ref: 0f6467a016e9a13dedb944b239b6eddb2af33ca3
dir: /src/type1/t1parse.c/
#include <freetype/internal/ftdebug.h> #include <freetype/internal/t1types.h> #include <t1parse.h> #include <stdio.h> /* for sscanf */ /*************************************************************************/ /* */ /* <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 T1_Error T1_New_Table( T1_Table* table, T1_Int count, FT_Memory memory ) { T1_Error error; table->memory = memory; if ( ALLOC_ARRAY( table->elements, count, T1_Byte* ) ) return error; if ( ALLOC_ARRAY( table->lengths, count, T1_Byte* ) ) { FREE( table->elements ); return error; } table->max_elems = count; table->num_elems = 0; table->block = 0; table->capacity = 0; table->cursor = 0; 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 T1_Error reallocate_t1_table( T1_Table* table, T1_Int new_size ) { FT_Memory memory = table->memory; T1_Byte* old_base = table->block; T1_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) { T1_Long delta = table->block - old_base; T1_Byte** offset = table->elements; T1_Byte** limit = offset + table->max_elems; if (delta) for ( ; offset < limit; offset ++ ) if (offset[0]) offset[0] += delta; } return T1_Err_Ok; } LOCAL_FUNC T1_Error T1_Add_Table( T1_Table* table, T1_Int index, void* object, T1_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 ) { T1_Error error; T1_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. */ /* */ LOCAL_FUNC void T1_Done_Table( T1_Table* table ) { FT_Memory memory = table->memory; T1_Error error; T1_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) { T1_Long delta = table->block - old_base; T1_Byte** element = table->elements; T1_Byte** limit = element + table->max_elems; for ( ; element < limit; element++ ) if (element[0]) element[0] += delta; } } LOCAL_FUNC T1_String* CopyString( T1_Parser* parser ) { T1_String* string = NULL; T1_Token* token = parser->args++; FT_Memory memory = parser->tokenizer->memory; T1_Error error; if ( token->kind == tok_string ) { int len = token->len-2; if ( ALLOC( string, len+1 ) ) { parser->error = error; return 0; } MEM_Copy( string, parser->tokenizer->base + token->start+1, len ); string[len] = '\0'; parser->error = T1_Err_Ok; } else { FT_ERROR(( "T1.CopyString : syntax error, string token expected !\n" )); parser->error = T1_Err_Syntax_Error; } return string; } static T1_Error parse_int( T1_Byte* base, T1_Byte* limit, T1_Long* result ) { T1_Bool sign = 0; T1_Long sum = 0; if (base >= limit) goto Fail; /* check sign */ if ( *base == '+' ) base++; else if ( *base == '-' ) { sign++; base++; } /* parse digits */ if ( base >= limit ) goto Fail; do { sum = ( 10*sum + (*base++ - '0') ); } while (base < limit); if (sign) sum = -sum; *result = sum; return T1_Err_Ok; Fail: FT_ERROR(( "T1.parse_integer : integer expected\n" )); *result = 0; return T1_Err_Syntax_Error; } static T1_Error parse_float( T1_Byte* base, T1_Byte* limit, T1_Int scale, T1_Long* result ) { #if 1 /* XXX : We're simply much too lazy to code this function */ /* properly for now.. We'll do that when the rest of */ /* the driver works properly.. */ char temp[32]; int len = limit-base; double value; if (len > 31) goto Fail; strncpy( temp, (char*)base, len ); temp[len] = '\0'; if ( sscanf( temp, "%lf", &value ) != 1 ) goto Fail; *result = (T1_Long)(scale*value); return 0; #else T1_Byte* cur; T1_Bool sign = 0; /* sign */ T1_Long number_int = 0; /* integer part */ T1_Long number_frac = 0; /* fractional part */ T1_Long exponent = 0; /* exponent value */ T1_Int num_frac = 0; /* number of fractional digits */ /* check sign */ if (*base == '+') base++; else if (*base == '-') { sign++; base++; } /* find integer part */ cur = base; while ( cur < limit ) { T1_Byte c = *cur; if ( c == '.' || c == 'e' || c == 'E' ) break; cur++; } if ( cur > base ) { error = parse_integer( base, cur, &number_int ); if (error) goto Fail; } /* read fractional part, if any */ if ( *cur == '.' ) { cur++; base = cur; while ( cur < limit ) { T1_Byte c = *cur; if ( c == 'e' || c == 'E' ) break; cur++; } num_frac = cur - base; if ( cur > base ) { error = parse_integer( base, cur, &number_frac ); if (error) goto Fail; base = cur; } } /* read exponent, if any */ if ( *cur == 'e' || *cur == 'E' ) { cur++; base = cur; error = parse_integer( base, limit, &exponent ); if (error) goto Fail; /* now check that exponent is within 'correct bounds' */ /* i.e. between -6 and 6 */ if ( exponent < -6 || exponent > 6 ) goto Fail; } /* now adjust integer value and exponent for fractional part */ while ( num_frac > 0 ) { number_int *= 10; exponent --; num_frac--; } number_int += num_frac; /* skip point if any, read fractional part */ if ( cur+1 < limit ) { if (*cur } /* now compute scaled float value */ /* XXXXX : incomplete !!! */ #endif Fail: FT_ERROR(( "T1.parse_float : syntax error !\n" )); return T1_Err_Syntax_Error; } static T1_Error parse_integer( T1_Byte* base, T1_Byte* limit, T1_Long* result ) { T1_Byte* cur; /* the lexical analyser accepts floats as well as integers */ /* now, check that we really have an int in this token */ cur = base; while ( cur < limit ) { T1_Byte c = *cur++; if ( c == '.' || c == 'e' || c == 'E' ) goto Float_Number; } /* now read the number's value */ return parse_int( base, limit, result ); Float_Number: /* We really have a float there, simply call parse_float in this */ /* case with a scale of '10' to perform round.. */ { T1_Error error; error = parse_float( base, limit, 10, result ); if (!error) { if (*result >= 0) *result = (*result+5)/10; /* round value */ else *result = -((5-*result)/10); } return error; } } LOCAL_FUNC T1_Long CopyInteger( T1_Parser* parser ) { T1_Long sum = 0; T1_Token* token = parser->args++; if ( token->kind == tok_number ) { T1_Byte* base = parser->tokenizer->base + token->start; T1_Byte* limit = base + token->len; /* now read the number's value */ parser->error = parse_integer( base, limit, &sum ); return sum; } FT_ERROR(( "T1.CopyInteger : number expected\n" )); parser->args--; parser->error = T1_Err_Syntax_Error; return 0; } LOCAL_FUNC T1_Bool CopyBoolean( T1_Parser* parser ) { T1_Error error = T1_Err_Ok; T1_Bool result = 0; T1_Token* token = parser->args++; if ( token->kind == tok_keyword ) { if ( token->kind2 == key_false ) result = 0; else if ( token->kind2 == key_true ) result = !0; else goto Fail; } else { Fail: FT_ERROR(( "T1.CopyBoolean : syntax error, 'false' or 'true' expected\n" )); error = T1_Err_Syntax_Error; } parser->error = error; return result; } LOCAL_FUNC T1_Long CopyFloat( T1_Parser* parser, T1_Int scale ) { T1_Error error; T1_Long sum = 0; T1_Token* token = parser->args++; if ( token->kind == tok_number ) { T1_Byte* base = parser->tokenizer->base + token->start; T1_Byte* limit = base + token->len; error = parser->error = parse_float( base, limit, scale, &sum ); if (error) goto Fail; return sum; } Fail: FT_ERROR(( "T1.CopyFloat : syntax error !\n" )); parser->error = T1_Err_Syntax_Error; return 0; } LOCAL_FUNC void CopyBBox( T1_Parser* parser, T1_BBox* bbox ) { T1_Token* token = parser->args++; T1_Int n; T1_Error error; if ( token->kind == tok_program || token->kind == tok_array ) { /* get rid of '['/']', or '{'/'}' */ T1_Byte* base = parser->tokenizer->base + token->start + 1; T1_Byte* limit = base + token->len - 2; T1_Byte* cur; T1_Byte* start; /* read each parameter independently */ cur = base; for ( n = 0; n < 4; n++ ) { T1_Long* result; /* skip whitespace */ while (cur < limit && *cur == ' ') cur++; /* skip numbers */ start = cur; while (cur < limit && *cur != ' ') cur++; /* compute result address */ switch (n) { case 0 : result = &bbox->xMin; break; case 1 : result = &bbox->yMin; break; case 2 : result = &bbox->xMax; break; default: result = &bbox->yMax; } error = parse_integer( start, cur, result ); if (error) goto Fail; } parser->error = 0; return; } Fail: FT_ERROR(( "T1.CopyBBox : syntax error !\n" )); parser->error = T1_Err_Syntax_Error; } LOCAL_FUNC void CopyMatrix( T1_Parser* parser, T1_Matrix* matrix ) { T1_Token* token = parser->args++; T1_Error error; if ( token->kind == tok_array ) { /* get rid of '[' and ']' */ T1_Byte* base = parser->tokenizer->base + token->start + 1; T1_Byte* limit = base + token->len - 2; T1_Byte* cur; T1_Byte* start; T1_Int n; /* read each parameter independently */ cur = base; for ( n = 0; n < 4; n++ ) { T1_Long* result; /* skip whitespace */ while (cur < limit && *cur == ' ') cur++; /* skip numbers */ start = cur; while (cur < limit && *cur != ' ') cur++; /* compute result address */ switch (n) { case 0 : result = &matrix->xx; break; case 1 : result = &matrix->yx; break; case 2 : result = &matrix->xy; break; default: result = &matrix->yy; } error = parse_float( start, cur, 65536000, result ); if (error) goto Fail; } parser->error = 0; return; } Fail: FT_ERROR(( "T1.CopyMatrix : syntax error !\n" )); parser->error = T1_Err_Syntax_Error; } LOCAL_FUNC void CopyArray( T1_Parser* parser, T1_Byte* num_elements, T1_Short* elements, T1_Int max_elements ) { T1_Token* token = parser->args++; T1_Error error; if ( token->kind == tok_array || token->kind == tok_program ) /* in the case of MinFeature */ { /* get rid of '['/']', or '{'/'}' */ T1_Byte* base = parser->tokenizer->base + token->start + 1; T1_Byte* limit = base + token->len - 2; T1_Byte* cur; T1_Byte* start; T1_Int n; /* read each parameter independently */ cur = base; for ( n = 0; n < max_elements; n++ ) { T1_Long result; /* test end of string */ if (cur >= limit) break; /* skip whitespace */ while (cur < limit && *cur == ' ') cur++; /* end of list ? */ if (cur >= limit) break; /* skip numbers */ start = cur; while (cur < limit && *cur != ' ') cur++; error = parse_integer( start, cur, &result ); if (error) goto Fail; *elements ++ = (T1_Short)result; } if (num_elements) *num_elements = (T1_Byte)n; parser->error = 0; return; } Fail: FT_ERROR(( "T1.CopyArray : syntax error !\n" )); parser->error = T1_Err_Syntax_Error; }