/*
--------------------------------- qset_r.c implements set manipulations needed for quickhull see qh-set_r.htm and qset_r.h Be careful of strict aliasing (two pointers of different types that reference the same location). The last slot of a set is either the actual size of the set plus 1, or the NULL terminator of the set (i.e., setelemT). Only reference qh for qhmem or qhstat. Otherwise the matching code in qset.c will bring in qhT Copyright (c) 1993-2020 The Geometry Center. $Id: //main/2019/qhull/src/libqhull_r/qset_r.c#8 $$Change: 2953 $ $DateTime: 2020/05/21 22:05:32 $$Author: bbarber $ */ #include "libqhull_r.h" /* for qhT and QHULL_CRTDBG */ #include "qset_r.h" #include "mem_r.h" #include#include /*** uncomment here and qhull_ra.h if string.h does not define memcpy() #include */ #ifndef qhDEFlibqhull typedef struct ridgeT ridgeT; typedef struct facetT facetT; void qh_errexit(qhT *qh, int exitcode, facetT *, ridgeT *); void qh_fprintf(qhT *qh, FILE *fp, int msgcode, const char *fmt, ... ); # ifdef _MSC_VER /* Microsoft Visual C++ -- warning level 4 */ # pragma warning( disable : 4127) /* conditional expression is constant */ # pragma warning( disable : 4706) /* assignment within conditional function */ # endif #endif /*=============== internal macros ===========================*/ /*============ functions in alphabetical order ===================*/ /*---------------------------------- qh_setaddnth(qh, setp, nth, newelem ) adds newelem as n'th element of sorted or unsorted *setp notes: *setp and newelem must be defined *setp may be a temp set nth=0 is first element errors if nth is out of bounds design: expand *setp if empty or full move tail of *setp up one insert newelem */ void qh_setaddnth(qhT *qh, setT **setp, int nth, void *newelem) { int oldsize, i; setelemT *sizep; /* avoid strict aliasing */ setelemT *oldp, *newp; if (!*setp || (sizep= SETsizeaddr_(*setp))->i==0) { qh_setlarger(qh, setp); sizep= SETsizeaddr_(*setp); } oldsize= sizep->i - 1; if (nth < 0 || nth > oldsize) { qh_fprintf(qh, qh->qhmem.ferr, 6171, "qhull internal error (qh_setaddnth): nth %d is out-of-bounds for set:\n", nth); qh_setprint(qh, qh->qhmem.ferr, "", *setp); qh_errexit(qh, qhmem_ERRqhull, NULL, NULL); } sizep->i++; oldp= (setelemT *)SETelemaddr_(*setp, oldsize, void); /* NULL */ newp= oldp+1; for (i=oldsize-nth+1; i--; ) /* move at least NULL */ (newp--)->p= (oldp--)->p; /* may overwrite *sizep */ newp->p= newelem; } /* setaddnth */ /*---------------------------------- setaddsorted( setp, newelem ) adds an newelem into sorted *setp notes: *setp and newelem must be defined *setp may be a temp set nop if newelem already in set design: find newelem's position in *setp insert newelem */ void qh_setaddsorted(qhT *qh, setT **setp, void *newelem) { int newindex=0; void *elem, **elemp; FOREACHelem_(*setp) { /* could use binary search instead */ if (elem < newelem) newindex++; else if (elem == newelem) return; else break; } qh_setaddnth(qh, setp, newindex, newelem); } /* setaddsorted */ /*--------------------------------- qh_setappend(qh, setp, newelem ) append newelem to *setp notes: *setp may be a temp set *setp and newelem may be NULL design: expand *setp if empty or full append newelem to *setp */ void qh_setappend(qhT *qh, setT **setp, void *newelem) { setelemT *sizep; /* Avoid strict aliasing. Writing to *endp may overwrite *sizep */ setelemT *endp; int count; if (!newelem) return; if (!*setp || (sizep= SETsizeaddr_(*setp))->i==0) { qh_setlarger(qh, setp); sizep= SETsizeaddr_(*setp); } count= (sizep->i)++ - 1; endp= (setelemT *)SETelemaddr_(*setp, count, void); (endp++)->p= newelem; endp->p= NULL; } /* setappend */ /*--------------------------------- qh_setappend_set(qh, setp, setA ) appends setA to *setp notes: *setp can not be a temp set *setp and setA may be NULL design: setup for copy expand *setp if it is too small append all elements of setA to *setp */ void qh_setappend_set(qhT *qh, setT **setp, setT *setA) { int sizeA, size; setT *oldset; setelemT *sizep; if (!setA) return; SETreturnsize_(setA, sizeA); if (!*setp) *setp= qh_setnew(qh, sizeA); sizep= SETsizeaddr_(*setp); if (!(size= sizep->i)) size= (*setp)->maxsize; else size--; if (size + sizeA > (*setp)->maxsize) { oldset= *setp; *setp= qh_setcopy(qh, oldset, sizeA); qh_setfree(qh, &oldset); sizep= SETsizeaddr_(*setp); } if (sizeA > 0) { sizep->i= size+sizeA+1; /* memcpy may overwrite */ memcpy((char *)&((*setp)->e[size].p), (char *)&(setA->e[0].p), (size_t)(sizeA+1) * SETelemsize); } } /* setappend_set */ /*--------------------------------- qh_setappend2ndlast(qh, setp, newelem ) makes newelem the next to the last element in *setp notes: *setp must have at least one element newelem must be defined *setp may be a temp set design: expand *setp if empty or full move last element of *setp up one insert newelem */ void qh_setappend2ndlast(qhT *qh, setT **setp, void *newelem) { setelemT *sizep; /* Avoid strict aliasing. Writing to *endp may overwrite *sizep */ setelemT *endp, *lastp; int count; if (!*setp || (sizep= SETsizeaddr_(*setp))->i==0) { qh_setlarger(qh, setp); sizep= SETsizeaddr_(*setp); } count= (sizep->i)++ - 1; endp= (setelemT *)SETelemaddr_(*setp, count, void); /* NULL */ lastp= endp-1; *(endp++)= *lastp; endp->p= NULL; /* may overwrite *sizep */ lastp->p= newelem; } /* setappend2ndlast */ /*--------------------------------- qh_setcheck(qh, set, typename, id ) check set for validity report errors with typename and id design: checks that maxsize, actual size, and NULL terminator agree */ void qh_setcheck(qhT *qh, setT *set, const char *tname, unsigned int id) { int maxsize, size; int waserr= 0; if (!set) return; SETreturnsize_(set, size); maxsize= set->maxsize; if (size > maxsize || !maxsize) { qh_fprintf(qh, qh->qhmem.ferr, 6172, "qhull internal error (qh_setcheck): actual size %d of %s%d is greater than max size %d\n", size, tname, id, maxsize); waserr= 1; }else if (set->e[size].p) { qh_fprintf(qh, qh->qhmem.ferr, 6173, "qhull internal error (qh_setcheck): %s%d(size %d max %d) is not null terminated.\n", tname, id, size-1, maxsize); waserr= 1; } if (waserr) { qh_setprint(qh, qh->qhmem.ferr, "ERRONEOUS", set); qh_errexit(qh, qhmem_ERRqhull, NULL, NULL); } } /* setcheck */ /*--------------------------------- qh_setcompact(qh, set ) remove internal NULLs from an unsorted set returns: updated set notes: set may be NULL it would be faster to swap tail of set into holes, like qh_setdel design: setup pointers into set skip NULLs while copying elements to start of set update the actual size */ void qh_setcompact(qhT *qh, setT *set) { int size; void **destp, **elemp, **endp, **firstp; if (!set) return; SETreturnsize_(set, size); destp= elemp= firstp= SETaddr_(set, void); endp= destp + size; while (1) { if (!(*destp++= *elemp++)) { destp--; if (elemp > endp) break; } } qh_settruncate(qh, set, (int)(destp-firstp)); /* WARN64 */ } /* setcompact */ /*--------------------------------- qh_setcopy(qh, set, extra ) make a copy of a sorted or unsorted set with extra slots returns: new set design: create a newset with extra slots copy the elements to the newset */ setT *qh_setcopy(qhT *qh, setT *set, int extra) { setT *newset; int size; if (extra < 0) extra= 0; SETreturnsize_(set, size); newset= qh_setnew(qh, size+extra); SETsizeaddr_(newset)->i= size+1; /* memcpy may overwrite */ memcpy((char *)&(newset->e[0].p), (char *)&(set->e[0].p), (size_t)(size+1) * SETelemsize); return(newset); } /* setcopy */ /*--------------------------------- qh_setdel(set, oldelem ) delete oldelem from an unsorted set returns: returns oldelem if found returns NULL otherwise notes: set may be NULL oldelem must not be NULL; only deletes one copy of oldelem in set design: locate oldelem update actual size if it was full move the last element to the oldelem's location */ void *qh_setdel(setT *set, void *oldelem) { setelemT *sizep; setelemT *elemp; setelemT *lastp; if (!set) return NULL; elemp= (setelemT *)SETaddr_(set, void); while (elemp->p != oldelem && elemp->p) elemp++; if (elemp->p) { sizep= SETsizeaddr_(set); if (!(sizep->i)--) /* if was a full set */ sizep->i= set->maxsize; /* *sizep= (maxsize-1)+ 1 */ lastp= (setelemT *)SETelemaddr_(set, sizep->i-1, void); elemp->p= lastp->p; /* may overwrite itself */ lastp->p= NULL; return oldelem; } return NULL; } /* setdel */ /*--------------------------------- qh_setdellast( set ) return last element of set or NULL notes: deletes element from set set may be NULL design: return NULL if empty if full set delete last element and set actual size else delete last element and update actual size */ void *qh_setdellast(setT *set) { int setsize; /* actually, actual_size + 1 */ int maxsize; setelemT *sizep; void *returnvalue; if (!set || !(set->e[0].p)) return NULL; sizep= SETsizeaddr_(set); if ((setsize= sizep->i)) { returnvalue= set->e[setsize - 2].p; set->e[setsize - 2].p= NULL; sizep->i--; }else { maxsize= set->maxsize; returnvalue= set->e[maxsize - 1].p; set->e[maxsize - 1].p= NULL; sizep->i= maxsize; } return returnvalue; } /* setdellast */ /*--------------------------------- qh_setdelnth(qh, set, nth ) deletes nth element from unsorted set 0 is first element returns: returns the element (needs type conversion) notes: errors if nth invalid design: setup points and check nth delete nth element and overwrite with last element */ void *qh_setdelnth(qhT *qh, setT *set, int nth) { void *elem; setelemT *sizep; setelemT *elemp, *lastp; sizep= SETsizeaddr_(set); if ((sizep->i--)==0) /* if was a full set */ sizep->i= set->maxsize; /* *sizep= (maxsize-1)+ 1 */ if (nth < 0 || nth >= sizep->i) { qh_fprintf(qh, qh->qhmem.ferr, 6174, "qhull internal error (qh_setdelnth): nth %d is out-of-bounds for set:\n", nth); qh_setprint(qh, qh->qhmem.ferr, "", set); qh_errexit(qh, qhmem_ERRqhull, NULL, NULL); } elemp= (setelemT *)SETelemaddr_(set, nth, void); /* nth valid by QH6174 */ lastp= (setelemT *)SETelemaddr_(set, sizep->i-1, void); elem= elemp->p; elemp->p= lastp->p; /* may overwrite itself */ lastp->p= NULL; return elem; } /* setdelnth */ /*--------------------------------- qh_setdelnthsorted(qh, set, nth ) deletes nth element from sorted set returns: returns the element (use type conversion) notes: errors if nth invalid see also: setnew_delnthsorted design: setup points and check nth copy remaining elements down one update actual size */ void *qh_setdelnthsorted(qhT *qh, setT *set, int nth) { void *elem; setelemT *sizep; setelemT *newp, *oldp; sizep= SETsizeaddr_(set); if (nth < 0 || (sizep->i && nth >= sizep->i-1) || nth >= set->maxsize) { qh_fprintf(qh, qh->qhmem.ferr, 6175, "qhull internal error (qh_setdelnthsorted): nth %d is out-of-bounds for set:\n", nth); qh_setprint(qh, qh->qhmem.ferr, "", set); qh_errexit(qh, qhmem_ERRqhull, NULL, NULL); } newp= (setelemT *)SETelemaddr_(set, nth, void); elem= newp->p; oldp= newp+1; while (((newp++)->p= (oldp++)->p)) ; /* copy remaining elements and NULL */ if ((sizep->i--)==0) /* if was a full set */ sizep->i= set->maxsize; /* *sizep= (max size-1)+ 1 */ return elem; } /* setdelnthsorted */ /*--------------------------------- qh_setdelsorted( set, oldelem ) deletes oldelem from sorted set returns: returns oldelem if it was deleted notes: set may be NULL design: locate oldelem in set copy remaining elements down one update actual size */ void *qh_setdelsorted(setT *set, void *oldelem) { setelemT *sizep; setelemT *newp, *oldp; if (!set) return NULL; newp= (setelemT *)SETaddr_(set, void); while(newp->p != oldelem && newp->p) newp++; if (newp->p) { oldp= newp+1; while (((newp++)->p= (oldp++)->p)) ; /* copy remaining elements */ sizep= SETsizeaddr_(set); if ((sizep->i--)==0) /* if was a full set */ sizep->i= set->maxsize; /* *sizep= (max size-1)+ 1 */ return oldelem; } return NULL; } /* setdelsorted */ /*--------------------------------- qh_setduplicate(qh, set, elemsize ) duplicate a set of elemsize elements notes: use setcopy if retaining old elements design: create a new set for each elem of the old set create a newelem append newelem to newset */ setT *qh_setduplicate(qhT *qh, setT *set, int elemsize) { void *elem, **elemp, *newElem; setT *newSet; int size; if (!(size= qh_setsize(qh, set))) return NULL; newSet= qh_setnew(qh, size); FOREACHelem_(set) { newElem= qh_memalloc(qh, elemsize); memcpy(newElem, elem, (size_t)elemsize); qh_setappend(qh, &newSet, newElem); } return newSet; } /* setduplicate */ /*--------------------------------- qh_setendpointer( set ) Returns pointer to NULL terminator of a set's elements set can not be NULL */ void **qh_setendpointer(setT *set) { setelemT *sizep= SETsizeaddr_(set); int n= sizep->i; return (n ? &set->e[n-1].p : &sizep->p); } /* qh_setendpointer */ /*--------------------------------- qh_setequal( setA, setB ) returns 1 if two sorted sets are equal, otherwise returns 0 notes: either set may be NULL design: check size of each set setup pointers compare elements of each set */ int qh_setequal(setT *setA, setT *setB) { void **elemAp, **elemBp; int sizeA= 0, sizeB= 0; if (setA) { SETreturnsize_(setA, sizeA); } if (setB) { SETreturnsize_(setB, sizeB); } if (sizeA != sizeB) return 0; if (!sizeA) return 1; elemAp= SETaddr_(setA, void); elemBp= SETaddr_(setB, void); if (!memcmp((char *)elemAp, (char *)elemBp, (size_t)(sizeA * SETelemsize))) return 1; return 0; } /* setequal */ /*--------------------------------- qh_setequal_except( setA, skipelemA, setB, skipelemB ) returns 1 if sorted setA and setB are equal except for skipelemA & B returns: false if either skipelemA or skipelemB are missing notes: neither set may be NULL if skipelemB is NULL, can skip any one element of setB design: setup pointers search for skipelemA, skipelemB, and mismatches check results */ int qh_setequal_except(setT *setA, void *skipelemA, setT *setB, void *skipelemB) { void **elemA, **elemB; int skip=0; elemA= SETaddr_(setA, void); elemB= SETaddr_(setB, void); while (1) { if (*elemA == skipelemA) { skip++; elemA++; } if (skipelemB) { if (*elemB == skipelemB) { skip++; elemB++; } }else if (*elemA != *elemB) { skip++; if (!(skipelemB= *elemB++)) return 0; } if (!*elemA) break; if (*elemA++ != *elemB++) return 0; } if (skip != 2 || *elemB) return 0; return 1; } /* setequal_except */ /*--------------------------------- qh_setequal_skip( setA, skipA, setB, skipB ) returns 1 if sorted setA and setB are equal except for elements skipA & B returns: false if different size notes: neither set may be NULL design: setup pointers search for mismatches while skipping skipA and skipB */ int qh_setequal_skip(setT *setA, int skipA, setT *setB, int skipB) { void **elemA, **elemB, **skipAp, **skipBp; elemA= SETaddr_(setA, void); elemB= SETaddr_(setB, void); skipAp= SETelemaddr_(setA, skipA, void); skipBp= SETelemaddr_(setB, skipB, void); while (1) { if (elemA == skipAp) elemA++; if (elemB == skipBp) elemB++; if (!*elemA) break; if (*elemA++ != *elemB++) return 0; } if (*elemB) return 0; return 1; } /* setequal_skip */ /*--------------------------------- qh_setfree(qh, setp ) frees the space occupied by a sorted or unsorted set returns: sets setp to NULL notes: set may be NULL design: free array free set */ void qh_setfree(qhT *qh, setT **setp) { int size; void **freelistp; /* used if !qh_NOmem by qh_memfree_() */ if (*setp) { size= (int)sizeof(setT) + ((*setp)->maxsize)*SETelemsize; if (size <= qh->qhmem.LASTsize) { qh_memfree_(qh, *setp, size, freelistp); }else qh_memfree(qh, *setp, size); *setp= NULL; } } /* setfree */ /*--------------------------------- qh_setfree2(qh, setp, elemsize ) frees the space occupied by a set and its elements notes: set may be NULL design: free each element free set */ void qh_setfree2(qhT *qh, setT **setp, int elemsize) { void *elem, **elemp; FOREACHelem_(*setp) qh_memfree(qh, elem, elemsize); qh_setfree(qh, setp); } /* setfree2 */ /*--------------------------------- qh_setfreelong(qh, setp ) frees a set only if it's in long memory returns: sets setp to NULL if it is freed notes: set may be NULL design: if set is large free it */ void qh_setfreelong(qhT *qh, setT **setp) { int size; if (*setp) { size= (int)sizeof(setT) + ((*setp)->maxsize)*SETelemsize; if (size > qh->qhmem.LASTsize) { qh_memfree(qh, *setp, size); *setp= NULL; } } } /* setfreelong */ /*--------------------------------- qh_setin( set, setelem ) returns 1 if setelem is in a set, 0 otherwise notes: set may be NULL or unsorted design: scans set for setelem */ int qh_setin(setT *set, void *setelem) { void *elem, **elemp; FOREACHelem_(set) { if (elem == setelem) return 1; } return 0; } /* setin */ /*--------------------------------- qh_setindex(set, atelem ) returns the index of atelem in set. returns -1, if not in set or maxsize wrong notes: set may be NULL and may contain nulls. NOerrors returned (qh_pointid, QhullPoint::id) design: checks maxsize scans set for atelem */ int qh_setindex(setT *set, void *atelem) { void **elem; int size, i; if (!set) return -1; SETreturnsize_(set, size); if (size > set->maxsize) return -1; elem= SETaddr_(set, void); for (i=0; i < size; i++) { if (*elem++ == atelem) return i; } return -1; } /* setindex */ /*--------------------------------- qh_setlarger(qh, oldsetp ) returns a larger set that contains all elements of *oldsetp notes: if long memory, the new set is 2x larger if qhmem.LASTsize is between 1.5x and 2x the new set is qhmem.LASTsize otherwise use quick memory, the new set is 2x larger, rounded up to next qh_memsize if temp set, updates qh->qhmem.tempstack design: creates a new set copies the old set to the new set updates pointers in tempstack deletes the old set */ void qh_setlarger(qhT *qh, setT **oldsetp) { int setsize= 1, newsize; setT *newset, *set, **setp, *oldset; setelemT *sizep; setelemT *newp, *oldp; if (*oldsetp) { oldset= *oldsetp; SETreturnsize_(oldset, setsize); qh->qhmem.cntlarger++; qh->qhmem.totlarger += setsize+1; qh_setlarger_quick(qh, setsize, &newsize); newset= qh_setnew(qh, newsize); oldp= (setelemT *)SETaddr_(oldset, void); newp= (setelemT *)SETaddr_(newset, void); memcpy((char *)newp, (char *)oldp, (size_t)(setsize+1) * SETelemsize); sizep= SETsizeaddr_(newset); sizep->i= setsize+1; FOREACHset_((setT *)qh->qhmem.tempstack) { if (set == oldset) *(setp-1)= newset; } qh_setfree(qh, oldsetp); }else newset= qh_setnew(qh, 3); *oldsetp= newset; } /* setlarger */ /*--------------------------------- qh_setlarger_quick(qh, setsize, newsize ) determine newsize for setsize returns True if newsize fits in quick memory design: if 2x fits into quick memory return True, 2x if x+4 does not fit into quick memory return False, 2x if x+x/3 fits into quick memory return True, the last quick set otherwise return False, 2x */ int qh_setlarger_quick(qhT *qh, int setsize, int *newsize) { int lastquickset; *newsize= 2 * setsize; lastquickset= (qh->qhmem.LASTsize - (int)sizeof(setT)) / SETelemsize; /* matches size computation in qh_setnew */ if (*newsize <= lastquickset) return 1; if (setsize + 4 > lastquickset) return 0; if (setsize + setsize/3 <= lastquickset) { *newsize= lastquickset; return 1; } return 0; } /* setlarger_quick */ /*--------------------------------- qh_setlast( set ) return last element of set or NULL (use type conversion) notes: set may be NULL design: return last element */ void *qh_setlast(setT *set) { int size; if (set) { size= SETsizeaddr_(set)->i; if (!size) return SETelem_(set, set->maxsize - 1); else if (size > 1) return SETelem_(set, size - 2); } return NULL; } /* setlast */ /*--------------------------------- qh_setnew(qh, setsize ) creates and allocates space for a set notes: setsize means the number of elements (!including the NULL terminator) use qh_settemp/qh_setfreetemp if set is temporary design: allocate memory for set roundup memory if small set initialize as empty set */ setT *qh_setnew(qhT *qh, int setsize) { setT *set; int sizereceived; /* used if !qh_NOmem */ int size; void **freelistp; /* used if !qh_NOmem by qh_memalloc_() */ if (!setsize) setsize++; size= (int)sizeof(setT) + setsize * SETelemsize; /* setT includes NULL terminator, see qh.LASTquickset */ if (size>0 && size <= qh->qhmem.LASTsize) { qh_memalloc_(qh, size, freelistp, set, setT); #ifndef qh_NOmem sizereceived= qh->qhmem.sizetable[ qh->qhmem.indextable[size]]; if (sizereceived > size) setsize += (sizereceived - size)/SETelemsize; #endif }else set= (setT *)qh_memalloc(qh, size); set->maxsize= setsize; set->e[setsize].i= 1; set->e[0].p= NULL; return(set); } /* setnew */ /*--------------------------------- qh_setnew_delnthsorted(qh, set, size, nth, prepend ) creates a sorted set not containing nth element if prepend, the first prepend elements are undefined notes: set must be defined checks nth see also: setdelnthsorted design: create new set setup pointers and allocate room for prepend'ed entries append head of old set to new set append tail of old set to new set */ setT *qh_setnew_delnthsorted(qhT *qh, setT *set, int size, int nth, int prepend) { setT *newset; void **oldp, **newp; int tailsize= size - nth -1, newsize; if (tailsize < 0) { qh_fprintf(qh, qh->qhmem.ferr, 6176, "qhull internal error (qh_setnew_delnthsorted): nth %d is out-of-bounds for set:\n", nth); qh_setprint(qh, qh->qhmem.ferr, "", set); qh_errexit(qh, qhmem_ERRqhull, NULL, NULL); } newsize= size-1 + prepend; newset= qh_setnew(qh, newsize); newset->e[newset->maxsize].i= newsize+1; /* may be overwritten */ oldp= SETaddr_(set, void); newp= SETaddr_(newset, void) + prepend; switch (nth) { case 0: break; case 1: *(newp++)= *oldp++; break; case 2: *(newp++)= *oldp++; *(newp++)= *oldp++; break; case 3: *(newp++)= *oldp++; *(newp++)= *oldp++; *(newp++)= *oldp++; break; case 4: *(newp++)= *oldp++; *(newp++)= *oldp++; *(newp++)= *oldp++; *(newp++)= *oldp++; break; default: memcpy((char *)newp, (char *)oldp, (size_t)nth * SETelemsize); newp += nth; oldp += nth; break; } oldp++; switch (tailsize) { case 0: break; case 1: *(newp++)= *oldp++; break; case 2: *(newp++)= *oldp++; *(newp++)= *oldp++; break; case 3: *(newp++)= *oldp++; *(newp++)= *oldp++; *(newp++)= *oldp++; break; case 4: *(newp++)= *oldp++; *(newp++)= *oldp++; *(newp++)= *oldp++; *(newp++)= *oldp++; break; default: memcpy((char *)newp, (char *)oldp, (size_t)tailsize * SETelemsize); newp += tailsize; } *newp= NULL; return(newset); } /* setnew_delnthsorted */ /*--------------------------------- qh_setprint(qh, fp, string, set ) print set elements to fp with identifying string notes: never errors */ void qh_setprint(qhT *qh, FILE *fp, const char* string, setT *set) { int size, k; if (!set) qh_fprintf(qh, fp, 9346, "%s set is null\n", string); else { SETreturnsize_(set, size); qh_fprintf(qh, fp, 9347, "%s set=%p maxsize=%d size=%d elems=", string, set, set->maxsize, size); if (size > set->maxsize) size= set->maxsize+1; for (k=0; k < size; k++) qh_fprintf(qh, fp, 9348, " %p", set->e[k].p); qh_fprintf(qh, fp, 9349, "\n"); } } /* setprint */ /*--------------------------------- qh_setreplace(qh, set, oldelem, newelem ) replaces oldelem in set with newelem notes: errors if oldelem not in the set newelem may be NULL, but it turns the set into an indexed set (no FOREACH) design: find oldelem replace with newelem */ void qh_setreplace(qhT *qh, setT *set, void *oldelem, void *newelem) { void **elemp; elemp= SETaddr_(set, void); while (*elemp != oldelem && *elemp) elemp++; if (*elemp) *elemp= newelem; else { qh_fprintf(qh, qh->qhmem.ferr, 6177, "qhull internal error (qh_setreplace): elem %p not found in set\n", oldelem); qh_setprint(qh, qh->qhmem.ferr, "", set); qh_errexit(qh, qhmem_ERRqhull, NULL, NULL); } } /* setreplace */ /*--------------------------------- qh_setsize(qh, set ) returns the size of a set notes: errors if set's maxsize is incorrect same as SETreturnsize_(set) same code for qh_setsize [qset_r.c] and QhullSetBase::count if first element is NULL, SETempty_() is True but qh_setsize may be greater than 0 design: determine actual size of set from maxsize */ int qh_setsize(qhT *qh, setT *set) { int size; setelemT *sizep; if (!set) return(0); sizep= SETsizeaddr_(set); if ((size= sizep->i)) { size--; if (size > set->maxsize) { qh_fprintf(qh, qh->qhmem.ferr, 6178, "qhull internal error (qh_setsize): current set size %d is greater than maximum size %d\n", size, set->maxsize); qh_setprint(qh, qh->qhmem.ferr, "set: ", set); qh_errexit(qh, qhmem_ERRqhull, NULL, NULL); } }else size= set->maxsize; return size; } /* setsize */ /*--------------------------------- qh_settemp(qh, setsize ) return a stacked, temporary set of up to setsize elements notes: use settempfree or settempfree_all to release from qh->qhmem.tempstack see also qh_setnew design: allocate set append to qh->qhmem.tempstack */ setT *qh_settemp(qhT *qh, int setsize) { setT *newset; newset= qh_setnew(qh, setsize); qh_setappend(qh, &qh->qhmem.tempstack, newset); if (qh->qhmem.IStracing >= 5) qh_fprintf(qh, qh->qhmem.ferr, 8123, "qh_settemp: temp set %p of %d elements, depth %d\n", newset, newset->maxsize, qh_setsize(qh, qh->qhmem.tempstack)); return newset; } /* settemp */ /*--------------------------------- qh_settempfree(qh, set ) free temporary set at top of qh->qhmem.tempstack notes: nop if set is NULL errors if set not from previous qh_settemp to locate errors: use 'T2' to find source and then find mis-matching qh_settemp design: check top of qh->qhmem.tempstack free it */ void qh_settempfree(qhT *qh, setT **set) { setT *stackedset; if (!*set) return; stackedset= qh_settemppop(qh); if (stackedset != *set) { qh_settemppush(qh, stackedset); qh_fprintf(qh, qh->qhmem.ferr, 6179, "qhull internal error (qh_settempfree): set %p(size %d) was not last temporary allocated(depth %d, set %p, size %d)\n", *set, qh_setsize(qh, *set), qh_setsize(qh, qh->qhmem.tempstack)+1, stackedset, qh_setsize(qh, stackedset)); qh_errexit(qh, qhmem_ERRqhull, NULL, NULL); } qh_setfree(qh, set); } /* settempfree */ /*--------------------------------- qh_settempfree_all(qh) free all temporary sets in qh->qhmem.tempstack design: for each set in tempstack free set free qh->qhmem.tempstack */ void qh_settempfree_all(qhT *qh) { setT *set, **setp; FOREACHset_(qh->qhmem.tempstack) qh_setfree(qh, &set); qh_setfree(qh, &qh->qhmem.tempstack); } /* settempfree_all */ /*--------------------------------- qh_settemppop(qh) pop and return temporary set from qh->qhmem.tempstack notes: the returned set is permanent design: pop and check top of qh->qhmem.tempstack */ setT *qh_settemppop(qhT *qh) { setT *stackedset; stackedset= (setT *)qh_setdellast(qh->qhmem.tempstack); if (!stackedset) { qh_fprintf(qh, qh->qhmem.ferr, 6180, "qhull internal error (qh_settemppop): pop from empty temporary stack\n"); qh_errexit(qh, qhmem_ERRqhull, NULL, NULL); } if (qh->qhmem.IStracing >= 5) qh_fprintf(qh, qh->qhmem.ferr, 8124, "qh_settemppop: depth %d temp set %p of %d elements\n", qh_setsize(qh, qh->qhmem.tempstack)+1, stackedset, qh_setsize(qh, stackedset)); return stackedset; } /* settemppop */ /*--------------------------------- qh_settemppush(qh, set ) push temporary set unto qh->qhmem.tempstack (makes it temporary) notes: duplicates settemp() for tracing design: append set to tempstack */ void qh_settemppush(qhT *qh, setT *set) { if (!set) { qh_fprintf(qh, qh->qhmem.ferr, 6267, "qhull error (qh_settemppush): can not push a NULL temp\n"); qh_errexit(qh, qhmem_ERRqhull, NULL, NULL); } qh_setappend(qh, &qh->qhmem.tempstack, set); if (qh->qhmem.IStracing >= 5) qh_fprintf(qh, qh->qhmem.ferr, 8125, "qh_settemppush: depth %d temp set %p of %d elements\n", qh_setsize(qh, qh->qhmem.tempstack), set, qh_setsize(qh, set)); } /* settemppush */ /*--------------------------------- qh_settruncate(qh, set, size ) truncate set to size elements notes: set must be defined see: SETtruncate_ design: check size update actual size of set */ void qh_settruncate(qhT *qh, setT *set, int size) { if (size < 0 || size > set->maxsize) { qh_fprintf(qh, qh->qhmem.ferr, 6181, "qhull internal error (qh_settruncate): size %d out of bounds for set:\n", size); qh_setprint(qh, qh->qhmem.ferr, "", set); qh_errexit(qh, qhmem_ERRqhull, NULL, NULL); } set->e[set->maxsize].i= size+1; /* maybe overwritten */ set->e[size].p= NULL; } /* settruncate */ /*--------------------------------- qh_setunique(qh, set, elem ) add elem to unsorted set unless it is already in set notes: returns 1 if it is appended design: if elem not in set append elem to set */ int qh_setunique(qhT *qh, setT **set, void *elem) { if (!qh_setin(*set, elem)) { qh_setappend(qh, set, elem); return 1; } return 0; } /* setunique */ /*--------------------------------- qh_setzero(qh, set, index, size ) zero elements from index on set actual size of set to size notes: set must be defined the set becomes an indexed set (can not use FOREACH...) see also: qh_settruncate design: check index and size update actual size zero elements starting at e[index] */ void qh_setzero(qhT *qh, setT *set, int idx, int size) { int count; if (idx < 0 || idx >= size || size > set->maxsize) { qh_fprintf(qh, qh->qhmem.ferr, 6182, "qhull internal error (qh_setzero): index %d or size %d out of bounds for set:\n", idx, size); qh_setprint(qh, qh->qhmem.ferr, "", set); qh_errexit(qh, qhmem_ERRqhull, NULL, NULL); } set->e[set->maxsize].i= size+1; /* may be overwritten */ count= size - idx + 1; /* +1 for NULL terminator */ memset((char *)SETelemaddr_(set, idx, void), 0, (size_t)count * SETelemsize); } /* setzero */