#include "phylip.h" #include "seq.h" /* version 3.6 (c) Copyright 1993-2002 by the University of Washington. Written by Joseph Felsenstein, Akiko Fuseki, Sean Lamont, and Andrew Keeffe. Permission is granted to copy and use this program provided no fee is charged for it and provided that this copyright notice is not removed. */ #define MAXNUMTREES 1000000 /* bigger than number of user trees can be */ extern sequence y; #ifndef OLDC /* function prototypes */ void getoptions(void); void allocrest(void); void reallocchars(void); void doinit(void); void makeweights(void); void doinput(void); void initdnaparsnode(node **, node **, node *, long, long, long *, long *, initops, pointarray, pointarray, Char *, Char *, FILE *); void evaluate(node *); void tryadd(node *, node *, node *); void addpreorder(node *, node *, node *); void trydescendants(node *, node *, node *, node *, boolean); void trylocal(node *, node *); void trylocal2(node *, node *, node *); void tryrearr(node *, boolean *); void repreorder(node *, boolean *); void rearrange(node **); void describe(void); void dnapars_coordinates(node *, double, long *, double *); void dnapars_printree(void); void globrearrange(void); void grandrearr(void); void maketree(void); void freerest(void); void load_tree(long treei); /* function prototypes */ #endif Char infilename[FNMLNGTH], outfilename[FNMLNGTH], intreename[FNMLNGTH], outtreename[FNMLNGTH], weightfilename[FNMLNGTH]; char basechar[32]="ACMGRSVTWYHKDBNO???????????????"; node *root; long chars, col, msets, ith, njumble, jumb, maxtrees; /* chars = number of sites in actual sequences */ long inseed, inseed0; double threshold; boolean jumble, usertree, thresh, weights, thorough, rearrfirst, trout, progress, stepbox, ancseq, mulsets, justwts, firstset, mulf, global_multf; steptr oldweight; longer seed; pointarray treenode; /* pointers to all nodes in tree */ long *enterorder; long *zeros; /* local variables for Pascal maketree, propagated globally for C version: */ long minwhich; double like, minsteps, bestyet, bestlike, bstlike2; boolean lastrearr, recompute; double nsteps[maxuser]; long **fsteps; node *there, *oldnufork; long *place; bestelm *bestrees; long *threshwt; baseptr nothing; gbases *garbage; node *temp, *temp1, *temp2, *tempsum, *temprm, *tempadd, *tempf, *tmp, *tmp1, *tmp2, *tmp3, *tmprm, *tmpadd; boolean *names; node *grbg; char *progname; void getoptions() { /* interactively set options */ long loopcount, loopcount2; Char ch, ch2; fprintf(outfile, "\nDNA parsimony algorithm, version %s\n\n",VERSION); jumble = false; njumble = 1; outgrno = 1; outgropt = false; thresh = false; thorough = true; transvp = false; rearrfirst = false; maxtrees = 10000; trout = true; usertree = false; weights = false; mulsets = false; printdata = false; progress = true; treeprint = true; stepbox = false; ancseq = false; dotdiff = true; interleaved = true; loopcount = 0; for (;;) { cleerhome(); printf("\nDNA parsimony algorithm, version %s\n\n",VERSION); printf("Setting for this run:\n"); printf(" U Search for best tree? %s\n", (usertree ? "No, use user trees in input file" : "Yes")); if (!usertree) { printf(" S Search option? "); if (thorough) printf("More thorough search\n"); else if (rearrfirst) printf("Rearrange on one best tree\n"); else printf("Less thorough\n"); printf(" V Number of trees to save? %ld\n", maxtrees); printf(" J Randomize input order of sequences?"); if (jumble) printf(" Yes (seed =%8ld,%3ld times)\n", inseed0, njumble); else printf(" No. Use input order\n"); } printf(" O Outgroup root?"); if (outgropt) printf(" Yes, at sequence number%3ld\n", outgrno); else printf(" No, use as outgroup species%3ld\n", outgrno); printf(" T Use Threshold parsimony?"); if (thresh) printf(" Yes, count steps up to%4.1f per site\n", threshold); else printf(" No, use ordinary parsimony\n"); printf(" N Use Transversion parsimony?"); if (transvp) printf(" Yes, count only transversions\n"); else printf(" No, count all steps\n"); printf(" W Sites weighted? %s\n", (weights ? "Yes" : "No")); printf(" M Analyze multiple data sets?"); if (mulsets) printf(" Yes, %2ld %s\n", msets, (justwts ? "sets of weights" : "data sets")); else printf(" No\n"); printf(" I Input sequences interleaved? %s\n", (interleaved ? "Yes" : "No, sequential")); printf(" 0 Terminal type (IBM PC, ANSI, none)? %s\n", ibmpc ? "IBM PC" : ansi ? "ANSI" : "(none)"); printf(" 1 Print out the data at start of run %s\n", (printdata ? "Yes" : "No")); printf(" 2 Print indications of progress of run %s\n", progress ? "Yes" : "No"); printf(" 3 Print out tree %s\n", treeprint ? "Yes" : "No"); printf(" 4 Print out steps in each site %s\n", stepbox ? "Yes" : "No"); printf(" 5 Print sequences at all nodes of tree %s\n", ancseq ? "Yes" : "No"); if (ancseq || printdata) printf(" . Use dot-differencing to display them %s\n", dotdiff ? "Yes" : "No"); printf(" 6 Write out trees onto tree file? %s\n", trout ? "Yes" : "No"); printf("\n Y to accept these or type the letter for one to change\n"); #ifdef WIN32 phyFillScreenColor(); #endif scanf("%c%*[^\n]", &ch); getchar(); if (ch == '\n') ch = ' '; uppercase(&ch); if (ch == 'Y') break; if (strchr("WSVJOTNUMI12345.60",ch) != NULL){ switch (ch) { case 'J': jumble = !jumble; if (jumble) initjumble(&inseed, &inseed0, seed, &njumble); else njumble = 1; break; case 'O': outgropt = !outgropt; if (outgropt) initoutgroup(&outgrno, spp); break; case 'T': thresh = !thresh; if (thresh) initthreshold(&threshold); break; case 'N': transvp = !transvp; break; case 'W': weights = !weights; break; case 'M': mulsets = !mulsets; if (mulsets) { printf("Multiple data sets or multiple weights?"); loopcount2 = 0; do { printf(" (type D or W)\n"); #ifdef WIN32 phyFillScreenColor(); #endif scanf("%c%*[^\n]", &ch2); getchar(); if (ch2 == '\n') ch2 = ' '; uppercase(&ch2); countup(&loopcount2, 10); } while ((ch2 != 'W') && (ch2 != 'D')); justwts = (ch2 == 'W'); if (justwts) justweights(&msets); else initdatasets(&msets); if (!jumble) { jumble = true; initjumble(&inseed, &inseed0, seed, &njumble); } } break; case 'U': usertree = !usertree; break; case 'S': thorough = !thorough; if (!thorough) printf("Rearrange on just one best tree?"); loopcount2 = 0; do { printf(" (type Y or N)\n"); #ifdef WIN32 phyFillScreenColor(); #endif scanf("%c%*[^\n]", &ch2); getchar(); if (ch2 == '\n') ch2 = ' '; uppercase(&ch2); countup(&loopcount2, 10); } while ((ch2 != 'Y') && (ch2 != 'N')); rearrfirst = (ch2 == 'Y'); break; case 'V': loopcount2 = 0; do { printf("type the number of trees to save\n"); #ifdef WIN32 phyFillScreenColor(); #endif scanf("%ld%*[^\n]", &maxtrees); if (maxtrees > MAXNUMTREES) maxtrees = MAXNUMTREES; getchar(); countup(&loopcount2, 10); } while (maxtrees < 1); break; case 'I': interleaved = !interleaved; break; case '0': initterminal(&ibmpc, &ansi); break; case '1': printdata = !printdata; break; case '2': progress = !progress; break; case '3': treeprint = !treeprint; break; case '4': stepbox = !stepbox; break; case '5': ancseq = !ancseq; break; case '.': dotdiff = !dotdiff; break; case '6': trout = !trout; break; } } else printf("Not a possible option!\n"); countup(&loopcount, 100); } if (transvp) fprintf(outfile, "Transversion parsimony\n\n"); } /* getoptions */ void allocrest() { long i; y = (Char **)Malloc(spp*sizeof(Char *)); for (i = 0; i < spp; i++) y[i] = (Char *)Malloc(chars*sizeof(Char)); bestrees = (bestelm *)Malloc(maxtrees*sizeof(bestelm)); for (i = 1; i <= maxtrees; i++) bestrees[i - 1].btree = (long *)Malloc(nonodes*sizeof(long)); nayme = (naym *)Malloc(spp*sizeof(naym)); enterorder = (long *)Malloc(spp*sizeof(long)); place = (long *)Malloc(nonodes*sizeof(long)); weight = (long *)Malloc(chars*sizeof(long)); oldweight = (long *)Malloc(chars*sizeof(long)); alias = (long *)Malloc(chars*sizeof(long)); ally = (long *)Malloc(chars*sizeof(long)); location = (long *)Malloc(chars*sizeof(long)); } /* allocrest */ void doinit() { /* initializes variables */ inputnumbers(&spp, &chars, &nonodes, 1); getoptions(); if (printdata) fprintf(outfile, "%2ld species, %3ld sites\n\n", spp, chars); alloctree(&treenode, nonodes, usertree); } /* doinit */ void makeweights() { /* make up weights vector to avoid duplicate computations */ long i; for (i = 1; i <= chars; i++) { alias[i - 1] = i; oldweight[i - 1] = weight[i - 1]; ally[i - 1] = i; } sitesort(chars, weight); sitecombine(chars); sitescrunch(chars); endsite = 0; for (i = 1; i <= chars; i++) { if (ally[i - 1] == i) endsite++; } for (i = 1; i <= endsite; i++) location[alias[i - 1] - 1] = i; if (!thresh) threshold = spp; threshwt = (long *)Malloc(endsite*sizeof(long)); for (i = 0; i < endsite; i++) { weight[i] *= 10; threshwt[i] = (long)(threshold * weight[i] + 0.5); } zeros = (long *)Malloc(endsite*sizeof(long)); for (i = 0; i < endsite; i++) zeros[i] = 0; } /* makeweights */ void doinput() { /* reads the input data */ long i; if (justwts) { if (firstset) inputdata(chars); for (i = 0; i < chars; i++) weight[i] = 1; inputweights(chars, weight, &weights); if (justwts) { fprintf(outfile, "\n\nWeights set # %ld:\n\n", ith); if (progress) printf("\nWeights set # %ld:\n\n", ith); } if (printdata) printweights(outfile, 0, chars, weight, "Sites"); } else { if (!firstset){ samenumsp(&chars, ith); reallocchars(); } inputdata(chars); for (i = 0; i < chars; i++) weight[i] = 1; if (weights) { inputweights(chars, weight, &weights); if (printdata) printweights(outfile, 0, chars, weight, "Sites"); } } makeweights(); makevalues(treenode, zeros, usertree); if (!usertree) { allocnode(&temp, zeros, endsite); allocnode(&temp1, zeros, endsite); allocnode(&temp2, zeros, endsite); allocnode(&tempsum, zeros, endsite); allocnode(&temprm, zeros, endsite); allocnode(&tempadd, zeros, endsite); allocnode(&tempf, zeros, endsite); allocnode(&tmp, zeros, endsite); allocnode(&tmp1, zeros, endsite); allocnode(&tmp2, zeros, endsite); allocnode(&tmp3, zeros, endsite); allocnode(&tmprm, zeros, endsite); allocnode(&tmpadd, zeros, endsite); } } /* doinput */ void initdnaparsnode(node **p, node **local_grbg, node *UNUSED_q, long UNUSED_len, long nodei, long *UNUSED_ntips, long *parens, initops whichinit, pointarray local_treenode, pointarray UNUSED_nodep, Char *str, Char *ch, FILE *fp_intree) { (void)UNUSED_q; (void)UNUSED_len; (void)UNUSED_ntips; (void)UNUSED_nodep; /* initializes a node */ boolean minusread; double valyew, divisor; switch (whichinit) { case bottom: gnutreenode(local_grbg, p, nodei, endsite, zeros); local_treenode[nodei - 1] = *p; break; case nonbottom: gnutreenode(local_grbg, p, nodei, endsite, zeros); break; case tip: match_names_to_data (str, local_treenode, p, spp); break; case length: /* if there is a length, read it and discard value */ processlength(&valyew, &divisor, ch, &minusread, fp_intree, parens); break; default: /*cases hslength,hsnolength,treewt,unittrwt,iter,*/ break; } } /* initdnaparsnode */ void evaluate(node *r) { /* determines the number of steps needed for a tree. this is the minimum number of steps needed to evolve sequences on this tree */ long i, steps; long term; double sum; sum = 0.0; for (i = 0; i < endsite; i++) { steps = r->numsteps[i]; if ((long)steps <= threshwt[i]) term = steps; else term = threshwt[i]; sum += (double)term; if (usertree && which <= maxuser) fsteps[which - 1][i] = term; } if (usertree && which <= maxuser) { nsteps[which - 1] = sum; if (which == 1) { minwhich = 1; minsteps = sum; } else if (sum < minsteps) { minwhich = which; minsteps = sum; } } like = -sum; } /* evaluate */ void tryadd(node *p, node *item, node *nufork) { /* temporarily adds one fork and one tip to the tree. if the location where they are added yields greater "likelihood" than other locations tested up to that time, then keeps that location as there */ long pos; double belowsum, parentsum; boolean found, collapse, changethere, trysave; if (!p->tip) { memcpy(temp->base, p->base, endsite*sizeof(long)); memcpy(temp->numsteps, p->numsteps, endsite*sizeof(long)); memcpy(temp->numnuc, p->numnuc, endsite*sizeof(nucarray)); temp->numdesc = p->numdesc + 1; if (p->back) { multifillin(temp, tempadd, 1); sumnsteps2(tempsum, temp, p->back, 0, endsite, threshwt); } else { multisumnsteps(temp, tempadd, 0, endsite, threshwt); tempsum->sumsteps = temp->sumsteps; } if (tempsum->sumsteps <= -bestyet) { if (p->back) sumnsteps2(tempsum, temp, p->back, endsite+1, endsite, threshwt); else { multisumnsteps(temp, temp1, endsite+1, endsite, threshwt); tempsum->sumsteps = temp->sumsteps; } } p->sumsteps = tempsum->sumsteps; } if (p == root) sumnsteps2(temp, item, p, 0, endsite, threshwt); else { sumnsteps(temp1, item, p, 0, endsite); sumnsteps2(temp, temp1, p->back, 0, endsite, threshwt); } if (temp->sumsteps <= -bestyet) { if (p == root) sumnsteps2(temp, item, p, endsite+1, endsite, threshwt); else { sumnsteps(temp1, item, p, endsite+1, endsite); sumnsteps2(temp, temp1, p->back, endsite+1, endsite, threshwt); } } belowsum = temp->sumsteps; global_multf = false; like = -belowsum; if (!p->tip && belowsum >= p->sumsteps) { global_multf = true; like = -p->sumsteps; } trysave = true; if (!global_multf && p != root) { parentsum = treenode[p->back->index - 1]->sumsteps; if (belowsum >= parentsum) trysave = false; } if (lastrearr) { changethere = true; if (like >= bstlike2 && trysave) { if (like > bstlike2) found = false; else { addnsave(p, item, nufork, &root, &grbg, global_multf, treenode, place, zeros); pos = 0; findtree(&found, &pos, nextree, place, bestrees); } if (!found) { collapse = collapsible(item, p, temp, temp1, temp2, tempsum, temprm, tmpadd, global_multf, root, zeros, treenode); if (!thorough) changethere = !collapse; if (thorough || !collapse || like > bstlike2) { if (like > bstlike2) { addnsave(p, item, nufork, &root, &grbg, global_multf, treenode, place, zeros); bestlike = bstlike2 = like; addbestever(&pos, &nextree, maxtrees, collapse, place, bestrees); } else addtiedtree(pos, &nextree, maxtrees, collapse, place, bestrees); } } } if (like >= bestyet) { if (like > bstlike2) bstlike2 = like; if (changethere && trysave) { bestyet = like; there = p; mulf = global_multf; } } } else if ((like > bestyet) || (like >= bestyet && trysave)) { bestyet = like; there = p; mulf = global_multf; } } /* tryadd */ void addpreorder(node *p, node *item, node *nufork) { /* traverses a n-ary tree, calling function tryadd at a node before calling tryadd at its descendants */ node *q; if (p == NULL) return; tryadd(p, item, nufork); if (!p->tip) { q = p->next; while (q != p) { addpreorder(q->back, item, nufork); q = q->next; } } } /* addpreorder */ void trydescendants(node *item, node *forknode, node *parent, node *parentback, boolean trybelow) { /* tries rearrangements at parent and below parent's descendants */ node *q, *tempblw; boolean bestever=0, belowbetter, multf=0, saved, trysave; double parentsum=0, belowsum; memcpy(temp->base, parent->base, endsite*sizeof(long)); memcpy(temp->numsteps, parent->numsteps, endsite*sizeof(long)); memcpy(temp->numnuc, parent->numnuc, endsite*sizeof(nucarray)); temp->numdesc = parent->numdesc + 1; multifillin(temp, tempadd, 1); sumnsteps2(tempsum, parentback, temp, 0, endsite, threshwt); belowbetter = true; if (lastrearr) { parentsum = tempsum->sumsteps; if (-tempsum->sumsteps >= bstlike2) { belowbetter = false; bestever = false; multf = true; if (-tempsum->sumsteps > bstlike2) bestever = true; savelocrearr(item, forknode, parent, tmp, tmp1, tmp2, tmp3, tmprm, tmpadd, &root, maxtrees, &nextree, multf, bestever, &saved, place, bestrees, treenode, &grbg, zeros); if (saved) { like = bstlike2 = -tempsum->sumsteps; there = parent; mulf = true; } } } else if (-tempsum->sumsteps >= like) { there = parent; mulf = true; like = -tempsum->sumsteps; } if (trybelow) { sumnsteps(temp, parent, tempadd, 0, endsite); sumnsteps2(tempsum, temp, parentback, 0, endsite, threshwt); if (lastrearr) { belowsum = tempsum->sumsteps; if (-tempsum->sumsteps >= bstlike2 && belowbetter && (forknode->numdesc > 2 || (forknode->numdesc == 2 && parent->back->index != forknode->index))) { trysave = false; memcpy(temp->base, parentback->base, endsite*sizeof(long)); memcpy(temp->numsteps, parentback->numsteps, endsite*sizeof(long)); memcpy(temp->numnuc, parentback->numnuc, endsite*sizeof(nucarray)); temp->numdesc = parentback->numdesc + 1; multifillin(temp, tempadd, 1); sumnsteps2(tempsum, parent, temp, 0, endsite, threshwt); if (-tempsum->sumsteps < bstlike2) { multf = false; bestever = false; trysave = true; } if (-belowsum > bstlike2) { multf = false; bestever = true; trysave = true; } if (trysave) { if (treenode[parent->index - 1] != parent) tempblw = parent->back; else tempblw = parent; savelocrearr(item, forknode, tempblw, tmp, tmp1, tmp2, tmp3, tmprm, tmpadd, &root, maxtrees, &nextree, multf, bestever, &saved, place, bestrees, treenode, &grbg, zeros); if (saved) { like = bstlike2 = -belowsum; there = tempblw; mulf = false; } } } } else if (-tempsum->sumsteps > like) { like = -tempsum->sumsteps; if (-tempsum->sumsteps > bestyet) { if (treenode[parent->index - 1] != parent) tempblw = parent->back; else tempblw = parent; there = tempblw; mulf = false; } } } q = parent->next; while (q != parent) { if (q->back && q->back != item) { memcpy(temp1->base, q->base, endsite*sizeof(long)); memcpy(temp1->numsteps, q->numsteps, endsite*sizeof(long)); memcpy(temp1->numnuc, q->numnuc, endsite*sizeof(nucarray)); temp1->numdesc = q->numdesc; multifillin(temp1, parentback, 0); if (lastrearr) belowbetter = (-parentsum < bstlike2); if (!q->back->tip) { memcpy(temp->base, q->back->base, endsite*sizeof(long)); memcpy(temp->numsteps, q->back->numsteps, endsite*sizeof(long)); memcpy(temp->numnuc, q->back->numnuc, endsite*sizeof(nucarray)); temp->numdesc = q->back->numdesc + 1; multifillin(temp, tempadd, 1); sumnsteps2(tempsum, temp1, temp, 0, endsite, threshwt); if (lastrearr) { if (-tempsum->sumsteps >= bstlike2) { belowbetter = false; bestever = false; multf = true; if (-tempsum->sumsteps > bstlike2) bestever = true; savelocrearr(item, forknode, q->back, tmp, tmp1, tmp2, tmp3, tmprm, tmpadd, &root, maxtrees, &nextree, multf, bestever, &saved, place, bestrees, treenode, &grbg, zeros); if (saved) { like = bstlike2 = -tempsum->sumsteps; there = q->back; mulf = true; } } } else if (-tempsum->sumsteps >= like) { like = -tempsum->sumsteps; there = q->back; mulf = true; } } sumnsteps(temp, q->back, tempadd, 0, endsite); sumnsteps2(tempsum, temp, temp1, 0, endsite, threshwt); if (lastrearr) { if (-tempsum->sumsteps >= bstlike2) { trysave = false; multf = false; if (belowbetter) { bestever = false; trysave = true; } if (-tempsum->sumsteps > bstlike2) { bestever = true; trysave = true; } if (trysave) { if (treenode[q->back->index - 1] != q->back) tempblw = q; else tempblw = q->back; savelocrearr(item, forknode, tempblw, tmp, tmp1, tmp2, tmp3, tmprm, tmpadd, &root, maxtrees, &nextree, multf, bestever, &saved, place, bestrees, treenode, &grbg, zeros); if (saved) { like = bstlike2 = -tempsum->sumsteps; there = tempblw; mulf = false; } } } } else if (-tempsum->sumsteps > like) { like = -tempsum->sumsteps; if (-tempsum->sumsteps > bestyet) { if (treenode[q->back->index - 1] != q->back) tempblw = q; else tempblw = q->back; there = tempblw; mulf = false; } } } q = q->next; } } /* trydescendants */ void trylocal(node *item, node *forknode) { /* rearranges below forknode, below descendants of forknode when there are more than 2 descendants, then unroots the back of forknode and rearranges on its descendants */ node *q; boolean bestever, multf, saved; memcpy(temprm->base, zeros, endsite*sizeof(long)); memcpy(temprm->numsteps, zeros, endsite*sizeof(long)); memcpy(temprm->oldbase, item->base, endsite*sizeof(long)); memcpy(temprm->oldnumsteps, item->numsteps, endsite*sizeof(long)); memcpy(tempf->base, forknode->base, endsite*sizeof(long)); memcpy(tempf->numsteps, forknode->numsteps, endsite*sizeof(long)); memcpy(tempf->numnuc, forknode->numnuc, endsite*sizeof(nucarray)); tempf->numdesc = forknode->numdesc - 1; multifillin(tempf, temprm, -1); if (!forknode->back) { sumnsteps2(tempsum, tempf, tempadd, 0, endsite, threshwt); if (lastrearr) { if (-tempsum->sumsteps > bstlike2) { bestever = true; multf = false; savelocrearr(item, forknode, forknode, tmp, tmp1, tmp2, tmp3, tmprm, tmpadd, &root, maxtrees, &nextree, multf, bestever, &saved, place, bestrees, treenode, &grbg, zeros); if (saved) { like = bstlike2 = -tempsum->sumsteps; there = forknode; mulf = false; } } } else if (-tempsum->sumsteps > like) { like = -tempsum->sumsteps; if (-tempsum->sumsteps > bestyet) { there = forknode; mulf = false; } } } else { sumnsteps(temp, tempf, tempadd, 0, endsite); sumnsteps2(tempsum, temp, forknode->back, 0, endsite, threshwt); if (lastrearr) { if (-tempsum->sumsteps > bstlike2) { bestever = true; multf = false; savelocrearr(item, forknode, forknode, tmp, tmp1, tmp2, tmp3, tmprm, tmpadd, &root, maxtrees, &nextree, multf, bestever, &saved, place, bestrees, treenode, &grbg, zeros); if (saved) { like = bstlike2 = -tempsum->sumsteps; there = forknode; mulf = false; } } } else if (-tempsum->sumsteps > like) { like = -tempsum->sumsteps; if (-tempsum->sumsteps > bestyet) { there = forknode; mulf = false; } } trydescendants(item, forknode, forknode->back, tempf, false); } q = forknode->next; while (q != forknode) { if (q->back != item) { memcpy(temp2->base, q->base, endsite*sizeof(long)); memcpy(temp2->numsteps, q->numsteps, endsite*sizeof(long)); memcpy(temp2->numnuc, q->numnuc, endsite*sizeof(nucarray)); temp2->numdesc = q->numdesc - 1; multifillin(temp2, temprm, -1); if (!q->back->tip) { trydescendants(item, forknode, q->back, temp2, true); } else { sumnsteps(temp1, q->back, tempadd, 0, endsite); sumnsteps2(tempsum, temp1, temp2, 0, endsite, threshwt); if (lastrearr) { if (-tempsum->sumsteps > bstlike2) { multf = false; bestever = true; savelocrearr(item, forknode, q->back, tmp, tmp1, tmp2, tmp3, tmprm, tmpadd, &root, maxtrees, &nextree, multf, bestever, &saved, place, bestrees, treenode, &grbg, zeros); if (saved) { like = bstlike2 = -tempsum->sumsteps; there = q->back; mulf = false; } } } else if ((-tempsum->sumsteps) > like) { like = -tempsum->sumsteps; if (-tempsum->sumsteps > bestyet) { there = q->back; mulf = false; } } } } q = q->next; } } /* trylocal */ void trylocal2(node *item, node *forknode, node *other) { /* rearranges below forknode, below descendants of forknode when there are more than 2 descendants, then unroots the back of forknode and rearranges on its descendants. Used if forknode has binary descendants */ node *q; boolean bestever=0, multf, saved, belowbetter, trysave; memcpy(tempf->base, other->base, endsite*sizeof(long)); memcpy(tempf->numsteps, other->numsteps, endsite*sizeof(long)); memcpy(tempf->oldbase, forknode->base, endsite*sizeof(long)); memcpy(tempf->oldnumsteps, forknode->numsteps, endsite*sizeof(long)); tempf->numdesc = other->numdesc; if (forknode->back) trydescendants(item, forknode, forknode->back, tempf, false); if (!other->tip) { memcpy(temp->base, other->base, endsite*sizeof(long)); memcpy(temp->numsteps, other->numsteps, endsite*sizeof(long)); memcpy(temp->numnuc, other->numnuc, endsite*sizeof(nucarray)); temp->numdesc = other->numdesc + 1; multifillin(temp, tempadd, 1); if (forknode->back) sumnsteps2(tempsum, forknode->back, temp, 0, endsite, threshwt); else sumnsteps2(tempsum, NULL, temp, 0, endsite, threshwt); belowbetter = true; if (lastrearr) { if (-tempsum->sumsteps >= bstlike2) { belowbetter = false; bestever = false; multf = true; if (-tempsum->sumsteps > bstlike2) bestever = true; savelocrearr(item, forknode, other, tmp, tmp1, tmp2, tmp3, tmprm, tmpadd, &root, maxtrees, &nextree, multf, bestever, &saved, place, bestrees, treenode, &grbg, zeros); if (saved) { like = bstlike2 = -tempsum->sumsteps; there = other; mulf = true; } } } else if (-tempsum->sumsteps >= like) { there = other; mulf = true; like = -tempsum->sumsteps; } if (forknode->back) { memcpy(temprm->base, forknode->back->base, endsite*sizeof(long)); memcpy(temprm->numsteps, forknode->back->numsteps, endsite*sizeof(long)); } else { memcpy(temprm->base, zeros, endsite*sizeof(long)); memcpy(temprm->numsteps, zeros, endsite*sizeof(long)); } memcpy(temprm->oldbase, other->back->base, endsite*sizeof(long)); memcpy(temprm->oldnumsteps, other->back->numsteps, endsite*sizeof(long)); q = other->next; while (q != other) { memcpy(temp2->base, q->base, endsite*sizeof(long)); memcpy(temp2->numsteps, q->numsteps, endsite*sizeof(long)); memcpy(temp2->numnuc, q->numnuc, endsite*sizeof(nucarray)); if (forknode->back) { temp2->numdesc = q->numdesc; multifillin(temp2, temprm, 0); } else { temp2->numdesc = q->numdesc - 1; multifillin(temp2, temprm, -1); } if (!q->back->tip) trydescendants(item, forknode, q->back, temp2, true); else { sumnsteps(temp1, q->back, tempadd, 0, endsite); sumnsteps2(tempsum, temp1, temp2, 0, endsite, threshwt); if (lastrearr) { if (-tempsum->sumsteps >= bstlike2) { trysave = false; multf = false; if (belowbetter) { bestever = false; trysave = true; } if (-tempsum->sumsteps > bstlike2) { bestever = true; trysave = true; } if (trysave) { savelocrearr(item, forknode, q->back, tmp, tmp1, tmp2, tmp3, tmprm, tmpadd, &root, maxtrees, &nextree, multf, bestever, &saved, place, bestrees, treenode, &grbg, zeros); if (saved) { like = bstlike2 = -tempsum->sumsteps; there = q->back; mulf = false; } } } } else if (-tempsum->sumsteps > like) { like = -tempsum->sumsteps; if (-tempsum->sumsteps > bestyet) { there = q->back; mulf = false; } } } q = q->next; } } } /* trylocal2 */ void tryrearr(node *p, boolean *success) { /* evaluates one rearrangement of the tree. if the new tree has greater "likelihood" than the old one sets success = TRUE and keeps the new tree. otherwise, restores the old tree */ node *forknode, *newfork, *other, *oldthere; double oldlike; boolean oldmulf; if (p->back == NULL) return; forknode = treenode[p->back->index - 1]; if (!forknode->back && forknode->numdesc <= 2 && alltips(forknode, p)) return; oldlike = bestyet; like = -10.0 * spp * chars; memcpy(tempadd->base, p->base, endsite*sizeof(long)); memcpy(tempadd->numsteps, p->numsteps, endsite*sizeof(long)); memcpy(tempadd->oldbase, zeros, endsite*sizeof(long)); memcpy(tempadd->oldnumsteps, zeros, endsite*sizeof(long)); if (forknode->numdesc > 2) { oldthere = there = forknode; oldmulf = mulf = true; trylocal(p, forknode); } else { findbelow(&other, p, forknode); oldthere = there = other; oldmulf = mulf = false; trylocal2(p, forknode, other); } if ((like <= oldlike) || (there == oldthere && mulf == oldmulf)) return; recompute = true; re_move(p, &forknode, &root, recompute, treenode, &grbg, zeros); if (mulf) add(there, p, NULL, &root, recompute, treenode, &grbg, zeros); else { if (forknode->numdesc > 0) getnufork(&newfork, &grbg, treenode, zeros); else newfork = forknode; add(there, p, newfork, &root, recompute, treenode, &grbg, zeros); } if (like > oldlike) { *success = true; bestyet = like; } } /* tryrearr */ void repreorder(node *p, boolean *success) { /* traverses a binary tree, calling PROCEDURE tryrearr at a node before calling tryrearr at its descendants */ node *q, *this; if (p == NULL) return; if (!p->visited) { tryrearr(p, success); p->visited = true; } if (!p->tip) { q = p; while (q->next != p) { this = q->next->back; repreorder(q->next->back,success); if (q->next->back == this) q = q->next; } } } /* repreorder */ void rearrange(node **r) { /* traverses the tree (preorder), finding any local rearrangement which decreases the number of steps. if traversal succeeds in increasing the tree's "likelihood", PROCEDURE rearrange runs traversal again */ boolean success=true; while (success) { success = false; clearvisited(treenode); repreorder(*r, &success); } } /* rearrange */ void describe() { /* prints ancestors, steps and table of numbers of steps in each site */ if (treeprint) { fprintf(outfile, "\nrequires a total of %10.3f\n", like / -10.0); fprintf(outfile, "\n between and length\n"); fprintf(outfile, " ------- --- ------\n"); printbranchlengths(root); } if (stepbox) writesteps(chars, weights, oldweight, root); if (ancseq) { hypstates(chars, root, treenode, &garbage, basechar); putc('\n', outfile); } putc('\n', outfile); if (trout) { col = 0; treeout3(root, nextree, &col, root); } } /* describe */ void dnapars_coordinates(node *p, double lengthsum, long *tipy, double *tipmax) { /* establishes coordinates of nodes */ node *q, *first, *last; double xx; if (p == NULL) return; if (p->tip) { p->xcoord = (long)(over * lengthsum + 0.5); p->ycoord = (*tipy); p->ymin = (*tipy); p->ymax = (*tipy); (*tipy) += down; if (lengthsum > (*tipmax)) (*tipmax) = lengthsum; return; } q = p->next; do { xx = q->v; if (xx > 100.0) xx = 100.0; dnapars_coordinates(q->back, lengthsum + xx, tipy,tipmax); q = q->next; } while (p != q); first = p->next->back; q = p; while (q->next != p) q = q->next; last = q->back; p->xcoord = (long)(over * lengthsum + 0.5); if ((p == root) || count_sibs(p) > 2) p->ycoord = p->next->next->back->ycoord; else p->ycoord = (first->ycoord + last->ycoord) / 2; p->ymin = first->ymin; p->ymax = last->ymax; } /* dnapars_coordinates */ void dnapars_printree() { /* prints out diagram of the tree2 */ long tipy; double scale, tipmax; long i; if (!treeprint) return; putc('\n', outfile); tipy = 1; tipmax = 0.0; dnapars_coordinates(root, 0.0, &tipy, &tipmax); scale = 1.0 / (long)(tipmax + 1.000); for (i = 1; i <= (tipy - down); i++) drawline3(i, scale, root); putc('\n', outfile); } /* dnapars_printree */ void globrearrange() { /* does global rearrangements */ long j; double gotlike; boolean frommulti; node *item, *nufork; recompute = true; do { printf(" "); gotlike = bstlike2 = bestlike; for (j = 0; j < nonodes; j++) { bestyet = -10.0 * spp * chars; if (j < spp) item = treenode[enterorder[j] -1]; else item = treenode[j]; if ((item != root) && ((j < spp) || ((j >= spp) && (item->numdesc > 0))) && !((item->back->index == root->index) && (root->numdesc == 2) && alltips(root, item))) { re_move(item, &nufork, &root, recompute, treenode, &grbg, zeros); frommulti = (nufork->numdesc > 0); clearcollapse(treenode); there = root; memcpy(tempadd->base, item->base, endsite*sizeof(long)); memcpy(tempadd->numsteps, item->numsteps, endsite*sizeof(long)); memcpy(tempadd->oldbase, zeros, endsite*sizeof(long)); memcpy(tempadd->oldnumsteps, zeros, endsite*sizeof(long)); if (frommulti){ oldnufork = nufork; getnufork(&nufork, &grbg, treenode, zeros); } addpreorder(root, item, nufork); if (frommulti) oldnufork = NULL; if (!mulf) add(there, item, nufork, &root, recompute, treenode, &grbg, zeros); else add(there, item, NULL, &root, recompute, treenode, &grbg, zeros); } if (progress) { if (j % ((nonodes / 72) + 1) == 0) putchar('.'); fflush(stdout); } } if (progress) { putchar('\n'); #ifdef WIN32 phyFillScreenColor(); #endif } } while (bestlike > gotlike); } /* globrearrange */ void load_tree(long treei) { /* restores a tree from bestrees */ long j, nextnode; boolean local_recompute = false; node *dummy; for (j = spp - 1; j >= 1; j--) re_move(treenode[j], &dummy, &root, local_recompute, treenode, &grbg, zeros); root = treenode[0]; local_recompute = true; add(treenode[0], treenode[1], treenode[spp], &root, local_recompute, treenode, &grbg, zeros); nextnode = spp + 2; for (j = 3; j <= spp; j++) { if (bestrees[treei].btree[j - 1] > 0) add(treenode[bestrees[treei].btree[j - 1] - 1], treenode[j - 1], treenode[nextnode++ - 1], &root, local_recompute, treenode, &grbg, zeros); else add(treenode[treenode[-bestrees[treei].btree[j-1]-1]->back->index-1], treenode[j - 1], NULL, &root, local_recompute, treenode, &grbg, zeros); } } void grandrearr() { /* calls global rearrangement on best trees */ long treei; boolean done; done = false; do { treei = findunrearranged(bestrees, nextree, true); if (treei < 0) done = true; else bestrees[treei].gloreange = true; if (!done) { load_tree(treei); globrearrange(); done = rearrfirst; } } while (!done); } /* grandrearr */ void maketree() { /* constructs a binary tree from the pointers in treenode. adds each node at location which yields highest "likelihood" then rearranges the tree for greatest "likelihood" */ long i, j, numtrees, nextnode; boolean done, firsttree, goteof, haslengths; node *item, *nufork, *dummy; pointarray nodep; if (!usertree) { for (i = 1; i <= spp; i++) enterorder[i - 1] = i; if (jumble) randumize(seed, enterorder); recompute = true; root = treenode[enterorder[0] - 1]; add(treenode[enterorder[0] - 1], treenode[enterorder[1] - 1], treenode[spp], &root, recompute, treenode, &grbg, zeros); if (progress) { printf("Adding species:\n"); writename(0, 2, enterorder); #ifdef WIN32 phyFillScreenColor(); #endif } lastrearr = false; oldnufork = NULL; for (i = 3; i <= spp; i++) { bestyet = -10.0 * spp * chars; item = treenode[enterorder[i - 1] - 1]; getnufork(&nufork, &grbg, treenode, zeros); there = root; memcpy(tempadd->base, item->base, endsite*sizeof(long)); memcpy(tempadd->numsteps, item->numsteps, endsite*sizeof(long)); memcpy(tempadd->oldbase, zeros, endsite*sizeof(long)); memcpy(tempadd->oldnumsteps, zeros, endsite*sizeof(long)); addpreorder(root, item, nufork); if (!mulf) add(there, item, nufork, &root, recompute, treenode, &grbg, zeros); else add(there, item, NULL, &root, recompute, treenode, &grbg, zeros); like = bestyet; rearrange(&root); if (progress) { writename(i - 1, 1, enterorder); #ifdef WIN32 phyFillScreenColor(); #endif } lastrearr = (i == spp); if (lastrearr) { bestlike = bestyet; if (jumb == 1) { bstlike2 = bestlike; nextree = 1; initbestrees(bestrees, maxtrees, true); initbestrees(bestrees, maxtrees, false); } if (progress) { printf("\nDoing global rearrangements"); if (rearrfirst) printf(" on the first of the trees tied for best\n"); else printf(" on all trees tied for best\n"); printf(" !"); for (j = 0; j < nonodes; j++) if (j % ((nonodes / 72) + 1) == 0) putchar('-'); printf("!\n"); #ifdef WIN32 phyFillScreenColor(); #endif } globrearrange(); } } done = false; while (!done && findunrearranged(bestrees, nextree, true) >= 0) { grandrearr(); done = rearrfirst; } if (progress) putchar('\n'); recompute = false; for (i = spp - 1; i >= 1; i--) re_move(treenode[i], &dummy, &root, recompute, treenode, &grbg, zeros); if (jumb == njumble) { if (thorough && (nextree > 2)) reducebestrees(bestrees, &nextree); if (treeprint) { putc('\n', outfile); if (nextree == 2) fprintf(outfile, "One most parsimonious tree found:\n"); else fprintf(outfile, "%6ld trees in all found\n", nextree - 1); } if (nextree > maxtrees + 1) { if (treeprint) fprintf(outfile, "here are the first %4ld of them\n", (long)maxtrees); nextree = maxtrees + 1; } if (treeprint) putc('\n', outfile); for (i = 0; i <= (nextree - 2); i++) { root = treenode[0]; add(treenode[0], treenode[1], treenode[spp], &root, recompute, treenode, &grbg, zeros); nextnode = spp + 2; for (j = 3; j <= spp; j++) { if (bestrees[i].btree[j - 1] > 0) add(treenode[bestrees[i].btree[j - 1] - 1], treenode[j - 1], treenode[nextnode++ - 1], &root, recompute, treenode, &grbg, zeros); else add(treenode[treenode[-bestrees[i].btree[j - 1]-1]->back->index-1], treenode[j - 1], NULL, &root, recompute, treenode, &grbg, zeros); } reroot(treenode[outgrno - 1], root); postorder(root); evaluate(root); treelength(root, chars, treenode); dnapars_printree(); describe(); for (j = 1; j < spp; j++) re_move(treenode[j], &dummy, &root, recompute, treenode, &grbg, zeros); } } } else { openfile(&intree,INTREE,"input tree", "r",progname,intreename); numtrees = countsemic(&intree); if (numtrees > 2) initseed(&inseed, &inseed0, seed); if (numtrees > MAXNUMTREES) { printf("\nERROR: number of input trees is read incorrectly from %s\n", intreename); exxit(-1); } if (treeprint) { fprintf(outfile, "User-defined tree"); if (numtrees > 1) putc('s', outfile); fprintf(outfile, ":\n"); } fsteps = (long **)Malloc(maxuser*sizeof(long *)); for (j = 1; j <= maxuser; j++) fsteps[j - 1] = (long *)Malloc(endsite*sizeof(long)); if (trout) fprintf(outtree, "%ld\n", numtrees); nodep = NULL; which = 1; while (which <= numtrees) { firsttree = true; nextnode = 0; haslengths = true; treeread(intree, &root, treenode, &goteof, &firsttree, nodep, &nextnode, &haslengths, &grbg, initdnaparsnode); if (treeprint) fprintf(outfile, "\n\n"); if (outgropt) reroot(treenode[outgrno - 1], root); postorder(root); evaluate(root); treelength(root, chars, treenode); dnapars_printree(); describe(); if (which < numtrees) gdispose(root, &grbg, treenode); which++; } FClose(intree); putc('\n', outfile); if (numtrees > 1 && chars > 1 ) standev(chars, numtrees, minwhich, minsteps, nsteps, fsteps, seed); for (j = 1; j <= maxuser; j++) free(fsteps[j - 1]); free(fsteps); } if (jumb == njumble) { if (progress) { printf("\nOutput written to file \"%s\"\n\n", outfilename); if (trout) { printf("Tree"); if (numtrees > 1) printf("s"); printf(" also written onto file \"%s\"\n\n", outtreename); } } } } /* maketree */ void reallocchars() { /* The amount of chars can change between runs this function reallocates all the variables whose size depends on the amount of chars */ long i; for (i=0; i < spp; i++){ free(y[i]); y[i] = (Char *)Malloc(chars*sizeof(Char)); } free(weight); free(oldweight); free(alias); free(ally); free(location); weight = (long *)Malloc(chars*sizeof(long)); oldweight = (long *)Malloc(chars*sizeof(long)); alias = (long *)Malloc(chars*sizeof(long)); ally = (long *)Malloc(chars*sizeof(long)); location = (long *)Malloc(chars*sizeof(long)); } void freerest() { /* free variables that are allocated each data set */ long i; if (!usertree) { freenode(&temp); freenode(&temp1); freenode(&temp2); freenode(&tempsum); freenode(&temprm); freenode(&tempadd); freenode(&tempf); freenode(&tmp); freenode(&tmp1); freenode(&tmp2); freenode(&tmp3); freenode(&tmprm); freenode(&tmpadd); } for (i = 0; i < spp; i++) free(y[i]); free(y); for (i = 1; i <= maxtrees; i++) free(bestrees[i - 1].btree); free(bestrees); free(nayme); free(enterorder); free(place); free(weight); free(oldweight); free(alias); free(ally); free(location); freegrbg(&grbg); if (ancseq) freegarbage(&garbage); free(threshwt); free(zeros); freenodes(nonodes, treenode); } /* freerest */ int main(int argc, Char *argv[]) { /* DNA parsimony by uphill search */ /* reads in spp, chars, and the data. Then calls maketree to construct the tree */ #ifdef MAC argc = 1; /* macsetup("Dnapars",""); */ argv[0] = "Dnapars"; #endif init(argc, argv); progname = argv[0]; openfile(&infile,INFILE,"input file", "r",argv[0],infilename); openfile(&outfile,OUTFILE,"output file", "w",argv[0],outfilename); ibmpc = IBMCRT; ansi = ANSICRT; msets = 1; firstset = true; garbage = NULL; grbg = NULL; doinit(); if (weights || justwts) openfile(&weightfile,WEIGHTFILE,"weights file","r",argv[0],weightfilename); if (trout) openfile(&outtree,OUTTREE,"output tree file", "w",argv[0],outtreename); for (ith = 1; ith <= msets; ith++) { if (!(justwts && !firstset)) allocrest(); if (msets > 1 && !justwts) { fprintf(outfile, "\nData set # %ld:\n\n", ith); if (progress) printf("\nData set # %ld:\n\n", ith); } doinput(); if (ith == 1) firstset = false; for (jumb = 1; jumb <= njumble; jumb++) maketree(); if (!justwts) freerest(); } freetree(nonodes, treenode); FClose(infile); FClose(outfile); if (weights || justwts) FClose(weightfile); if (trout) FClose(outtree); if (usertree) FClose(intree); #ifdef MAC fixmacfile(outfilename); fixmacfile(outtreename); #endif if (progress) printf("Done.\n\n"); #ifdef WIN32 phyRestoreConsoleAttributes(); #endif return 0; } /* DNA parsimony by uphill search */