#define IMAGER_NO_CONTEXT #include "imager.h" #include "draw.h" #include "log.h" #include "imrender.h" #include "imageri.h" #define IMTRUNC(x) ((int)((x)*16)) #define coarse(x) ((x)/16) #define fine(x) ((x)%16) /*#define DEBUG_POLY*/ #ifdef DEBUG_POLY #define POLY_DEB(x) x #else #define POLY_DEB(x) #endif typedef i_img_dim pcord; typedef struct { size_t n; pcord x,y; } p_point; typedef struct { size_t n; pcord x1,y1; pcord x2,y2; pcord miny,maxy; pcord minx,maxx; int updown; /* -1 means down, 0 vertical, 1 up */ int dir; /* 1 for down, -1 for up */ } p_line; typedef struct { size_t n; double x; } p_slice; typedef struct { int *line; /* temporary buffer for scanline */ i_img_dim linelen; /* length of scanline */ } ss_scanline; static int p_compy(const p_point *p1, const p_point *p2) { if (p1->y > p2->y) return 1; if (p1->y < p2->y) return -1; return 0; } static int p_compx(const p_slice *p1, const p_slice *p2) { if (p1->x > p2->x) return 1; if (p1->x < p2->x) return -1; return 0; } /* Change this to int? and round right goddamn it! */ static double p_eval_aty(p_line *l, pcord y) { int t; t=l->y2-l->y1; if (t) return ( (y-l->y1)*l->x2 + (l->y2-y)*l->x1 )/t; return (l->x1+l->x2)/2.0; } static double p_eval_atx(p_line *l, pcord x) { int t; t = l->x2-l->x1; if (t) return ( (x-l->x1)*l->y2 + (l->x2-x)*l->y1 )/t; return (l->y1+l->y2)/2.0; } static p_line * line_set_new(const i_polygon_t *polys, size_t count, size_t *line_count) { size_t i, j, n; p_line *lset, *line; size_t lines = 0; for (i = 0; i < count; ++i) lines += polys[i].count; line = lset = mymalloc(sizeof(p_line) * lines); n = 0; for (i = 0; i < count; ++i) { const i_polygon_t *p = polys + i; for(j = 0; j < p->count; j++) { line->x1 = IMTRUNC(p->x[j]); line->y1 = IMTRUNC(p->y[j]); line->x2 = IMTRUNC(p->x[(j + 1) % p->count]); line->y2 = IMTRUNC(p->y[(j + 1) % p->count]); /* don't include purely horizontal lines, we don't usefully intersect with them. */ if (line->y1 == line->y2) continue; line->miny = i_min(line->y1, line->y2); line->maxy = i_max(line->y1, line->y2); line->minx = i_min(line->x1, line->x2); line->maxx = i_max(line->x1, line->x2); line->n = n++; ++line; } } *line_count = n; return lset; } static p_point * point_set_new(const i_polygon_t *polys, size_t count, size_t *point_count) { size_t i, j, n; p_point *pset, *pt; size_t points = 0; for (i = 0; i < count; ++i) points += polys[i].count; *point_count = points; pt = pset = mymalloc(sizeof(p_point) * points); n = 0; for (i = 0; i < count; ++i) { const i_polygon_t *p = polys + i; for(j = 0; j < p->count; j++) { pt->n = n++; pt->x = IMTRUNC(p->x[j]); pt->y = IMTRUNC(p->y[j]); ++pt; } } return pset; } static void ss_scanline_reset(ss_scanline *ss) { memset(ss->line, 0, sizeof(int) * ss->linelen); } static void ss_scanline_init(ss_scanline *ss, i_img_dim linelen, int linepairs) { ss->line = mymalloc( sizeof(int) * linelen ); ss->linelen = linelen; ss_scanline_reset(ss); } static void ss_scanline_exorcise(ss_scanline *ss) { myfree(ss->line); } /* returns the number of matches */ static int lines_in_interval(p_line *lset, int l, p_slice *tllist, pcord minc, pcord maxc) { int k; int count = 0; for(k=0; k minc && lset[k].miny < maxc) { if (lset[k].miny == lset[k].maxy) { POLY_DEB( printf(" HORIZONTAL - skipped\n") ); } else { tllist[count].x=p_eval_aty(&lset[k],(minc+maxc)/2.0 ); tllist[count].n=k; count++; } } } return count; } /* marks the up variable for all lines in a slice */ static void mark_updown_slices(pIMCTX, p_line *lset, p_slice *tllist, int count) { p_line *l, *r; int k; for(k=0; ky1 == l->y2) { im_log((aIMCTX,1, "mark_updown_slices: horizontal line being marked: internal error!\n")); exit(3); } l->updown = (l->x1 == l->x2) ? 0 : (l->x1 > l->x2) ? (l->y1 > l->y2) ? -1 : 1 : (l->y1 > l->y2) ? 1 : -1; l->dir = l->y1 < l->y2 ? 1 : -1; POLY_DEB( printf("marking left line %d as %s(%d)\n", l->n, l->updown ? l->updown == 1 ? "up" : "down" : "vert", l->updown, l->updown) ); if (k+1 >= count) { im_log((aIMCTX, 1, "Invalid polygon spec, odd number of line crossings.\n")); return; } r = lset + tllist[k+1].n; if (r->y1 == r->y2) { im_log((aIMCTX, 1, "mark_updown_slices: horizontal line being marked: internal error!\n")); exit(3); } r->updown = (r->x1 == r->x2) ? 0 : (r->x1 > r->x2) ? (r->y1 > r->y2) ? -1 : 1 : (r->y1 > r->y2) ? 1 : -1; r->dir = r->y1 < r->y2 ? 1 : -1; POLY_DEB( printf("marking right line %d as %s(%d)\n", r->n, r->updown ? r->updown == 1 ? "up" : "down" : "vert", r->updown, r->updown) ); } } static unsigned char saturate(int in) { if (in>255) { return 255; } else if (in>0) return in; return 0; } typedef void (*scanline_flusher)(i_img *im, ss_scanline *ss, int y, void *ctx); /* This function must be modified later to do proper blending */ static void scanline_flush(i_img *im, ss_scanline *ss, int y, void *ctx) { int x, ch, tv; i_color t; i_color *val = (i_color *)ctx; POLY_DEB( printf("Flushing line %d\n", y) ); for(x=0; xxsize; x++) { tv = saturate(ss->line[x]); i_gpix(im, x, y, &t); for(ch=0; chchannels; ch++) t.channel[ch] = tv/255.0 * val->channel[ch] + (1.0-tv/255.0) * t.channel[ch]; i_ppix(im, x, y, &t); } } static int trap_square(pcord xlen, pcord ylen, double xl, double yl) { POLY_DEB( printf("trap_square: %d %d %.2f %.2f\n", xlen, ylen, xl, yl) ); return xlen*ylen-(xl*yl)/2.0; } /* pixel_coverage calculates the 'left side' pixel coverage of a pixel that is within the min/max ranges. The shape always corresponds to a square with some sort of a triangle cut from it (which can also yield a triangle). */ static int pixel_coverage(p_line *line, pcord minx, pcord maxx, pcord miny, pcord maxy) { double lycross, rycross; int l, r; POLY_DEB ( printf(" pixel_coverage(..., minx %g, maxx%g, miny %g, maxy %g)\n", minx/16.0, maxx/16.0, miny/16.0, maxy/16.0) ); if (!line->updown) { l = r = 0; } else { lycross = p_eval_atx(line, minx); rycross = p_eval_atx(line, maxx); l = lycross <= maxy && lycross >= miny; /* true if it enters through left side */ r = rycross <= maxy && rycross >= miny; /* true if it enters through left side */ } POLY_DEB( printf(" %4s(%+d): ", line->updown ? line->updown == 1 ? "up" : "down" : "vert", line->updown); printf(" (%2d,%2d) [%3d-%3d, %3d-%3d] lycross=%.2f rycross=%.2f", coarse(minx), coarse(miny), minx, maxx, miny, maxy, lycross, rycross); printf(" l=%d r=%d\n", l, r) ); if (l && r) return line->updown == 1 ? (double)(maxx-minx) * (2.0*maxy-lycross-rycross)/2.0 /* up case */ : (double)(maxx-minx) * (lycross+rycross-2*miny)/2.0; /* down case */ if (!l && !r) return (maxy-miny)*(maxx*2-p_eval_aty(line, miny)-p_eval_aty(line, maxy))/2.0; if (l && !r) return line->updown == 1 ? trap_square(maxx-minx, maxy-miny, p_eval_aty(line, miny)-minx, p_eval_atx(line, minx)-miny) : trap_square(maxx-minx, maxy-miny, p_eval_aty(line, maxy)-minx, maxy-p_eval_atx(line, minx)); if (!l && r) { int r = line->updown == 1 ? (maxx-p_eval_aty(line, maxy))*(maxy-p_eval_atx(line, maxx))/2.0 : (maxx-p_eval_aty(line, miny))*(p_eval_atx(line, maxx)-miny)/2.0; return r; } /* NOTREACHED */ return 0; /* silence compiler warning */ } /* handle the scanline slice in three steps 1. Where only the left edge is inside a pixel 2a. Where both left and right edge are inside a pixel 2b. Where neither left or right edge are inside a pixel 3. Where only the right edge is inside a pixel */ static void render_slice_scanline(ss_scanline *ss, int y, p_line *l, p_line *r, pcord miny, pcord maxy) { pcord lminx, lmaxx; /* left line min/max within y bounds in fine coords */ pcord rminx, rmaxx; /* right line min/max within y bounds in fine coords */ i_img_dim cpix; /* x-coordinate of current pixel */ i_img_dim startpix; /* temporary variable for "start of this interval" */ i_img_dim stoppix; /* temporary variable for "end of this interval" */ /* Find the y bounds of scanline_slice */ POLY_DEB ( printf("render_slice_scanline(..., y=%d)\n"); printf(" left n=%d p1(%.2g, %.2g) p2(%.2g,%.2g) min(%.2g, %.2g) max(%.2g,%.2g) updown(%d)\n", l->n, l->x1/16.0, l->y1/16.0, l->x2/16.0, l->y2/16.0, l->minx/16.0, l->miny/16.0, l->maxx/16.0, l->maxy/16.0, l->updown); printf(" right n=%d p1(%.2g, %.2g) p2(%.2g,%.2g) min(%.2g, %.2g) max(%.2g,%.2g) updown(%d)\n", r->n, r->x1/16.0, r->y1/16.0, r->x2/16.0, r->y2/16.0, r->minx/16.0, r->miny/16.0, r->maxx/16.0, r->maxy/16.0, r->updown); ); lminx = i_min( p_eval_aty(l, maxy), p_eval_aty(l, miny) ); lmaxx = i_max( p_eval_aty(l, maxy), p_eval_aty(l, miny) ); rminx = i_min( p_eval_aty(r, maxy), p_eval_aty(r, miny) ); rmaxx = i_max( p_eval_aty(r, maxy), p_eval_aty(r, miny) ); startpix = i_max( coarse(lminx), 0 ); stoppix = i_min( coarse(rmaxx-1), ss->linelen-1 ); POLY_DEB( printf(" miny=%g maxy=%g\n", miny/16.0, maxy/16.0) ); for(cpix=startpix; cpix<=stoppix; cpix++) { int lt = coarse(lmaxx-1) >= cpix; int rt = coarse(rminx) <= cpix; int A, B, C; POLY_DEB( printf(" (%d,%d) lt=%d rt=%d\n", cpix, y, lt, rt) ); A = lt ? pixel_coverage(l, cpix*16, cpix*16+16, miny, maxy) : 0; B = lt ? 0 : 16*(maxy-miny); C = rt ? pixel_coverage(r, cpix*16, cpix*16+16, miny, maxy) : 0; POLY_DEB( printf(" A=%d B=%d C=%d\n", A, B, C) ); ss->line[cpix] += A+B-C; } POLY_DEB( printf("end render_slice_scanline()\n") ); } /* Antialiasing polygon algorithm specs: 1. only nice polygons - no crossovers 2. 1/16 pixel resolution 3. full antialiasing ( complete spectrum of blends ) 4. uses hardly any memory 5. no subsampling phase Algorithm outline: 1. Split into vertical intervals. 2. handle each interval For each interval we must: 1. find which lines are in it 2. order the lines from in increasing x order. since we are assuming no crossovers it is sufficent to check a single point on each line. */ /* Definitions: 1. Interval: A vertical segment in which no lines cross nor end. 2. Scanline: A physical line, contains 16 subpixels in the horizontal direction 3. Slice: A start stop line pair. */ static int i_poly_poly_aa_low(i_img *im, int count, const i_polygon_t *polys, i_poly_fill_mode_t mode, void *ctx, scanline_flusher flusher) { int i ,k; /* Index variables */ i_img_dim clc; /* Lines inside current interval */ /* initialize to avoid compiler warnings */ pcord tempy = 0; i_img_dim cscl = 0; /* Current scanline */ ss_scanline templine; /* scanline accumulator */ p_point *pset; /* List of points in polygon */ p_line *lset; /* List of lines in polygon */ p_slice *tllist; /* List of slices */ size_t pcount, lcount; dIMCTX; im_log((aIMCTX, 1, "i_poly_poly_aa_low(im %p, count %d, polys %p, ctx %p, flusher %p)\n", im, count, polys, ctx, flusher)); i_clear_error(); if (count < 1) { i_push_error(0, "no polygons to draw"); return 0; } for (k = 0; k < count; ++k) { if (polys[k].count < 3) { i_push_error(0, "polygons must have at least 3 points"); return 0; } } for (k = 0; k < count; ++k) { const i_polygon_t *p = polys + k; im_log((aIMCTX, 2, "poly %d\n", k)); for(i = 0; i < p->count; i++) { im_log((aIMCTX, 2, " (%.2f, %.2f)\n", p->x[i], p->y[i])); } } POLY_DEB( fflush(stdout); setbuf(stdout, NULL); ); pset = point_set_new(polys, count, &pcount); lset = line_set_new(polys, count, &lcount); ss_scanline_init(&templine, im->xsize, lcount); tllist = mymalloc(sizeof(p_slice) * lcount); qsort(pset, pcount, sizeof(p_point), (int(*)(const void *,const void *))p_compy); POLY_DEB( for(i=0;i (%d , %d) yspan ( %d , %d )\n", i, lset[i].n, lset[i].x1, lset[i].y1, lset[i].x2, lset[i].y2, lset[i].miny, lset[i].maxy); } printf("MAIN LOOP\n\n"); ); /* loop on intervals */ for(i=0; iysize); pcord miny, maxy; /* y bounds in fine coordinates */ POLY_DEB( pcord cc = (pset[i].y + pset[i+1].y)/2 ); POLY_DEB( printf("current slice is %d: %d to %d ( cpoint %d ) scanlines %d to %d\n", i, pset[i].y, pset[i+1].y, cc, startscan, stopscan) ); if (pset[i].y == pset[i+1].y) { POLY_DEB( printf("current slice thickness = 0 => skipping\n") ); continue; } clc = lines_in_interval(lset, lcount, tllist, pset[i].y, pset[i+1].y); qsort(tllist, clc, sizeof(p_slice), (int(*)(const void *,const void *))p_compx); mark_updown_slices(aIMCTX, lset, tllist, clc); POLY_DEB ( printf("Interval contains %d lines\n", clc); for(k=0; k(%2d, %2d) (%2d/%2d, %2d/%2d) -> (%2d/%2d, %2d/%2d) alignment=%s\n", k, lno, ln->x1, ln->y1, ln->x2, ln->y2, coarse(ln->x1), fine(ln->x1), coarse(ln->y1), fine(ln->y1), coarse(ln->x2), fine(ln->x2), coarse(ln->y2), fine(ln->y2), ln->updown == 0 ? "vert" : ln->updown == 1 ? "up" : "down"); } ); maxy = im->ysize * 16; miny = 0; for (k = 0; k < clc; ++k) { p_line const * line = lset + tllist[k].n; if (line->miny > miny) miny = line->miny; if (line->maxy < maxy) maxy = line->maxy; POLY_DEB( printf(" line miny %g maxy %g\n", line->miny/16.0, line->maxy/16.0) ); } POLY_DEB( printf("miny %g maxy %g\n", miny/16.0, maxy/16.0) ); for(cscl=startscan; cscldir; while (k < clc && acc) { current = lset + tllist[k++].n; acc += current->dir; } if (acc == 0) { render_slice_scanline(&templine, cscl, left, current, scan_miny, scan_maxy); } } } if (16*coarse(tempy) == tempy) { POLY_DEB( printf("flushing scan line %d\n", cscl) ); flusher(im, &templine, cscl, ctx); ss_scanline_reset(&templine); } /* else { scanline_flush(im, &templine, cscl, val); ss_scanline_reset(&templine); return 0; } */ } } /* Intervals */ if (16*coarse(tempy) != tempy) flusher(im, &templine, cscl-1, ctx); ss_scanline_exorcise(&templine); myfree(pset); myfree(lset); myfree(tllist); return 1; } /* =item i_poly_poly_aa(im, count, polys, mode, color) =synopsis i_poly_poly_aa(im, 1, &poly, mode, color); =category Drawing Fill the C polygons defined by C the color specified by C. At least one polygon must be supplied. All polygons must have at least 3 points. =cut */ int i_poly_poly_aa(i_img *im, int count, const i_polygon_t *polys, i_poly_fill_mode_t mode, const i_color *val) { i_color c = *val; return i_poly_poly_aa_low(im, count, polys, mode, &c, scanline_flush); } /* =item i_poly_aa_m(im, count, x, y, mode, color) =synopsis i_poly_aa_m(im, count, x, y, mode, color); =category Drawing Fill a polygon defined by the points specified by the x and y arrays with the color specified by C. =cut */ int i_poly_aa_m(i_img *im, int l, const double *x, const double *y, i_poly_fill_mode_t mode, const i_color *val) { i_polygon_t poly; poly.count = l; poly.x = x; poly.y = y; return i_poly_poly_aa(im, 1, &poly, mode, val); } int i_poly_aa(i_img *im, int l, const double *x, const double *y, const i_color *val) { i_polygon_t poly; poly.count = l; poly.x = x; poly.y = y; return i_poly_poly_aa(im, 1, &poly, i_pfm_evenodd, val); } struct poly_render_state { i_render render; i_fill_t *fill; unsigned char *cover; }; static void scanline_flush_render(i_img *im, ss_scanline *ss, int y, void *ctx) { i_img_dim x; i_img_dim left, right; struct poly_render_state *state = (struct poly_render_state *)ctx; left = 0; while (left < im->xsize && ss->line[left] <= 0) ++left; if (left < im->xsize) { right = im->xsize; /* since going from the left found something, moving from the right should */ while (/* right > left && */ ss->line[right-1] <= 0) --right; /* convert to the format the render interface wants */ for (x = left; x < right; ++x) { state->cover[x-left] = saturate(ss->line[x]); } i_render_fill(&state->render, left, y, right-left, state->cover, state->fill); } } /* =item i_poly_poly_aa_cfill(im, count, polys, mode, fill) =synopsis i_poly_poly_aa_cfill(im, 1, &poly, mode, fill); =category Drawing Fill the C polygons defined by C the fill specified by C. At least one polygon must be supplied. All polygons must have at least 3 points. =cut */ int i_poly_poly_aa_cfill(i_img *im, int count, const i_polygon_t *polys, i_poly_fill_mode_t mode, i_fill_t *fill) { struct poly_render_state ctx; int result; i_render_init(&ctx.render, im, im->xsize); ctx.fill = fill; ctx.cover = mymalloc(im->xsize); result = i_poly_poly_aa_low(im, count, polys, mode, &ctx, scanline_flush_render); myfree(ctx.cover); i_render_done(&ctx.render); return result; } /* =item i_poly_aa_cfill_m(im, count, x, y, mode, fill) =synopsis i_poly_aa_cfill(im, count, x, y, mode, fill); =category Drawing Fill a polygon defined by the points specified by the x and y arrays with the fill specified by C. =cut */ int i_poly_aa_cfill_m(i_img *im, int l, const double *x, const double *y, i_poly_fill_mode_t mode, i_fill_t *fill) { i_polygon_t poly; poly.count = l; poly.x = x; poly.y = y; return i_poly_poly_aa_cfill(im, 1, &poly, mode, fill); } int i_poly_aa_cfill(i_img *im, int l, const double *x, const double *y, i_fill_t *fill) { i_polygon_t poly; poly.count = l; poly.x = x; poly.y = y; return i_poly_poly_aa_cfill(im, 1, &poly, i_pfm_evenodd, fill); }