| version 1.7, 2003/02/14 22:29:19 |
version 1.8, 2011/08/10 04:51:58 |
|
|
| * DEVELOPER SHALL HAVE NO LIABILITY IN CONNECTION WITH THE USE, |
* DEVELOPER SHALL HAVE NO LIABILITY IN CONNECTION WITH THE USE, |
| * PERFORMANCE OR NON-PERFORMANCE OF THE SOFTWARE. |
* PERFORMANCE OR NON-PERFORMANCE OF THE SOFTWARE. |
| * |
* |
| * $OpenXM: OpenXM_contrib2/asir2000/plot/calc.c,v 1.6 2002/08/02 08:59:47 noro Exp $ |
* $OpenXM: OpenXM_contrib2/asir2000/plot/calc.c,v 1.7 2003/02/14 22:29:19 ohara Exp $ |
| */ |
*/ |
| #include "ca.h" |
#include "ca.h" |
| #include "parse.h" |
#include "parse.h" |
| Line 78 void calc(double **tab,struct canvas *can,int nox) |
|
| Line 78 void calc(double **tab,struct canvas *can,int nox) |
|
| ymin = can->ymin; ystep = (can->ymax-can->ymin)/h; |
ymin = can->ymin; ystep = (can->ymax-can->ymin)/h; |
| MKReal(1.0,rx); MKReal(1.0,ry); /* dummy real */ |
MKReal(1.0,rx); MKReal(1.0,ry); /* dummy real */ |
| for( ix = 0, x = xmin; ix < w ; ix++, x += xstep ) { |
for( ix = 0, x = xmin; ix < w ; ix++, x += xstep ) { |
| #if 0 |
|
| MKReal(x,r); substp(CO,fr,vx,(P)r,&g); |
|
| if ( !nox ) marker(can,DIR_X,ix); |
|
| for( iy = 0, y = ymin; iy < h ; iy++, y += ystep ) |
|
| tab[ix][iy] = usubstrp(g,y); |
|
| #endif |
|
| BDY(rx) = x; substr(CO,0,fr,vx,x?(Obj)rx:0,&t); |
BDY(rx) = x; substr(CO,0,fr,vx,x?(Obj)rx:0,&t); |
| devalr(CO,t,&g); |
devalr(CO,t,&g); |
| if ( !nox ) marker(can,DIR_X,ix); |
if ( !nox ) marker(can,DIR_X,ix); |
| Line 127 void qcalc(char **tab,struct canvas *can) |
|
| Line 121 void qcalc(char **tab,struct canvas *can) |
|
| int *a,*pa; |
int *a,*pa; |
| VECT ss; |
VECT ss; |
| |
|
| |
|
| subq(can->qxmax,can->qxmin,&dx); STOQ(can->width,w); divq(dx,w,&xstep); |
subq(can->qxmax,can->qxmin,&dx); STOQ(can->width,w); divq(dx,w,&xstep); |
| subq(can->qymax,can->qymin,&dy); STOQ(can->height,h); divq(dy,h,&ystep); |
subq(can->qymax,can->qymin,&dy); STOQ(can->height,h); divq(dy,h,&ystep); |
| MKV(can->vx,x); mulp(CO,(P)xstep,x,&t); |
MKV(can->vx,x); mulp(CO,(P)xstep,x,&t); |
| Line 314 void plotcalc(struct canvas *can) |
|
| Line 307 void plotcalc(struct canvas *can) |
|
| if ( t && (OID(t)!=O_N || NID((Num)t)!=N_R) ) |
if ( t && (OID(t)!=O_N || NID((Num)t)!=N_R) ) |
| error("plotcalc : invalid evaluation"); |
error("plotcalc : invalid evaluation"); |
| tab[ix] = ToReal((Num)t); |
tab[ix] = ToReal((Num)t); |
| #if 0 |
|
| tab[ix] = usubstrp(fr,x); |
|
| #endif |
|
| } |
} |
| if ( can->ymax == can->ymin ) { |
if ( can->ymax == can->ymin ) { |
| for ( ymax = ymin = tab[0], ix = 1; ix < w; ix++ ) { |
for ( ymax = ymin = tab[0], ix = 1; ix < w; ix++ ) { |
| Line 396 void polarplotcalc(struct canvas *can) |
|
| Line 386 void polarplotcalc(struct canvas *can) |
|
| YC(pa[i]) = (h-1)*(ymax-taby[i])/dy; |
YC(pa[i]) = (h-1)*(ymax-taby[i])/dy; |
| } |
} |
| } |
} |
| |
|
| |
#if defined(INTERVAL) |
| |
#define NORMAL 1 |
| |
#define TRANSFER 1 |
| |
#define RECURSION 1 |
| |
#define RECTRANS 1 |
| |
|
| |
void ineqncalc(double **tab,struct canvas *can,int nox) |
| |
{ |
| |
double x, y, xmin, ymax, xstep, ystep; |
| |
int ix, iy; |
| |
Real r, rx, ry; |
| |
Obj fr, g, t, s; |
| |
int w, h; |
| |
V vx, vy; |
| |
|
| |
if ( !nox ) initmarker(can,"Evaluating..."); |
| |
MKReal(1.0,r); mulr(CO,(Obj)can->formula,(Obj)r,&fr); |
| |
vx = can->vx; vy = can->vy; |
| |
w = can->width; h = can->height; |
| |
xmin = can->xmin; xstep = (can->xmax-can->xmin)/w; |
| |
ymax = can->ymax; ystep = (can->ymax-can->ymin)/h; |
| |
MKReal(1.0,rx); MKReal(1.0,ry); /* dummy real */ |
| |
|
| |
for( iy = 0, y = ymax; iy <= h ; iy++, y -= ystep ) { |
| |
BDY(ry) = y; substr(CO,0,fr,vy,y?(Obj)ry:0,&t); |
| |
devalr(CO,t,&g); |
| |
if ( !nox ) marker(can,DIR_Y,iy); |
| |
for( ix = 0, x = xmin; ix <= w ; ix++, x += xstep ) { |
| |
BDY(rx) = x; |
| |
substr(CO,0,g,vx,x?(Obj)rx:0,&t); |
| |
devalr(CO,t,&s); |
| |
tab[iy][ix] = ToReal(s); |
| |
} |
| |
} |
| |
} |
| |
|
| |
void reccalc(P fr, V vx, V vy, int ixlw, int ixhg, int iylw, int iyhg, |
| |
double *xval, double *yval, int w, int **mask, int itvsize) |
| |
{ |
| |
int i, j; |
| |
int ixmd, iymd; |
| |
double inf, sup, dt; |
| |
Real rxwid, rywid, rxlw, rylw, rzero; |
| |
Itv itx, ity; |
| |
Obj fr1; |
| |
P py, px, tmp; |
| |
|
| |
double **tbl , xs, ys; |
| |
int ywidth, xwidth; |
| |
Real rx, ry; |
| |
Obj g, t, s; |
| |
|
| |
if ( (ixlw > ixhg) || (iylw > iyhg) ) return; |
| |
NEWItvP(itx); NEWItvP(ity); |
| |
MKReal(xval[ixhg + 1] - xval[ixlw], rxwid); |
| |
MKReal(yval[iyhg + 1] - yval[iylw], rywid); |
| |
MKReal(0.0,rzero); |
| |
istoitv((Num)rzero, (Num)rxwid, &itx); |
| |
istoitv((Num)rzero, (Num)rywid, &ity); |
| |
|
| |
MKReal(xval[ixlw],rxlw);MKReal(yval[iylw],rylw); |
| |
MKV(vx,tmp); addp(CO,(P)tmp,(P)rxlw,&px); |
| |
MKV(vy,tmp); addp(CO,(P)tmp,(P)rylw,&py); |
| |
substp(CO,(P)fr,(V)vx,(P)px,(P*)&fr1); |
| |
substp(CO,(P)fr1,(V)vy,(P)py,(P*)&fr1); |
| |
substr(CO,0,(Obj)fr1,vx,(Obj)itx,&fr1); |
| |
substr(CO,0,(Obj)fr1,vy,(Obj)ity,&fr1); |
| |
Num2double((Num)fr1,&inf,&sup); |
| |
|
| |
if(inf > sup){dt=inf;inf=sup;sup=dt;} |
| |
if ( inf <= 0.0 && sup >= 0.0 ) { |
| |
if ( (ixhg - ixlw <= itvsize) && (iyhg - iylw <= itvsize) ){ |
| |
ywidth = iyhg - iylw + 2; xwidth = ixhg - ixlw + 2; |
| |
MKReal(1.0, rx); MKReal(1.0, ry); |
| |
tbl = (double **)ALLOCA((ywidth)*sizeof(double *)); |
| |
for (i=0;i<ywidth;i++) |
| |
tbl[i] = (double *)ALLOCA((xwidth)*sizeof(double)); |
| |
for (i = 0; i < ywidth; i++){ |
| |
BDY(ry) = yval[iylw+i]; |
| |
substr(CO,0,(Obj)fr,vy,(Obj)ry,&t); |
| |
devalr(CO, t, &g); |
| |
for (j = 0; j < xwidth; j++){ |
| |
BDY(rx) = xval[ixlw+j]; |
| |
substr(CO,0,g,vx,(Obj)rx,&t); |
| |
devalr(CO, t, &s); |
| |
tbl[i][j] = ToReal(s); |
| |
} |
| |
} |
| |
for ( i = 0; i < ywidth - 1; i++){ |
| |
for ( j = 0; j < xwidth - 1; j++){ |
| |
if ( tbl[i][j] >= 0.0 ){ |
| |
if ( (tbl[i+1][j] <= 0.0) || |
| |
(tbl[i+1][j+1] <= 0.0) || |
| |
(tbl[i][j+1] <= 0.0) ) mask[w-(i+iylw)][j+ixlw] = 0; |
| |
else mask[w-(i+iylw)][j+ixlw] = 1; |
| |
} else { |
| |
if ( (tbl[i+1][j] >= 0.0) || |
| |
(tbl[i+1][j+1] >= 0.0) || |
| |
(tbl[i][j+1] >= 0.0) ) mask[w-(i+iylw)][j+ixlw] = 0; |
| |
else mask[w-(i+iylw)][j+ixlw] = 1; |
| |
} |
| |
} |
| |
} |
| |
} else { |
| |
ixmd = (ixhg + ixlw)/2; iymd = (iyhg + iylw)/2; |
| |
reccalc((P)fr,vx,vy,ixlw,ixmd,iylw,iymd,xval,yval,w,mask,itvsize); |
| |
reccalc((P)fr,vx,vy,ixmd+1,ixhg,iylw,iymd,xval,yval,w,mask,itvsize); |
| |
reccalc((P)fr,vx,vy,ixlw,ixmd,iymd+1,iyhg,xval,yval,w,mask,itvsize); |
| |
reccalc((P)fr,vx,vy,ixmd+1,ixhg,iymd+1,iyhg,xval,yval,w,mask,itvsize); |
| |
} |
| |
} else { |
| |
for (i=w-iyhg; i> w-iylw; i--) |
| |
for (j=ixlw; j <= ixhg; j++) mask[i][j] = -1; |
| |
} |
| |
} |
| |
|
| |
void itvcalc(int **mask, struct canvas *can, int nox, int itvsize) |
| |
{ |
| |
double xstep, ystep, xv, yv, *xval, *yval; |
| |
int imx, imy, i, w, h; |
| |
Real r; |
| |
Obj fr; |
| |
V vx, vy; |
| |
|
| |
if ( !nox ) initmarker(can,"Evaluating..."); |
| |
MKReal(1.0,r); mulr(CO,(Obj)can->formula,(Obj)r,&fr); |
| |
vx = can->vx; vy = can->vy; |
| |
w = can->width; h = can->height; |
| |
xstep = (can->xmax - can->xmin)/w; |
| |
ystep = (can->ymax - can->ymin)/h; |
| |
|
| |
xval = (double *)ALLOCA((w+1)*sizeof(double)); |
| |
yval = (double *)ALLOCA((h+1)*sizeof(double)); |
| |
for (i=0, xv=can->xmin; i<= w; i++, xv += xstep) xval[i] = xv; |
| |
for (i=0, yv=can->ymin; i<= h; i++, yv += ystep) yval[i] = yv; |
| |
imx = w/2; imy = h/2; |
| |
|
| |
reccalc((P)fr,vx,vy,0,imx,0,imy,xval,yval,w-1,mask,itvsize); |
| |
reccalc((P)fr,vx,vy,imx+1,w-1,0,imy,xval,yval,w-1,mask,itvsize); |
| |
reccalc((P)fr,vx,vy,0,imx,imy+1,h-1,xval,yval,w-1,mask,itvsize); |
| |
reccalc((P)fr,vx,vy,imx+1,w-1,imy+1,h-1,xval,yval,w-1,mask,itvsize); |
| |
} |
| |
|
| |
#if NORMAL |
| |
void itvcalc1(int **mask, struct canvas *can, int nox) |
| |
{ |
| |
double x, y, xstep, ystep; |
| |
int ix, iy, w, h; |
| |
Itv ity, itx; |
| |
Real r, rx, ry, rx1, ry1; |
| |
Obj fr, g, t; |
| |
V vx, vy; |
| |
|
| |
if ( !nox ) initmarker(can,"Evaluating..."); |
| |
MKReal(1.0,r); mulr(CO,(Obj)can->formula,(Obj)r,&fr); |
| |
vx = can->vx; vy = can->vy; |
| |
w = can->width; h = can->height; |
| |
xstep = (can->xmax - can->xmin)/w; |
| |
ystep = (can->ymax - can->ymin)/h; |
| |
|
| |
for( iy = 0, y = can->ymax; iy < h ; iy++, y -= ystep ) { |
| |
MKReal(y, ry); |
| |
MKReal(y-ystep,ry1); |
| |
istoitv((Num)(ry1),(Num)ry,&ity); |
| |
substr(CO,0,(Obj)fr,vy,(Obj)ity,&t); |
| |
for( ix = 0, x = can->xmin; ix < w ; ix++, x += xstep ) { |
| |
MKReal(x,rx); |
| |
MKReal(x+xstep,rx1); |
| |
istoitv((Num)rx,(Num)rx1,&itx); |
| |
substr(CO,0,(Obj)t,vx,(Obj)itx,&g); |
| |
if (compnum(0,0,(Num)g)) mask[iy][ix] = -1; |
| |
else mask[iy][ix] = 0; |
| |
} |
| |
} |
| |
} |
| |
#endif |
| |
|
| |
#if TRANSFER |
| |
void itvcalc2(int **mask, struct canvas *can, int nox) |
| |
{ |
| |
double x, y, xstep, ystep; |
| |
int ix, iy, w, h; |
| |
Itv ity, itx; |
| |
Real r, rx, ry, rzero; |
| |
Obj fr, g, t, s; |
| |
V vx, vy; |
| |
P mp, fr2; |
| |
Real qx,qy; |
| |
|
| |
if ( !nox ) initmarker(can,"Evaluating..."); |
| |
MKReal(1.0,r); mulr(CO,(Obj)can->formula,(Obj)r,&fr); |
| |
vx = can->vx; vy = can->vy; |
| |
w = can->width; h = can->height; |
| |
xstep = (can->xmax - can->xmin)/w; |
| |
ystep = (can->ymax - can->ymin)/h; |
| |
|
| |
MKReal(0.0, rzero); |
| |
MKReal(ystep,ry); |
| |
istoitv((Num)rzero,(Num)ry,&ity); |
| |
MKReal(xstep,rx); |
| |
istoitv((Num)rzero,(Num)rx,&itx); |
| |
for( iy = 0, y = can->ymin; iy < h ; iy++, y += ystep ) { |
| |
MKReal(y,qy); |
| |
MKV(vy,mp);subp(CO,mp,(P)qy,&mp); |
| |
substp(CO,(P)fr,(V)vy,(P)mp,&fr2); |
| |
substr(CO,0,(Obj)fr2,vy,(Obj)ity,&t); |
| |
for( ix = 0, x = can->xmin; ix < w ; ix++, x += xstep ) { |
| |
MKReal(x,qx); |
| |
MKV(vx,mp);addp(CO,mp,(P)qx,&mp); |
| |
substp(CO,(P)t,(V)vx,(P)mp,(P*)&s); |
| |
substr(CO,0,(Obj)s,vx,(Obj)itx,&g); |
| |
if (compnum(0,0,(Num)g)) mask[iy][ix] = -1; |
| |
else mask[iy][ix] = 0; |
| |
} |
| |
} |
| |
} |
| |
#endif |
| |
|
| |
#if RECURSION |
| |
void reccalc3(P fr, V vx, V vy, int ixlw, int ixhg, int iylw, int iyhg, |
| |
double *xval, double *yval,int w, int **mask, int itvsize) |
| |
{ |
| |
int i, j, ixmd, iymd; |
| |
double inf, sup, dt; |
| |
Real rxlw, rxhg, rylw, ryhg; |
| |
Itv itx, ity; |
| |
Obj fr1; |
| |
|
| |
NEWItvP(itx); NEWItvP(ity); |
| |
|
| |
if ( (ixlw > ixhg) || (iylw > iyhg) ) return; |
| |
|
| |
MKReal(xval[ixlw], rxlw); MKReal(xval[ixhg + 1], rxhg); |
| |
MKReal(yval[iylw], rylw); MKReal(yval[iyhg + 1], ryhg); |
| |
istoitv((Num)rxlw, (Num)rxhg, &itx); |
| |
istoitv((Num)rylw, (Num)ryhg, &ity); |
| |
substr(CO, 0, (Obj)fr, vy, (Obj)ity, &fr1); |
| |
substr(CO, 0, (Obj)fr1, vx, (Obj)itx, &fr1); |
| |
Num2double((Num)fr1, &inf, &sup); |
| |
|
| |
if( itvsize <= 0 ) itvsize = 1; |
| |
if(inf > sup){dt = inf; inf = sup; sup = dt;} |
| |
if ( inf <= 0.0 && sup >= 0.0 ) { |
| |
if ( (ixhg - ixlw < itvsize) || (iyhg - iylw < itvsize) ){ |
| |
for(i = iylw; i <=iyhg; i++) |
| |
for(j = ixlw; j <=ixhg; j++) mask[w-i][j] = 0; |
| |
} else { |
| |
ixmd = (ixhg + ixlw)/2; iymd = (iyhg + iylw)/2; |
| |
reccalc3((P)fr,vx,vy,ixlw,ixmd,iylw,iymd,xval,yval,w,mask,itvsize); |
| |
reccalc3((P)fr,vx,vy,ixmd+1,ixhg,iylw,iymd,xval,yval,w,mask,itvsize); |
| |
reccalc3((P)fr,vx,vy,ixlw,ixmd,iymd+1,iyhg,xval,yval,w,mask,itvsize); |
| |
reccalc3((P)fr,vx,vy,ixmd+1,ixhg,iymd+1,iyhg,xval,yval,w,mask,itvsize); |
| |
} |
| |
} else { |
| |
for (i = iylw; i<= iyhg; i++) |
| |
for (j = ixlw; j <= ixhg; j++) mask[w-i][j] = -1; |
| |
} |
| |
} |
| |
|
| |
void itvcalc3(int **mask, struct canvas *can, int nox, int itvsize) |
| |
{ |
| |
double xstep, ystep, xv, yv, *xval, *yval; |
| |
int i, imx, imy, w, h; |
| |
Real r; |
| |
Obj fr; |
| |
V vx, vy; |
| |
|
| |
if ( !nox ) initmarker(can,"Evaluating..."); |
| |
MKReal(1.0,r); mulr(CO,(Obj)can->formula,(Obj)r,&fr); |
| |
vx = can->vx; vy = can->vy; |
| |
w = can->width; h = can->height; |
| |
xstep = (can->xmax - can->xmin)/w; |
| |
ystep = (can->ymax - can->ymin)/h; |
| |
|
| |
xval = (double *)ALLOCA((w+1)*sizeof(double)); |
| |
yval = (double *)ALLOCA((h+1)*sizeof(double)); |
| |
for (i = 0, xv = can->xmin; i <= w; i++, xv += xstep) xval[i] = xv; |
| |
for (i = 0, yv = can->ymin; i <= h; i++, yv += ystep) yval[i] = yv; |
| |
imx = w/2; imy = h/2; |
| |
|
| |
reccalc3((P)fr,vx,vy,0,imx,0,imy,xval,yval,w-1,mask,itvsize); |
| |
reccalc3((P)fr,vx,vy,imx+1,w-1,0,imy,xval,yval,w-1,mask,itvsize); |
| |
reccalc3((P)fr,vx,vy,0,imx,imy+1,h-1,xval,yval,w-1,mask,itvsize); |
| |
reccalc3((P)fr,vx,vy,imx+1,w-1,imy+1,h-1,xval,yval,w-1,mask,itvsize); |
| |
} |
| |
#endif |
| |
|
| |
#if RECTRANS |
| |
void reccalc4(P fr, V vx, V vy, int ixlw, int ixhg, int iylw, int iyhg, |
| |
double *xval, double *yval, int w, int **mask, int itvsize) |
| |
{ |
| |
int i, j; |
| |
int ixmd, iymd; |
| |
double inf, sup, dt; |
| |
Real rxlw, rylw, rzero, rxwid, rywid; |
| |
Itv itx, ity; |
| |
Obj fr1; |
| |
P py, px, tmp; |
| |
|
| |
if ( (ixlw > ixhg) || (iylw > iyhg)) return; |
| |
NEWItvP(itx); NEWItvP(ity); |
| |
|
| |
MKReal(0.0,rzero); |
| |
MKReal(xval[ixhg + 1] - xval[ixlw], rxwid); |
| |
MKReal(yval[iyhg + 1] - yval[iylw], rywid); |
| |
istoitv((Num)rzero, (Num)rxwid, &itx); |
| |
istoitv((Num)rzero, (Num)rywid, &ity); |
| |
|
| |
MKReal(xval[ixlw], rxlw); MKReal(yval[iylw], rylw); |
| |
MKV(vx,tmp);addp(CO, (P)tmp, (P)rxlw, &px); |
| |
MKV(vy,tmp);addp(CO, (P)tmp, (P)rylw, &py); |
| |
substp(CO, (P)fr, (V)vx, (P)px, (P*)&fr1); |
| |
substp(CO, (P)fr1, (V)vy, (P)py, (P*)&fr1); |
| |
substr(CO, 0, (Obj)fr1, vx, (Obj)itx, &fr1); |
| |
substr(CO, 0, (Obj)fr1, vy, (Obj)ity, &fr1); |
| |
Num2double((Num)fr1, &inf, &sup); |
| |
|
| |
if(inf > sup){dt=inf;inf=sup;sup=dt;} |
| |
if ( inf <= 0.0 && sup >= 0.0 ) { |
| |
if ( (ixhg - ixlw <= itvsize) && (iyhg - iylw <= itvsize) ){ |
| |
for(i = iylw; i <= iyhg; i++) |
| |
for(j = ixlw; j <= ixhg; j++) mask[w-i][j]=0; |
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} else { |
| |
ixmd = (ixhg + ixlw)/2; iymd = (iyhg + iylw)/2; |
| |
|
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reccalc4((P)fr,vx,vy,ixlw,ixmd,iylw,iymd,xval,yval,w,mask,itvsize); |
| |
reccalc4((P)fr,vx,vy,ixmd+1,ixhg,iylw,iymd,xval,yval,w,mask,itvsize); |
| |
reccalc4((P)fr,vx,vy,ixlw,ixmd,iymd+1,iyhg,xval,yval,w,mask,itvsize); |
| |
reccalc4((P)fr,vx,vy,ixmd+1,ixhg,iymd+1,iyhg,xval,yval,w,mask,itvsize); |
| |
} |
| |
} else { |
| |
for (i = iylw; i<= iyhg; i++) |
| |
for (j = ixlw; j <= ixhg; j++) mask[w-i][j] = -1; |
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} |
| |
} |
| |
|
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void itvcalc4(int **mask, struct canvas *can, int nox, int itvsize) |
| |
{ |
| |
double xstep, ystep, xv, yv, *xval, *yval; |
| |
int i, imx, imy, w, h; |
| |
Real r; |
| |
Obj fr; |
| |
V vx, vy; |
| |
|
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if ( !nox ) initmarker(can,"Evaluating..."); |
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MKReal(1.0,r); mulr(CO,(Obj)can->formula,(Obj)r,&fr); |
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vx = can->vx; vy = can->vy; |
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w = can->width; h = can->height; |
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xstep = (can->xmax - can->xmin)/w; |
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ystep = (can->ymax - can->ymin)/h; |
| |
|
| |
xval = (double *)ALLOCA((w+1)*sizeof(double)); |
| |
yval = (double *)ALLOCA((h+1)*sizeof(double)); |
| |
for (i=0, xv=can->xmin; i <= w; i++, xv += xstep) xval[i] = xv; |
| |
for (i=0, yv=can->ymin; i <= h; i++, yv += ystep) yval[i] = yv; |
| |
imx = w/2; imy = h/2; |
| |
|
| |
reccalc4((P)fr,vx,vy,0,imx,0,imy,xval,yval,w-1,mask,itvsize); |
| |
reccalc4((P)fr,vx,vy,imx+1,w-1,0,imy,xval,yval,w-1,mask,itvsize); |
| |
reccalc4((P)fr,vx,vy,0,imx,imy+1,h-1,xval,yval,w-1,mask,itvsize); |
| |
reccalc4((P)fr,vx,vy,imx+1,w-1,imy+1,h-1,xval,yval,w-1,mask,itvsize); |
| |
} |
| |
#endif |
| |
#endif |
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