strrchr(Subkey, ',');
                    if (Value == NULL)
                        return SynError(it8, "Invalid value for property '%s'.", VarName);
 
                    // gobble the spaces before the coma, and the coma itself
                    temp = Value++;
                    do *temp-- = '\0'; while (temp >= Subkey && *temp == ' ');
 
                    // gobble any space at the right
                    temp = Value + strlen(Value) - 1;
                    while (*temp == ' ') *temp-- = '\0';
 
                    // trim the strings from the left
                    Subkey += strspn(Subkey, " ");
                    Value += strspn(Value, " ");
 
                    if (Subkey[0] == 0 || Value[0] == 0)
                        return SynError(it8, "Invalid value for property '%s'.", VarName);
                    AddToList(it8, &GetTable(it8)->HeaderList, VarName, Subkey, Value, WRITE_PAIR);
                }
            }
 
            InSymbol(it8);
            break;
 
 
        case SEOLN: break;
 
        default:
                return SynError(it8, "expected keyword or identifier");
        }
 
    SkipEOLN(it8);
    }
 
    return TRUE;
 
}
 
 
static
void ReadType(cmsIT8* it8, char* SheetTypePtr)
{
    cmsInt32Number cnt = 0;
 
    // First line is a very special case.
 
    while (isseparator(it8->ch))
            NextCh(it8);
 
    while (it8->ch != '\r' && it8 ->ch != '\n' && it8->ch != '\t' && it8 -> ch != 0) {
 
        if (cnt++ < MAXSTR) 
            *SheetTypePtr++= (char) it8 ->ch;
        NextCh(it8);
    }
 
    *SheetTypePtr = 0;
}
 
 
static
cmsBool ParseIT8(cmsIT8* it8, cmsBool nosheet)
{
    char* SheetTypePtr = it8 ->Tab[0].SheetType;
 
    if (nosheet == 0) {
        ReadType(it8, SheetTypePtr);
    }
 
    InSymbol(it8);
 
    SkipEOLN(it8);
 
    while (it8-> sy != SEOF &&
           it8-> sy != SSYNERROR) {
 
            switch (it8 -> sy) {
 
            case SBEGIN_DATA_FORMAT:
                    if (!DataFormatSection(it8)) return FALSE;
                    break;
 
            case SBEGIN_DATA:
 
                    if (!DataSection(it8)) return FALSE;
 
                    if (it8 -> sy != SEOF) {
 
                            AllocTable(it8);
                            it8 ->nTable = it8 ->TablesCount - 1;
 
                            // Read sheet type if present. We only support identifier and string.
                            // <ident> <eoln> is a type string
                            // anything else, is not a type string
                            if (nosheet == 0) {
 
                                if (it8 ->sy == SIDENT) {
 
                                    // May be a type sheet or may be a prop value statement. We cannot use insymbol in
                                    // this special case...
                                     while (isseparator(it8->ch))
                                         NextCh(it8);
 
                                     // If a newline is found, then this is a type string
                                    if (it8 ->ch == '\n' || it8->ch == '\r') {
 
                                         cmsIT8SetSheetType(it8, it8 ->id);
                                         InSymbol(it8);
                                    }
                                    else
                                    {
                                        // It is not. Just continue
                                        cmsIT8SetSheetType(it8, "");
                                    }
                                }
                                else
                                    // Validate quoted strings
                                    if (it8 ->sy == SSTRING) {
                                        cmsIT8SetSheetType(it8, it8 ->str);
                                        InSymbol(it8);
                                    }
                           }
 
                    }
                    break;
 
            case SEOLN:
                    SkipEOLN(it8);
                    break;
 
            default:
                    if (!HeaderSection(it8)) return FALSE;
           }
 
    }
 
    return (it8 -> sy != SSYNERROR);
}
 
 
 
// Init useful pointers
 
static
void CookPointers(cmsIT8* it8)
{
    int idField, i;
    char* Fld;
    cmsUInt32Number j;
    cmsUInt32Number nOldTable = it8 ->nTable;
 
    for (j=0; j < it8 ->TablesCount; j++) {
 
    TABLE* t = it8 ->Tab + j;
 
    t -> SampleID = 0;
    it8 ->nTable = j;
 
    for (idField = 0; idField < t -> nSamples; idField++)
    {
        if (t ->DataFormat == NULL){
            SynError(it8, "Undefined DATA_FORMAT");
            return;
        }
 
        Fld = t->DataFormat[idField];
        if (!Fld) continue;
 
 
        if (cmsstrcasecmp(Fld, "SAMPLE_ID") == 0) {
 
            t -> SampleID = idField;            
        }
 
        // "LABEL" is an extension. It keeps references to forward tables
 
        if ((cmsstrcasecmp(Fld, "LABEL") == 0) || Fld[0] == '$') {
 
            // Search for table references...
            for (i = 0; i < t->nPatches; i++) {
 
                char* Label = GetData(it8, i, idField);
 
                if (Label) {
 
                    cmsUInt32Number k;
 
                    // This is the label, search for a table containing
                    // this property
 
                    for (k = 0; k < it8->TablesCount; k++) {
 
                        TABLE* Table = it8->Tab + k;
                        KEYVALUE* p;
 
                        if (IsAvailableOnList(Table->HeaderList, Label, NULL, &p)) {
 
                            // Available, keep type and table
                            char Buffer[256];
 
                            char* Type = p->Value;
                            int  nTable = (int)k;
 
                            snprintf(Buffer, 255, "%s %d %s", Label, nTable, Type);
 
                            SetData(it8, i, idField, Buffer);
                        }
                    }
 
 
                }
 
            }
 
 
        }
 
    }
    }
 
    it8 ->nTable = nOldTable;
}
 
// Try to infere if the file is a CGATS/IT8 file at all. Read first line
// that should be something like some printable characters plus a \n
// returns 0 if this is not like a CGATS, or an integer otherwise. This integer is the number of words in first line?
static
int IsMyBlock(const cmsUInt8Number* Buffer, cmsUInt32Number n)
{
    int words = 1, space = 0, quot = 0;
    cmsUInt32Number i;
 
    if (n < 10) return 0;   // Too small
 
    if (n > 132)
        n = 132;
 
    for (i = 1; i < n; i++) {
 
        switch(Buffer[i])
        {
        case '\n':
        case '\r':
            return ((quot == 1) || (words > 2)) ? 0 : words;
        case '\t':
        case ' ':
            if(!quot && !space)
                space = 1;
            break;
        case '\"':
            quot = !quot;
            break;
        default:
            if (Buffer[i] < 32) return 0;
            if (Buffer[i] > 127) return 0;
            words += space;
            space = 0;
            break;
        }
    }
 
    return 0;
}
 
 
static
cmsBool IsMyFile(const char* FileName)
{
   FILE *fp;
   cmsUInt32Number Size;
   cmsUInt8Number Ptr[133];
 
   fp = fopen(FileName, "rt");
   if (!fp) {
       cmsSignalError(0, cmsERROR_FILE, "File '%s' not found", FileName);
       return FALSE;
   }
 
   Size = (cmsUInt32Number) fread(Ptr, 1, 132, fp);
 
   if (fclose(fp) != 0)
       return FALSE;
 
   Ptr[Size] = '\0';
 
   return IsMyBlock(Ptr, Size);
}
 
// ---------------------------------------------------------- Exported routines
 
 
cmsHANDLE  CMSEXPORT cmsIT8LoadFromMem(cmsContext ContextID, const void *Ptr, cmsUInt32Number len)
{
    cmsHANDLE hIT8;
    cmsIT8*  it8;
    int type;
 
    _cmsAssert(Ptr != NULL);
    _cmsAssert(len != 0);
 
    type = IsMyBlock((const cmsUInt8Number*)Ptr, len);
    if (type == 0) return NULL;
 
    hIT8 = cmsIT8Alloc(ContextID);
    if (!hIT8) return NULL;
 
    it8 = (cmsIT8*) hIT8;
    it8 ->MemoryBlock = (char*) _cmsMalloc(ContextID, len + 1);
    if (it8->MemoryBlock == NULL)
    {
        cmsIT8Free(hIT8);
        return FALSE;
    }
 
    strncpy(it8 ->MemoryBlock, (const char*) Ptr, len);
    it8 ->MemoryBlock[len] = 0;
 
    strncpy(it8->FileStack[0]->FileName, "", cmsMAX_PATH-1);
    it8-> Source = it8 -> MemoryBlock;
 
    if (!ParseIT8(it8, type-1)) {
 
        cmsIT8Free(hIT8);
        return FALSE;
    }
 
    CookPointers(it8);
    it8 ->nTable = 0;
 
    _cmsFree(ContextID, it8->MemoryBlock);
    it8 -> MemoryBlock = NULL;
 
    return hIT8;
 
 
}
 
 
cmsHANDLE  CMSEXPORT cmsIT8LoadFromFile(cmsContext ContextID, const char* cFileName)
{
 
     cmsHANDLE hIT8;
     cmsIT8*  it8;
     int type;
 
     _cmsAssert(cFileName != NULL);
 
     type = IsMyFile(cFileName);
     if (type == 0) return NULL;
 
     hIT8 = cmsIT8Alloc(ContextID);
     it8 = (cmsIT8*) hIT8;
     if (!hIT8) return NULL;
 
 
     it8 ->FileStack[0]->Stream = fopen(cFileName, "rt");
 
     if (!it8 ->FileStack[0]->Stream) {
         cmsIT8Free(hIT8);
         return NULL;
     }
 
 
    strncpy(it8->FileStack[0]->FileName, cFileName, cmsMAX_PATH-1);
    it8->FileStack[0]->FileName[cmsMAX_PATH-1] = 0;
 
    if (!ParseIT8(it8, type-1)) {
 
            fclose(it8 ->FileStack[0]->Stream);
            cmsIT8Free(hIT8);
            return NULL;
    }
 
    CookPointers(it8);
    it8 ->nTable = 0;
 
    if (fclose(it8 ->FileStack[0]->Stream)!= 0) {
            cmsIT8Free(hIT8);
            return NULL;
    }
 
    return hIT8;
 
}
 
int CMSEXPORT cmsIT8EnumDataFormat(cmsHANDLE hIT8, char ***SampleNames)
{
    cmsIT8* it8 = (cmsIT8*) hIT8;
    TABLE* t;
 
    _cmsAssert(hIT8 != NULL);
 
    t = GetTable(it8);
 
    if (SampleNames)
        *SampleNames = t -> DataFormat;
    return t -> nSamples;
}
 
 
cmsUInt32Number CMSEXPORT cmsIT8EnumProperties(cmsHANDLE hIT8, char ***PropertyNames)
{
    cmsIT8* it8 = (cmsIT8*) hIT8;
    KEYVALUE* p;
    cmsUInt32Number n;
    char **Props;
    TABLE* t;
 
    _cmsAssert(hIT8 != NULL);
 
    t = GetTable(it8);
 
    // Pass#1 - count properties
 
    n = 0;
    for (p = t -> HeaderList;  p != NULL; p = p->Next) {
        n++;
    }
 
 
    Props = (char **) AllocChunk(it8, sizeof(char *) * n);
 
    // Pass#2 - Fill pointers
    n = 0;
    for (p = t -> HeaderList;  p != NULL; p = p->Next) {
        Props[n++] = p -> Keyword;
    }
 
    *PropertyNames = Props;
    return n;
}
 
cmsUInt32Number CMSEXPORT cmsIT8EnumPropertyMulti(cmsHANDLE hIT8, const char* cProp, const char ***SubpropertyNames)
{
    cmsIT8* it8 = (cmsIT8*) hIT8;
    KEYVALUE *p, *tmp;
    cmsUInt32Number n;
    const char **Props;
    TABLE* t;
 
    _cmsAssert(hIT8 != NULL);
 
 
    t = GetTable(it8);
 
    if(!IsAvailableOnList(t->HeaderList, cProp, NULL, &p)) {
        *SubpropertyNames = 0;
        return 0;
    }
 
    // Pass#1 - count properties
 
    n = 0;
    for (tmp = p;  tmp != NULL; tmp = tmp->NextSubkey) {
        if(tmp->Subkey != NULL)
            n++;
    }
 
 
    Props = (const char **) AllocChunk(it8, sizeof(char *) * n);
 
    // Pass#2 - Fill pointers
    n = 0;
    for (tmp = p;  tmp != NULL; tmp = tmp->NextSubkey) {
        if(tmp->Subkey != NULL)
            Props[n++] = p ->Subkey;
    }
 
    *SubpropertyNames = Props;
    return n;
}
 
static
int LocatePatch(cmsIT8* it8, const char* cPatch)
{
    int i;
    const char *data;
    TABLE* t = GetTable(it8);
 
    for (i=0; i < t-> nPatches; i++) {
 
        data = GetData(it8, i, t->SampleID);
 
        if (data != NULL) {
 
                if (cmsstrcasecmp(data, cPatch) == 0)
                        return i;
                }
        }
 
        // SynError(it8, "Couldn't find patch '%s'\n", cPatch);
        return -1;
}
 
 
static
int LocateEmptyPatch(cmsIT8* it8)
{
    int i;
    const char *data;
    TABLE* t = GetTable(it8);
 
    for (i=0; i < t-> nPatches; i++) {
 
        data = GetData(it8, i, t->SampleID);
 
        if (data == NULL)
            return i;
 
    }
 
    return -1;
}
 
static
int LocateSample(cmsIT8* it8, const char* cSample)
{
    int i;
    const char *fld;
    TABLE* t = GetTable(it8);
 
    for (i=0; i < t->nSamples; i++) {
 
        fld = GetDataFormat(it8, i);
        if (fld != NULL) {
            if (cmsstrcasecmp(fld, cSample) == 0)
                return i;
        }
    }
 
    return -1;
 
}
 
 
int CMSEXPORT cmsIT8FindDataFormat(cmsHANDLE hIT8, const char* cSample)
{
    cmsIT8* it8 = (cmsIT8*) hIT8;
 
    _cmsAssert(hIT8 != NULL);
 
    return LocateSample(it8, cSample);
}
 
 
 
const char* CMSEXPORT cmsIT8GetDataRowCol(cmsHANDLE hIT8, int row, int col)
{
    cmsIT8* it8 = (cmsIT8*) hIT8;
 
    _cmsAssert(hIT8 != NULL);
 
    return GetData(it8, row, col);
}
 
 
cmsFloat64Number CMSEXPORT cmsIT8GetDataRowColDbl(cmsHANDLE hIT8, int row, int col)
{
    const char* Buffer;
 
    Buffer = cmsIT8GetDataRowCol(hIT8, row, col);
 
    if (Buffer == NULL) return 0.0;
 
    return ParseFloatNumber(Buffer);
}
 
 
cmsBool CMSEXPORT cmsIT8SetDataRowCol(cmsHANDLE hIT8, int row, int col, const char* Val)
{
    cmsIT8* it8 = (cmsIT8*) hIT8;
 
    _cmsAssert(hIT8 != NULL);
 
    return SetData(it8, row, col, Val);
}
 
 
cmsBool CMSEXPORT cmsIT8SetDataRowColDbl(cmsHANDLE hIT8, int row, int col, cmsFloat64Number Val)
{
    cmsIT8* it8 = (cmsIT8*) hIT8;
    char Buff[256];
 
    _cmsAssert(hIT8 != NULL);
 
    snprintf(Buff, 255, it8->DoubleFormatter, Val);
 
    return SetData(it8, row, col, Buff);
}
 
 
 
const char* CMSEXPORT cmsIT8GetData(cmsHANDLE hIT8, const char* cPatch, const char* cSample)
{
    cmsIT8* it8 = (cmsIT8*) hIT8;
    int iField, iSet;
 
    _cmsAssert(hIT8 != NULL);
 
    iField = LocateSample(it8, cSample);
    if (iField < 0) {
        return NULL;
    }
 
    iSet = LocatePatch(it8, cPatch);
    if (iSet < 0) {
            return NULL;
    }
 
    return GetData(it8, iSet, iField);
}
 
 
cmsFloat64Number CMSEXPORT cmsIT8GetDataDbl(cmsHANDLE  it8, const char* cPatch, const char* cSample)
{
    const char* Buffer;
 
    Buffer = cmsIT8GetData(it8, cPatch, cSample);
 
    return ParseFloatNumber(Buffer);
}
 
 
 
cmsBool CMSEXPORT cmsIT8SetData(cmsHANDLE hIT8, const char* cPatch, const char* cSample, const char *Val)
{
    cmsIT8* it8 = (cmsIT8*) hIT8;
    int iField, iSet;
    TABLE* t;
 
    _cmsAssert(hIT8 != NULL);
 
    t = GetTable(it8);
 
    iField = LocateSample(it8, cSample);
 
    if (iField < 0)
        return FALSE;
 
    if (t-> nPatches == 0) {
 
        AllocateDataFormat(it8);
        AllocateDataSet(it8);
        CookPointers(it8);
    }
 
    if (cmsstrcasecmp(cSample, "SAMPLE_ID") == 0) {
 
        iSet   = LocateEmptyPatch(it8);
        if (iSet < 0) {
            return SynError(it8, "Couldn't add more patches '%s'\n", cPatch);
        }
 
        iField = t -> SampleID;
    }
    else {
        iSet = LocatePatch(it8, cPatch);
        if (iSet < 0) {
            return FALSE;
        }
    }
 
    return SetData(it8, iSet, iField, Val);
}
 
 
cmsBool CMSEXPORT cmsIT8SetDataDbl(cmsHANDLE hIT8, const char* cPatch,
                                   const char* cSample,
                                   cmsFloat64Number Val)
{
    cmsIT8* it8 = (cmsIT8*) hIT8;
    char Buff[256];
 
    _cmsAssert(hIT8 != NULL);
 
    snprintf(Buff, 255, it8->DoubleFormatter, Val);
    return cmsIT8SetData(hIT8, cPatch, cSample, Buff);
}
 
// Buffer should get MAXSTR at least
 
const char* CMSEXPORT cmsIT8GetPatchName(cmsHANDLE hIT8, int nPatch, char* buffer)
{
    cmsIT8* it8 = (cmsIT8*) hIT8;
    TABLE* t;
    char* Data;
 
    _cmsAssert(hIT8 != NULL);
 
    t = GetTable(it8);
    Data = GetData(it8, nPatch, t->SampleID);
 
    if (!Data) return NULL;
    if (!buffer) return Data;
 
    strncpy(buffer, Data, MAXSTR-1);
    buffer[MAXSTR-1] = 0;
    return buffer;
}
 
int CMSEXPORT cmsIT8GetPatchByName(cmsHANDLE hIT8, const char *cPatch)
{
    _cmsAssert(hIT8 != NULL);
 
    return LocatePatch((cmsIT8*)hIT8, cPatch);
}
 
cmsUInt32Number CMSEXPORT cmsIT8TableCount(cmsHANDLE hIT8)
{
    cmsIT8* it8 = (cmsIT8*) hIT8;
 
    _cmsAssert(hIT8 != NULL);
 
    return it8 ->TablesCount;
}
 
// This handles the "LABEL" extension.
// Label, nTable, Type
 
int CMSEXPORT cmsIT8SetTableByLabel(cmsHANDLE hIT8, const char* cSet, const char* cField, const char* ExpectedType)
{
    const char* cLabelFld;
    char Type[256], Label[256];
    cmsUInt32Number nTable;
 
    _cmsAssert(hIT8 != NULL);
 
    if (cField != NULL && *cField == 0)
            cField = "LABEL";
 
    if (cField == NULL)
            cField = "LABEL";
 
    cLabelFld = cmsIT8GetData(hIT8, cSet, cField);
    if (!cLabelFld) return -1;
 
    if (sscanf(cLabelFld, "%255s %u %255s", Label, &nTable, Type) != 3)
            return -1;
 
    if (ExpectedType != NULL && *ExpectedType == 0)
        ExpectedType = NULL;
 
    if (ExpectedType) {
 
        if (cmsstrcasecmp(Type, ExpectedType) != 0) return -1;
    }
 
    return cmsIT8SetTable(hIT8, nTable);
}
 
 
cmsBool CMSEXPORT cmsIT8SetIndexColumn(cmsHANDLE hIT8, const char* cSample)
{
    cmsIT8* it8 = (cmsIT8*) hIT8;
    int pos;
 
    _cmsAssert(hIT8 != NULL);
 
    pos = LocateSample(it8, cSample);
    if(pos == -1)
        return FALSE;
 
    it8->Tab[it8->nTable].SampleID = pos;
    return TRUE;
}
 
 
void CMSEXPORT cmsIT8DefineDblFormat(cmsHANDLE hIT8, const char* Formatter)
{
    cmsIT8* it8 = (cmsIT8*) hIT8;
 
    _cmsAssert(hIT8 != NULL);
 
    if (Formatter == NULL)
        strcpy(it8->DoubleFormatter, DEFAULT_DBL_FORMAT);
    else
        strncpy(it8->DoubleFormatter, Formatter, sizeof(it8->DoubleFormatter));
 
    it8 ->DoubleFormatter[sizeof(it8 ->DoubleFormatter)-1] = 0;
}
 

V124 Function 'fread' reads '132' bytes. The alignment rules and type sizes have been changed. Consider reviewing this value.

V1048 The 'sgn' variable was assigned the same value.

V1048 The 'sgn' variable was assigned the same value.

V560 A part of conditional expression is always true: it8->sy != SEND_DATA.

V560 A part of conditional expression is always true: it8->sy != SEOF.

V581 The conditional expressions of the 'if' statements situated alongside each other are identical. Check lines: 1570, 1573.

V522 There might be dereferencing of a potential null pointer 'it8'.

V769 The 'it8->Allocator.Block' pointer in the expression could be nullptr. In such case, resulting value of arithmetic operations on this pointer will be senseless and it should not be used.