mirror of
https://github.com/0intro/conterm
synced 2024-11-22 05:41:28 +03:00
1005 lines
23 KiB
C
1005 lines
23 KiB
C
#include <u.h>
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#include <libc.h>
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#include <bio.h>
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#include <draw.h>
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#include <memdraw.h>
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#define DBG if(0)
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#define RGB2K(r,g,b) ((299*((ulong)(r))+587*((ulong)(g))+114*((ulong)(b)))/1000)
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/*
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* This program tests the 'memimagedraw' primitive stochastically.
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* It tests the combination aspects of it thoroughly, but since the
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* three images it uses are disjoint, it makes no check of the
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* correct behavior when images overlap. That is, however, much
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* easier to get right and to test.
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*/
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void drawonepixel(Memimage*, Point, Memimage*, Point, Memimage*, Point);
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void verifyone(void);
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void verifyline(void);
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void verifyrect(void);
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void verifyrectrepl(int, int);
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void putpixel(Memimage *img, Point pt, ulong nv);
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ulong rgbatopix(uchar, uchar, uchar, uchar);
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char *dchan, *schan, *mchan;
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int dbpp, sbpp, mbpp;
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int drawdebug=0;
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int seed;
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int niters = 100;
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int dbpp; /* bits per pixel in destination */
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int sbpp; /* bits per pixel in src */
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int mbpp; /* bits per pixel in mask */
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int dpm; /* pixel mask at high part of byte, in destination */
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int nbytes; /* in destination */
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int Xrange = 64;
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int Yrange = 8;
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Memimage *dst;
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Memimage *src;
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Memimage *mask;
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Memimage *stmp;
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Memimage *mtmp;
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Memimage *ones;
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uchar *dstbits;
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uchar *srcbits;
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uchar *maskbits;
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ulong *savedstbits;
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void
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rdb(void)
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{
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}
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int
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iprint(char *fmt, ...)
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{
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int n;
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va_list va;
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char buf[1024];
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va_start(va, fmt);
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n = doprint(buf, buf+sizeof buf, fmt, va) - buf;
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va_end(va);
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write(1,buf,n);
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return 1;
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}
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void
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main(int argc, char *argv[])
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{
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memimageinit();
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seed = time(0);
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ARGBEGIN{
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case 'x':
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Xrange = atoi(ARGF());
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break;
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case 'y':
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Yrange = atoi(ARGF());
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break;
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case 'n':
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niters = atoi(ARGF());
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break;
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case 's':
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seed = atoi(ARGF());
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break;
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}ARGEND
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dchan = "r8g8b8";
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schan = "r8g8b8";
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mchan = "r8g8b8";
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switch(argc){
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case 3: mchan = argv[2];
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case 2: schan = argv[1];
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case 1: dchan = argv[0];
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case 0: break;
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default: goto Usage;
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Usage:
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fprint(2, "usage: dtest [dchan [schan [mchan]]]\n");
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exits("usage");
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}
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fmtinstall('b', numbconv); /* binary! */
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fprint(2, "%s -x %d -y %d -s 0x%x %s %s %s\n", argv0, Xrange, Yrange, seed, dchan, schan, mchan);
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srand(seed);
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dst = allocmemimage(Rect(0, 0, Xrange, Yrange), strtochan(dchan));
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src = allocmemimage(Rect(0, 0, Xrange, Yrange), strtochan(schan));
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mask = allocmemimage(Rect(0, 0, Xrange, Yrange), strtochan(mchan));
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stmp = allocmemimage(Rect(0, 0, Xrange, Yrange), strtochan(schan));
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mtmp = allocmemimage(Rect(0, 0, Xrange, Yrange), strtochan(mchan));
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ones = allocmemimage(Rect(0, 0, Xrange, Yrange), strtochan(mchan));
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// print("chan %lux %lux %lux %lux %lux %lux\n", dst->chan, src->chan, mask->chan, stmp->chan, mtmp->chan, ones->chan);
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if(dst==0 || src==0 || mask==0 || mtmp==0 || ones==0) {
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Alloc:
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fprint(2, "dtest: allocation failed: %r\n");
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exits("alloc");
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}
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nbytes = (4*Xrange+4)*Yrange;
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srcbits = malloc(nbytes);
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dstbits = malloc(nbytes);
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maskbits = malloc(nbytes);
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savedstbits = malloc(nbytes);
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if(dstbits==0 || srcbits==0 || maskbits==0 || savedstbits==0)
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goto Alloc;
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dbpp = dst->depth;
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sbpp = src->depth;
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mbpp = mask->depth;
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dpm = 0xFF ^ (0xFF>>dbpp);
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memset(ones->data->bdata, 0xFF, ones->width*sizeof(ulong)*Yrange);
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fprint(2, "dtest: verify single pixel operation\n");
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verifyone();
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fprint(2, "dtest: verify full line non-replicated\n");
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verifyline();
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fprint(2, "dtest: verify full rectangle non-replicated\n");
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verifyrect();
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fprint(2, "dtest: verify full rectangle source replicated\n");
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verifyrectrepl(1, 0);
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fprint(2, "dtest: verify full rectangle mask replicated\n");
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verifyrectrepl(0, 1);
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fprint(2, "dtest: verify full rectangle source and mask replicated\n");
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verifyrectrepl(1, 1);
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exits(0);
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}
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/*
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* Dump out an ASCII representation of an image. The label specifies
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* a list of characters to put at various points in the picture.
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*/
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static void
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Bprintr5g6b5(Biobuf *bio, char*, ulong v)
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{
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int r,g,b;
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r = (v>>11)&31;
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g = (v>>5)&63;
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b = v&31;
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Bprint(bio, "%.2x%.2x%.2x", r,g,b);
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}
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static void
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Bprintr5g5b5a1(Biobuf *bio, char*, ulong v)
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{
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int r,g,b,a;
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r = (v>>11)&31;
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g = (v>>6)&31;
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b = (v>>1)&31;
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a = v&1;
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Bprint(bio, "%.2x%.2x%.2x%.2x", r,g,b,a);
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}
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void
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dumpimage(char *name, Memimage *img, void *vdata, Point labelpt)
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{
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Biobuf b;
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uchar *data;
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uchar *p;
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char *arg;
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void (*fmt)(Biobuf*, char*, ulong);
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int npr, x, y, nb, bpp;
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ulong v, mask;
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Rectangle r;
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fmt = nil;
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arg = nil;
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switch(img->depth){
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case 1:
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case 2:
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case 4:
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fmt = (void(*)(Biobuf*,char*,ulong))Bprint;
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arg = "%.1ux";
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break;
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case 8:
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fmt = (void(*)(Biobuf*,char*,ulong))Bprint;
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arg = "%.2ux";
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break;
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case 16:
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arg = nil;
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if(img->chan == RGB16)
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fmt = Bprintr5g6b5;
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else{
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fmt = (void(*)(Biobuf*,char*,ulong))Bprint;
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arg = "%.4ux";
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}
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break;
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case 24:
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fmt = (void(*)(Biobuf*,char*,ulong))Bprint;
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arg = "%.6lux";
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break;
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case 32:
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fmt = (void(*)(Biobuf*,char*,ulong))Bprint;
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arg = "%.8lux";
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break;
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}
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if(fmt == nil){
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fprint(2, "bad format\n");
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abort();
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}
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r = img->r;
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Binit(&b, 2, OWRITE);
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data = vdata;
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bpp = img->depth;
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Bprint(&b, "%s\t%d\tr %R clipr %R repl %d data %p *%P\n", name, r.min.x, r, img->clipr, (img->flags&Frepl) ? 1 : 0, vdata, labelpt);
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mask = (1ULL<<bpp)-1;
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// for(y=r.min.y; y<r.max.y; y++){
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for(y=0; y<Yrange; y++){
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nb = 0;
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v = 0;
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p = data+(byteaddr(img, Pt(0,y))-(uchar*)img->data->bdata);
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Bprint(&b, "%-4d\t", y);
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// for(x=r.min.x; x<r.max.x; x++){
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for(x=0; x<Xrange; x++){
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if(x==0)
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Bprint(&b, "\t");
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if(x != 0 && (x%8)==0)
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Bprint(&b, " ");
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npr = 0;
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if(x==labelpt.x && y==labelpt.y){
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Bprint(&b, "*");
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npr++;
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}
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if(npr == 0)
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Bprint(&b, " ");
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while(nb < bpp){
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v &= (1<<nb)-1;
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v |= (ulong)(*p++) << nb;
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nb += 8;
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}
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nb -= bpp;
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// print("bpp %d v %.8lux mask %.8lux nb %d\n", bpp, v, mask, nb);
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fmt(&b, arg, (v>>nb)&mask);
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}
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Bprint(&b, "\n");
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}
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Bterm(&b);
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}
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/*
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* Verify that the destination pixel has the specified value.
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* The value is in the high bits of v, suitably masked, but must
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* be extracted from the destination Memimage.
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*/
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void
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checkone(Point p, Point sp, Point mp)
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{
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int delta;
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uchar *dp, *sdp;
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delta = (uchar*)byteaddr(dst, p)-(uchar*)dst->data->bdata;
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dp = (uchar*)dst->data->bdata+delta;
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sdp = (uchar*)savedstbits+delta;
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if(memcmp(dp, sdp, (dst->depth+7)/8) != 0) {
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fprint(2, "dtest: one bad pixel drawing at dst %P from source %P mask %P\n", p, sp, mp);
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fprint(2, " %.2ux %.2ux %.2ux %.2ux should be %.2ux %.2ux %.2ux %.2ux\n",
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dp[0], dp[1], dp[2], dp[3], sdp[0], sdp[1], sdp[2], sdp[3]);
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fprint(2, "addresses dst %p src %p mask %p\n", dp, byteaddr(src, sp), byteaddr(mask, mp));
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dumpimage("src", src, src->data->bdata, sp);
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dumpimage("mask", mask, mask->data->bdata, mp);
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dumpimage("origdst", dst, dstbits, p);
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dumpimage("dst", dst, dst->data->bdata, p);
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dumpimage("gooddst", dst, savedstbits, p);
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abort();
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}
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}
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/*
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* Verify that the destination line has the same value as the saved line.
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*/
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#define RECTPTS(r) (r).min.x, (r).min.y, (r).max.x, (r).max.y
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void
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checkline(Rectangle r, Point sp, Point mp, int y, Memimage *stmp, Memimage *mtmp)
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{
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ulong *dp;
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int nb;
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ulong *saved;
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dp = wordaddr(dst, Pt(0, y));
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saved = savedstbits + y*dst->width;
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if(dst->depth < 8)
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nb = Xrange/(8/dst->depth);
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else
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nb = Xrange*(dst->depth/8);
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if(memcmp(dp, saved, nb) != 0){
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fprint(2, "dtest: bad line at y=%d; saved %p dp %p\n", y, saved, dp);
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fprint(2, "draw dst %R src %P mask %P\n", r, sp, mp);
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dumpimage("src", src, src->data->bdata, sp);
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if(stmp) dumpimage("stmp", stmp, stmp->data->bdata, sp);
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dumpimage("mask", mask, mask->data->bdata, mp);
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if(mtmp) dumpimage("mtmp", mtmp, mtmp->data->bdata, mp);
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dumpimage("origdst", dst, dstbits, r.min);
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dumpimage("dst", dst, dst->data->bdata, r.min);
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dumpimage("gooddst", dst, savedstbits, r.min);
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abort();
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}
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}
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/*
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* Fill the bits of an image with random data.
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* The Memimage parameter is used only to make sure
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* the data is well formatted: only ucbits is written.
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*/
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void
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fill(Memimage *img, uchar *ucbits)
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{
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int i, x, y;
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ushort *up;
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uchar alpha, r, g, b;
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void *data;
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if((img->flags&Falpha) == 0){
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up = (ushort*)ucbits;
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for(i=0; i<nbytes/2; i++)
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*up++ = lrand() >> 7;
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if(i+i != nbytes)
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*(uchar*)up = lrand() >> 7;
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}else{
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data = img->data->bdata;
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img->data->bdata = ucbits;
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for(x=img->r.min.x; x<img->r.max.x; x++)
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for(y=img->r.min.y; y<img->r.max.y; y++){
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alpha = rand() >> 4;
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r = rand()%(alpha+1);
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g = rand()%(alpha+1);
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b = rand()%(alpha+1);
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putpixel(img, Pt(x,y), rgbatopix(r,g,b,alpha));
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}
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img->data->bdata = data;
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}
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}
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/*
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* Mask is preset; do the rest
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*/
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void
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verifyonemask(void)
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{
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Point dp, sp, mp;
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fill(dst, dstbits);
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fill(src, srcbits);
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memmove(dst->data->bdata, dstbits, dst->width*sizeof(ulong)*Yrange);
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memmove(src->data->bdata, srcbits, src->width*sizeof(ulong)*Yrange);
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memmove(mask->data->bdata, maskbits, mask->width*sizeof(ulong)*Yrange);
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dp.x = nrand(Xrange);
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dp.y = nrand(Yrange);
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sp.x = nrand(Xrange);
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sp.y = nrand(Yrange);
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mp.x = nrand(Xrange);
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mp.y = nrand(Yrange);
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drawonepixel(dst, dp, src, sp, mask, mp);
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memmove(mask->data->bdata, maskbits, mask->width*sizeof(ulong)*Yrange);
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memmove(savedstbits, dst->data->bdata, dst->width*sizeof(ulong)*Yrange);
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memmove(dst->data->bdata, dstbits, dst->width*sizeof(ulong)*Yrange);
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memimagedraw(dst, Rect(dp.x, dp.y, dp.x+1, dp.y+1), src, sp, mask, mp, SoverD);
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memmove(mask->data->bdata, maskbits, mask->width*sizeof(ulong)*Yrange);
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checkone(dp, sp, mp);
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}
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void
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verifyone(void)
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{
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int i;
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/* mask all zeros */
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memset(maskbits, 0, nbytes);
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for(i=0; i<niters; i++)
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verifyonemask();
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/* mask all ones */
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memset(maskbits, 0xFF, nbytes);
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for(i=0; i<niters; i++)
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verifyonemask();
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/* random mask */
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for(i=0; i<niters; i++){
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fill(mask, maskbits);
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verifyonemask();
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}
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}
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/*
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* Mask is preset; do the rest
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*/
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void
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verifylinemask(void)
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{
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Point sp, mp, tp, up;
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Rectangle dr;
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int x;
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fill(dst, dstbits);
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fill(src, srcbits);
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memmove(dst->data->bdata, dstbits, dst->width*sizeof(ulong)*Yrange);
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memmove(src->data->bdata, srcbits, src->width*sizeof(ulong)*Yrange);
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memmove(mask->data->bdata, maskbits, mask->width*sizeof(ulong)*Yrange);
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dr.min.x = nrand(Xrange-1);
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dr.min.y = nrand(Yrange-1);
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dr.max.x = dr.min.x + 1 + nrand(Xrange-1-dr.min.x);
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dr.max.y = dr.min.y + 1;
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sp.x = nrand(Xrange);
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sp.y = nrand(Yrange);
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mp.x = nrand(Xrange);
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mp.y = nrand(Yrange);
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tp = sp;
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up = mp;
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for(x=dr.min.x; x<dr.max.x && tp.x<Xrange && up.x<Xrange; x++,tp.x++,up.x++)
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memimagedraw(dst, Rect(x, dr.min.y, x+1, dr.min.y+1), src, tp, mask, up, SoverD);
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memmove(savedstbits, dst->data->bdata, dst->width*sizeof(ulong)*Yrange);
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memmove(dst->data->bdata, dstbits, dst->width*sizeof(ulong)*Yrange);
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memimagedraw(dst, dr, src, sp, mask, mp, SoverD);
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checkline(dr, drawrepl(src->r, sp), drawrepl(mask->r, mp), dr.min.y, nil, nil);
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}
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void
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verifyline(void)
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{
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int i;
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/* mask all ones */
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memset(maskbits, 0xFF, nbytes);
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for(i=0; i<niters; i++)
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verifylinemask();
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/* mask all zeros */
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memset(maskbits, 0, nbytes);
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for(i=0; i<niters; i++)
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verifylinemask();
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/* random mask */
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for(i=0; i<niters; i++){
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fill(mask, maskbits);
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verifylinemask();
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}
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}
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/*
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* Mask is preset; do the rest
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*/
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void
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verifyrectmask(void)
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{
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Point sp, mp, tp, up;
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Rectangle dr;
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int x, y;
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fill(dst, dstbits);
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fill(src, srcbits);
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memmove(dst->data->bdata, dstbits, dst->width*sizeof(ulong)*Yrange);
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memmove(src->data->bdata, srcbits, src->width*sizeof(ulong)*Yrange);
|
||
memmove(mask->data->bdata, maskbits, mask->width*sizeof(ulong)*Yrange);
|
||
|
||
dr.min.x = nrand(Xrange-1);
|
||
dr.min.y = nrand(Yrange-1);
|
||
dr.max.x = dr.min.x + 1 + nrand(Xrange-1-dr.min.x);
|
||
dr.max.y = dr.min.y + 1 + nrand(Yrange-1-dr.min.y);
|
||
|
||
sp.x = nrand(Xrange);
|
||
sp.y = nrand(Yrange);
|
||
|
||
mp.x = nrand(Xrange);
|
||
mp.y = nrand(Yrange);
|
||
|
||
tp = sp;
|
||
up = mp;
|
||
for(y=dr.min.y; y<dr.max.y && tp.y<Yrange && up.y<Yrange; y++,tp.y++,up.y++){
|
||
for(x=dr.min.x; x<dr.max.x && tp.x<Xrange && up.x<Xrange; x++,tp.x++,up.x++)
|
||
memimagedraw(dst, Rect(x, y, x+1, y+1), src, tp, mask, up, SoverD);
|
||
tp.x = sp.x;
|
||
up.x = mp.x;
|
||
}
|
||
memmove(savedstbits, dst->data->bdata, dst->width*sizeof(ulong)*Yrange);
|
||
|
||
memmove(dst->data->bdata, dstbits, dst->width*sizeof(ulong)*Yrange);
|
||
|
||
memimagedraw(dst, dr, src, sp, mask, mp, SoverD);
|
||
for(y=0; y<Yrange; y++)
|
||
checkline(dr, drawrepl(src->r, sp), drawrepl(mask->r, mp), y, nil, nil);
|
||
}
|
||
|
||
void
|
||
verifyrect(void)
|
||
{
|
||
int i;
|
||
|
||
/* mask all zeros */
|
||
memset(maskbits, 0, nbytes);
|
||
for(i=0; i<niters; i++)
|
||
verifyrectmask();
|
||
|
||
/* mask all ones */
|
||
memset(maskbits, 0xFF, nbytes);
|
||
for(i=0; i<niters; i++)
|
||
verifyrectmask();
|
||
|
||
/* random mask */
|
||
for(i=0; i<niters; i++){
|
||
fill(mask, maskbits);
|
||
verifyrectmask();
|
||
}
|
||
}
|
||
|
||
Rectangle
|
||
randrect(void)
|
||
{
|
||
Rectangle r;
|
||
|
||
r.min.x = nrand(Xrange-1);
|
||
r.min.y = nrand(Yrange-1);
|
||
r.max.x = r.min.x + 1 + nrand(Xrange-1-r.min.x);
|
||
r.max.y = r.min.y + 1 + nrand(Yrange-1-r.min.y);
|
||
return r;
|
||
}
|
||
|
||
/*
|
||
* Return coordinate corresponding to x withing range [minx, maxx)
|
||
*/
|
||
int
|
||
tilexy(int minx, int maxx, int x)
|
||
{
|
||
int sx;
|
||
|
||
sx = (x-minx) % (maxx-minx);
|
||
if(sx < 0)
|
||
sx += maxx-minx;
|
||
return sx+minx;
|
||
}
|
||
|
||
void
|
||
replicate(Memimage *i, Memimage *tmp)
|
||
{
|
||
Rectangle r, r1;
|
||
int x, y, nb;
|
||
|
||
/* choose the replication window (i->r) */
|
||
r.min.x = nrand(Xrange-1);
|
||
r.min.y = nrand(Yrange-1);
|
||
/* make it trivial more often than pure chance allows */
|
||
switch(lrand()&0){
|
||
case 1:
|
||
r.max.x = r.min.x + 2;
|
||
r.max.y = r.min.y + 2;
|
||
if(r.max.x < Xrange && r.max.y < Yrange)
|
||
break;
|
||
/* fall through */
|
||
case 0:
|
||
r.max.x = r.min.x + 1;
|
||
r.max.y = r.min.y + 1;
|
||
break;
|
||
default:
|
||
if(r.min.x+3 >= Xrange)
|
||
r.max.x = Xrange;
|
||
else
|
||
r.max.x = r.min.x+3 + nrand(Xrange-(r.min.x+3));
|
||
|
||
if(r.min.y+3 >= Yrange)
|
||
r.max.y = Yrange;
|
||
else
|
||
r.max.y = r.min.y+3 + nrand(Yrange-(r.min.y+3));
|
||
}
|
||
assert(r.min.x >= 0);
|
||
assert(r.max.x <= Xrange);
|
||
assert(r.min.y >= 0);
|
||
assert(r.max.y <= Yrange);
|
||
/* copy from i to tmp so we have just the replicated bits */
|
||
nb = tmp->width*sizeof(ulong)*Yrange;
|
||
memset(tmp->data->bdata, 0, nb);
|
||
memimagedraw(tmp, r, i, r.min, ones, r.min, SoverD);
|
||
memmove(i->data->bdata, tmp->data->bdata, nb);
|
||
/* i is now a non-replicated instance of the replication */
|
||
/* replicate it by hand through tmp */
|
||
memset(tmp->data->bdata, 0, nb);
|
||
x = -(tilexy(r.min.x, r.max.x, 0)-r.min.x);
|
||
for(; x<Xrange; x+=Dx(r)){
|
||
y = -(tilexy(r.min.y, r.max.y, 0)-r.min.y);
|
||
for(; y<Yrange; y+=Dy(r)){
|
||
/* set r1 to instance of tile by translation */
|
||
r1.min.x = x;
|
||
r1.min.y = y;
|
||
r1.max.x = r1.min.x+Dx(r);
|
||
r1.max.y = r1.min.y+Dy(r);
|
||
memimagedraw(tmp, r1, i, r.min, ones, r.min, SoverD);
|
||
}
|
||
}
|
||
i->flags |= Frepl;
|
||
i->r = r;
|
||
i->clipr = randrect();
|
||
// fprint(2, "replicate [[%d %d] [%d %d]] [[%d %d][%d %d]]\n", r.min.x, r.min.y, r.max.x, r.max.y,
|
||
// i->clipr.min.x, i->clipr.min.y, i->clipr.max.x, i->clipr.max.y);
|
||
tmp->clipr = i->clipr;
|
||
}
|
||
|
||
/*
|
||
* Mask is preset; do the rest
|
||
*/
|
||
void
|
||
verifyrectmaskrepl(int srcrepl, int maskrepl)
|
||
{
|
||
Point sp, mp, tp, up;
|
||
Rectangle dr;
|
||
int x, y;
|
||
Memimage *s, *m;
|
||
|
||
// print("verfrect %d %d\n", srcrepl, maskrepl);
|
||
src->flags &= ~Frepl;
|
||
src->r = Rect(0, 0, Xrange, Yrange);
|
||
src->clipr = src->r;
|
||
stmp->flags &= ~Frepl;
|
||
stmp->r = Rect(0, 0, Xrange, Yrange);
|
||
stmp->clipr = src->r;
|
||
mask->flags &= ~Frepl;
|
||
mask->r = Rect(0, 0, Xrange, Yrange);
|
||
mask->clipr = mask->r;
|
||
mtmp->flags &= ~Frepl;
|
||
mtmp->r = Rect(0, 0, Xrange, Yrange);
|
||
mtmp->clipr = mask->r;
|
||
|
||
fill(dst, dstbits);
|
||
fill(src, srcbits);
|
||
|
||
memmove(dst->data->bdata, dstbits, dst->width*sizeof(ulong)*Yrange);
|
||
memmove(src->data->bdata, srcbits, src->width*sizeof(ulong)*Yrange);
|
||
memmove(mask->data->bdata, maskbits, mask->width*sizeof(ulong)*Yrange);
|
||
|
||
if(srcrepl){
|
||
replicate(src, stmp);
|
||
s = stmp;
|
||
}else
|
||
s = src;
|
||
if(maskrepl){
|
||
replicate(mask, mtmp);
|
||
m = mtmp;
|
||
}else
|
||
m = mask;
|
||
|
||
dr = randrect();
|
||
|
||
sp.x = nrand(Xrange);
|
||
sp.y = nrand(Yrange);
|
||
|
||
mp.x = nrand(Xrange);
|
||
mp.y = nrand(Yrange);
|
||
|
||
DBG print("smalldraws\n");
|
||
for(tp.y=sp.y,up.y=mp.y,y=dr.min.y; y<dr.max.y && tp.y<Yrange && up.y<Yrange; y++,tp.y++,up.y++)
|
||
for(tp.x=sp.x,up.x=mp.x,x=dr.min.x; x<dr.max.x && tp.x<Xrange && up.x<Xrange; x++,tp.x++,up.x++)
|
||
memimagedraw(dst, Rect(x, y, x+1, y+1), s, tp, m, up, SoverD);
|
||
memmove(savedstbits, dst->data->bdata, dst->width*sizeof(ulong)*Yrange);
|
||
|
||
memmove(dst->data->bdata, dstbits, dst->width*sizeof(ulong)*Yrange);
|
||
|
||
DBG print("bigdraw\n");
|
||
memimagedraw(dst, dr, src, sp, mask, mp, SoverD);
|
||
for(y=0; y<Yrange; y++)
|
||
checkline(dr, drawrepl(src->r, sp), drawrepl(mask->r, mp), y, srcrepl?stmp:nil, maskrepl?mtmp:nil);
|
||
}
|
||
|
||
void
|
||
verifyrectrepl(int srcrepl, int maskrepl)
|
||
{
|
||
int i;
|
||
|
||
/* mask all ones */
|
||
memset(maskbits, 0xFF, nbytes);
|
||
for(i=0; i<niters; i++)
|
||
verifyrectmaskrepl(srcrepl, maskrepl);
|
||
|
||
/* mask all zeros */
|
||
memset(maskbits, 0, nbytes);
|
||
for(i=0; i<niters; i++)
|
||
verifyrectmaskrepl(srcrepl, maskrepl);
|
||
|
||
/* random mask */
|
||
for(i=0; i<niters; i++){
|
||
fill(mask, maskbits);
|
||
verifyrectmaskrepl(srcrepl, maskrepl);
|
||
}
|
||
}
|
||
|
||
/*
|
||
* Trivial draw implementation.
|
||
* Color values are passed around as ulongs containing ααRRGGBB
|
||
*/
|
||
|
||
/*
|
||
* Convert v, which is nhave bits wide, into its nwant bits wide equivalent.
|
||
* Replicates to widen the value, truncates to narrow it.
|
||
*/
|
||
ulong
|
||
replbits(ulong v, int nhave, int nwant)
|
||
{
|
||
v &= (1<<nhave)-1;
|
||
for(; nhave<nwant; nhave*=2)
|
||
v |= v<<nhave;
|
||
v >>= (nhave-nwant);
|
||
return v & ((1<<nwant)-1);
|
||
}
|
||
|
||
/*
|
||
* Decode a pixel into the uchar* values.
|
||
*/
|
||
void
|
||
pixtorgba(ulong v, uchar *r, uchar *g, uchar *b, uchar *a)
|
||
{
|
||
*a = v>>24;
|
||
*r = v>>16;
|
||
*g = v>>8;
|
||
*b = v;
|
||
}
|
||
|
||
/*
|
||
* Convert uchar channels into ulong pixel.
|
||
*/
|
||
ulong
|
||
rgbatopix(uchar r, uchar g, uchar b, uchar a)
|
||
{
|
||
return (a<<24)|(r<<16)|(g<<8)|b;
|
||
}
|
||
|
||
/*
|
||
* Retrieve the pixel value at pt in the image.
|
||
*/
|
||
ulong
|
||
getpixel(Memimage *img, Point pt)
|
||
{
|
||
uchar r, g, b, a, *p;
|
||
int nbits, npack, bpp;
|
||
ulong v, c, rbits, bits;
|
||
|
||
r = g = b = 0;
|
||
a = ~0; /* default alpha is full */
|
||
|
||
p = byteaddr(img, pt);
|
||
v = p[0]|(p[1]<<8)|(p[2]<<16)|(p[3]<<24);
|
||
bpp = img->depth;
|
||
if(bpp<8){
|
||
/*
|
||
* Sub-byte greyscale pixels.
|
||
*
|
||
* We want to throw away the top pt.x%npack pixels and then use the next bpp bits
|
||
* in the bottom byte of v. This madness is due to having big endian bits
|
||
* but little endian bytes.
|
||
*/
|
||
npack = 8/bpp;
|
||
v >>= 8 - bpp*(pt.x%npack+1);
|
||
v &= (1<<bpp)-1;
|
||
r = g = b = replbits(v, bpp, 8);
|
||
}else{
|
||
/*
|
||
* General case. We need to parse the channel descriptor and do what it says.
|
||
* In all channels but the color map, we replicate to 8 bits because that's the
|
||
* precision that all calculations are done at.
|
||
*
|
||
* In the case of the color map, we leave the bits alone, in case a color map
|
||
* with less than 8 bits of index is used. This is currently disallowed, so it's
|
||
* sort of silly.
|
||
*/
|
||
|
||
for(c=img->chan; c; c>>=8){
|
||
nbits = NBITS(c);
|
||
bits = v & ((1<<nbits)-1);
|
||
rbits = replbits(bits, nbits, 8);
|
||
v >>= nbits;
|
||
switch(TYPE(c)){
|
||
case CRed:
|
||
r = rbits;
|
||
break;
|
||
case CGreen:
|
||
g = rbits;
|
||
break;
|
||
case CBlue:
|
||
b = rbits;
|
||
break;
|
||
case CGrey:
|
||
r = g = b = rbits;
|
||
break;
|
||
case CAlpha:
|
||
a = rbits;
|
||
break;
|
||
case CMap:
|
||
p = img->cmap->cmap2rgb + 3*bits;
|
||
r = p[0];
|
||
g = p[1];
|
||
b = p[2];
|
||
break;
|
||
case CIgnore:
|
||
break;
|
||
default:
|
||
fprint(2, "unknown channel type %lud\n", TYPE(c));
|
||
abort();
|
||
}
|
||
}
|
||
}
|
||
return rgbatopix(r, g, b, a);
|
||
}
|
||
|
||
/*
|
||
* Return the greyscale equivalent of a pixel.
|
||
*/
|
||
uchar
|
||
getgrey(Memimage *img, Point pt)
|
||
{
|
||
uchar r, g, b, a;
|
||
pixtorgba(getpixel(img, pt), &r, &g, &b, &a);
|
||
return RGB2K(r, g, b);
|
||
}
|
||
|
||
/*
|
||
* Return the value at pt in image, if image is interpreted
|
||
* as a mask. This means the alpha channel if present, else
|
||
* the greyscale or its computed equivalent.
|
||
*/
|
||
uchar
|
||
getmask(Memimage *img, Point pt)
|
||
{
|
||
if(img->flags&Falpha)
|
||
return getpixel(img, pt)>>24;
|
||
else
|
||
return getgrey(img, pt);
|
||
}
|
||
#undef DBG
|
||
|
||
#define DBG if(0)
|
||
/*
|
||
* Write a pixel to img at point pt.
|
||
*
|
||
* We do this by reading a 32-bit little endian
|
||
* value from p and then writing it back
|
||
* after tweaking the appropriate bits. Because
|
||
* the data is little endian, we don't have to worry
|
||
* about what the actual depth is, as long as it is
|
||
* less than 32 bits.
|
||
*/
|
||
void
|
||
putpixel(Memimage *img, Point pt, ulong nv)
|
||
{
|
||
uchar r, g, b, a, *p, *q;
|
||
ulong c, mask, bits, v;
|
||
int bpp, sh, npack, nbits;
|
||
|
||
pixtorgba(nv, &r, &g, &b, &a);
|
||
|
||
p = byteaddr(img, pt);
|
||
v = p[0]|(p[1]<<8)|(p[2]<<16)|(p[3]<<24);
|
||
bpp = img->depth;
|
||
DBG print("v %.8lux...", v);
|
||
if(bpp < 8){
|
||
/*
|
||
* Sub-byte greyscale pixels. We need to skip the leftmost pt.x%npack pixels,
|
||
* which is equivalent to skipping the rightmost npack - pt.x%npack - 1 pixels.
|
||
*/
|
||
npack = 8/bpp;
|
||
sh = bpp*(npack - pt.x%npack - 1);
|
||
bits = RGB2K(r,g,b);
|
||
DBG print("repl %lux 8 %d = %lux...", bits, bpp, replbits(bits, 8, bpp));
|
||
bits = replbits(bits, 8, bpp);
|
||
mask = (1<<bpp)-1;
|
||
DBG print("bits %lux mask %lux sh %d...", bits, mask, sh);
|
||
mask <<= sh;
|
||
bits <<= sh;
|
||
DBG print("(%lux & %lux) | (%lux & %lux)", v, ~mask, bits, mask);
|
||
v = (v & ~mask) | (bits & mask);
|
||
} else {
|
||
/*
|
||
* General case. We need to parse the channel descriptor again.
|
||
*/
|
||
sh = 0;
|
||
for(c=img->chan; c; c>>=8){
|
||
nbits = NBITS(c);
|
||
switch(TYPE(c)){
|
||
case CRed:
|
||
bits = r;
|
||
break;
|
||
case CGreen:
|
||
bits = g;
|
||
break;
|
||
case CBlue:
|
||
bits = b;
|
||
break;
|
||
case CGrey:
|
||
bits = RGB2K(r, g, b);
|
||
break;
|
||
case CAlpha:
|
||
bits = a;
|
||
break;
|
||
case CIgnore:
|
||
bits = 0;
|
||
break;
|
||
case CMap:
|
||
q = img->cmap->rgb2cmap;
|
||
bits = q[(r>>4)*16*16+(g>>4)*16+(b>>4)];
|
||
break;
|
||
default:
|
||
SET(bits);
|
||
fprint(2, "unknown channel type %lud\n", TYPE(c));
|
||
abort();
|
||
}
|
||
|
||
DBG print("repl %lux 8 %d = %lux...", bits, nbits, replbits(bits, 8, nbits));
|
||
if(TYPE(c) != CMap)
|
||
bits = replbits(bits, 8, nbits);
|
||
mask = (1<<nbits)-1;
|
||
DBG print("bits %lux mask %lux sh %d...", bits, mask, sh);
|
||
bits <<= sh;
|
||
mask <<= sh;
|
||
v = (v & ~mask) | (bits & mask);
|
||
sh += nbits;
|
||
}
|
||
}
|
||
DBG print("v %.8lux\n", v);
|
||
p[0] = v;
|
||
p[1] = v>>8;
|
||
p[2] = v>>16;
|
||
p[3] = v>>24;
|
||
}
|
||
#undef DBG
|
||
|
||
#define DBG if(0)
|
||
void
|
||
drawonepixel(Memimage *dst, Point dp, Memimage *src, Point sp, Memimage *mask, Point mp)
|
||
{
|
||
uchar m, M, sr, sg, sb, sa, sk, dr, dg, db, da, dk;
|
||
|
||
pixtorgba(getpixel(dst, dp), &dr, &dg, &db, &da);
|
||
pixtorgba(getpixel(src, sp), &sr, &sg, &sb, &sa);
|
||
m = getmask(mask, mp);
|
||
M = 255-(sa*m)/255;
|
||
|
||
DBG print("dst %x %x %x %x src %x %x %x %x m %x = ", dr,dg,db,da, sr,sg,sb,sa, m);
|
||
if(dst->flags&Fgrey){
|
||
/*
|
||
* We need to do the conversion to grey before the alpha calculation
|
||
* because the draw operator does this, and we need to be operating
|
||
* at the same precision so we get exactly the same answers.
|
||
*/
|
||
sk = RGB2K(sr, sg, sb);
|
||
dk = RGB2K(dr, dg, db);
|
||
dk = (sk*m + dk*M)/255;
|
||
dr = dg = db = dk;
|
||
da = (sa*m + da*M)/255;
|
||
}else{
|
||
/*
|
||
* True color alpha calculation treats all channels (including alpha)
|
||
* the same. It might have been nice to use an array, but oh well.
|
||
*/
|
||
dr = (sr*m + dr*M)/255;
|
||
dg = (sg*m + dg*M)/255;
|
||
db = (sb*m + db*M)/255;
|
||
da = (sa*m + da*M)/255;
|
||
}
|
||
|
||
DBG print("%x %x %x %x\n", dr,dg,db,da);
|
||
putpixel(dst, dp, rgbatopix(dr, dg, db, da));
|
||
}
|