freetype2/src/cid/cidparse.c

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/*******************************************************************
*
* cidparse.c 2.0
*
* CID-keyed Type1 parser.
*
* Copyright 1996-1998 by
* David Turner, Robert Wilhelm, and Werner Lemberg.
*
* This file is part of the FreeType project, and may only be used
* modified and distributed under the terms of the FreeType project
* license, LICENSE.TXT. By continuing to use, modify, or distribute
* this file you indicate that you have read the license and
* understand and accept it fully.
*
* The Type 1 parser is in charge of the following:
*
* - provide an implementation of a growing sequence of
* objects called a T1_Table (used to build various tables
* needed by the loader).
*
* - opening .pfb and .pfa files to extract their top-level
* and private dictionaries
*
* - read numbers, arrays & strings from any dictionary
*
* See "t1load.c" to see how data is loaded from the font file
*
******************************************************************/
#include <freetype/internal/ftdebug.h>
#include <freetype/internal/ftcalc.h>
#include <freetype/internal/ftobjs.h>
#include <freetype/internal/ftstream.h>
#include <t1errors.h>
#include <cidparse.h>
#undef FT_COMPONENT
#define FT_COMPONENT trace_t1load
#if 0
/*************************************************************************/
/*************************************************************************/
/*************************************************************************/
/***** *****/
/***** IMPLEMENTATION OF T1_TABLE OBJECT *****/
/***** *****/
/***** *****/
/*************************************************************************/
/*************************************************************************/
/*************************************************************************/
/*************************************************************************/
/* */
/* <Function> T1_New_Table */
/* */
/* <Description> */
/* Initialise a T1_Table. */
/* */
/* <Input> */
/* table :: address of target table */
/* count :: table size = maximum number of elements */
/* memory :: memory object to use for all subsequent reallocations */
/* */
/* <Return> */
/* Error code. 0 means success */
/* */
LOCAL_FUNC
FT_Error T1_New_Table( T1_Table* table,
FT_Int count,
FT_Memory memory )
{
FT_Error error;
table->memory = memory;
if ( ALLOC_ARRAY( table->elements, count, FT_Byte* ) ||
ALLOC_ARRAY( table->lengths, count, FT_Byte* ) )
goto Exit;
table->max_elems = count;
table->init = 0xdeadbeef;
table->num_elems = 0;
table->block = 0;
table->capacity = 0;
table->cursor = 0;
Exit:
if (error) FREE(table->elements);
return error;
}
/*************************************************************************/
/* */
/* <Function> T1_Add_Table */
/* */
/* <Description> */
/* Adds an object to a T1_Table, possibly growing its memory block */
/* */
/* <Input> */
/* table :: target table */
/* index :: index of object in table */
/* object :: address of object to copy in memory */
/* length :: length in bytes of source object */
/* */
/* <Return> */
/* Error code. 0 means success. An error is returned when a */
/* realloc failed.. */
/* */
static void shift_elements( T1_Table* table, FT_Byte* old_base )
{
FT_Long delta = table->block - old_base;
FT_Byte** offset = table->elements;
FT_Byte** limit = offset + table->max_elems;
if (delta)
for ( ; offset < limit; offset++ )
{
if (offset[0])
offset[0] += delta;
}
}
static
FT_Error reallocate_t1_table( T1_Table* table,
FT_Int new_size )
{
FT_Memory memory = table->memory;
FT_Byte* old_base = table->block;
FT_Error error;
/* realloc the base block */
if ( REALLOC( table->block, table->capacity, new_size ) )
return error;
table->capacity = new_size;
/* shift all offsets when needed */
if (old_base)
shift_elements( table, old_base );
return T1_Err_Ok;
}
LOCAL_FUNC
FT_Error T1_Add_Table( T1_Table* table,
FT_Int index,
void* object,
FT_Int length )
{
if (index < 0 || index > table->max_elems)
{
FT_ERROR(( "T1.Add_Table: invalid index\n" ));
return T1_Err_Syntax_Error;
}
/* grow the base block if needed */
if ( table->cursor + length > table->capacity )
{
FT_Error error;
FT_Int new_size = table->capacity;
while ( new_size < table->cursor+length )
new_size += 1024;
error = reallocate_t1_table( table, new_size );
if (error) return error;
}
/* add the object to the base block and adjust offset */
table->elements[ index ] = table->block + table->cursor;
table->lengths [ index ] = length;
MEM_Copy( table->block + table->cursor, object, length );
table->cursor += length;
return T1_Err_Ok;
}
/*************************************************************************/
/* */
/* <Function> T1_Done_Table */
/* */
/* <Description> */
/* Finalise a T1_Table. (realloc it to its current cursor). */
/* */
/* <Input> */
/* table :: target table */
/* */
/* <Note> */
/* This function does NOT release the heap's memory block. It is up */
/* to the caller to clean it, or reference it in its own structures. */
/* */
#if 0
LOCAL_FUNC
void T1_Done_Table( T1_Table* table )
{
FT_Memory memory = table->memory;
FT_Error error;
FT_Byte* old_base;
/* should never fail, as rec.cursor <= rec.size */
old_base = table->block;
if (!old_base)
return;
(void)REALLOC( table->block, table->capacity, table->cursor );
table->capacity = table->cursor;
if (old_base != table->block)
shift_elements( table, old_base );
}
#endif
LOCAL_FUNC
void T1_Release_Table( T1_Table* table )
{
FT_Memory memory = table->memory;
if (table->init == (FT_Long)0xdeadbeef)
{
FREE( table->block );
FREE( table->elements );
FREE( table->lengths );
table->init = 0;
}
}
#endif
/*************************************************************************/
/*************************************************************************/
/*************************************************************************/
/***** *****/
/***** INPUT STREAM PARSER *****/
/***** *****/
/***** *****/
/*************************************************************************/
/*************************************************************************/
/*************************************************************************/
#define IS_T1_WHITESPACE(c) ( (c) == ' ' || (c) == '\t' )
#define IS_T1_LINESPACE(c) ( (c) == '\r' || (c) == '\n' )
#define IS_T1_SPACE(c) ( IS_T1_WHITESPACE(c) || IS_T1_LINESPACE(c) )
LOCAL_FUNC
void CID_Skip_Spaces( CID_Parser* parser )
{
FT_Byte* cur = parser->cursor;
FT_Byte* limit = parser->limit;
while (cur < limit)
{
FT_Byte c = *cur;
if (!IS_T1_SPACE(c))
break;
cur++;
}
parser->cursor = cur;
}
LOCAL_FUNC
void CID_ToToken( CID_Parser* parser,
T1_Token_Rec* token )
{
FT_Byte* cur;
FT_Byte* limit;
FT_Byte starter, ender;
FT_Int embed;
token->type = t1_token_none;
token->start = 0;
token->limit = 0;
/* first of all, skip space */
CID_Skip_Spaces(parser);
cur = parser->cursor;
limit = parser->limit;
if ( cur < limit )
{
switch (*cur)
{
/************* check for strings ***********************/
case '(':
token->type = t1_token_string;
ender = ')';
goto Lookup_Ender;
/************* check for programs/array ****************/
case '{':
token->type = t1_token_array;
ender = '}';
goto Lookup_Ender;
/************* check for table/array ******************/
case '[':
token->type = t1_token_array;
ender = ']';
Lookup_Ender:
embed = 1;
starter = *cur++;
token->start = cur;
while (cur < limit)
{
if (*cur == starter)
embed++;
else if (*cur == ender)
{
embed--;
if (embed <= 0)
{
token->limit = cur++;
break;
}
}
cur++;
}
break;
/* **************** otherwise, it's any token **********/
default:
token->start = cur++;
token->type = t1_token_any;
while (cur < limit && !IS_T1_SPACE(*cur))
cur++;
token->limit = cur;
}
if (!token->limit)
{
token->start = 0;
token->type = t1_token_none;
}
parser->cursor = cur;
}
}
LOCAL_FUNC
void CID_ToTokenArray( CID_Parser* parser,
T1_Token_Rec* tokens,
FT_UInt max_tokens,
FT_Int *pnum_tokens )
{
T1_Token_Rec master;
*pnum_tokens = -1;
CID_ToToken( parser, &master );
if (master.type == t1_token_array)
{
FT_Byte* old_cursor = parser->cursor;
FT_Byte* old_limit = parser->limit;
T1_Token_Rec* cur = tokens;
T1_Token_Rec* limit = cur + max_tokens;
parser->cursor = master.start;
parser->limit = master.limit;
while (parser->cursor < parser->limit)
{
T1_Token_Rec token;
CID_ToToken( parser, &token );
if (!token.type)
break;
if (cur < limit)
*cur = token;
cur++;
}
*pnum_tokens = cur - tokens;
parser->cursor = old_cursor;
parser->limit = old_limit;
}
}
static
FT_Long t1_toint( FT_Byte* *cursor,
FT_Byte* limit )
{
FT_Long result = 0;
FT_Byte* cur = *cursor;
FT_Byte c, d;
for (; cur < limit; cur++)
{
c = *cur;
d = (FT_Byte)(c - '0');
if (d < 10) break;
if ( c=='-' )
{
cur++;
break;
}
}
if (cur < limit)
{
do
{
d = (FT_Byte)(cur[0] - '0');
if (d >= 10)
break;
result = result*10 + d;
cur++;
} while (cur < limit);
if (c == '-')
result = -result;
}
*cursor = cur;
return result;
}
static
FT_Long t1_tofixed( FT_Byte* *cursor,
FT_Byte* limit,
FT_Long power_ten )
{
FT_Byte* cur = *cursor;
FT_Long num, divider, result;
FT_Int sign = 0;
FT_Byte d;
if (cur >= limit) return 0;
/* first of all, read the integer part */
result = t1_toint( &cur, limit ) << 16;
num = 0;
divider = 1;
if (result < 0)
{
sign = 1;
result = -result;
}
if (cur >= limit) goto Exit;
/* read decimal part, if any */
if (*cur == '.' && cur+1 < limit)
{
cur++;
for (;;)
{
d = (FT_Byte)(*cur - '0');
if (d >= 10) break;
if (divider < 10000000L)
{
num = num*10 + d;
divider *= 10;
}
cur++;
if (cur >= limit) break;
}
}
/* read exponent, if any */
if ( cur+1 < limit && (*cur == 'e' || *cur == 'E'))
{
cur++;
power_ten += t1_toint( &cur, limit );
}
Exit:
/* raise to power of ten if needed */
while (power_ten > 0)
{
result = result*10;
num = num*10;
power_ten--;
}
while (power_ten < 0)
{
result = result/10;
divider = divider*10;
power_ten++;
}
if (num)
result += FT_DivFix( num, divider );
if (sign)
result = -result;
*cursor = cur;
return result;
}
static
int t1_tobool( FT_Byte* *cursor, FT_Byte* limit )
{
FT_Byte* cur = *cursor;
T1_Bool result = 0;
/* return 1 if we find a "true", 0 otherwise */
if ( cur+3 < limit &&
cur[0] == 't' &&
cur[1] == 'r' &&
cur[2] == 'u' &&
cur[3] == 'e' )
{
result = 1;
cur += 5;
}
else if ( cur+4 < limit &&
cur[0] == 'f' &&
cur[1] == 'a' &&
cur[2] == 'l' &&
cur[3] == 's' &&
cur[4] == 'e' )
{
result = 0;
cur += 6;
}
*cursor = cur;
return result;
}
static
FT_Int t1_tocoordarray( FT_Byte* *cursor,
FT_Byte* limit,
FT_Int max_coords,
FT_Short* coords )
{
FT_Byte* cur = *cursor;
FT_Int count = 0;
FT_Byte c, ender;
if (cur >= limit) goto Exit;
/* check for the beginning of an array. If not, only one number will be read */
c = *cur;
ender = 0;
if (c == '[')
ender = ']';
if (c == '{')
ender = '}';
if (ender)
cur++;
/* now, read the coordinates */
for ( ; cur < limit; )
{
/* skip whitespace in front of data */
for (;;)
{
c = *cur;
if ( c != ' ' && c != '\t' ) break;
cur++;
if (cur >= limit) goto Exit;
}
if (count >= max_coords || c == ender)
break;
coords[count] = (T1_Short)(t1_tofixed(&cur,limit,0) >> 16);
count++;
if (!ender)
break;
}
Exit:
*cursor = cur;
return count;
}
static
FT_Int t1_tofixedarray( FT_Byte* *cursor,
FT_Byte* limit,
FT_Int max_values,
FT_Fixed* values,
FT_Int power_ten )
{
FT_Byte* cur = *cursor;
FT_Int count = 0;
FT_Byte c, ender;
if (cur >= limit) goto Exit;
/* check for the beginning of an array. If not, only one number will be read */
c = *cur;
ender = 0;
if (c == '[')
ender = ']';
if (c == '{')
ender = '}';
if (ender)
cur++;
/* now, read the values */
for ( ; cur < limit; )
{
/* skip whitespace in front of data */
for (;;)
{
c = *cur;
if ( c != ' ' && c != '\t' ) break;
cur++;
if (cur >= limit) goto Exit;
}
if (count >= max_values || c == ender)
break;
values[count] = t1_tofixed(&cur,limit,power_ten);
count++;
if (!ender)
break;
}
Exit:
*cursor = cur;
return count;
}
/* Loads a simple field (i.e. non-table) into the current list of objects */
LOCAL_FUNC
FT_Error CID_Load_Field( CID_Parser* parser,
const T1_Field_Rec* field,
void* object )
{
T1_Token_Rec token;
FT_Byte* cur;
FT_Byte* limit;
FT_UInt count;
FT_UInt index;
FT_Error error;
CID_ToToken( parser, &token );
if (!token.type)
goto Fail;
count = 1;
index = 0;
cur = token.start;
limit = token.limit;
{
FT_Byte* q = (FT_Byte*)object + field->offset;
FT_Long val;
T1_String* string;
switch (field->type)
{
case t1_field_bool:
{
val = t1_tobool( &cur, limit );
goto Store_Integer;
}
case t1_field_fixed:
{
val = t1_tofixed( &cur, limit, 0 );
goto Store_Integer;
}
case t1_field_integer:
{
val = t1_toint( &cur, limit );
Store_Integer:
switch (field->size)
{
case 1: *(FT_Byte*) q = (FT_Byte)val; break;
case 2: *(FT_UShort*)q = (FT_UShort)val; break;
default: *(FT_Long*) q = val;
}
}
break;
case t1_field_string:
{
FT_Memory memory = parser->memory;
FT_UInt len = limit-cur;
if ( ALLOC( string, len+1 ) )
goto Exit;
MEM_Copy( string, cur, len );
string[len] = 0;
*(T1_String**)q = string;
}
break;
default:
/* an error occured */
goto Fail;
}
}
error = 0;
Exit:
return error;
Fail:
error = T1_Err_Invalid_File_Format;
goto Exit;
}
#define CID_MAX_TABLE_ELEMENTS 32
LOCAL_FUNC
FT_Error CID_Load_Field_Table( CID_Parser* parser,
const T1_Field_Rec* field,
void* object )
{
T1_Token_Rec elements[CID_MAX_TABLE_ELEMENTS];
T1_Token_Rec* token;
FT_Int num_elements;
FT_Error error = 0;
FT_Byte* old_cursor;
FT_Byte* old_limit;
T1_Field_Rec fieldrec = *(T1_Field_Rec*)field;
fieldrec.type = t1_field_integer;
if (field->type == t1_field_fixed_array )
fieldrec.type = t1_field_fixed;
CID_ToTokenArray( parser, elements, 32, &num_elements );
if (num_elements < 0)
goto Fail;
if (num_elements > CID_MAX_TABLE_ELEMENTS)
num_elements = CID_MAX_TABLE_ELEMENTS;
old_cursor = parser->cursor;
old_limit = parser->limit;
/* we store the elements count */
if (field->count_offset)
*(FT_Byte*)((FT_Byte*)object + field->count_offset) = num_elements;
/* we now load each element, adjusting the field.offset on each one */
token = elements;
for ( ; num_elements > 0; num_elements--, token++ )
{
parser->cursor = token->start;
parser->limit = token->limit;
CID_Load_Field( parser, &fieldrec, object );
fieldrec.offset += fieldrec.size;
}
parser->cursor = old_cursor;
parser->limit = old_limit;
Exit:
return error;
Fail:
error = T1_Err_Invalid_File_Format;
goto Exit;
}
LOCAL_FUNC
FT_Long CID_ToInt ( CID_Parser* parser )
{
return t1_toint( &parser->cursor, parser->limit );
}
LOCAL_FUNC
FT_Int CID_ToCoordArray( CID_Parser* parser,
FT_Int max_coords,
FT_Short* coords )
{
return t1_tocoordarray( &parser->cursor, parser->limit, max_coords, coords );
}
LOCAL_FUNC
FT_Int CID_ToFixedArray( CID_Parser* parser,
FT_Int max_values,
FT_Fixed* values,
FT_Int power_ten )
{
return t1_tofixedarray( &parser->cursor, parser->limit, max_values, values, power_ten );
}
#if 0
/* return the value of an hexadecimal digit */
static
int hexa_value( char c )
{
unsigned int d;
d = (unsigned int)(c-'0');
if ( d <= 9 ) return (int)d;
d = (unsigned int)(c-'a');
if ( d <= 5 ) return (int)(d+10);
d = (unsigned int)(c-'A');
if ( d <= 5 ) return (int)(d+10);
return -1;
}
#endif
LOCAL_FUNC
FT_Error CID_New_Parser( CID_Parser* parser,
FT_Stream stream,
FT_Memory memory )
{
FT_Error error;
FT_ULong base_offset, offset, ps_len;
FT_Byte buffer[ 256 + 10 ];
FT_Int buff_len;
MEM_Set( parser, 0, sizeof(*parser ) );
parser->stream = stream;
parser->memory = memory;
base_offset = FILE_Pos();
/* first of all, check the font format in the header */
if ( ACCESS_Frame(31) )
goto Exit;
if ( strncmp( stream->cursor, "%!PS-Adobe-3.0 Resource-CIDFont", 31 ) )
{
FT_ERROR(( "[not a valid CID-keyed font]\n" ));
error = FT_Err_Unknown_File_Format;
}
FORGET_Frame();
if (error) goto Exit;
/* now, read the rest of the file, until we find a "StartData" */
buff_len = 256;
for (;;)
{
FT_Byte *p, *limit = buffer + 256;
/* fill input buffer */
buff_len -= 256;
if (buff_len > 0)
MEM_Move( buffer, limit, buff_len );
if ( FILE_Read( buffer, 256+10-buff_len ) )
goto Exit;
buff_len = 256+10;
/* look for "StartData" */
for ( p = buffer; p < limit; p++ )
{
if ( p[0] == 'S' && strncmp( (char*)p, "StartData", 9 ) == 0 )
{
/* save offset of binary data after "StartData" */
offset = FILE_Pos() - ( limit-p ) + 10;
goto Found;
}
}
}
Found:
/* all right, we found the start of the binary data. We will now rewind */
/* and extract the frame of corresponding to the Postscript section */
ps_len = offset - base_offset;
if ( FILE_Seek( base_offset ) ||
EXTRACT_Frame( ps_len, parser->postscript ) )
goto Exit;
parser->data_offset = offset;
parser->postscript_len = ps_len;
parser->cursor = parser->postscript;
parser->limit = parser->cursor + ps_len;
parser->num_dict = -1;
Exit:
return error;
}
LOCAL_FUNC
void CID_Done_Parser( CID_Parser* parser )
{
/* always free the private dictionary */
if (parser->postscript)
{
FT_Stream stream = parser->stream;
RELEASE_Frame( parser->postscript );
}
}