freetype2/src/base/ftcalc.c

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/***************************************************************************/
/* */
/* ftcalc.c */
/* */
/* Arithmetic computations (body). */
/* */
/* Copyright 1996-2006, 2008, 2012-2014 by */
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/* 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 */
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/* 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. */
/* */
/***************************************************************************/
/*************************************************************************/
/* */
/* Support for 1-complement arithmetic has been totally dropped in this */
/* release. You can still write your own code if you need it. */
/* */
/*************************************************************************/
/*************************************************************************/
/* */
/* Implementing basic computation routines. */
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/* */
/* FT_MulDiv(), FT_MulFix(), FT_DivFix(), FT_RoundFix(), FT_CeilFix(), */
/* and FT_FloorFix() are declared in freetype.h. */
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/* */
/*************************************************************************/
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#include <ft2build.h>
#include FT_GLYPH_H
#include FT_TRIGONOMETRY_H
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#include FT_INTERNAL_CALC_H
#include FT_INTERNAL_DEBUG_H
#include FT_INTERNAL_OBJECTS_H
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#ifdef FT_MULFIX_ASSEMBLER
#undef FT_MulFix
#endif
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/* we need to emulate a 64-bit data type if a real one isn't available */
#ifndef FT_LONG64
typedef struct FT_Int64_
{
FT_UInt32 lo;
FT_UInt32 hi;
} FT_Int64;
#endif /* !FT_LONG64 */
/*************************************************************************/
/* */
/* 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_calc
/* The following three functions are available regardless of whether */
/* FT_LONG64 is defined. */
/* documentation is in freetype.h */
FT_EXPORT_DEF( FT_Fixed )
FT_RoundFix( FT_Fixed a )
{
return ( a >= 0 ) ? ( a + 0x8000L ) & ~0xFFFFL
: -((-a + 0x8000L ) & ~0xFFFFL );
}
/* documentation is in freetype.h */
FT_EXPORT_DEF( FT_Fixed )
FT_CeilFix( FT_Fixed a )
{
return ( a >= 0 ) ? ( a + 0xFFFFL ) & ~0xFFFFL
: -((-a + 0xFFFFL ) & ~0xFFFFL );
}
/* documentation is in freetype.h */
FT_EXPORT_DEF( FT_Fixed )
FT_FloorFix( FT_Fixed a )
{
return ( a >= 0 ) ? a & ~0xFFFFL
: -((-a) & ~0xFFFFL );
}
#ifndef FT_MSB
FT_BASE_DEF ( FT_Int )
FT_MSB( FT_UInt32 z )
{
FT_Int shift = 0;
/* determine msb bit index in `shift' */
if ( z >= ( 1L << 16 ) )
{
z >>= 16;
shift += 16;
}
if ( z >= ( 1L << 8 ) )
{
z >>= 8;
shift += 8;
}
if ( z >= ( 1L << 4 ) )
{
z >>= 4;
shift += 4;
}
if ( z >= ( 1L << 2 ) )
{
z >>= 2;
shift += 2;
}
if ( z >= ( 1L << 1 ) )
{
/* z >>= 1; */
shift += 1;
}
return shift;
}
#endif /* !FT_MSB */
/* documentation is in ftcalc.h */
FT_BASE_DEF( FT_Fixed )
FT_Hypot( FT_Fixed x,
FT_Fixed y )
{
FT_Vector v;
v.x = x;
v.y = y;
return FT_Vector_Length( &v );
}
#ifdef FT_LONG64
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/* documentation is in freetype.h */
FT_EXPORT_DEF( FT_Long )
FT_MulDiv( FT_Long a,
FT_Long b,
FT_Long c )
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{
FT_Int s;
FT_Long d;
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s = 1;
if ( a < 0 ) { a = -a; s = -1; }
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if ( b < 0 ) { b = -b; s = -s; }
if ( c < 0 ) { c = -c; s = -s; }
d = (FT_Long)( c > 0 ? ( (FT_Int64)a * b + ( c >> 1 ) ) / c
: 0x7FFFFFFFL );
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return ( s > 0 ) ? d : -d;
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}
/* documentation is in ftcalc.h */
FT_BASE_DEF( FT_Long )
FT_MulDiv_No_Round( FT_Long a,
FT_Long b,
FT_Long c )
{
FT_Int s;
FT_Long d;
s = 1;
if ( a < 0 ) { a = -a; s = -1; }
if ( b < 0 ) { b = -b; s = -s; }
if ( c < 0 ) { c = -c; s = -s; }
d = (FT_Long)( c > 0 ? (FT_Int64)a * b / c
: 0x7FFFFFFFL );
return ( s > 0 ) ? d : -d;
}
/* documentation is in freetype.h */
FT_EXPORT_DEF( FT_Long )
FT_MulFix( FT_Long a,
FT_Long b )
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{
#ifdef FT_MULFIX_ASSEMBLER
return FT_MULFIX_ASSEMBLER( a, b );
#else
FT_Int s = 1;
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FT_Long c;
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if ( a < 0 )
{
a = -a;
s = -1;
}
if ( b < 0 )
{
b = -b;
s = -s;
}
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c = (FT_Long)( ( (FT_Int64)a * b + 0x8000L ) >> 16 );
return ( s > 0 ) ? c : -c;
#endif /* FT_MULFIX_ASSEMBLER */
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}
/* documentation is in freetype.h */
FT_EXPORT_DEF( FT_Long )
FT_DivFix( FT_Long a,
FT_Long b )
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{
FT_Int s = 1;
FT_Long q;
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if ( a < 0 )
{
a = -a;
s = -1;
}
if ( b < 0 )
{
b = -b;
s = -s;
}
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if ( b == 0 )
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/* check for division by 0 */
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q = 0x7FFFFFFFL;
else
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/* compute result directly */
q = (FT_Long)( ( ( (FT_UInt64)a << 16 ) + ( b >> 1 ) ) / b );
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return ( s < 0 ? -q : q );
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}
#else /* !FT_LONG64 */
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static void
ft_multo64( FT_UInt32 x,
FT_UInt32 y,
FT_Int64 *z )
{
FT_UInt32 lo1, hi1, lo2, hi2, lo, hi, i1, i2;
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lo1 = x & 0x0000FFFFU; hi1 = x >> 16;
lo2 = y & 0x0000FFFFU; hi2 = y >> 16;
lo = lo1 * lo2;
i1 = lo1 * hi2;
i2 = lo2 * hi1;
hi = hi1 * hi2;
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/* Check carry overflow of i1 + i2 */
i1 += i2;
hi += (FT_UInt32)( i1 < i2 ) << 16;
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hi += i1 >> 16;
i1 = i1 << 16;
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/* Check carry overflow of i1 + lo */
lo += i1;
hi += ( lo < i1 );
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z->lo = lo;
z->hi = hi;
}
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static FT_UInt32
ft_div64by32( FT_UInt32 hi,
FT_UInt32 lo,
FT_UInt32 y )
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{
FT_UInt32 r, q;
FT_Int i;
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q = 0;
r = hi;
if ( r >= y )
return (FT_UInt32)0x7FFFFFFFL;
i = 32;
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do
{
r <<= 1;
q <<= 1;
r |= lo >> 31;
if ( r >= y )
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{
r -= y;
q |= 1;
}
lo <<= 1;
} while ( --i );
return q;
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}
static void
FT_Add64( FT_Int64* x,
FT_Int64* y,
FT_Int64 *z )
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{
FT_UInt32 lo, hi;
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lo = x->lo + y->lo;
hi = x->hi + y->hi + ( lo < x->lo );
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z->lo = lo;
z->hi = hi;
}
/* The FT_MulDiv function has been optimized thanks to ideas from */
/* Graham Asher and Alexei Podtelezhnikov. The trick is to optimize */
/* a rather common case when everything fits within 32-bits. */
/* */
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/* We compute 'a*b+c/2', then divide it by 'c' (all positive values). */
/* */
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/* The product of two positive numbers never exceeds the square of */
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/* its mean values. Therefore, we always avoid the overflow by */
/* imposing */
/* */
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/* (a + b) / 2 <= sqrt(X - c/2) , */
/* */
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/* where X = 2^32 - 1, the maximum unsigned 32-bit value, and using */
/* unsigned arithmetic. Now we replace `sqrt' with a linear function */
/* that is smaller or equal for all values of c in the interval */
/* [0;X/2]; it should be equal to sqrt(X) and sqrt(3X/4) at the */
/* endpoints. Substituting the linear solution and explicit numbers */
/* we get */
/* */
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/* a + b <= 131071.99 - c / 122291.84 . */
/* */
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/* In practice, we should use a faster and even stronger inequality */
/* */
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/* a + b <= 131071 - (c >> 16) */
/* */
/* or, alternatively, */
/* */
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/* a + b <= 129895 - (c >> 17) . */
/* */
/* FT_MulFix, on the other hand, is optimized for a small value of */
/* the first argument, when the second argument can be much larger. */
/* This can be achieved by scaling the second argument and the limit */
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/* in the above inequalities. For example, */
/* */
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/* a + (b >> 8) <= (131071 >> 4) */
/* */
/* should work well to avoid the overflow. */
/* */
/* documentation is in freetype.h */
FT_EXPORT_DEF( FT_Long )
FT_MulDiv( FT_Long a,
FT_Long b,
FT_Long c )
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{
long s;
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/* XXX: this function does not allow 64-bit arguments */
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if ( a == 0 || b == c )
return a;
s = a; a = FT_ABS( a );
s ^= b; b = FT_ABS( b );
s ^= c; c = FT_ABS( c );
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if ( c == 0 )
a = 0x7FFFFFFFL;
else if ( (FT_ULong)a + b <= 129895UL - ( c >> 17 ) )
a = ( (FT_ULong)a * b + ( c >> 1 ) ) / c;
else
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{
FT_Int64 temp, temp2;
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ft_multo64( (FT_Int32)a, (FT_Int32)b, &temp );
temp2.hi = 0;
temp2.lo = (FT_UInt32)(c >> 1);
FT_Add64( &temp, &temp2, &temp );
a = ft_div64by32( temp.hi, temp.lo, (FT_Int32)c );
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}
return ( s < 0 ? -a : a );
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}
FT_BASE_DEF( FT_Long )
FT_MulDiv_No_Round( FT_Long a,
FT_Long b,
FT_Long c )
{
long s;
if ( a == 0 || b == c )
return a;
s = a; a = FT_ABS( a );
s ^= b; b = FT_ABS( b );
s ^= c; c = FT_ABS( c );
if ( c == 0 )
a = 0x7FFFFFFFL;
else if ( (FT_ULong)a + b <= 131071UL )
a = (FT_ULong)a * b / c;
else
{
FT_Int64 temp;
ft_multo64( (FT_Int32)a, (FT_Int32)b, &temp );
a = ft_div64by32( temp.hi, temp.lo, (FT_Int32)c );
}
return ( s < 0 ? -a : a );
}
/* documentation is in freetype.h */
FT_EXPORT_DEF( FT_Long )
FT_MulFix( FT_Long a,
FT_Long b )
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{
#ifdef FT_MULFIX_ASSEMBLER
return FT_MULFIX_ASSEMBLER( a, b );
#elif 0
/*
* This code is nonportable. See comment below.
*
* However, on a platform where right-shift of a signed quantity fills
* the leftmost bits by copying the sign bit, it might be faster.
*/
FT_Long sa, sb;
FT_ULong ua, ub;
if ( a == 0 || b == 0x10000L )
return a;
/*
* This is a clever way of converting a signed number `a' into its
* absolute value (stored back into `a') and its sign. The sign is
* stored in `sa'; 0 means `a' was positive or zero, and -1 means `a'
* was negative. (Similarly for `b' and `sb').
*
* Unfortunately, it doesn't work (at least not portably).
*
* It makes the assumption that right-shift on a negative signed value
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* fills the leftmost bits by copying the sign bit. This is wrong.
* According to K&R 2nd ed, section `A7.8 Shift Operators' on page 206,
* the result of right-shift of a negative signed value is
* implementation-defined. At least one implementation fills the
* leftmost bits with 0s (i.e., it is exactly the same as an unsigned
* right shift). This means that when `a' is negative, `sa' ends up
* with the value 1 rather than -1. After that, everything else goes
* wrong.
*/
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sa = ( a >> ( sizeof ( a ) * 8 - 1 ) );
a = ( a ^ sa ) - sa;
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sb = ( b >> ( sizeof ( b ) * 8 - 1 ) );
b = ( b ^ sb ) - sb;
ua = (FT_ULong)a;
ub = (FT_ULong)b;
if ( ua + ( ub >> 8 ) <= 8191UL )
ua = ( ua * ub + 0x8000U ) >> 16;
else
{
FT_ULong al = ua & 0xFFFFU;
ua = ( ua >> 16 ) * ub + al * ( ub >> 16 ) +
( ( al * ( ub & 0xFFFFU ) + 0x8000U ) >> 16 );
}
sa ^= sb,
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ua = (FT_ULong)(( ua ^ sa ) - sa);
return (FT_Long)ua;
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#else /* 0 */
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FT_Long s;
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FT_ULong ua, ub;
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if ( a == 0 || b == 0x10000L )
return a;
s = a; a = FT_ABS( a );
s ^= b; b = FT_ABS( b );
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ua = (FT_ULong)a;
ub = (FT_ULong)b;
if ( ua + ( ub >> 8 ) <= 8191UL )
ua = ( ua * ub + 0x8000UL ) >> 16;
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else
{
FT_ULong al = ua & 0xFFFFUL;
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ua = ( ua >> 16 ) * ub + al * ( ub >> 16 ) +
( ( al * ( ub & 0xFFFFUL ) + 0x8000UL ) >> 16 );
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}
* src/base/ftdbgmem.c (ft_mem_table_resize, ft_mem_table_new, ft_mem_table_set, ft_mem_debug_alloc, ft_mem_debug_free, ft_mem_debug_realloc, ft_mem_debug_done, FT_Alloc_Debug, FT_Realloc_Debug, FT_Free_Debug): Fix compiler warnings. * src/base/ftcalc.c (FT_MulFix): Ditto. * src/cff/cffdrivr.c (cff_get_name_index): Ditto. * src/cff/cffobjs.c (CFF_Size_Get_Global_Funcs, CFF_Size_Init, CFF_GlyphSlot_Init): Ditto. * src/cid/cidobjs.c (CID_GlyphSlot_Init, CID_Size_Get_Globals_Funcs): Ditto. * src/type1/t1objs.c (T1_Size_Get_Globals_Funcs, T1_GlyphSlot_Init): Ditto. * src/pshinter/pshmod.c (pshinter_interface): Use `static const'. * src/winfonts/winfnt.c (FNT_Get_Next_Char): Remove unused variables. * include/freetype/internal/psaux.h (T1_Builder_Funcs): Renamed to... (T1_Builder_FuncsRec): This. (T1_Builder_Funcs): New typedef. (PSAux_Interface): Remove compiler warnings. * src/psaux/psauxmod.c (t1_builder_funcs), src/psaux/psobjs.h (t1_builder_funcs): Updated. * src/pshinter/pshglob.h (PSH_Blue_Align): Replaced with ... (PSH_BLUE_ALIGN_{NONE,TOP,BOT}): New defines. (PSH_AlignmentRec): Updated. * include/freetype/internal/ftstream.h (GET_Char, GET_Byte): Fix typo. * include/freetype/internal/ftgloadr.h (FT_SubGlyph): Ditto. * src/base/ftstream (FT_Get_Char): Rename to... (FT_Stream_Get_Char): This. * src/base/ftnames.c (FT_Get_Sfnt_Name): s/index/idx/ -- `index' is a built-in function in gcc, causing warning messages with gcc 3.0. * src/autohint/ahglyph.c (ah_outline_load): Ditto. * src/autohint/ahglobal.c (ah_hinter_compute_blues): Ditto. * src/cache/ftcmanag.c (ftc_family_table_alloc, ftc_family_table_free, FTC_Manager_Done, FTC_Manager_Register_Cache): Ditto. * src/cff/cffload.c (cff_new_index, cff_done_index, cff_explicit_index, CFF_Access_Element, CFF_Forget_Element, CFF_Get_Name, CFF_Get_String, CFF_Load_SubFont, CFF_Load_Font, CFF_Done_Font): Ditto. * src/psaux/psobjs.c (PS_Table_Add, PS_Parser_LoadField): Ditto. * src/psaux/t1decode.c (T1_Decoder_Parse_Charstrings): Ditto. * src/pshinter/pshrec.c (ps_mask_test_bit, ps_mask_clear_bit, ps_mask_set_bit, ps_dimension_add_t1stem, ps_hints_t1stem3, * src/pshinter/pshalgo1.c (psh1_hint_table_record, psh1_hint_table_record_mask, psh1_hint_table_activate_mask): Ditto. * src/pshinter/pshalgo2.c (psh2_hint_table_record, psh2_hint_table_record_mask, psh2_hint_table_activate_mask): Ditto. * src/sfnt/ttpost.c (Load_Format_20, Load_Format_25, TT_Get_PS_Name): Ditto. * src/truetype/ttgload.c (TT_Get_Metrics, Get_HMetrics, load_truetype_glyph): Ditto. * src/type1/t1load.c (parse_subrs, T1_Open_Face): Ditto. * src/type1/t1afm.c (T1_Get_Kerning): Ditto. * include/freetype/cache/ftcmanag.h (ftc_family_table_free): Ditto.
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return ( s < 0 ? -(FT_Long)ua : (FT_Long)ua );
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#endif /* 0 */
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}
/* documentation is in freetype.h */
FT_EXPORT_DEF( FT_Long )
FT_DivFix( FT_Long a,
FT_Long b )
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{
FT_Long s;
FT_Long q;
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/* XXX: this function does not allow 64-bit arguments */
s = a; a = FT_ABS( a );
s ^= b; b = FT_ABS( b );
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if ( b == 0 )
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{
/* check for division by 0 */
q = 0x7FFFFFFFL;
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}
else if ( ( a >> 16 ) == 0 )
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{
/* compute result directly */
q = (FT_Long)( ( ( (FT_ULong)a << 16 ) + ( b >> 1 ) ) / b );
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}
else
{
/* we need more bits; we have to do it by hand */
FT_Int64 temp, temp2;
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temp.hi = (FT_Int32)( a >> 16 );
temp.lo = (FT_UInt32)a << 16;
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temp2.hi = 0;
temp2.lo = (FT_UInt32)( b >> 1 );
FT_Add64( &temp, &temp2, &temp );
q = (FT_Long)ft_div64by32( temp.hi, temp.lo, (FT_Int32)b );
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}
return ( s < 0 ? -q : q );
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}
#if 0
/* documentation is in ftcalc.h */
FT_EXPORT_DEF( void )
FT_MulTo64( FT_Int32 x,
FT_Int32 y,
FT_Int64 *z )
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{
FT_Int32 s;
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s = x; x = FT_ABS( x );
s ^= y; y = FT_ABS( y );
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ft_multo64( x, y, z );
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if ( s < 0 )
{
z->lo = (FT_UInt32)-(FT_Int32)z->lo;
z->hi = ~z->hi + !( z->lo );
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}
}
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/* apparently, the second version of this code is not compiled correctly */
/* on Mac machines with the MPW C compiler.. tsk, tsk, tsk... */
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#if 1
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FT_EXPORT_DEF( FT_Int32 )
FT_Div64by32( FT_Int64* x,
FT_Int32 y )
{
FT_Int32 s;
FT_UInt32 q, r, i, lo;
s = x->hi;
if ( s < 0 )
{
x->lo = (FT_UInt32)-(FT_Int32)x->lo;
x->hi = ~x->hi + !x->lo;
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}
s ^= y; y = FT_ABS( y );
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/* Shortcut */
if ( x->hi == 0 )
{
if ( y > 0 )
q = x->lo / y;
else
q = 0x7FFFFFFFL;
return ( s < 0 ? -(FT_Int32)q : (FT_Int32)q );
}
r = x->hi;
lo = x->lo;
if ( r >= (FT_UInt32)y ) /* we know y is to be treated as unsigned here */
return ( s < 0 ? 0x80000001UL : 0x7FFFFFFFUL );
/* Return Max/Min Int32 if division overflow. */
/* This includes division by zero! */
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q = 0;
for ( i = 0; i < 32; i++ )
{
r <<= 1;
q <<= 1;
r |= lo >> 31;
if ( r >= (FT_UInt32)y )
{
r -= y;
q |= 1;
}
lo <<= 1;
}
return ( s < 0 ? -(FT_Int32)q : (FT_Int32)q );
}
#else /* 0 */
FT_EXPORT_DEF( FT_Int32 )
FT_Div64by32( FT_Int64* x,
FT_Int32 y )
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{
FT_Int32 s;
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FT_UInt32 q;
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s = x->hi;
if ( s < 0 )
{
x->lo = (FT_UInt32)-(FT_Int32)x->lo;
x->hi = ~x->hi + !x->lo;
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}
s ^= y; y = FT_ABS( y );
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/* Shortcut */
if ( x->hi == 0 )
{
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if ( y > 0 )
q = ( x->lo + ( y >> 1 ) ) / y;
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else
q = 0x7FFFFFFFL;
return ( s < 0 ? -(FT_Int32)q : (FT_Int32)q );
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}
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q = ft_div64by32( x->hi, x->lo, y );
return ( s < 0 ? -(FT_Int32)q : (FT_Int32)q );
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}
#endif /* 0 */
#endif /* 0 */
#endif /* FT_LONG64 */
/* documentation is in ftglyph.h */
FT_EXPORT_DEF( void )
FT_Matrix_Multiply( const FT_Matrix* a,
FT_Matrix *b )
{
FT_Fixed xx, xy, yx, yy;
if ( !a || !b )
return;
xx = FT_MulFix( a->xx, b->xx ) + FT_MulFix( a->xy, b->yx );
xy = FT_MulFix( a->xx, b->xy ) + FT_MulFix( a->xy, b->yy );
yx = FT_MulFix( a->yx, b->xx ) + FT_MulFix( a->yy, b->yx );
yy = FT_MulFix( a->yx, b->xy ) + FT_MulFix( a->yy, b->yy );
b->xx = xx; b->xy = xy;
b->yx = yx; b->yy = yy;
}
/* documentation is in ftglyph.h */
FT_EXPORT_DEF( FT_Error )
FT_Matrix_Invert( FT_Matrix* matrix )
{
FT_Pos delta, xx, yy;
if ( !matrix )
return FT_THROW( Invalid_Argument );
/* compute discriminant */
delta = FT_MulFix( matrix->xx, matrix->yy ) -
FT_MulFix( matrix->xy, matrix->yx );
if ( !delta )
return FT_THROW( Invalid_Argument ); /* matrix can't be inverted */
matrix->xy = - FT_DivFix( matrix->xy, delta );
matrix->yx = - FT_DivFix( matrix->yx, delta );
xx = matrix->xx;
yy = matrix->yy;
matrix->xx = FT_DivFix( yy, delta );
matrix->yy = FT_DivFix( xx, delta );
return FT_Err_Ok;
}
/* documentation is in ftcalc.h */
FT_BASE_DEF( void )
FT_Matrix_Multiply_Scaled( const FT_Matrix* a,
FT_Matrix *b,
FT_Long scaling )
{
FT_Fixed xx, xy, yx, yy;
FT_Long val = 0x10000L * scaling;
if ( !a || !b )
return;
xx = FT_MulDiv( a->xx, b->xx, val ) + FT_MulDiv( a->xy, b->yx, val );
xy = FT_MulDiv( a->xx, b->xy, val ) + FT_MulDiv( a->xy, b->yy, val );
yx = FT_MulDiv( a->yx, b->xx, val ) + FT_MulDiv( a->yy, b->yx, val );
yy = FT_MulDiv( a->yx, b->xy, val ) + FT_MulDiv( a->yy, b->yy, val );
b->xx = xx; b->xy = xy;
b->yx = yx; b->yy = yy;
}
/* documentation is in ftcalc.h */
FT_BASE_DEF( void )
FT_Vector_Transform_Scaled( FT_Vector* vector,
const FT_Matrix* matrix,
FT_Long scaling )
{
FT_Pos xz, yz;
FT_Long val = 0x10000L * scaling;
if ( !vector || !matrix )
return;
xz = FT_MulDiv( vector->x, matrix->xx, val ) +
FT_MulDiv( vector->y, matrix->xy, val );
yz = FT_MulDiv( vector->x, matrix->yx, val ) +
FT_MulDiv( vector->y, matrix->yy, val );
vector->x = xz;
vector->y = yz;
}
#if 0
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/* documentation is in ftcalc.h */
FT_BASE_DEF( FT_Int32 )
FT_SqrtFixed( FT_Int32 x )
{
FT_UInt32 root, rem_hi, rem_lo, test_div;
FT_Int count;
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root = 0;
if ( x > 0 )
{
rem_hi = 0;
rem_lo = x;
count = 24;
do
{
rem_hi = ( rem_hi << 2 ) | ( rem_lo >> 30 );
rem_lo <<= 2;
root <<= 1;
test_div = ( root << 1 ) + 1;
if ( rem_hi >= test_div )
{
rem_hi -= test_div;
root += 1;
}
} while ( --count );
}
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return (FT_Int32)root;
}
#endif /* 0 */
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/* documentation is in ftcalc.h */
FT_BASE_DEF( FT_Int )
ft_corner_orientation( FT_Pos in_x,
FT_Pos in_y,
FT_Pos out_x,
FT_Pos out_y )
{
FT_Long result; /* avoid overflow on 16-bit system */
/* deal with the trivial cases quickly */
if ( in_y == 0 )
{
if ( in_x >= 0 )
result = out_y;
else
result = -out_y;
}
else if ( in_x == 0 )
{
if ( in_y >= 0 )
result = -out_x;
else
result = out_x;
}
else if ( out_y == 0 )
{
if ( out_x >= 0 )
result = in_y;
else
result = -in_y;
}
else if ( out_x == 0 )
{
if ( out_y >= 0 )
result = -in_x;
else
result = in_x;
}
else /* general case */
{
#ifdef FT_LONG64
FT_Int64 delta = (FT_Int64)in_x * out_y - (FT_Int64)in_y * out_x;
if ( delta == 0 )
result = 0;
else
result = 1 - 2 * ( delta < 0 );
#else
FT_Int64 z1, z2;
/* XXX: this function does not allow 64-bit arguments */
ft_multo64( (FT_Int32)in_x, (FT_Int32)out_y, &z1 );
ft_multo64( (FT_Int32)in_y, (FT_Int32)out_x, &z2 );
if ( z1.hi > z2.hi )
result = +1;
else if ( z1.hi < z2.hi )
result = -1;
else if ( z1.lo > z2.lo )
result = +1;
else if ( z1.lo < z2.lo )
result = -1;
else
result = 0;
#endif
}
/* XXX: only the sign of return value, +1/0/-1 must be used */
return (FT_Int)result;
}
/* documentation is in ftcalc.h */
FT_BASE_DEF( FT_Int )
ft_corner_is_flat( FT_Pos in_x,
FT_Pos in_y,
FT_Pos out_x,
FT_Pos out_y )
{
FT_Pos ax = in_x;
FT_Pos ay = in_y;
FT_Pos d_in, d_out, d_corner;
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/* We approximate the Euclidean metric (sqrt(x^2 + y^2)) with */
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/* the Taxicab metric (|x| + |y|), which can be computed much */
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/* faster. If one of the two vectors is much longer than the */
/* other one, the direction of the shorter vector doesn't */
/* influence the result any more. */
/* */
/* corner */
/* x---------------------------x */
/* \ / */
/* \ / */
/* in \ / out */
/* \ / */
/* o */
/* Point */
/* */
if ( ax < 0 )
ax = -ax;
if ( ay < 0 )
ay = -ay;
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d_in = ax + ay; /* d_in = || in || */
ax = out_x;
if ( ax < 0 )
ax = -ax;
ay = out_y;
if ( ay < 0 )
ay = -ay;
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d_out = ax + ay; /* d_out = || out || */
ax = out_x + in_x;
if ( ax < 0 )
ax = -ax;
ay = out_y + in_y;
if ( ay < 0 )
ay = -ay;
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d_corner = ax + ay; /* d_corner = || in + out || */
/* now do a simple length comparison: */
/* */
/* d_in + d_out < 17/16 d_corner */
return ( d_in + d_out - d_corner ) < ( d_corner >> 4 );
}
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/* END */