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git://projects.qi-hardware.com/ben-scans.git
synced 2024-11-22 03:37:31 +02:00
Instead of performing the tranformations stepwise for each point, pre-calculate
them once. - solidify/matrix.h, solidify/matrix.c: 2D matrix operations - solidify/Makefile (OBJS): added matrix.o - solidify/face.h (struct matrix): moved to solidify/matrix.h - solidify/overlap.c (point, merge_matrix, draw_map): precalculate a single vA+b transformation instead of stepwise transforming the vector inside the loop - solidify/overlap.c (do_shift): now that the math is right (or at least better), reverse the shift
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@ -12,8 +12,8 @@
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SHELL = /bin/bash
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OBJS = array.o face.o histo.o level.o overlap.o solid.o solidify.o style.o \
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util.o
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OBJS = array.o face.o histo.o level.o matrix.o overlap.o solid.o solidify.o \
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style.o util.o
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CFLAGS_WARN = -Wall -Wshadow -Wmissing-prototypes \
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-Wmissing-declarations -Wno-format-zero-length
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@ -14,21 +14,9 @@
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#define FACE_H
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#include "array.h"
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#include "matrix.h"
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/*
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* 2D transformation:
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*
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* x' = x*a[0][0]+y*a[0][1]+b[0]
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* y' = x*a[1][0]+y*a[1][1]+b[1]
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*/
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struct matrix {
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double a[2][2];
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double b[2];
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};
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struct face {
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struct array *a;
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int sx, sy; /* size */
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@ -47,4 +35,4 @@ static inline double face_z0(const struct face *f, int x, int y)
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struct face *read_face(const char *name);
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#endif /* FACE_H */
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#endif /* !FACE_H */
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66
solidify/matrix.c
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66
solidify/matrix.c
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@ -0,0 +1,66 @@
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/*
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* matrix.c - 2D matrix operations
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*
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* Written 2010 by Werner Almesberger
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* Copyright 2010 by Werner Almesberger
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2 of the License, or
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* (at your option) any later version.
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*/
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#include <assert.h>
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#include "matrix.h"
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void matrix_identity(struct matrix *m)
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{
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m->a[0][0] = m->a[1][1] = 1;
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m->a[0][1] = m->a[1][0] = 0;
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m->b[0] = m->b[1] = 0;
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}
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void matrix_invert(const double m[2][2], double res[2][2])
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{
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double det = m[0][0]*m[1][1]-m[0][1]*m[1][0];
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assert(res != (void *) m);
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res[0][0] = m[1][1]/det;
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res[0][1] = -m[0][1]/det;
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res[1][0] = -m[1][0]/det;
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res[1][1] = m[0][0]/det;
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}
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void matrix_mult(double a[2][2], double b[2][2], double res[2][2])
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{
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assert(res != a);
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assert(res != b);
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res[0][0] = a[0][0]*b[0][0]+a[0][1]*b[1][0];
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res[0][1] = a[0][0]*b[0][1]+a[0][1]*b[1][1];
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res[1][0] = a[1][0]*b[0][0]+a[1][1]*b[1][0];
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res[1][1] = a[1][0]*b[0][1]+a[1][1]*b[1][1];
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}
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void matrix_multv(const double v[2], double m[2][2], double res[2])
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{
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double tmp;
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tmp = v[0]*m[0][0]+v[1]*m[0][1];
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res[1] = v[0]*m[1][0]+v[1]*m[1][1];
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res[0] = tmp;
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}
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void matrix_copy(double from[2][2], double to[2][2])
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{
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to[0][0] = from[0][0];
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to[0][1] = from[0][1];
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to[1][0] = from[1][0];
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to[1][1] = from[1][1];
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}
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45
solidify/matrix.h
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45
solidify/matrix.h
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/*
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* matrix.h - 2D matrix operations
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*
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* Written 2010 by Werner Almesberger
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* Copyright 2010 by Werner Almesberger
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2 of the License, or
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* (at your option) any later version.
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*/
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#ifndef MATRIX_H
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#define MATRIX_H
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/*
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* 2D transformation:
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*
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* x' = x*a[0][0]+y*a[0][1]+b[0]
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* y' = x*a[1][0]+y*a[1][1]+b[1]
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*/
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struct matrix {
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double a[2][2];
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double b[2];
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};
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void matrix_identity(struct matrix *m);
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void matrix_invert(const double m[2][2], double res[2][2]);
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void matrix_mult(double a[2][2], double b[2][2], double res[2][2]);
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void matrix_multv(const double v[2], double m[2][2], double res[2]);
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void matrix_copy(double from[2][2], double to[2][2]);
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static inline void matrix_map(int x, int y, const struct matrix *m,
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double *res_x, double *res_y)
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{
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*res_x = x*m->a[0][0]+y*m->a[0][1]+m->b[0];
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*res_y = x*m->a[1][0]+y*m->a[1][1]+m->b[1];
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}
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#endif /* !MATRIX_H */
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@ -92,22 +92,16 @@ static double zmix(struct face *f, double x, double y)
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* - our model runs from min_x to max_x. Its center is at cx.
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*/
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static void point(const struct solid *s, int x, int y, guchar *p)
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static void point(const struct solid *s, int x, int y, guchar *p,
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const struct matrix *ma, const struct matrix *mb)
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{
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double za, zb, z;
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int xa, xb, ya, yb;
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double xaf, xbf, yaf, ybf;
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xa = x-sx(s)/2;
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ya = y-sy(s)/2;
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xaf = xa*s->a->m.a[0][0]+ya*s->a->m.a[0][1]+s->a->m.b[0]+s->a->cx;
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yaf = xa*s->a->m.a[1][0]+ya*s->a->m.a[1][1]+s->a->m.b[1]+s->a->cy;
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za = zmix(s->a, xaf, yaf);
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matrix_map(x, y, ma, &xaf, &yaf);
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matrix_map(x, y, mb, &xbf, &ybf);
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xb = x-sx(s)/2;
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yb = (sy(s)-1)/2-y;
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xbf = xb*s->b->m.a[0][0]+yb*s->b->m.a[0][1]+s->b->m.b[0]+s->b->cx;
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ybf = xb*s->b->m.a[1][0]+yb*s->b->m.a[1][1]+s->b->m.b[1]+s->b->cy;
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za = zmix(s->a, xaf, yaf);
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zb = zmix(s->b, xbf, ybf);
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if (za == UNDEF_F && zb == UNDEF_F)
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@ -158,19 +152,115 @@ static void point(const struct solid *s, int x, int y, guchar *p)
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}
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static void merge_matrix(struct matrix *m, const struct solid *s,
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const struct face *f)
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{
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double tm[2][2], tm2[2][2];
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double tv[2];
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double f_x, f_y;
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/*
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* Finally, we convert to model matrix coordinates.
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*
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* v' = v+c
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*/
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m->b[0] += f->cx;
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m->b[1] += f->cy;
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/*
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* Apply shrinkage caused by rotation out of z0. We use that
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* cos a = sqrt(1-sin^2 a)
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*/
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f_x = 1.0/sqrt(1-f->fx*f->fx);
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f_y = 1.0/sqrt(1-f->fy*f->fy);
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m->a[0][0] *= f_x;
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m->a[0][1] *= f_x;
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m->b[0] *= f_x;
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m->a[1][0] *= f_y;
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m->a[1][1] *= f_y;
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m->b[1] *= f_y;
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/*
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* The transformation matrix f->m describes a transformation of
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* (centered) model coordinates. We therefore have to reverse it:
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*
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* v = v'A+b
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* v-b = v'A
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* (v-b)A^-1 = v'
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* vA^-1-bA^-1 = v'
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*/
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matrix_invert(f->m.a, tm);
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matrix_multv(f->m.b, tm, tv);
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tv[0] = -tv[0];
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tv[1] = -tv[1];
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/*
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* Merge with the transformations we have so far:
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*
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* v' = vA1+b1 the transformation we have so far
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* v'' = v'A2+b2 the transformation we apply
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*
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* v'' = (vA1+b1)A2+b2
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* v'' = vA1A2+b1A2+b2
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*/
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/*
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* So far, the theory. To make it really work, we have to calculate
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* v'' = vA1A2+b1+b2
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* duh ?!?
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*/
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matrix_mult(m->a, tm, tm2); /* A1A2 */
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matrix_copy(tm2, m->a);
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// matrix_multv(m->b, tm, m->b); /* b1A2 */
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m->b[0] += tv[0]; /* b2 */
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m->b[1] += tv[1];
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/*
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* Our input is a screen coordinate, its origin is in a corner so we
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* first have to make it center-based:
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*
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* v' = (v-s/2)A+b
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* v' = vA+(b-s/2*A)
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*/
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tv[0] = sx(s)/2;
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tv[1] = sy(s)/2;
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matrix_multv(tv, m->a, tv);
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m->b[0] -= tv[0];
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m->b[1] -= tv[1];
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}
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static void draw_map(GtkWidget *widget, struct solid *s)
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{
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guchar *rgbbuf, *p;
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int x, y;
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struct matrix ma = {
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.a = { { 1, 0 }, { 0, 1 } },
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.b = { 0, 0 },
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};
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struct matrix mb = {
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.a = { { 1, 0 }, { 0, 1 } }, /* @@@ why not a[1][1] = -1 ? */
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.b = { 0, 0 },
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};
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rgbbuf = p = calloc(sx(s)*sy(s), 3);
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if (!rgbbuf) {
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perror("calloc");
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exit(1);
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}
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merge_matrix(&ma, s, s->a);
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merge_matrix(&mb, s, s->b);
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for (y = sy(s)-1; y >= 0; y--)
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for (x = 0; x != sx(s) ; x++) {
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point(s, x, y, p);
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point(s, x, y, p, &ma, &mb);
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p += 3;
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}
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gdk_draw_rgb_image(widget->window,
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@ -221,8 +311,8 @@ static void rotate(struct matrix *m, double r)
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static void do_shift(struct matrix *m, int dx, int dy)
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{
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m->b[0] -= dx;
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m->b[1] += dy;
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m->b[0] += dx;
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m->b[1] -= dy;
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}
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