- Implement AI land marks which only used to tracks visited areas on the map for now. Significantly reduces wasting of cpu time by AI checking same place several times (10x or even more in rare cases)
- More branching in walk algorythm which allows for better coverage of reachable places. Sometimes makes AI perform ridiculous jumping just to make a tiny step.
- Small fixes/adjustments
/***************************************************************************/
/* */
/* t1parse.c */
/* */
/* Type 1 parser (body). */
/* */
/* Copyright 1996-2001, 2002, 2003, 2004, 2005, 2008, 2009 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 <ft2build.h>
#include FT_INTERNAL_DEBUG_H
#include FT_INTERNAL_STREAM_H
#include FT_INTERNAL_POSTSCRIPT_AUX_H
#include "t1parse.h"
#include "t1errors.h"
/*************************************************************************/
/* */
/* The macro FT_COMPONENT is used in trace mode. It is an implicit */
/* parameter of the FT_TRACE() and FT_ERROR() macros, used to print/log */
/* messages during execution. */
/* */
#undef FT_COMPONENT
#define FT_COMPONENT trace_t1parse
/*************************************************************************/
/*************************************************************************/
/*************************************************************************/
/***** *****/
/***** INPUT STREAM PARSER *****/
/***** *****/
/*************************************************************************/
/*************************************************************************/
/*************************************************************************/
/* see Adobe Technical Note 5040.Download_Fonts.pdf */
static FT_Error
read_pfb_tag( FT_Stream stream,
FT_UShort *atag,
FT_ULong *asize )
{
FT_Error error;
FT_UShort tag;
FT_ULong size;
*atag = 0;
*asize = 0;
if ( !FT_READ_USHORT( tag ) )
{
if ( tag == 0x8001U || tag == 0x8002U )
{
if ( !FT_READ_ULONG_LE( size ) )
*asize = size;
}
*atag = tag;
}
return error;
}
static FT_Error
check_type1_format( FT_Stream stream,
const char* header_string,
size_t header_length )
{
FT_Error error;
FT_UShort tag;
FT_ULong dummy;
if ( FT_STREAM_SEEK( 0 ) )
goto Exit;
error = read_pfb_tag( stream, &tag, &dummy );
if ( error )
goto Exit;
/* We assume that the first segment in a PFB is always encoded as */
/* text. This might be wrong (and the specification doesn't insist */
/* on that), but we have never seen a counterexample. */
if ( tag != 0x8001U && FT_STREAM_SEEK( 0 ) )
goto Exit;
if ( !FT_FRAME_ENTER( header_length ) )
{
error = T1_Err_Ok;
if ( ft_memcmp( stream->cursor, header_string, header_length ) != 0 )
error = T1_Err_Unknown_File_Format;
FT_FRAME_EXIT();
}
Exit:
return error;
}
FT_LOCAL_DEF( FT_Error )
T1_New_Parser( T1_Parser parser,
FT_Stream stream,
FT_Memory memory,
PSAux_Service psaux )
{
FT_Error error;
FT_UShort tag;
FT_ULong size;
psaux->ps_parser_funcs->init( &parser->root, 0, 0, memory );
parser->stream = stream;
parser->base_len = 0;
parser->base_dict = 0;
parser->private_len = 0;
parser->private_dict = 0;
parser->in_pfb = 0;
parser->in_memory = 0;
parser->single_block = 0;
/* check the header format */
error = check_type1_format( stream, "%!PS-AdobeFont", 14 );
if ( error )
{
if ( error != T1_Err_Unknown_File_Format )
goto Exit;
error = check_type1_format( stream, "%!FontType", 10 );
if ( error )
{
FT_TRACE2(( "[not a Type1 font]\n" ));
goto Exit;
}
}
/******************************************************************/
/* */
/* Here a short summary of what is going on: */
/* */
/* When creating a new Type 1 parser, we try to locate and load */
/* the base dictionary if this is possible (i.e., for PFB */
/* files). Otherwise, we load the whole font into memory. */
/* */
/* When `loading' the base dictionary, we only setup pointers */
/* in the case of a memory-based stream. Otherwise, we */
/* allocate and load the base dictionary in it. */
/* */
/* parser->in_pfb is set if we are in a binary (`.pfb') font. */
/* parser->in_memory is set if we have a memory stream. */
/* */
/* try to compute the size of the base dictionary; */
/* look for a Postscript binary file tag, i.e., 0x8001 */
if ( FT_STREAM_SEEK( 0L ) )
goto Exit;
error = read_pfb_tag( stream, &tag, &size );
if ( error )
goto Exit;
if ( tag != 0x8001U )
{
/* assume that this is a PFA file for now; an error will */
/* be produced later when more things are checked */
if ( FT_STREAM_SEEK( 0L ) )
goto Exit;
size = stream->size;
}
else
parser->in_pfb = 1;
/* now, try to load `size' bytes of the `base' dictionary we */
/* found previously */
/* if it is a memory-based resource, set up pointers */
if ( !stream->read )
{
parser->base_dict = (FT_Byte*)stream->base + stream->pos;
parser->base_len = size;
parser->in_memory = 1;
/* check that the `size' field is valid */
if ( FT_STREAM_SKIP( size ) )
goto Exit;
}
else
{
/* read segment in memory -- this is clumsy, but so does the format */
if ( FT_ALLOC( parser->base_dict, size ) ||
FT_STREAM_READ( parser->base_dict, size ) )
goto Exit;
parser->base_len = size;
}
parser->root.base = parser->base_dict;
parser->root.cursor = parser->base_dict;
parser->root.limit = parser->root.cursor + parser->base_len;
Exit:
if ( error && !parser->in_memory )
FT_FREE( parser->base_dict );
return error;
}
FT_LOCAL_DEF( void )
T1_Finalize_Parser( T1_Parser parser )
{
FT_Memory memory = parser->root.memory;
/* always free the private dictionary */
FT_FREE( parser->private_dict );
/* free the base dictionary only when we have a disk stream */
if ( !parser->in_memory )
FT_FREE( parser->base_dict );
parser->root.funcs.done( &parser->root );
}
FT_LOCAL_DEF( FT_Error )
T1_Get_Private_Dict( T1_Parser parser,
PSAux_Service psaux )
{
FT_Stream stream = parser->stream;
FT_Memory memory = parser->root.memory;
FT_Error error = T1_Err_Ok;
FT_ULong size;
if ( parser->in_pfb )
{
/* in the case of the PFB format, the private dictionary can be */
/* made of several segments. We thus first read the number of */
/* segments to compute the total size of the private dictionary */
/* then re-read them into memory. */
FT_Long start_pos = FT_STREAM_POS();
FT_UShort tag;
parser->private_len = 0;
for (;;)
{
error = read_pfb_tag( stream, &tag, &size );
if ( error )
goto Fail;
if ( tag != 0x8002U )
break;
parser->private_len += size;
if ( FT_STREAM_SKIP( size ) )
goto Fail;
}
/* Check that we have a private dictionary there */
/* and allocate private dictionary buffer */
if ( parser->private_len == 0 )
{
FT_ERROR(( "T1_Get_Private_Dict:"
" invalid private dictionary section\n" ));
error = T1_Err_Invalid_File_Format;
goto Fail;
}
if ( FT_STREAM_SEEK( start_pos ) ||
FT_ALLOC( parser->private_dict, parser->private_len ) )
goto Fail;
parser->private_len = 0;
for (;;)
{
error = read_pfb_tag( stream, &tag, &size );
if ( error || tag != 0x8002U )
{
error = T1_Err_Ok;
break;
}
if ( FT_STREAM_READ( parser->private_dict + parser->private_len,
size ) )
goto Fail;
parser->private_len += size;
}
}
else
{
/* We have already `loaded' the whole PFA font file into memory; */
/* if this is a memory resource, allocate a new block to hold */
/* the private dict. Otherwise, simply overwrite into the base */
/* dictionary block in the heap. */
/* first of all, look at the `eexec' keyword */
FT_Byte* cur = parser->base_dict;
FT_Byte* limit = cur + parser->base_len;
FT_Byte c;
Again:
for (;;)
{
c = cur[0];
if ( c == 'e' && cur + 9 < limit ) /* 9 = 5 letters for `eexec' + */
/* newline + 4 chars */
{
if ( cur[1] == 'e' &&
cur[2] == 'x' &&
cur[3] == 'e' &&
cur[4] == 'c' )
break;
}
cur++;
if ( cur >= limit )
{
FT_ERROR(( "T1_Get_Private_Dict:"
" could not find `eexec' keyword\n" ));
error = T1_Err_Invalid_File_Format;
goto Exit;
}
}
/* check whether `eexec' was real -- it could be in a comment */
/* or string (as e.g. in u003043t.gsf from ghostscript) */
parser->root.cursor = parser->base_dict;
parser->root.limit = cur + 9;
cur = parser->root.cursor;
limit = parser->root.limit;
while ( cur < limit )
{
if ( *cur == 'e' && ft_strncmp( (char*)cur, "eexec", 5 ) == 0 )
goto Found;
T1_Skip_PS_Token( parser );
if ( parser->root.error )
break;
T1_Skip_Spaces ( parser );
cur = parser->root.cursor;
}
/* we haven't found the correct `eexec'; go back and continue */
/* searching */
cur = limit;
limit = parser->base_dict + parser->base_len;
goto Again;
/* now determine where to write the _encrypted_ binary private */
/* dictionary. We overwrite the base dictionary for disk-based */
/* resources and allocate a new block otherwise */
Found:
parser->root.limit = parser->base_dict + parser->base_len;
T1_Skip_PS_Token( parser );
cur = parser->root.cursor;
/* according to the Type1 spec, the first cipher byte must not be */
/* an ASCII whitespace character code (blank, tab, carriage return */
/* or line feed). We have seen Type 1 fonts with two line feed */
/* characters... So skip now all whitespace character codes. */
while ( cur < limit &&
( *cur == ' ' ||
*cur == '\t' ||
*cur == '\r' ||
*cur == '\n' ) )
++cur;
if ( cur >= limit )
{
FT_ERROR(( "T1_Get_Private_Dict:"
" `eexec' not properly terminated\n" ));
error = T1_Err_Invalid_File_Format;
goto Exit;
}
size = parser->base_len - ( cur - parser->base_dict );
if ( parser->in_memory )
{
/* note that we allocate one more byte to put a terminating `0' */
if ( FT_ALLOC( parser->private_dict, size + 1 ) )
goto Fail;
parser->private_len = size;
}
else
{
parser->single_block = 1;
parser->private_dict = parser->base_dict;
parser->private_len = size;
parser->base_dict = 0;
parser->base_len = 0;
}
/* now determine whether the private dictionary is encoded in binary */
/* or hexadecimal ASCII format -- decode it accordingly */
/* we need to access the next 4 bytes (after the final \r following */
/* the `eexec' keyword); if they all are hexadecimal digits, then */
/* we have a case of ASCII storage */
if ( ft_isxdigit( cur[0] ) && ft_isxdigit( cur[1] ) &&
ft_isxdigit( cur[2] ) && ft_isxdigit( cur[3] ) )
{
/* ASCII hexadecimal encoding */
FT_Long len;
parser->root.cursor = cur;
(void)psaux->ps_parser_funcs->to_bytes( &parser->root,
parser->private_dict,
parser->private_len,
&len,
0 );
parser->private_len = len;
/* put a safeguard */
parser->private_dict[len] = '\0';
}
else
/* binary encoding -- copy the private dict */
FT_MEM_MOVE( parser->private_dict, cur, size );
}
/* we now decrypt the encoded binary private dictionary */
psaux->t1_decrypt( parser->private_dict, parser->private_len, 55665U );
/* replace the four random bytes at the beginning with whitespace */
parser->private_dict[0] = ' ';
parser->private_dict[1] = ' ';
parser->private_dict[2] = ' ';
parser->private_dict[3] = ' ';
parser->root.base = parser->private_dict;
parser->root.cursor = parser->private_dict;
parser->root.limit = parser->root.cursor + parser->private_len;
Fail:
Exit:
return error;
}
/* END */