ref: 1e03fff62b1e9c1577858551924f531adeaa76e0
dir: /src/autofit/afangles.c/
#include "aftypes.h"
/*
* a python script used to generate the following table
*
import sys, math
units = 256
scale = units/math.pi
comma = ""
print ""
print "table of arctan( 1/2^n ) for PI = " + repr(units/65536.0) + " units"
r = [-1] + range(32)
for n in r:
if n >= 0:
x = 1.0/(2.0**n) # tangent value
else:
x = 2.0**(-n)
angle = math.atan(x) # arctangent
angle2 = angle*scale # arctangent in FT_Angle units
# determine which integer value for angle gives the best tangent
lo = int(angle2)
hi = lo + 1
tlo = math.tan(lo/scale)
thi = math.tan(hi/scale)
errlo = abs( tlo - x )
errhi = abs( thi - x )
angle2 = hi
if errlo < errhi:
angle2 = lo
if angle2 <= 0:
break
sys.stdout.write( comma + repr( int(angle2) ) )
comma = ", "
*
* end of python script
*/
/* this table was generated for AF_ANGLE_PI = 256 */
#define AF_ANGLE_MAX_ITERS 8
#define AF_TRIG_MAX_ITERS 8
static const FT_Fixed
af_angle_arctan_table[9] =
{
90, 64, 38, 20, 10, 5, 3, 1, 1
};
static FT_Int
af_angle_prenorm( FT_Vector* vec )
{
FT_Fixed x, y, z;
FT_Int shift;
x = vec->x;
y = vec->y;
z = ( ( x >= 0 ) ? x : - x ) | ( (y >= 0) ? y : -y );
shift = 0;
if ( z < ( 1L << 27 ) )
{
do
{
shift++;
z <<= 1;
} while ( z < ( 1L << 27 ) );
vec->x = x << shift;
vec->y = y << shift;
}
else if ( z > ( 1L << 28 ) )
{
do
{
shift++;
z >>= 1;
} while ( z > ( 1L << 28 ) );
vec->x = x >> shift;
vec->y = y >> shift;
shift = -shift;
}
return shift;
}
static void
af_angle_pseudo_polarize( FT_Vector* vec )
{
FT_Fixed theta;
FT_Fixed yi, i;
FT_Fixed x, y;
const FT_Fixed *arctanptr;
x = vec->x;
y = vec->y;
/* Get the vector into the right half plane */
theta = 0;
if ( x < 0 )
{
x = -x;
y = -y;
theta = AF_ANGLE_PI;
}
if ( y > 0 )
theta = - theta;
arctanptr = af_angle_arctan_table;
if ( y < 0 )
{
/* Rotate positive */
yi = y + ( x << 1 );
x = x - ( y << 1 );
y = yi;
theta -= *arctanptr++; /* Subtract angle */
}
else
{
/* Rotate negative */
yi = y - ( x << 1 );
x = x + ( y << 1 );
y = yi;
theta += *arctanptr++; /* Add angle */
}
i = 0;
do
{
if ( y < 0 )
{
/* Rotate positive */
yi = y + ( x >> i );
x = x - ( y >> i );
y = yi;
theta -= *arctanptr++;
}
else
{
/* Rotate negative */
yi = y - ( x >> i );
x = x + ( y >> i );
y = yi;
theta += *arctanptr++;
}
} while ( ++i < AF_TRIG_MAX_ITERS );
#if 0
/* round theta */
if ( theta >= 0 )
theta = FT_PAD_ROUND( theta, 2 );
else
theta = - FT_PAD_ROUND( -theta, 2 );
#endif
vec->x = x;
vec->y = theta;
}
/* documentation is in fttrigon.h */
FT_LOCAL_DEF( AF_Angle )
af_angle_atan( FT_Fixed dx,
FT_Fixed dy )
{
FT_Vector v;
if ( dx == 0 && dy == 0 )
return 0;
v.x = dx;
v.y = dy;
af_angle_prenorm( &v );
af_angle_pseudo_polarize( &v );
return v.y;
}
FT_LOCAL_DEF( AF_Angle )
af_angle_diff( AF_Angle angle1,
AF_Angle angle2 )
{
AF_Angle delta = angle2 - angle1;
delta %= AF_ANGLE_2PI;
if ( delta < 0 )
delta += AF_ANGLE_2PI;
if ( delta > AF_ANGLE_PI )
delta -= AF_ANGLE_2PI;
return delta;
}
/* well, this needs to be somewhere, right :-)
*/
FT_LOCAL_DEF( void )
af_sort_pos( FT_UInt count,
FT_Pos* table )
{
FT_UInt i, j;
FT_Pos swap;
for ( i = 1; i < count; i++ )
{
for ( j = i; j > 0; j-- )
{
if ( table[j] > table[j - 1] )
break;
swap = table[j];
table[j] = table[j - 1];
table[j - 1] = swap;
}
}
}
FT_LOCAL_DEF( void )
af_sort_widths( FT_UInt count,
AF_Width table )
{
FT_UInt i, j;
AF_WidthRec swap;
for ( i = 1; i < count; i++ )
{
for ( j = i; j > 0; j-- )
{
if ( table[j].org > table[j - 1].org )
break;
swap = table[j];
table[j] = table[j - 1];
table[j - 1] = swap;
}
}
}
#ifdef TEST
#include <stdio.h>
#include <math.h>
int main( void )
{
int angle;
int dist;
for ( dist = 100; dist < 1000; dist++ )
{
for ( angle = AF_ANGLE_PI; angle < AF_ANGLE_2PI*4; angle++ )
{
double a = (angle*3.1415926535)/(1.0*AF_ANGLE_PI);
int dx, dy, angle1, angle2, delta;
dx = dist * cos(a);
dy = dist * sin(a);
angle1 = ((atan2(dy,dx)*AF_ANGLE_PI)/3.1415926535);
angle2 = af_angle_atan( dx, dy );
delta = (angle2 - angle1) % AF_ANGLE_2PI;
if ( delta < 0 )
delta = -delta;
if ( delta >= 2 )
{
printf( "dist:%4d angle:%4d => (%4d,%4d) angle1:%4d angle2:%4d\n",
dist, angle, dx, dy, angle1, angle2 );
}
}
}
return 0;
}
#endif