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335 lines
7.8 KiB
C
335 lines
7.8 KiB
C
#include "gd.h"
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#include <math.h>
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#ifndef M_PI
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# define M_PI 3.14159265358979323846
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#endif
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/**
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* Title: Matrix
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* Group: Affine Matrix
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*/
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/**
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* Function: gdAffineApplyToPointF
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* Applies an affine transformation to a point (floating point
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* gdPointF)
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*
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*
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* Parameters:
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* dst - Where to store the resulting point
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* affine - Source Point
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* flip_horz - affine matrix
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*
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* Returns:
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* GD_TRUE if the affine is rectilinear or GD_FALSE
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*/
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int gdAffineApplyToPointF (gdPointFPtr dst, const gdPointFPtr src,
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const double affine[6])
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{
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double x = src->x;
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double y = src->y;
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x = src->x;
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y = src->y;
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dst->x = x * affine[0] + y * affine[2] + affine[4];
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dst->y = x * affine[1] + y * affine[3] + affine[5];
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return GD_TRUE;
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}
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/**
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* Function: gdAffineInvert
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* Find the inverse of an affine transformation.
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*
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* All non-degenerate affine transforms are invertible. Applying the
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* inverted matrix will restore the original values. Multiplying <src>
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* by <dst> (commutative) will return the identity affine (rounding
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* error possible).
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*
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* Parameters:
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* dst - Where to store the resulting affine transform
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* src_affine - Original affine matrix
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* flip_horz - Whether or not to flip horizontally
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* flip_vert - Whether or not to flip vertically
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*
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* See also:
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* <gdAffineIdentity>
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*
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* Returns:
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* GD_TRUE if the affine is rectilinear or GD_FALSE
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*/
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int gdAffineInvert (double dst[6], const double src[6])
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{
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double r_det = (src[0] * src[3] - src[1] * src[2]);
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if (r_det <= 0.0) {
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return GD_FALSE;
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}
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r_det = 1.0 / r_det;
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dst[0] = src[3] * r_det;
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dst[1] = -src[1] * r_det;
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dst[2] = -src[2] * r_det;
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dst[3] = src[0] * r_det;
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dst[4] = -src[4] * dst[0] - src[5] * dst[2];
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dst[5] = -src[4] * dst[1] - src[5] * dst[3];
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return GD_TRUE;
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}
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/**
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* Function: gdAffineFlip
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* Flip an affine transformation horizontally or vertically.
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*
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* Flips the affine transform, giving GD_FALSE for <flip_horz> and
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* <flip_vert> will clone the affine matrix. GD_TRUE for both will
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* copy a 180° rotation.
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*
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* Parameters:
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* dst - Where to store the resulting affine transform
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* src_affine - Original affine matrix
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* flip_h - Whether or not to flip horizontally
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* flip_v - Whether or not to flip vertically
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*
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* Returns:
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* GD_SUCCESS on success or GD_FAILURE
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*/
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int gdAffineFlip (double dst[6], const double src[6], const int flip_h, const int flip_v)
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{
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dst[0] = flip_h ? - src[0] : src[0];
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dst[1] = flip_h ? - src[1] : src[1];
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dst[2] = flip_v ? - src[2] : src[2];
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dst[3] = flip_v ? - src[3] : src[3];
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dst[4] = flip_h ? - src[4] : src[4];
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dst[5] = flip_v ? - src[5] : src[5];
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return GD_TRUE;
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}
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/**
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* Function: gdAffineConcat
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* Concat (Multiply) two affine transformation matrices.
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*
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* Concats two affine transforms together, i.e. the result
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* will be the equivalent of doing first the transformation m1 and then
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* m2. All parameters can be the same matrix (safe to call using
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* the same array for all three arguments).
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*
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* Parameters:
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* dst - Where to store the resulting affine transform
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* m1 - First affine matrix
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* m2 - Second affine matrix
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*
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* Returns:
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* GD_SUCCESS on success or GD_FAILURE
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*/
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int gdAffineConcat (double dst[6], const double m1[6], const double m2[6])
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{
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double dst0, dst1, dst2, dst3, dst4, dst5;
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dst0 = m1[0] * m2[0] + m1[1] * m2[2];
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dst1 = m1[0] * m2[1] + m1[1] * m2[3];
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dst2 = m1[2] * m2[0] + m1[3] * m2[2];
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dst3 = m1[2] * m2[1] + m1[3] * m2[3];
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dst4 = m1[4] * m2[0] + m1[5] * m2[2] + m2[4];
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dst5 = m1[4] * m2[1] + m1[5] * m2[3] + m2[5];
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dst[0] = dst0;
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dst[1] = dst1;
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dst[2] = dst2;
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dst[3] = dst3;
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dst[4] = dst4;
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dst[5] = dst5;
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return GD_TRUE;
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}
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/**
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* Function: gdAffineIdentity
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* Set up the identity matrix.
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*
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* Parameters:
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* dst - Where to store the resulting affine transform
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*
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* Returns:
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* GD_SUCCESS on success or GD_FAILURE
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*/
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int gdAffineIdentity (double dst[6])
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{
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dst[0] = 1;
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dst[1] = 0;
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dst[2] = 0;
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dst[3] = 1;
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dst[4] = 0;
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dst[5] = 0;
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return GD_TRUE;
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}
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/**
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* Function: gdAffineScale
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* Set up a scaling matrix.
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*
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* Parameters:
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* scale_x - X scale factor
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* scale_y - Y scale factor
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*
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* Returns:
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* GD_SUCCESS on success or GD_FAILURE
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*/
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int gdAffineScale (double dst[6], const double scale_x, const double scale_y)
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{
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dst[0] = scale_x;
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dst[1] = 0;
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dst[2] = 0;
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dst[3] = scale_y;
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dst[4] = 0;
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dst[5] = 0;
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return GD_TRUE;
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}
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/**
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* Function: gdAffineRotate
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* Set up a rotation affine transform.
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*
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* Like the other angle in libGD, in which increasing y moves
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* downward, this is a counterclockwise rotation.
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*
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* Parameters:
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* dst - Where to store the resulting affine transform
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* angle - Rotation angle in degrees
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*
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* Returns:
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* GD_SUCCESS on success or GD_FAILURE
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*/
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int gdAffineRotate (double dst[6], const double angle)
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{
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const double sin_t = sin (angle * M_PI / 180.0);
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const double cos_t = cos (angle * M_PI / 180.0);
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dst[0] = cos_t;
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dst[1] = sin_t;
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dst[2] = -sin_t;
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dst[3] = cos_t;
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dst[4] = 0;
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dst[5] = 0;
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return GD_TRUE;
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}
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/**
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* Function: gdAffineShearHorizontal
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* Set up a horizontal shearing matrix || becomes \\.
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*
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* Parameters:
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* dst - Where to store the resulting affine transform
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* angle - Shear angle in degrees
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*
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* Returns:
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* GD_SUCCESS on success or GD_FAILURE
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*/
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int gdAffineShearHorizontal(double dst[6], const double angle)
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{
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dst[0] = 1;
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dst[1] = 0;
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dst[2] = tan(angle * M_PI / 180.0);
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dst[3] = 1;
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dst[4] = 0;
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dst[5] = 0;
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return GD_TRUE;
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}
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/**
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* Function: gdAffineShearVertical
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* Set up a vertical shearing matrix, columns are untouched.
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*
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* Parameters:
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* dst - Where to store the resulting affine transform
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* angle - Shear angle in degrees
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*
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* Returns:
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* GD_SUCCESS on success or GD_FAILURE
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*/
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int gdAffineShearVertical(double dst[6], const double angle)
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{
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dst[0] = 1;
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dst[1] = tan(angle * M_PI / 180.0);;
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dst[2] = 0;
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dst[3] = 1;
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dst[4] = 0;
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dst[5] = 0;
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return GD_TRUE;
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}
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/**
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* Function: gdAffineTranslate
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* Set up a translation matrix.
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*
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* Parameters:
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* dst - Where to store the resulting affine transform
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* offset_x - Horizontal translation amount
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* offset_y - Vertical translation amount
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*
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* Returns:
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* GD_SUCCESS on success or GD_FAILURE
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*/
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int gdAffineTranslate (double dst[6], const double offset_x, const double offset_y)
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{
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dst[0] = 1;
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dst[1] = 0;
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dst[2] = 0;
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dst[3] = 1;
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dst[4] = offset_x;
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dst[5] = offset_y;
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return GD_TRUE;
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}
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/**
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* gdAffineexpansion: Find the affine's expansion factor.
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* @src: The affine transformation.
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*
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* Finds the expansion factor, i.e. the square root of the factor
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* by which the affine transform affects area. In an affine transform
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* composed of scaling, rotation, shearing, and translation, returns
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* the amount of scaling.
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*
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* GD_SUCCESS on success or GD_FAILURE
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**/
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double gdAffineExpansion (const double src[6])
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{
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return sqrt (fabs (src[0] * src[3] - src[1] * src[2]));
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}
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/**
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* Function: gdAffineRectilinear
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* Determines whether the affine transformation is axis aligned. A
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* tolerance has been implemented using GD_EPSILON.
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*
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* Parameters:
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* m - The affine transformation
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*
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* Returns:
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* GD_TRUE if the affine is rectilinear or GD_FALSE
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*/
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int gdAffineRectilinear (const double m[6])
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{
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return ((fabs (m[1]) < GD_EPSILON && fabs (m[2]) < GD_EPSILON) ||
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(fabs (m[0]) < GD_EPSILON && fabs (m[3]) < GD_EPSILON));
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}
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/**
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* Function: gdAffineEqual
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* Determines whether two affine transformations are equal. A tolerance
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* has been implemented using GD_EPSILON.
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*
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* Parameters:
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* m1 - The first affine transformation
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* m2 - The first affine transformation
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*
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* Returns:
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* GD_SUCCESS on success or GD_FAILURE
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*/
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int gdAffineEqual (const double m1[6], const double m2[6])
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{
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return (fabs (m1[0] - m2[0]) < GD_EPSILON &&
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fabs (m1[1] - m2[1]) < GD_EPSILON &&
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fabs (m1[2] - m2[2]) < GD_EPSILON &&
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fabs (m1[3] - m2[3]) < GD_EPSILON &&
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fabs (m1[4] - m2[4]) < GD_EPSILON &&
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fabs (m1[5] - m2[5]) < GD_EPSILON);
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}
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