src/cmd/postscript/tr2post/draw.c - plan9 - Git at Google

 #include <u.h>
 #include <libc.h>
 #include <bio.h>
 #include <ctype.h>
 #include "../common/common.h"
 #include "tr2post.h"

 BOOLEAN drawflag = FALSE;
 BOOLEAN	inpath = FALSE;			/* TRUE if we're putting pieces together */

 void
 cover(double x, double y) {
 }

 void
 drawspline(Biobuf *Bp, int flag) {	/* flag!=1 connect end points */
 	int x[100], y[100];
 	int i, N;
 /*
  *
  * Spline drawing routine for Postscript printers. The complicated stuff is
  * handled by procedure Ds, which should be defined in the library file. I've
  * seen wrong implementations of troff's spline drawing, so fo the record I'll
  * write down the parametric equations and the necessary conversions to Bezier
  * cubic splines (as used in Postscript).
  *
  *
  * Parametric equation (x coordinate only):
  *
  *
  *	    (x2 - 2 * x1 + x0)    2                    (x0 + x1)
  *	x = ------------------ * t   + (x1 - x0) * t + ---------
  *		    2					   2
  *
  *
  * The coefficients in the Bezier cubic are,
  *
  *
  *	A = 0
  *	B = (x2 - 2 * x1 + x0) / 2
  *	C = x1 - x0
  *
  *
  * while the current point is,
  *
  *	current-point = (x0 + x1) / 2
  *
  * Using the relationships given in the Postscript manual (page 121) it's easy to
  * see that the control points are given by,
  *
  *
  *	x0' = (x0 + 5 * x1) / 6
  *	x1' = (x2 + 5 * x1) / 6
  *	x2' = (x1 + x2) / 2
  *
  *
  * where the primed variables are the ones used by curveto. The calculations
  * shown above are done in procedure Ds using the coordinates set up in both
  * the x[] and y[] arrays.
  *
  * A simple test of whether your spline drawing is correct would be to use cip
  * to draw a spline and some tangent lines at appropriate points and then print
  * the file.
  *
  */

 	for (N=2; N<sizeof(x)/sizeof(x[0]); N++)
 		if (Bgetfield(Bp, 'd', &x[N], 0)<=0 || Bgetfield(Bp, 'd', &y[N], 0)<=0)
 			break;

 	x[0] = x[1] = hpos;
 	y[0] = y[1] = vpos;

 	for (i = 1; i < N; i++) {
 		x[i+1] += x[i];
 		y[i+1] += y[i];
 	}

 	x[N] = x[N-1];
 	y[N] = y[N-1];

 	for (i = ((flag!=1)?0:1); i < ((flag!=1)?N-1:N-2); i++) {
 		endstring();
 		if (pageon())
 			Bprint(Bstdout, "%d %d %d %d %d %d Ds\n", x[i], y[i], x[i+1], y[i+1], x[i+2], y[i+2]);
 /*		if (dobbox == TRUE) {		/* could be better */
 /*	    		cover((double)(x[i] + x[i+1])/2,(double)-(y[i] + y[i+1])/2);
 /*	    		cover((double)x[i+1], (double)-y[i+1]);
 /*	    		cover((double)(x[i+1] + x[i+2])/2, (double)-(y[i+1] + y[i+2])/2);
 /*		}
  */
 	}

 	hpos = x[N];			/* where troff expects to be */
 	vpos = y[N];
 }

 void
 draw(Biobuf *Bp) {

 	int r, x1, y1, x2, y2, i;
 	int d1, d2;

 	drawflag = TRUE;
 	r = Bgetrune(Bp);
 	switch(r) {
 	case 'l':
 		if (Bgetfield(Bp, 'd', &x1, 0)<=0 || Bgetfield(Bp, 'd', &y1, 0)<=0 || Bgetfield(Bp, 'r', &i, 0)<=0) {
 			error(FATAL, "draw line function, destination coordinates not found.\n");
 			return;
 		}

 		endstring();
 		if (pageon())
 			Bprint(Bstdout, "%d %d %d %d Dl\n", hpos, vpos, hpos+x1, vpos+y1);
 		hpos += x1;
 		vpos += y1;
 		break;
 	case 'c':
 		if (Bgetfield(Bp, 'd', &d1, 0)<=0) {
 			error(FATAL, "draw circle function, diameter coordinates not found.\n");
 			return;
 		}

 		endstring();
 		if (pageon())
 			Bprint(Bstdout, "%d %d %d %d De\n", hpos, vpos, d1, d1);
 		hpos += d1;
 		break;
 	case 'e':
 		if (Bgetfield(Bp, 'd', &d1, 0)<=0 || Bgetfield(Bp, 'd', &d2, 0)<=0) {
 			error(FATAL, "draw ellipse function, diameter coordinates not found.\n");
 			return;
 		}

 		endstring();
 		if (pageon())
 			Bprint(Bstdout, "%d %d %d %d De\n", hpos, vpos, d1, d2);
 		hpos += d1;
 		break;
 	case 'a':
 		if (Bgetfield(Bp, 'd', &x1, 0)<=0 || Bgetfield(Bp, 'd', &y1, 0)<=0 || Bgetfield(Bp, 'd', &x2, 0)<=0 || Bgetfield(Bp, 'd', &y2, 0)<=0) {
 			error(FATAL, "draw arc function, coordinates not found.\n");
 			return;
 		}

 		endstring();
 		if (pageon())
 			Bprint(Bstdout, "%d %d %d %d %d %d Da\n", hpos, vpos, x1, y1, x2, y2);
 		hpos += x1 + x2;
 		vpos += y1 + y2;
 		break;
 	case 'q':
 		drawspline(Bp, 1);
 		break;
 	case '~':
 		drawspline(Bp, 2);
 		break;
 	default:
 		error(FATAL, "unknown draw function <%c>\n", r);
 		return;
 	}
 }

 void
 beginpath(char *buf, int copy) {

 /*
  * Called from devcntrl() whenever an "x X BeginPath" command is read. It's used
  * to mark the start of a sequence of drawing commands that should be grouped
  * together and treated as a single path. By default the drawing procedures in
  * *drawfile treat each drawing command as a separate object, and usually start
  * with a newpath (just as a precaution) and end with a stroke. The newpath and
  * stroke isolate individual drawing commands and make it impossible to deal with
  * composite objects. "x X BeginPath" can be used to mark the start of drawing
  * commands that should be grouped together and treated as a single object, and
  * part of what's done here ensures that the PostScript drawing commands defined
  * in *drawfile skip the newpath and stroke, until after the next "x X DrawPath"
  * command. At that point the path that's been built up can be manipulated in
  * various ways (eg. filled and/or stroked with a different line width).
  *
  * Color selection is one of the options that's available in parsebuf(),
  * so if we get here we add *colorfile to the output file before doing
  * anything important.
  *
  */
 	if (inpath == FALSE) {
 		endstring();
 	/*	getdraw();	*/
 	/*	getcolor(); */
 		Bprint(Bstdout, "gsave\n");
 		Bprint(Bstdout, "newpath\n");
 		Bprint(Bstdout, "%d %d m\n", hpos, vpos);
 		Bprint(Bstdout, "/inpath true def\n");
 		if ( copy == TRUE )
 			Bprint(Bstdout, "%s\n", buf);
 		inpath = TRUE;
 	}
 }

 static void parsebuf(char*);

 void
 drawpath(char *buf, int copy) {

 /*
  *
  * Called from devcntrl() whenever an "x X DrawPath" command is read. It marks the
  * end of the path started by the last "x X BeginPath" command and uses whatever
  * has been passed along in *buf to manipulate the path (eg. fill and/or stroke
  * the path). Once that's been done the drawing procedures are restored to their
  * default behavior in which each drawing command is treated as an isolated path.
  * The new version (called after "x X DrawPath") has copy set to FALSE, and calls
  * parsebuf() to figure out what goes in the output file. It's a feeble attempt
  * to free users and preprocessors (like pic) from having to know PostScript. The
  * comments in parsebuf() describe what's handled.
  *
  * In the early version a path was started with "x X BeginObject" and ended with
  * "x X EndObject". In both cases *buf was just copied to the output file, and
  * was expected to be legitimate PostScript that manipulated the current path.
  * The old escape sequence will be supported for a while (for Ravi), and always
  * call this routine with copy set to TRUE.
  *
  *
  */

 	if ( inpath == TRUE ) {
 		if ( copy == TRUE )
 			Bprint(Bstdout, "%s\n", buf);
 		else
 			parsebuf(buf);
 		Bprint(Bstdout, "grestore\n");
 		Bprint(Bstdout, "/inpath false def\n");
 /*		reset();		*/
 		inpath = FALSE;
 	}
 }


 /*****************************************************************************/

 static void
 parsebuf(char *buf)
 {
 	char	*p = (char*)0;			/* usually the next token */
 	char *q;
 	int		gsavelevel = 0;		/* non-zero if we've done a gsave */

 /*
  *
  * Simple minded attempt at parsing the string that followed an "x X DrawPath"
  * command. Everything not recognized here is simply ignored - there's absolutely
  * no error checking and what was originally in buf is clobbered by strtok().
  * A typical *buf might look like,
  *
  *	gray .9 fill stroke
  *
  * to fill the current path with a gray level of .9 and follow that by stroking the
  * outline of the path. Since unrecognized tokens are ignored the last example
  * could also be written as,
  *
  *	with gray .9 fill then stroke
  *
  * The "with" and "then" strings aren't recognized tokens and are simply discarded.
  * The "stroke", "fill", and "wfill" force out appropriate PostScript code and are
  * followed by a grestore. In otherwords changes to the grahics state (eg. a gray
  * level or color) are reset to default values immediately after the stroke, fill,
  * or wfill tokens. For now "fill" gets invokes PostScript's eofill operator and
  * "wfill" calls fill (ie. the operator that uses the non-zero winding rule).
  *
  * The tokens that cause temporary changes to the graphics state are "gray" (for
  * setting the gray level), "color" (for selecting a known color from the colordict
  * dictionary defined in *colorfile), and "line" (for setting the line width). All
  * three tokens can be extended since strncmp() makes the comparison. For example
  * the strings "line" and "linewidth" accomplish the same thing. Colors are named
  * (eg. "red"), but must be appropriately defined in *colorfile. For now all three
  * tokens must be followed immediately by their single argument. The gray level
  * (ie. the argument that follows "gray") should be a number between 0 and 1, with
  * 0 for black and 1 for white.
  *
  * To pass straight PostScript through enclose the appropriate commands in double
  * quotes. Straight PostScript is only bracketed by the outermost gsave/grestore
  * pair (ie. the one from the initial "x X BeginPath") although that's probably
  * a mistake. Suspect I may have to change the double quote delimiters.
  *
  */

 	for( ; p != nil ; p = q ) {
 		if( q = strchr(p, ' ') ) {
 			*q++ = '\0';
 		}

 		if ( gsavelevel == 0 ) {
 			Bprint(Bstdout, "gsave\n");
 			gsavelevel++;
 		}
 		if ( strcmp(p, "stroke") == 0 ) {
 			Bprint(Bstdout, "closepath stroke\ngrestore\n");
 			gsavelevel--;
 		} else if ( strcmp(p, "openstroke") == 0 ) {
 			Bprint(Bstdout, "stroke\ngrestore\n");
 			gsavelevel--;
 		} else if ( strcmp(p, "fill") == 0 ) {
 			Bprint(Bstdout, "eofill\ngrestore\n");
 			gsavelevel--;
 		} else if ( strcmp(p, "wfill") == 0 ) {
 			Bprint(Bstdout, "fill\ngrestore\n");
 			gsavelevel--;
 		} else if ( strcmp(p, "sfill") == 0 ) {
 			Bprint(Bstdout, "eofill\ngrestore\ngsave\nstroke\ngrestore\n");
 			gsavelevel--;
 		} else if ( strncmp(p, "gray", strlen("gray")) == 0 ) {
 			if( q ) {
 				p = q;
 				if ( q = strchr(p, ' ') )
 					*q++ = '\0';
 				Bprint(Bstdout, "%s setgray\n", p);
 			}
 		} else if ( strncmp(p, "color", strlen("color")) == 0 ) {
 			if( q ) {
 				p = q;
 				if ( q = strchr(p, ' ') )
 					*q++ = '\0';
 				Bprint(Bstdout, "/%s setcolor\n", p);
 			}
 		} else if ( strncmp(p, "line", strlen("line")) == 0 ) {
 			if( q ) {
 				p = q;
 				if ( q = strchr(p, ' ') )
 					*q++ = '\0';
 				Bprint(Bstdout, "%s resolution mul 2 div setlinewidth\n", p);
 			}
 		} else if ( strncmp(p, "reverse", strlen("reverse")) == 0 )
 			Bprint(Bstdout, "reversepath\n");
 		else if ( *p == '"' ) {
 			for ( ; gsavelevel > 0; gsavelevel-- )
 				Bprint(Bstdout, "grestore\n");
 			if ( q != nil )
 				*--q = ' ';
 			if ( (q = strchr(p, '"')) != nil ) {
 				*q++ = '\0';
 				Bprint(Bstdout, "%s\n", p);
 			}
 		}
 	}

 	for ( ; gsavelevel > 0; gsavelevel-- )
 		Bprint(Bstdout, "grestore\n");

 }
	#include <u.h>
	#include <libc.h>
	#include <bio.h>
	#include <ctype.h>
	#include "../common/common.h"
	#include "tr2post.h"

	BOOLEAN drawflag = FALSE;
	BOOLEAN inpath = FALSE; /* TRUE if we're putting pieces together */

	void
	cover(double x, double y) {
	}

	void
	drawspline(Biobuf Bp, int flag) { / flag!=1 connect end points */
	int x[100], y[100];
	int i, N;
	/*
	*
	* Spline drawing routine for Postscript printers. The complicated stuff is
	* handled by procedure Ds, which should be defined in the library file. I've
	* seen wrong implementations of troff's spline drawing, so fo the record I'll
	* write down the parametric equations and the necessary conversions to Bezier
	* cubic splines (as used in Postscript).
	*
	*
	* Parametric equation (x coordinate only):
	*
	*
	* (x2 - 2 * x1 + x0) 2 (x0 + x1)
	* x = ------------------ * t + (x1 - x0) * t + ---------
	* 2 2
	*
	*
	* The coefficients in the Bezier cubic are,
	*
	*
	* A = 0
	* B = (x2 - 2 * x1 + x0) / 2
	* C = x1 - x0
	*
	*
	* while the current point is,
	*
	* current-point = (x0 + x1) / 2
	*
	* Using the relationships given in the Postscript manual (page 121) it's easy to
	* see that the control points are given by,
	*
	*
	* x0' = (x0 + 5 * x1) / 6
	* x1' = (x2 + 5 * x1) / 6
	* x2' = (x1 + x2) / 2
	*
	*
	* where the primed variables are the ones used by curveto. The calculations
	* shown above are done in procedure Ds using the coordinates set up in both
	* the x[] and y[] arrays.
	*
	* A simple test of whether your spline drawing is correct would be to use cip
	* to draw a spline and some tangent lines at appropriate points and then print
	* the file.
	*
	*/

	for (N=2; N<sizeof(x)/sizeof(x[0]); N++)
	if (Bgetfield(Bp, 'd', &x[N], 0)<=0 \|\| Bgetfield(Bp, 'd', &y[N], 0)<=0)
	break;

	x[0] = x[1] = hpos;
	y[0] = y[1] = vpos;

	for (i = 1; i < N; i++) {
	x[i+1] += x[i];
	y[i+1] += y[i];
	}

	x[N] = x[N-1];
	y[N] = y[N-1];

	for (i = ((flag!=1)?0:1); i < ((flag!=1)?N-1:N-2); i++) {
	endstring();
	if (pageon())
	Bprint(Bstdout, "%d %d %d %d %d %d Ds\n", x[i], y[i], x[i+1], y[i+1], x[i+2], y[i+2]);
	/* if (dobbox == TRUE) { /* could be better */
	/* cover((double)(x[i] + x[i+1])/2,(double)-(y[i] + y[i+1])/2);
	/* cover((double)x[i+1], (double)-y[i+1]);
	/* cover((double)(x[i+1] + x[i+2])/2, (double)-(y[i+1] + y[i+2])/2);
	/* }
	*/
	}

	hpos = x[N]; /* where troff expects to be */
	vpos = y[N];
	}

	void
	draw(Biobuf *Bp) {

	int r, x1, y1, x2, y2, i;
	int d1, d2;

	drawflag = TRUE;
	r = Bgetrune(Bp);
	switch(r) {
	case 'l':
	if (Bgetfield(Bp, 'd', &x1, 0)<=0 \|\| Bgetfield(Bp, 'd', &y1, 0)<=0 \|\| Bgetfield(Bp, 'r', &i, 0)<=0) {
	error(FATAL, "draw line function, destination coordinates not found.\n");
	return;
	}

	endstring();
	if (pageon())
	Bprint(Bstdout, "%d %d %d %d Dl\n", hpos, vpos, hpos+x1, vpos+y1);
	hpos += x1;
	vpos += y1;
	break;
	case 'c':
	if (Bgetfield(Bp, 'd', &d1, 0)<=0) {
	error(FATAL, "draw circle function, diameter coordinates not found.\n");
	return;
	}

	endstring();
	if (pageon())
	Bprint(Bstdout, "%d %d %d %d De\n", hpos, vpos, d1, d1);
	hpos += d1;
	break;
	case 'e':
	if (Bgetfield(Bp, 'd', &d1, 0)<=0 \|\| Bgetfield(Bp, 'd', &d2, 0)<=0) {
	error(FATAL, "draw ellipse function, diameter coordinates not found.\n");
	return;
	}

	endstring();
	if (pageon())
	Bprint(Bstdout, "%d %d %d %d De\n", hpos, vpos, d1, d2);
	hpos += d1;
	break;
	case 'a':
	if (Bgetfield(Bp, 'd', &x1, 0)<=0 \|\| Bgetfield(Bp, 'd', &y1, 0)<=0 \|\| Bgetfield(Bp, 'd', &x2, 0)<=0 \|\| Bgetfield(Bp, 'd', &y2, 0)<=0) {
	error(FATAL, "draw arc function, coordinates not found.\n");
	return;
	}

	endstring();
	if (pageon())
	Bprint(Bstdout, "%d %d %d %d %d %d Da\n", hpos, vpos, x1, y1, x2, y2);
	hpos += x1 + x2;
	vpos += y1 + y2;
	break;
	case 'q':
	drawspline(Bp, 1);
	break;
	case '~':
	drawspline(Bp, 2);
	break;
	default:
	error(FATAL, "unknown draw function <%c>\n", r);
	return;
	}
	}

	void
	beginpath(char *buf, int copy) {

	/*
	* Called from devcntrl() whenever an "x X BeginPath" command is read. It's used
	* to mark the start of a sequence of drawing commands that should be grouped
	* together and treated as a single path. By default the drawing procedures in
	* *drawfile treat each drawing command as a separate object, and usually start
	* with a newpath (just as a precaution) and end with a stroke. The newpath and
	* stroke isolate individual drawing commands and make it impossible to deal with
	* composite objects. "x X BeginPath" can be used to mark the start of drawing
	* commands that should be grouped together and treated as a single object, and
	* part of what's done here ensures that the PostScript drawing commands defined
	* in *drawfile skip the newpath and stroke, until after the next "x X DrawPath"
	* command. At that point the path that's been built up can be manipulated in
	* various ways (eg. filled and/or stroked with a different line width).
	*
	* Color selection is one of the options that's available in parsebuf(),
	* so if we get here we add *colorfile to the output file before doing
	* anything important.
	*
	*/
	if (inpath == FALSE) {
	endstring();
	/* getdraw(); */
	/* getcolor(); */
	Bprint(Bstdout, "gsave\n");
	Bprint(Bstdout, "newpath\n");
	Bprint(Bstdout, "%d %d m\n", hpos, vpos);
	Bprint(Bstdout, "/inpath true def\n");
	if ( copy == TRUE )
	Bprint(Bstdout, "%s\n", buf);
	inpath = TRUE;
	}
	}

	static void parsebuf(char*);

	void
	drawpath(char *buf, int copy) {

	/*
	*
	* Called from devcntrl() whenever an "x X DrawPath" command is read. It marks the
	* end of the path started by the last "x X BeginPath" command and uses whatever
	* has been passed along in *buf to manipulate the path (eg. fill and/or stroke
	* the path). Once that's been done the drawing procedures are restored to their
	* default behavior in which each drawing command is treated as an isolated path.
	* The new version (called after "x X DrawPath") has copy set to FALSE, and calls
	* parsebuf() to figure out what goes in the output file. It's a feeble attempt
	* to free users and preprocessors (like pic) from having to know PostScript. The
	* comments in parsebuf() describe what's handled.
	*
	* In the early version a path was started with "x X BeginObject" and ended with
	* "x X EndObject". In both cases *buf was just copied to the output file, and
	* was expected to be legitimate PostScript that manipulated the current path.
	* The old escape sequence will be supported for a while (for Ravi), and always
	* call this routine with copy set to TRUE.
	*
	*
	*/

	if ( inpath == TRUE ) {
	if ( copy == TRUE )
	Bprint(Bstdout, "%s\n", buf);
	else
	parsebuf(buf);
	Bprint(Bstdout, "grestore\n");
	Bprint(Bstdout, "/inpath false def\n");
	/* reset(); */
	inpath = FALSE;
	}
	}


	/*****************************************************************************/

	static void
	parsebuf(char *buf)
	{
	char p = (char)0; /* usually the next token */
	char *q;
	int gsavelevel = 0; /* non-zero if we've done a gsave */

	/*
	*
	* Simple minded attempt at parsing the string that followed an "x X DrawPath"
	* command. Everything not recognized here is simply ignored - there's absolutely
	* no error checking and what was originally in buf is clobbered by strtok().
	* A typical *buf might look like,
	*
	* gray .9 fill stroke
	*
	* to fill the current path with a gray level of .9 and follow that by stroking the
	* outline of the path. Since unrecognized tokens are ignored the last example
	* could also be written as,
	*
	* with gray .9 fill then stroke
	*
	* The "with" and "then" strings aren't recognized tokens and are simply discarded.
	* The "stroke", "fill", and "wfill" force out appropriate PostScript code and are
	* followed by a grestore. In otherwords changes to the grahics state (eg. a gray
	* level or color) are reset to default values immediately after the stroke, fill,
	* or wfill tokens. For now "fill" gets invokes PostScript's eofill operator and
	* "wfill" calls fill (ie. the operator that uses the non-zero winding rule).
	*
	* The tokens that cause temporary changes to the graphics state are "gray" (for
	* setting the gray level), "color" (for selecting a known color from the colordict
	* dictionary defined in *colorfile), and "line" (for setting the line width). All
	* three tokens can be extended since strncmp() makes the comparison. For example
	* the strings "line" and "linewidth" accomplish the same thing. Colors are named
	* (eg. "red"), but must be appropriately defined in *colorfile. For now all three
	* tokens must be followed immediately by their single argument. The gray level
	* (ie. the argument that follows "gray") should be a number between 0 and 1, with
	* 0 for black and 1 for white.
	*
	* To pass straight PostScript through enclose the appropriate commands in double
	* quotes. Straight PostScript is only bracketed by the outermost gsave/grestore
	* pair (ie. the one from the initial "x X BeginPath") although that's probably
	* a mistake. Suspect I may have to change the double quote delimiters.
	*
	*/

	for( ; p != nil ; p = q ) {
	if( q = strchr(p, ' ') ) {
	*q++ = '\0';
	}

	if ( gsavelevel == 0 ) {
	Bprint(Bstdout, "gsave\n");
	gsavelevel++;
	}
	if ( strcmp(p, "stroke") == 0 ) {
	Bprint(Bstdout, "closepath stroke\ngrestore\n");
	gsavelevel--;
	} else if ( strcmp(p, "openstroke") == 0 ) {
	Bprint(Bstdout, "stroke\ngrestore\n");
	gsavelevel--;
	} else if ( strcmp(p, "fill") == 0 ) {
	Bprint(Bstdout, "eofill\ngrestore\n");
	gsavelevel--;
	} else if ( strcmp(p, "wfill") == 0 ) {
	Bprint(Bstdout, "fill\ngrestore\n");
	gsavelevel--;
	} else if ( strcmp(p, "sfill") == 0 ) {
	Bprint(Bstdout, "eofill\ngrestore\ngsave\nstroke\ngrestore\n");
	gsavelevel--;
	} else if ( strncmp(p, "gray", strlen("gray")) == 0 ) {
	if( q ) {
	p = q;
	if ( q = strchr(p, ' ') )
	*q++ = '\0';
	Bprint(Bstdout, "%s setgray\n", p);
	}
	} else if ( strncmp(p, "color", strlen("color")) == 0 ) {
	if( q ) {
	p = q;
	if ( q = strchr(p, ' ') )
	*q++ = '\0';
	Bprint(Bstdout, "/%s setcolor\n", p);
	}
	} else if ( strncmp(p, "line", strlen("line")) == 0 ) {
	if( q ) {
	p = q;
	if ( q = strchr(p, ' ') )
	*q++ = '\0';
	Bprint(Bstdout, "%s resolution mul 2 div setlinewidth\n", p);
	}
	} else if ( strncmp(p, "reverse", strlen("reverse")) == 0 )
	Bprint(Bstdout, "reversepath\n");
	else if ( *p == '"' ) {
	for ( ; gsavelevel > 0; gsavelevel-- )
	Bprint(Bstdout, "grestore\n");
	if ( q != nil )
	*--q = ' ';
	if ( (q = strchr(p, '"')) != nil ) {
	*q++ = '\0';
	Bprint(Bstdout, "%s\n", p);
	}
	}
	}

	for ( ; gsavelevel > 0; gsavelevel-- )
	Bprint(Bstdout, "grestore\n");

	}