include/freetype/internal/ftcalc.h - chromium/src/third_party/freetype - Git at Google

 /***************************************************************************/
 /*                                                                         */
 /*  ftcalc.h                                                               */
 /*                                                                         */
 /*    Arithmetic computations (specification).                             */
 /*                                                                         */
 /*  Copyright 1996-2006, 2008, 2009, 2012-2013 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.                                        */
 /*                                                                         */
 /***************************************************************************/


 #ifndef __FTCALC_H__
 #define __FTCALC_H__


 #include <ft2build.h>
 #include FT_FREETYPE_H


 FT_BEGIN_HEADER


   /*************************************************************************/
   /*                                                                       */
   /* <Function>                                                            */
   /*    FT_FixedSqrt                                                       */
   /*                                                                       */
   /* <Description>                                                         */
   /*    Computes the square root of a 16.16 fixed-point value.             */
   /*                                                                       */
   /* <Input>                                                               */
   /*    x :: The value to compute the root for.                            */
   /*                                                                       */
   /* <Return>                                                              */
   /*    The result of `sqrt(x)'.                                           */
   /*                                                                       */
   /* <Note>                                                                */
   /*    This function is not very fast.                                    */
   /*                                                                       */
   FT_BASE( FT_Int32 )
   FT_SqrtFixed( FT_Int32  x );


   /*************************************************************************/
   /*                                                                       */
   /* FT_MulDiv() and FT_MulFix() are declared in freetype.h.               */
   /*                                                                       */
   /*************************************************************************/


   /*************************************************************************/
   /*                                                                       */
   /* <Function>                                                            */
   /*    FT_MulDiv_No_Round                                                 */
   /*                                                                       */
   /* <Description>                                                         */
   /*    A very simple function used to perform the computation `(a*b)/c'   */
   /*    (without rounding) with maximum accuracy (it uses a 64-bit         */
   /*    intermediate integer whenever necessary).                          */
   /*                                                                       */
   /*    This function isn't necessarily as fast as some processor specific */
   /*    operations, but is at least completely portable.                   */
   /*                                                                       */
   /* <Input>                                                               */
   /*    a :: The first multiplier.                                         */
   /*    b :: The second multiplier.                                        */
   /*    c :: The divisor.                                                  */
   /*                                                                       */
   /* <Return>                                                              */
   /*    The result of `(a*b)/c'.  This function never traps when trying to */
   /*    divide by zero; it simply returns `MaxInt' or `MinInt' depending   */
   /*    on the signs of `a' and `b'.                                       */
   /*                                                                       */
   FT_BASE( FT_Long )
   FT_MulDiv_No_Round( FT_Long  a,
                       FT_Long  b,
                       FT_Long  c );


   /*
    *  A variant of FT_Matrix_Multiply which scales its result afterwards.
    *  The idea is that both `a' and `b' are scaled by factors of 10 so that
    *  the values are as precise as possible to get a correct result during
    *  the 64bit multiplication.  Let `sa' and `sb' be the scaling factors of
    *  `a' and `b', respectively, then the scaling factor of the result is
    *  `sa*sb'.
    */
   FT_BASE( void )
   FT_Matrix_Multiply_Scaled( const FT_Matrix*  a,
                              FT_Matrix        *b,
                              FT_Long           scaling );


   /*
    *  A variant of FT_Vector_Transform.  See comments for
    *  FT_Matrix_Multiply_Scaled.
    */
   FT_BASE( void )
   FT_Vector_Transform_Scaled( FT_Vector*        vector,
                               const FT_Matrix*  matrix,
                               FT_Long           scaling );


   /*
    *  Return -1, 0, or +1, depending on the orientation of a given corner.
    *  We use the Cartesian coordinate system, with positive vertical values
    *  going upwards.  The function returns +1 if the corner turns to the
    *  left, -1 to the right, and 0 for undecidable cases.
    */
   FT_BASE( FT_Int )
   ft_corner_orientation( FT_Pos  in_x,
                          FT_Pos  in_y,
                          FT_Pos  out_x,
                          FT_Pos  out_y );

   /*
    *  Return TRUE if a corner is flat or nearly flat.  This is equivalent to
    *  saying that the angle difference between the `in' and `out' vectors is
    *  very small.
    */
   FT_BASE( FT_Int )
   ft_corner_is_flat( FT_Pos  in_x,
                      FT_Pos  in_y,
                      FT_Pos  out_x,
                      FT_Pos  out_y );


   /*
    *  Return the most significant bit index.
    */
   FT_BASE( FT_Int )
   FT_MSB( FT_UInt32  z );


   /*
    *  Return sqrt(x*x+y*y), which is the same as `FT_Vector_Length' but uses
    *  two fixed-point arguments instead.
    */
   FT_BASE( FT_Fixed )
   FT_Hypot( FT_Fixed  x,
             FT_Fixed  y );


 #define INT_TO_F26DOT6( x )    ( (FT_Long)(x) << 6  )
 #define INT_TO_F2DOT14( x )    ( (FT_Long)(x) << 14 )
 #define INT_TO_FIXED( x )      ( (FT_Long)(x) << 16 )
 #define F2DOT14_TO_FIXED( x )  ( (FT_Long)(x) << 2  )
 #define FLOAT_TO_FIXED( x )    ( (FT_Long)( x * 65536.0 ) )
 #define FIXED_TO_INT( x )      ( FT_RoundFix( x ) >> 16 )

 #define ROUND_F26DOT6( x )     ( x >= 0 ? (    ( (x) + 32 ) & -64 )     \
                                         : ( -( ( 32 - (x) ) & -64 ) ) )


 FT_END_HEADER

 #endif /* __FTCALC_H__ */


 /* END */
	/***************************************************************************/
	/* */
	/* ftcalc.h */
	/* */
	/* Arithmetic computations (specification). */
	/* */
	/* Copyright 1996-2006, 2008, 2009, 2012-2013 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. */
	/* */
	/***************************************************************************/


	#ifndef __FTCALC_H__
	#define __FTCALC_H__


	#include <ft2build.h>
	#include FT_FREETYPE_H


	FT_BEGIN_HEADER


	/*************************************************************************/
	/* */
	/* <Function> */
	/* FT_FixedSqrt */
	/* */
	/* <Description> */
	/* Computes the square root of a 16.16 fixed-point value. */
	/* */
	/* <Input> */
	/* x :: The value to compute the root for. */
	/* */
	/* <Return> */
	/* The result of `sqrt(x)'. */
	/* */
	/* <Note> */
	/* This function is not very fast. */
	/* */
	FT_BASE( FT_Int32 )
	FT_SqrtFixed( FT_Int32 x );


	/*************************************************************************/
	/* */
	/* FT_MulDiv() and FT_MulFix() are declared in freetype.h. */
	/* */
	/*************************************************************************/


	/*************************************************************************/
	/* */
	/* <Function> */
	/* FT_MulDiv_No_Round */
	/* */
	/* <Description> */
	/* A very simple function used to perform the computation `(ab)/c' /
	/* (without rounding) with maximum accuracy (it uses a 64-bit */
	/* intermediate integer whenever necessary). */
	/* */
	/* This function isn't necessarily as fast as some processor specific */
	/* operations, but is at least completely portable. */
	/* */
	/* <Input> */
	/* a :: The first multiplier. */
	/* b :: The second multiplier. */
	/* c :: The divisor. */
	/* */
	/* <Return> */
	/* The result of `(ab)/c'. This function never traps when trying to /
	/* divide by zero; it simply returns `MaxInt' or `MinInt' depending */
	/* on the signs of `a' and `b'. */
	/* */
	FT_BASE( FT_Long )
	FT_MulDiv_No_Round( FT_Long a,
	FT_Long b,
	FT_Long c );


	/*
	* A variant of FT_Matrix_Multiply which scales its result afterwards.
	* The idea is that both `a' and `b' are scaled by factors of 10 so that
	* the values are as precise as possible to get a correct result during
	* the 64bit multiplication. Let `sa' and `sb' be the scaling factors of
	* `a' and `b', respectively, then the scaling factor of the result is
	* `sa*sb'.
	*/
	FT_BASE( void )
	FT_Matrix_Multiply_Scaled( const FT_Matrix* a,
	FT_Matrix *b,
	FT_Long scaling );


	/*
	* A variant of FT_Vector_Transform. See comments for
	* FT_Matrix_Multiply_Scaled.
	*/
	FT_BASE( void )
	FT_Vector_Transform_Scaled( FT_Vector* vector,
	const FT_Matrix* matrix,
	FT_Long scaling );


	/*
	* Return -1, 0, or +1, depending on the orientation of a given corner.
	* We use the Cartesian coordinate system, with positive vertical values
	* going upwards. The function returns +1 if the corner turns to the
	* left, -1 to the right, and 0 for undecidable cases.
	*/
	FT_BASE( FT_Int )
	ft_corner_orientation( FT_Pos in_x,
	FT_Pos in_y,
	FT_Pos out_x,
	FT_Pos out_y );

	/*
	* Return TRUE if a corner is flat or nearly flat. This is equivalent to
	* saying that the angle difference between the `in' and `out' vectors is
	* very small.
	*/
	FT_BASE( FT_Int )
	ft_corner_is_flat( FT_Pos in_x,
	FT_Pos in_y,
	FT_Pos out_x,
	FT_Pos out_y );


	/*
	* Return the most significant bit index.
	*/
	FT_BASE( FT_Int )
	FT_MSB( FT_UInt32 z );


	/*
	* Return sqrt(xx+yy), which is the same as `FT_Vector_Length' but uses
	* two fixed-point arguments instead.
	*/
	FT_BASE( FT_Fixed )
	FT_Hypot( FT_Fixed x,
	FT_Fixed y );


	#define INT_TO_F26DOT6( x ) ( (FT_Long)(x) << 6 )
	#define INT_TO_F2DOT14( x ) ( (FT_Long)(x) << 14 )
	#define INT_TO_FIXED( x ) ( (FT_Long)(x) << 16 )
	#define F2DOT14_TO_FIXED( x ) ( (FT_Long)(x) << 2 )
	#define FLOAT_TO_FIXED( x ) ( (FT_Long)( x * 65536.0 ) )
	#define FIXED_TO_INT( x ) ( FT_RoundFix( x ) >> 16 )

	#define ROUND_F26DOT6( x ) ( x >= 0 ? ( ( (x) + 32 ) & -64 ) \
	: ( -( ( 32 - (x) ) & -64 ) ) )


	FT_END_HEADER

	#endif /* __FTCALC_H__ */


	/* END */