/* $OpenBSD: display.c,v 1.36 2008/06/11 19:35:37 kjell Exp $ */ /* This file is in the public domain. */ /* * The functions in this file handle redisplay. The * redisplay system knows almost nothing about the editing * process; the editing functions do, however, set some * hints to eliminate a lot of the grinding. There is more * that can be done; the "vtputc" interface is a real * pig. */ #include "def.h" #include "kbd.h" #include /* * You can change these back to the types * implied by the name if you get tight for space. If you * make both of them "int" you get better code on the VAX. * They do nothing if this is not Gosling redisplay, except * for change the size of a structure that isn't used. * A bit of a cheat. */ #define XCHAR int #define XSHORT int #ifdef STANDOUT_GLITCH #include #endif /* * A video structure always holds * an array of characters whose length is equal to * the longest line possible. v_text is allocated * dynamically to fit the screen width. */ struct video { short v_hash; /* Hash code, for compares. */ short v_flag; /* Flag word. */ short v_color; /* Color of the line. */ XSHORT v_cost; /* Cost of display. */ char *v_text; /* The actual characters. */ }; #define VFCHG 0x0001 /* Changed. */ #define VFHBAD 0x0002 /* Hash and cost are bad. */ #define VFEXT 0x0004 /* extended line (beond ncol) */ /* * SCORE structures hold the optimal * trace trajectory, and the cost of redisplay, when * the dynamic programming redisplay code is used. * If no fancy redisplay, this isn't used. The trace index * fields can be "char", and the cost a "short", but * this makes the code worse on the VAX. */ struct score { XCHAR s_itrace; /* "i" index for track back. */ XCHAR s_jtrace; /* "j" index for trace back. */ XSHORT s_cost; /* Display cost. */ }; void vtmove(int, int); void vtputc(int); void vtpute(int); int vtputs(const char *); void vteeol(void); void updext(int, int); void modeline(struct mgwin *); void setscores(int, int); void traceback(int, int, int, int); void ucopy(struct video *, struct video *); void uline(int, struct video *, struct video *); void hash(struct video *); int sgarbf = TRUE; /* TRUE if screen is garbage. */ int vtrow = HUGE; /* Virtual cursor row. */ int vtcol = HUGE; /* Virtual cursor column. */ int tthue = CNONE; /* Current color. */ int ttrow = HUGE; /* Physical cursor row. */ int ttcol = HUGE; /* Physical cursor column. */ int tttop = HUGE; /* Top of scroll region. */ int ttbot = HUGE; /* Bottom of scroll region. */ int lbound = 0; /* leftmost bound of the current */ /* line being displayed */ struct video **vscreen; /* Edge vector, virtual. */ struct video **pscreen; /* Edge vector, physical. */ struct video *video; /* Actual screen data. */ struct video blanks; /* Blank line image. */ /* * This matrix is written as an array because * we do funny things in the "setscores" routine, which * is very compute intensive, to make the subscripts go away. * It would be "SCORE score[NROW][NROW]" in old speak. * Look at "setscores" to understand what is up. */ struct score *score; /* [NROW * NROW] */ #ifndef LINENOMODE #define LINENOMODE TRUE #endif /* !LINENOMODE */ static int linenos = LINENOMODE; /* Is macro recording enabled? */ extern int macrodef; /* Is working directory global? */ extern int globalwd; /* * Since we don't have variables (we probably should) these are command * processors for changing the values of mode flags. */ /* ARGSUSED */ int linenotoggle(int f, int n) { if (f & FFARG) linenos = n > 0; else linenos = !linenos; sgarbf = TRUE; return (TRUE); } /* * Reinit the display data structures, this is called when the terminal * size changes. */ int vtresize(int force, int newrow, int newcol) { int i; int rowchanged, colchanged; static int first_run = 1; struct video *vp; if (newrow < 1 || newcol < 1) return (FALSE); rowchanged = (newrow != nrow); colchanged = (newcol != ncol); #define TRYREALLOC(a, n) do { \ void *tmp; \ if ((tmp = realloc((a), (n))) == NULL) { \ panic("out of memory in display code"); \ } \ (a) = tmp; \ } while (0) /* No update needed */ if (!first_run && !force && !rowchanged && !colchanged) return (TRUE); if (first_run) memset(&blanks, 0, sizeof(blanks)); if (rowchanged || first_run) { int vidstart; /* * This is not pretty. */ if (nrow == 0) vidstart = 0; else vidstart = 2 * (nrow - 1); /* * We're shrinking, free some internal data. */ if (newrow < nrow) { for (i = 2 * (newrow - 1); i < 2 * (nrow - 1); i++) { free(video[i].v_text); video[i].v_text = NULL; } } TRYREALLOC(score, newrow * newrow * sizeof(struct score)); TRYREALLOC(vscreen, (newrow - 1) * sizeof(struct video *)); TRYREALLOC(pscreen, (newrow - 1) * sizeof(struct video *)); TRYREALLOC(video, (2 * (newrow - 1)) * sizeof(struct video)); /* * Zero-out the entries we just allocated. */ for (i = vidstart; i < 2 * (newrow - 1); i++) memset(&video[i], 0, sizeof(struct video)); /* * Reinitialize vscreen and pscreen arrays completely. */ vp = &video[0]; for (i = 0; i < newrow - 1; ++i) { vscreen[i] = vp; ++vp; pscreen[i] = vp; ++vp; } } if (rowchanged || colchanged || first_run) { for (i = 0; i < 2 * (newrow - 1); i++) TRYREALLOC(video[i].v_text, newcol * sizeof(char)); TRYREALLOC(blanks.v_text, newcol * sizeof(char)); } nrow = newrow; ncol = newcol; if (ttrow > nrow) ttrow = nrow; if (ttcol > ncol) ttcol = ncol; first_run = 0; return (TRUE); } #undef TRYREALLOC /* * Initialize the data structures used * by the display code. The edge vectors used * to access the screens are set up. The operating * system's terminal I/O channel is set up. Fill the * "blanks" array with ASCII blanks. The rest is done * at compile time. The original window is marked * as needing full update, and the physical screen * is marked as garbage, so all the right stuff happens * on the first call to redisplay. */ void vtinit(void) { int i; ttopen(); ttinit(); /* * ttinit called ttresize(), which called vtresize(), so our data * structures are setup correctly. */ blanks.v_color = CTEXT; for (i = 0; i < ncol; ++i) blanks.v_text[i] = ' '; } /* * Tidy up the virtual display system * in anticipation of a return back to the host * operating system. Right now all we do is position * the cursor to the last line, erase the line, and * close the terminal channel. */ void vttidy(void) { ttcolor(CTEXT); ttnowindow(); /* No scroll window. */ ttmove(nrow - 1, 0); /* Echo line. */ tteeol(); tttidy(); ttflush(); ttclose(); } /* * Move the virtual cursor to an origin * 0 spot on the virtual display screen. I could * store the column as a character pointer to the spot * on the line, which would make "vtputc" a little bit * more efficient. No checking for errors. */ void vtmove(int row, int col) { vtrow = row; vtcol = col; } /* * Write a character to the virtual display, * dealing with long lines and the display of unprintable * things like control characters. Also expand tabs every 8 * columns. This code only puts printing characters into * the virtual display image. Special care must be taken when * expanding tabs. On a screen whose width is not a multiple * of 8, it is possible for the virtual cursor to hit the * right margin before the next tab stop is reached. This * makes the tab code loop if you are not careful. * Three guesses how we found this. */ void vtputc(int c) { struct video *vp; c &= 0xff; vp = vscreen[vtrow]; if (vtcol >= ncol) vp->v_text[ncol - 1] = '$'; else if (c == '\t' #ifdef NOTAB && !(curbp->b_flag & BFNOTAB) #endif ) { do { vtputc(' '); } while (vtcol < ncol && (vtcol & 0x07) != 0); } else if (ISCTRL(c)) { vtputc('^'); vtputc(CCHR(c)); } else if (isprint(c)) vp->v_text[vtcol++] = c; else { char bf[5]; snprintf(bf, sizeof(bf), "\\%o", c); vtputs(bf); } } /* * Put a character to the virtual screen in an extended line. If we are not * yet on left edge, don't print it yet. Check for overflow on the right * margin. */ void vtpute(int c) { struct video *vp; c &= 0xff; vp = vscreen[vtrow]; if (vtcol >= ncol) vp->v_text[ncol - 1] = '$'; else if (c == '\t' #ifdef NOTAB && !(curbp->b_flag & BFNOTAB) #endif ) { do { vtpute(' '); } while (((vtcol + lbound) & 0x07) != 0 && vtcol < ncol); } else if (ISCTRL(c) != FALSE) { vtpute('^'); vtpute(CCHR(c)); } else { if (vtcol >= 0) vp->v_text[vtcol] = c; ++vtcol; } } /* * Erase from the end of the software cursor to the end of the line on which * the software cursor is located. The display routines will decide if a * hardware erase to end of line command should be used to display this. */ void vteeol(void) { struct video *vp; vp = vscreen[vtrow]; while (vtcol < ncol) vp->v_text[vtcol++] = ' '; } /* * Make sure that the display is * right. This is a three part process. First, * scan through all of the windows looking for dirty * ones. Check the framing, and refresh the screen. * Second, make sure that "currow" and "curcol" are * correct for the current window. Third, make the * virtual and physical screens the same. */ void update(void) { struct line *lp; struct mgwin *wp; struct video *vp1; struct video *vp2; int c, i, j; int hflag; int currow, curcol; int offs, size; if (charswaiting()) return; if (sgarbf) { /* must update everything */ wp = wheadp; while (wp != NULL) { wp->w_flag |= WFMODE | WFFULL; wp = wp->w_wndp; } } if (linenos) { wp = wheadp; while (wp != NULL) { wp->w_flag |= WFMODE; wp = wp->w_wndp; } } hflag = FALSE; /* Not hard. */ for (wp = wheadp; wp != NULL; wp = wp->w_wndp) { /* * Nothing to be done. */ if (wp->w_flag == 0) continue; if ((wp->w_flag & WFFRAME) == 0) { lp = wp->w_linep; for (i = 0; i < wp->w_ntrows; ++i) { if (lp == wp->w_dotp) goto out; if (lp == wp->w_bufp->b_headp) break; lp = lforw(lp); } } /* * Put the middle-line in place. */ i = wp->w_frame; if (i > 0) { --i; if (i >= wp->w_ntrows) i = wp->w_ntrows - 1; } else if (i < 0) { i += wp->w_ntrows; if (i < 0) i = 0; } else i = wp->w_ntrows / 2; /* current center, no change */ /* * Find the line. */ lp = wp->w_dotp; while (i != 0 && lback(lp) != wp->w_bufp->b_headp) { --i; lp = lback(lp); } wp->w_linep = lp; wp->w_flag |= WFFULL; /* Force full. */ out: lp = wp->w_linep; /* Try reduced update. */ i = wp->w_toprow; if ((wp->w_flag & ~WFMODE) == WFEDIT) { while (lp != wp->w_dotp) { ++i; lp = lforw(lp); } vscreen[i]->v_color = CTEXT; vscreen[i]->v_flag |= (VFCHG | VFHBAD); vtmove(i, 0); for (j = 0; j < llength(lp); ++j) vtputc(lgetc(lp, j)); vteeol(); } else if ((wp->w_flag & (WFEDIT | WFFULL)) != 0) { hflag = TRUE; while (i < wp->w_toprow + wp->w_ntrows) { vscreen[i]->v_color = CTEXT; vscreen[i]->v_flag |= (VFCHG | VFHBAD); vtmove(i, 0); if (lp != wp->w_bufp->b_headp) { for (j = 0; j < llength(lp); ++j) vtputc(lgetc(lp, j)); lp = lforw(lp); } vteeol(); ++i; } } if ((wp->w_flag & WFMODE) != 0) modeline(wp); wp->w_flag = 0; wp->w_frame = 0; } lp = curwp->w_linep; /* Cursor location. */ currow = curwp->w_toprow; while (lp != curwp->w_dotp) { ++currow; lp = lforw(lp); } curcol = 0; i = 0; while (i < curwp->w_doto) { c = lgetc(lp, i++); if (c == '\t' #ifdef NOTAB && !(curbp->b_flag & BFNOTAB) #endif ) { curcol |= 0x07; curcol++; } else if (ISCTRL(c) != FALSE) curcol += 2; else if (isprint(c)) curcol++; else { char bf[5]; snprintf(bf, sizeof(bf), "\\%o", c); curcol += strlen(bf); } } if (curcol >= ncol - 1) { /* extended line. */ /* flag we are extended and changed */ vscreen[currow]->v_flag |= VFEXT | VFCHG; updext(currow, curcol); /* and output extended line */ } else lbound = 0; /* not extended line */ /* * Make sure no lines need to be de-extended because the cursor is no * longer on them. */ wp = wheadp; while (wp != NULL) { lp = wp->w_linep; i = wp->w_toprow; while (i < wp->w_toprow + wp->w_ntrows) { if (vscreen[i]->v_flag & VFEXT) { /* always flag extended lines as changed */ vscreen[i]->v_flag |= VFCHG; if ((wp != curwp) || (lp != wp->w_dotp) || (curcol < ncol - 1)) { vtmove(i, 0); for (j = 0; j < llength(lp); ++j) vtputc(lgetc(lp, j)); vteeol(); /* this line no longer is extended */ vscreen[i]->v_flag &= ~VFEXT; } } lp = lforw(lp); ++i; } /* if garbaged then fix up mode lines */ if (sgarbf != FALSE) vscreen[i]->v_flag |= VFCHG; /* and onward to the next window */ wp = wp->w_wndp; } if (sgarbf != FALSE) { /* Screen is garbage. */ sgarbf = FALSE; /* Erase-page clears. */ epresf = FALSE; /* The message area. */ tttop = HUGE; /* Forget where you set. */ ttbot = HUGE; /* scroll region. */ tthue = CNONE; /* Color unknown. */ ttmove(0, 0); tteeop(); for (i = 0; i < nrow - 1; ++i) { uline(i, vscreen[i], &blanks); ucopy(vscreen[i], pscreen[i]); } ttmove(currow, curcol - lbound); ttflush(); return; } if (hflag != FALSE) { /* Hard update? */ for (i = 0; i < nrow - 1; ++i) {/* Compute hash data. */ hash(vscreen[i]); hash(pscreen[i]); } offs = 0; /* Get top match. */ while (offs != nrow - 1) { vp1 = vscreen[offs]; vp2 = pscreen[offs]; if (vp1->v_color != vp2->v_color || vp1->v_hash != vp2->v_hash) break; uline(offs, vp1, vp2); ucopy(vp1, vp2); ++offs; } if (offs == nrow - 1) { /* Might get it all. */ ttmove(currow, curcol - lbound); ttflush(); return; } size = nrow - 1; /* Get bottom match. */ while (size != offs) { vp1 = vscreen[size - 1]; vp2 = pscreen[size - 1]; if (vp1->v_color != vp2->v_color || vp1->v_hash != vp2->v_hash) break; uline(size - 1, vp1, vp2); ucopy(vp1, vp2); --size; } if ((size -= offs) == 0) /* Get screen size. */ panic("Illegal screen size in update"); setscores(offs, size); /* Do hard update. */ traceback(offs, size, size, size); for (i = 0; i < size; ++i) ucopy(vscreen[offs + i], pscreen[offs + i]); ttmove(currow, curcol - lbound); ttflush(); return; } for (i = 0; i < nrow - 1; ++i) { /* Easy update. */ vp1 = vscreen[i]; vp2 = pscreen[i]; if ((vp1->v_flag & VFCHG) != 0) { uline(i, vp1, vp2); ucopy(vp1, vp2); } } ttmove(currow, curcol - lbound); ttflush(); } /* * Update a saved copy of a line, * kept in a video structure. The "vvp" is * the one in the "vscreen". The "pvp" is the one * in the "pscreen". This is called to make the * virtual and physical screens the same when * display has done an update. */ void ucopy(struct video *vvp, struct video *pvp) { vvp->v_flag &= ~VFCHG; /* Changes done. */ pvp->v_flag = vvp->v_flag; /* Update model. */ pvp->v_hash = vvp->v_hash; pvp->v_cost = vvp->v_cost; pvp->v_color = vvp->v_color; bcopy(vvp->v_text, pvp->v_text, ncol); } /* * updext: update the extended line which the cursor is currently on at a * column greater than the terminal width. The line will be scrolled right or * left to let the user see where the cursor is. */ void updext(int currow, int curcol) { struct line *lp; /* pointer to current line */ int j; /* index into line */ if (ncol < 2) return; /* * calculate what column the left bound should be * (force cursor into middle half of screen) */ lbound = curcol - (curcol % (ncol >> 1)) - (ncol >> 2); /* * scan through the line outputing characters to the virtual screen * once we reach the left edge */ vtmove(currow, -lbound); /* start scanning offscreen */ lp = curwp->w_dotp; /* line to output */ for (j = 0; j < llength(lp); ++j) /* until the end-of-line */ vtpute(lgetc(lp, j)); vteeol(); /* truncate the virtual line */ vscreen[currow]->v_text[0] = '$'; /* and put a '$' in column 1 */ } /* * Update a single line. This routine only * uses basic functionality (no insert and delete character, * but erase to end of line). The "vvp" points at the video * structure for the line on the virtual screen, and the "pvp" * is the same for the physical screen. Avoid erase to end of * line when updating CMODE color lines, because of the way that * reverse video works on most terminals. */ void uline(int row, struct video *vvp, struct video *pvp) { char *cp1; char *cp2; char *cp3; char *cp4; char *cp5; int nbflag; if (vvp->v_color != pvp->v_color) { /* Wrong color, do a */ ttmove(row, 0); /* full redraw. */ #ifdef STANDOUT_GLITCH if (pvp->v_color != CTEXT && magic_cookie_glitch >= 0) tteeol(); #endif ttcolor(vvp->v_color); #ifdef STANDOUT_GLITCH cp1 = &vvp->v_text[magic_cookie_glitch > 0 ? magic_cookie_glitch : 0]; /* * The odd code for magic_cookie_glitch==0 is to avoid * putting the invisible glitch character on the next line. * (Hazeltine executive 80 model 30) */ cp2 = &vvp->v_text[ncol - (magic_cookie_glitch >= 0 ? (magic_cookie_glitch != 0 ? magic_cookie_glitch : 1) : 0)]; #else cp1 = &vvp->v_text[0]; cp2 = &vvp->v_text[ncol]; #endif while (cp1 != cp2) { ttputc(*cp1++); ++ttcol; } #ifndef MOVE_STANDOUT ttcolor(CTEXT); #endif return; } cp1 = &vvp->v_text[0]; /* Compute left match. */ cp2 = &pvp->v_text[0]; while (cp1 != &vvp->v_text[ncol] && cp1[0] == cp2[0]) { ++cp1; ++cp2; } if (cp1 == &vvp->v_text[ncol]) /* All equal. */ return; nbflag = FALSE; cp3 = &vvp->v_text[ncol]; /* Compute right match. */ cp4 = &pvp->v_text[ncol]; while (cp3[-1] == cp4[-1]) { --cp3; --cp4; if (cp3[0] != ' ') /* Note non-blanks in */ nbflag = TRUE; /* the right match. */ } cp5 = cp3; /* Is erase good? */ if (nbflag == FALSE && vvp->v_color == CTEXT) { while (cp5 != cp1 && cp5[-1] == ' ') --cp5; /* Alcyon hack */ if ((int) (cp3 - cp5) <= tceeol) cp5 = cp3; } /* Alcyon hack */ ttmove(row, (int) (cp1 - &vvp->v_text[0])); #ifdef STANDOUT_GLITCH if (vvp->v_color != CTEXT && magic_cookie_glitch > 0) { if (cp1 < &vvp->v_text[magic_cookie_glitch]) cp1 = &vvp->v_text[magic_cookie_glitch]; if (cp5 > &vvp->v_text[ncol - magic_cookie_glitch]) cp5 = &vvp->v_text[ncol - magic_cookie_glitch]; } else if (magic_cookie_glitch < 0) #endif ttcolor(vvp->v_color); while (cp1 != cp5) { ttputc(*cp1++); ++ttcol; } if (cp5 != cp3) /* Do erase. */ tteeol(); } /* * Redisplay the mode line for the window pointed to by the "wp". * This is the only routine that has any idea of how the mode line is * formatted. You can change the modeline format by hacking at this * routine. Called by "update" any time there is a dirty window. Note * that if STANDOUT_GLITCH is defined, first and last magic_cookie_glitch * characters may never be seen. */ void modeline(struct mgwin *wp) { int n, md; struct buffer *bp; char sl[21]; /* Overkill. Space for 2^64 in base 10. */ int len; n = wp->w_toprow + wp->w_ntrows; /* Location. */ vscreen[n]->v_color = CMODE; /* Mode line color. */ vscreen[n]->v_flag |= (VFCHG | VFHBAD); /* Recompute, display. */ vtmove(n, 0); /* Seek to right line. */ bp = wp->w_bufp; vtputc('-'); vtputc('-'); if ((bp->b_flag & BFREADONLY) != 0) { vtputc('%'); if ((bp->b_flag & BFCHG) != 0) vtputc('*'); else vtputc('%'); } else if ((bp->b_flag & BFCHG) != 0) { /* "*" if changed. */ vtputc('*'); vtputc('*'); } else { vtputc('-'); vtputc('-'); } vtputc('-'); n = 5; n += vtputs("Mg: "); if (bp->b_bname[0] != '\0') n += vtputs(&(bp->b_bname[0])); while (n < 42) { /* Pad out with blanks. */ vtputc(' '); ++n; } vtputc('('); ++n; for (md = 0; ; ) { n += vtputs(bp->b_modes[md]->p_name); if (++md > bp->b_nmodes) break; vtputc('-'); ++n; } /* XXX These should eventually move to a real mode */ if (macrodef == TRUE) n += vtputs("-def"); if (globalwd == TRUE) n += vtputs("-gwd"); vtputc(')'); ++n; if (linenos) { len = snprintf(sl, sizeof(sl), "--L%d--C%d", wp->w_dotline, getcolpos()); if (len < sizeof(sl) && len != -1) n += vtputs(sl); } while (n < ncol) { /* Pad out. */ vtputc('-'); ++n; } } /* * Output a string to the mode line, report how long it was. */ int vtputs(const char *s) { int n = 0; while (*s != '\0') { vtputc(*s++); ++n; } return (n); } /* * Compute the hash code for the line pointed to by the "vp". * Recompute it if necessary. Also set the approximate redisplay * cost. The validity of the hash code is marked by a flag bit. * The cost understand the advantages of erase to end of line. * Tuned for the VAX by Bob McNamara; better than it used to be on * just about any machine. */ void hash(struct video *vp) { int i, n; char *s; if ((vp->v_flag & VFHBAD) != 0) { /* Hash bad. */ s = &vp->v_text[ncol - 1]; for (i = ncol; i != 0; --i, --s) if (*s != ' ') break; n = ncol - i; /* Erase cheaper? */ if (n > tceeol) n = tceeol; vp->v_cost = i + n; /* Bytes + blanks. */ for (n = 0; i != 0; --i, --s) n = (n << 5) + n + *s; vp->v_hash = n; /* Hash code. */ vp->v_flag &= ~VFHBAD; /* Flag as all done. */ } } /* * Compute the Insert-Delete * cost matrix. The dynamic programming algorithm * described by James Gosling is used. This code assumes * that the line above the echo line is the last line involved * in the scroll region. This is easy to arrange on the VT100 * because of the scrolling region. The "offs" is the origin 0 * offset of the first row in the virtual/physical screen that * is being updated; the "size" is the length of the chunk of * screen being updated. For a full screen update, use offs=0 * and size=nrow-1. * * Older versions of this code implemented the score matrix by * a two dimensional array of SCORE nodes. This put all kinds of * multiply instructions in the code! This version is written to * use a linear array and pointers, and contains no multiplication * at all. The code has been carefully looked at on the VAX, with * only marginal checking on other machines for efficiency. In * fact, this has been tuned twice! Bob McNamara tuned it even * more for the VAX, which is a big issue for him because of * the 66 line X displays. * * On some machines, replacing the "for (i=1; i<=size; ++i)" with * i = 1; do { } while (++i <=size)" will make the code quite a * bit better; but it looks ugly. */ void setscores(int offs, int size) { struct score *sp; struct score *sp1; struct video **vp, **pp; struct video **vbase, **pbase; int tempcost; int bestcost; int j, i; vbase = &vscreen[offs - 1]; /* By hand CSE's. */ pbase = &pscreen[offs - 1]; score[0].s_itrace = 0; /* [0, 0] */ score[0].s_jtrace = 0; score[0].s_cost = 0; sp = &score[1]; /* Row 0, inserts. */ tempcost = 0; vp = &vbase[1]; for (j = 1; j <= size; ++j) { sp->s_itrace = 0; sp->s_jtrace = j - 1; tempcost += tcinsl; tempcost += (*vp)->v_cost; sp->s_cost = tempcost; ++vp; ++sp; } sp = &score[nrow]; /* Column 0, deletes. */ tempcost = 0; for (i = 1; i <= size; ++i) { sp->s_itrace = i - 1; sp->s_jtrace = 0; tempcost += tcdell; sp->s_cost = tempcost; sp += nrow; } sp1 = &score[nrow + 1]; /* [1, 1]. */ pp = &pbase[1]; for (i = 1; i <= size; ++i) { sp = sp1; vp = &vbase[1]; for (j = 1; j <= size; ++j) { sp->s_itrace = i - 1; sp->s_jtrace = j; bestcost = (sp - nrow)->s_cost; if (j != size) /* Cd(A[i])=0 @ Dis. */ bestcost += tcdell; tempcost = (sp - 1)->s_cost; tempcost += (*vp)->v_cost; if (i != size) /* Ci(B[j])=0 @ Dsj. */ tempcost += tcinsl; if (tempcost < bestcost) { sp->s_itrace = i; sp->s_jtrace = j - 1; bestcost = tempcost; } tempcost = (sp - nrow - 1)->s_cost; if ((*pp)->v_color != (*vp)->v_color || (*pp)->v_hash != (*vp)->v_hash) tempcost += (*vp)->v_cost; if (tempcost < bestcost) { sp->s_itrace = i - 1; sp->s_jtrace = j - 1; bestcost = tempcost; } sp->s_cost = bestcost; ++sp; /* Next column. */ ++vp; } ++pp; sp1 += nrow; /* Next row. */ } } /* * Trace back through the dynamic programming cost * matrix, and update the screen using an optimal sequence * of redraws, insert lines, and delete lines. The "offs" is * the origin 0 offset of the chunk of the screen we are about to * update. The "i" and "j" are always started in the lower right * corner of the matrix, and imply the size of the screen. * A full screen traceback is called with offs=0 and i=j=nrow-1. * There is some do-it-yourself double subscripting here, * which is acceptable because this routine is much less compute * intensive then the code that builds the score matrix! */ void traceback(int offs, int size, int i, int j) { int itrace, jtrace; int k; int ninsl, ndraw, ndell; if (i == 0 && j == 0) /* End of update. */ return; itrace = score[(nrow * i) + j].s_itrace; jtrace = score[(nrow * i) + j].s_jtrace; if (itrace == i) { /* [i, j-1] */ ninsl = 0; /* Collect inserts. */ if (i != size) ninsl = 1; ndraw = 1; while (itrace != 0 || jtrace != 0) { if (score[(nrow * itrace) + jtrace].s_itrace != itrace) break; jtrace = score[(nrow * itrace) + jtrace].s_jtrace; if (i != size) ++ninsl; ++ndraw; } traceback(offs, size, itrace, jtrace); if (ninsl != 0) { ttcolor(CTEXT); ttinsl(offs + j - ninsl, offs + size - 1, ninsl); } do { /* B[j], A[j] blank. */ k = offs + j - ndraw; uline(k, vscreen[k], &blanks); } while (--ndraw); return; } if (jtrace == j) { /* [i-1, j] */ ndell = 0; /* Collect deletes. */ if (j != size) ndell = 1; while (itrace != 0 || jtrace != 0) { if (score[(nrow * itrace) + jtrace].s_jtrace != jtrace) break; itrace = score[(nrow * itrace) + jtrace].s_itrace; if (j != size) ++ndell; } if (ndell != 0) { ttcolor(CTEXT); ttdell(offs + i - ndell, offs + size - 1, ndell); } traceback(offs, size, itrace, jtrace); return; } traceback(offs, size, itrace, jtrace); k = offs + j - 1; uline(k, vscreen[k], pscreen[offs + i - 1]); }