/** \ingroup header * \file rpmdb/header.c */ /* RPM - Copyright (C) 1995-2000 Red Hat Software */ /* Data written to file descriptors is in network byte order. */ /* Data read from file descriptors is expected to be in */ /* network byte order and is converted on the fly to host order. */ #include "system.h" #include #include #include #define __HEADER_PROTOTYPES__ #include /* We get parseEVR() from there used in parsing the >-test in conditionals: */ #include "rpmlib.h" #include "debug.h" /*@-redecl@*/ /* FIX: avoid rpmlib.h, need for debugging. */ /*@observer@*/ const char * tagName(int tag) /*@*/; /*@=redecl@*/ /*@access entryInfo @*/ /*@access indexEntry @*/ /*@access extensionCache @*/ /*@access sprintfTag @*/ /*@access sprintfToken @*/ /*@access HV_t @*/ #define PARSER_BEGIN 0 #define PARSER_IN_ARRAY 1 #define PARSER_IN_EXPR 2 /** \ingroup header */ /*@observer@*/ /*@unchecked@*/ static unsigned char header_magic[8] = { 0x8e, 0xad, 0xe8, 0x01, 0x00, 0x00, 0x00, 0x00 }; /** \ingroup header * Maximum no. of bytes permitted in a header. */ /*@unchecked@*/ static size_t headerMaxbytes = (32*1024*1024); /** * Sanity check on no. of tags. * This check imposes a limit of 65K tags, more than enough. */ #define hdrchkTags(_ntags) ((_ntags) & 0xffff0000) /** * Sanity check on data size and/or offset. * This check imposes a limit of 16Mb, more than enough. */ #define hdrchkData(_nbytes) ((_nbytes) & 0xff000000) /** * Sanity check on range of data offset. */ #define hdrchkRange(_dl, _off) ((_off) < 0 || (_off) > (_dl)) /** \ingroup header * Alignment needs (and sizeof scalars types) for internal rpm data types. */ /*@observer@*/ /*@unchecked@*/ static int typeSizes[] = { 0, /*!< RPM_NULL_TYPE */ 1, /*!< RPM_CHAR_TYPE */ 1, /*!< RPM_INT8_TYPE */ 2, /*!< RPM_INT16_TYPE */ 4, /*!< RPM_INT32_TYPE */ -1, /*!< RPM_INT64_TYPE */ -1, /*!< RPM_STRING_TYPE */ 1, /*!< RPM_BIN_TYPE */ -1, /*!< RPM_STRING_ARRAY_TYPE */ -1 /*!< RPM_I18NSTRING_TYPE */ }; /*@observer@*/ /*@unchecked@*/ HV_t hdrVec; /* forward reference */ /* Already defined in */ #if 0 /** * Wrapper to free(3), hides const compilation noise, permit NULL, return NULL. * @param p memory to free * @return NULL always */ /*@unused@*/ static inline /*@null@*/ void * _free(/*@only@*/ /*@null@*/ /*@out@*/ const void * p) /*@modifies *p @*/ { if (p != NULL) free((void *)p); return NULL; } #endif /** \ingroup header * Reference a header instance. * @param h header * @return referenced header instance */ static Header headerLink(Header h) /*@modifies h @*/ { if (h != NULL) h->nrefs++; /*@-refcounttrans -nullret @*/ return h; /*@=refcounttrans =nullret @*/ } /** \ingroup header * Dereference a header instance. * @param h header * @return NULL always */ static /*@null@*/ Header headerUnlink(/*@killref@*/ /*@null@*/ Header h) /*@modifies h @*/ { if (h != NULL) h->nrefs--; return NULL; } /** \ingroup header * Dereference a header instance. * @param h header * @return NULL always */ static /*@null@*/ Header headerFree(/*@killref@*/ /*@null@*/ Header h) /*@modifies h @*/ { (void) headerUnlink(h); /*@-usereleased@*/ if (h == NULL || h->nrefs > 0) return NULL; /* XXX return previous header? */ if (h->index) { indexEntry entry = h->index; int i; for (i = 0; i < h->indexUsed; i++, entry++) { if ((h->flags & HEADERFLAG_ALLOCATED) && ENTRY_IS_REGION(entry)) { if (entry->length > 0) { int_32 * ei = entry->data; if ((ei - 2) == h->blob) h->blob = _free(h->blob); entry->data = NULL; } } else if (!ENTRY_IN_REGION(entry)) { entry->data = _free(entry->data); } entry->data = NULL; } h->index = _free(h->index); } /*@-refcounttrans@*/ h = _free(h); /*@=refcounttrans@*/ return h; /*@=usereleased@*/ } /** \ingroup header * Create new (empty) header instance. * @return header */ static Header headerNew(void) /*@*/ { Header h = xcalloc(1, sizeof(*h)); /*@-assignexpose@*/ h->hv = *hdrVec; /* structure assignment */ /*@=assignexpose@*/ h->blob = NULL; h->indexAlloced = INDEX_MALLOC_SIZE; h->indexUsed = 0; h->instance = 0; h->flags = HEADERFLAG_SORTED; h->index = (h->indexAlloced ? xcalloc(h->indexAlloced, sizeof(*h->index)) : NULL); /*@-globstate -observertrans @*/ h->nrefs = 0; return headerLink(h); /*@=globstate =observertrans @*/ } /** */ static int indexCmp(const void * avp, const void * bvp) /*@*/ { /*@-castexpose@*/ indexEntry ap = (indexEntry) avp, bp = (indexEntry) bvp; /*@=castexpose@*/ return (ap->info.tag - bp->info.tag); } /** \ingroup header * Sort tags in header. * @param h header */ static void headerSort(Header h) /*@modifies h @*/ { if (!(h->flags & HEADERFLAG_SORTED)) { qsort(h->index, h->indexUsed, sizeof(*h->index), indexCmp); h->flags |= HEADERFLAG_SORTED; } } /** */ static int offsetCmp(const void * avp, const void * bvp) /*@*/ { /*@-castexpose@*/ indexEntry ap = (indexEntry) avp, bp = (indexEntry) bvp; /*@=castexpose@*/ int rc = (ap->info.offset - bp->info.offset); if (rc == 0) { /* Within a region, entries sort by address. Added drips sort by tag. */ if (ap->info.offset < 0) rc = (((char *)ap->data) - ((char *)bp->data)); else rc = (ap->info.tag - bp->info.tag); } return rc; } /** \ingroup header * Restore tags in header to original ordering. * @param h header */ static void headerUnsort(Header h) /*@modifies h @*/ { qsort(h->index, h->indexUsed, sizeof(*h->index), offsetCmp); } /** \ingroup header * Return size of on-disk header representation in bytes. * @param h header * @param magicp include size of 8 bytes for (magic, 0)? * @return size of on-disk header */ static unsigned int headerSizeof(/*@null@*/ Header h, enum hMagic magicp) /*@modifies h @*/ { indexEntry entry; unsigned int size = 0; unsigned int pad = 0; int i; if (h == NULL) return size; headerSort(h); switch (magicp) { case HEADER_MAGIC_YES: size += sizeof(header_magic); break; case HEADER_MAGIC_NO: break; } /*@-sizeoftype@*/ size += 2 * sizeof(int_32); /* count of index entries */ /*@=sizeoftype@*/ for (i = 0, entry = h->index; i < h->indexUsed; i++, entry++) { unsigned diff; int_32 type; /* Regions go in as is ... */ if (ENTRY_IS_REGION(entry)) { size += entry->length; /* XXX Legacy regions do not include the region tag and data. */ /*@-sizeoftype@*/ if (i == 0 && (h->flags & HEADERFLAG_LEGACY)) size += sizeof(struct entryInfo) + entry->info.count; /*@=sizeoftype@*/ continue; } /* ... and region elements are skipped. */ if (entry->info.offset < 0) continue; /* Alignment */ type = entry->info.type; if (typeSizes[type] > 1) { diff = typeSizes[type] - (size % typeSizes[type]); if (diff != typeSizes[type]) { size += diff; pad += diff; } } /*@-sizeoftype@*/ size += sizeof(struct entryInfo) + entry->length; /*@=sizeoftype@*/ } return size; } /** * Return length of entry data. * @todo Remove sanity check exit's. * @param type entry data type * @param p entry data * @param count entry item count * @param onDisk data is concatenated strings (with NUL's))? * @return no. bytes in data */ /*@mayexit@*/ static int dataLength(int_32 type, hPTR_t p, int_32 count, int onDisk) /*@*/ { int length = 0; switch (type) { case RPM_STRING_TYPE: if (count == 1) { /* Special case -- p is just the string */ length = strlen(p) + 1; break; } /* This should not be allowed */ /*@-modfilesys@*/ fprintf(stderr, _("dataLength() RPM_STRING_TYPE count must be 1.\n")); /*@=modfilesys@*/ exit(EXIT_FAILURE); /*@notreached@*/ break; case RPM_STRING_ARRAY_TYPE: case RPM_I18NSTRING_TYPE: /* This is like RPM_STRING_TYPE, except it's *always* an array */ /* Compute sum of length of all strings, including null terminators */ if (onDisk) { const char *end = p; while (count--) end += strlen(end) + 1; length = end - (const char *) p; } else { const char **src = (const char **) p; const char **end = src + count; while (src < end) length += strlen(*src++) + 1; } break; default: if (typeSizes[type] != -1) { length = typeSizes[type] * count; break; } /*@-modfilesys@*/ fprintf(stderr, _("Data type %d not supported\n"), (int) type); /*@=modfilesys@*/ exit(EXIT_FAILURE); /*@notreached@*/ break; } return length; } /** \ingroup header * Swap int_32 and int_16 arrays within header region. * * This code is way more twisty than I would like. * * A bug with RPM_I18NSTRING_TYPE in rpm-2.5.x (fixed in August 1998) * causes the offset and length of elements in a header region to disagree * regarding the total length of the region data. * * The "fix" is to compute the size using both offset and length and * return the larger of the two numbers as the size of the region. * Kinda like computing left and right Riemann sums of the data elements * to determine the size of a data structure, go figger :-). * * There's one other twist if a header region tag is in the set to be swabbed, * as the data for a header region is located after all other tag data. * * @param entry header entry * @param il no. of entries * @param dl start no. bytes of data * @param pe header physical entry pointer (swapped) * @param dataStart header data * @param regionid region offset * @return no. bytes of data in region, -1 on error */ static int regionSwab(/*@null@*/ indexEntry entry, int il, int dl, entryInfo pe, char * dataStart, int regionid) /*@modifies *entry, *dataStart @*/ { char * tprev = NULL; char * t = NULL; int tdel, tl = dl; struct indexEntry ieprev; if ((entry != NULL && regionid >= 0) || (entry == NULL && regionid != 0)) return -1; memset(&ieprev, 0, sizeof(ieprev)); for (; il > 0; il--, pe++) { struct indexEntry ie; int_32 type; ie.info.tag = ntohl(pe->tag); ie.info.type = ntohl(pe->type); if (ie.info.type < RPM_MIN_TYPE || ie.info.type > RPM_MAX_TYPE) return -1; ie.info.count = ntohl(pe->count); ie.info.offset = ntohl(pe->offset); ie.data = t = dataStart + ie.info.offset; ie.length = dataLength(ie.info.type, ie.data, ie.info.count, 1); ie.rdlen = 0; if (entry) { ie.info.offset = regionid; *entry = ie; /* structure assignment */ entry++; } /* Alignment */ type = ie.info.type; if (typeSizes[type] > 1) { unsigned diff; diff = typeSizes[type] - (dl % typeSizes[type]); if (diff != typeSizes[type]) { dl += diff; if (ieprev.info.type == RPM_I18NSTRING_TYPE) ieprev.length += diff; } } tdel = (tprev ? (t - tprev) : 0); if (ieprev.info.type == RPM_I18NSTRING_TYPE) tdel = ieprev.length; if (ie.info.tag >= HEADER_I18NTABLE) { tprev = t; } else { tprev = dataStart; /* XXX HEADER_IMAGE tags don't include region sub-tag. */ /*@-sizeoftype@*/ if (ie.info.tag == HEADER_IMAGE) tprev -= REGION_TAG_COUNT; /*@=sizeoftype@*/ } /* Perform endian conversions */ switch (type) { case RPM_INT32_TYPE: { int_32 *it = (int_32 *) t; t = (char *)(it + ie.info.count); for (; it < (int_32 *) t; ++it) *it = htonl(*it); } /*@switchbreak@*/ break; case RPM_INT16_TYPE: { int_16 *it = (int_16 *) t; t = (char *)(it + ie.info.count); for (; it < (int_16 *) t; ++it) *it = htons(*it); } /*@switchbreak@*/ break; default: t += ie.length; /*@switchbreak@*/ break; } dl += ie.length; tl += tdel; ieprev = ie; /* structure assignment */ } tdel = (tprev ? (t - tprev) : 0); tl += tdel; /* XXX * There are two hacks here: * 1) tl is 16b (i.e. REGION_TAG_COUNT) short while doing headerReload(). * 2) the 8/98 rpm bug with inserting i18n tags needs to use tl, not dl. */ /*@-sizeoftype@*/ if (tl+REGION_TAG_COUNT == dl) tl += REGION_TAG_COUNT; /*@=sizeoftype@*/ return dl; } /** \ingroup header */ static /*@only@*/ /*@null@*/ void * doHeaderUnload(Header h, /*@out@*/ int * lengthPtr) /*@modifies h, *lengthPtr @*/ { int_32 * ei = NULL; entryInfo pe; char * dataStart; char * te; unsigned pad; unsigned len; int_32 il = 0; int_32 dl = 0; indexEntry entry; int_32 type; int i; int drlen, ndribbles; int driplen, ndrips; /* Sort entries by (offset,tag). */ headerUnsort(h); /* Compute (il,dl) for all tags, including those deleted in region. */ pad = 0; drlen = ndribbles = driplen = ndrips = 0; for (i = 0, entry = h->index; i < h->indexUsed; i++, entry++) { if (ENTRY_IS_REGION(entry)) { int_32 rdl = -entry->info.offset; /* negative offset */ int_32 ril = rdl/sizeof(*pe); int rid = entry->info.offset; il += ril; dl += entry->rdlen + entry->info.count; /* XXX Legacy regions do not include the region tag and data. */ if (i == 0 && (h->flags & HEADERFLAG_LEGACY)) il += 1; /* Skip rest of entries in region, but account for dribbles. */ for (; i < h->indexUsed && entry->info.offset <= rid+1; i++, entry++) { if (entry->info.offset <= rid) /*@innercontinue@*/ continue; /* Alignment */ type = entry->info.type; if (typeSizes[type] > 1) { unsigned diff; diff = typeSizes[type] - (dl % typeSizes[type]); if (diff != typeSizes[type]) { drlen += diff; pad += diff; dl += diff; } } ndribbles++; il++; drlen += entry->length; dl += entry->length; } i--; entry--; continue; } /* Ignore deleted drips. */ if (entry->data == NULL || entry->length <= 0) continue; /* Alignment */ type = entry->info.type; if (typeSizes[type] > 1) { unsigned diff; diff = typeSizes[type] - (dl % typeSizes[type]); if (diff != typeSizes[type]) { driplen += diff; pad += diff; dl += diff; } else diff = 0; } ndrips++; il++; driplen += entry->length; dl += entry->length; } /* Sanity checks on header intro. */ if (hdrchkTags(il) || hdrchkData(dl)) goto errxit; len = sizeof(il) + sizeof(dl) + (il * sizeof(*pe)) + dl; ei = xmalloc(len); ei[0] = htonl(il); ei[1] = htonl(dl); pe = (entryInfo) &ei[2]; dataStart = te = (char *) (pe + il); pad = 0; for (i = 0, entry = h->index; i < h->indexUsed; i++, entry++) { const char * src; char *t; int count; int rdlen; if (entry->data == NULL || entry->length <= 0) continue; t = te; pe->tag = htonl(entry->info.tag); pe->type = htonl(entry->info.type); pe->count = htonl(entry->info.count); if (ENTRY_IS_REGION(entry)) { int_32 rdl = -entry->info.offset; /* negative offset */ int_32 ril = rdl/sizeof(*pe) + ndribbles; int rid = entry->info.offset; src = (char *)entry->data; rdlen = entry->rdlen; /* XXX Legacy regions do not include the region tag and data. */ if (i == 0 && (h->flags & HEADERFLAG_LEGACY)) { int_32 stei[4]; memcpy(pe+1, src, rdl); memcpy(te, src + rdl, rdlen); te += rdlen; pe->offset = htonl(te - dataStart); stei[0] = pe->tag; stei[1] = pe->type; stei[2] = htonl(-rdl-entry->info.count); stei[3] = pe->count; memcpy(te, stei, entry->info.count); te += entry->info.count; ril++; rdlen += entry->info.count; count = regionSwab(NULL, ril, 0, pe, t, 0); if (count != rdlen) goto errxit; } else { memcpy(pe+1, src + sizeof(*pe), ((ril-1) * sizeof(*pe))); memcpy(te, src + (ril * sizeof(*pe)), rdlen+entry->info.count+drlen); te += rdlen; { /*@-castexpose@*/ entryInfo se = (entryInfo)src; /*@=castexpose@*/ int off = ntohl(se->offset); pe->offset = (off) ? htonl(te - dataStart) : htonl(off); } te += entry->info.count + drlen; count = regionSwab(NULL, ril, 0, pe, t, 0); if (count != (rdlen + entry->info.count + drlen)) goto errxit; } /* Skip rest of entries in region. */ while (i < h->indexUsed && entry->info.offset <= rid+1) { i++; entry++; } i--; entry--; pe += ril; continue; } /* Ignore deleted drips. */ if (entry->data == NULL || entry->length <= 0) continue; /* Alignment */ type = entry->info.type; if (typeSizes[type] > 1) { unsigned diff; diff = typeSizes[type] - ((te - dataStart) % typeSizes[type]); if (diff != typeSizes[type]) { memset(te, 0, diff); te += diff; pad += diff; } } pe->offset = htonl(te - dataStart); /* copy data w/ endian conversions */ switch (entry->info.type) { case RPM_INT32_TYPE: count = entry->info.count; src = entry->data; while (count--) { *((int_32 *)te) = htonl(*((int_32 *)src)); /*@-sizeoftype@*/ te += sizeof(int_32); src += sizeof(int_32); /*@=sizeoftype@*/ } /*@switchbreak@*/ break; case RPM_INT16_TYPE: count = entry->info.count; src = entry->data; while (count--) { *((int_16 *)te) = htons(*((int_16 *)src)); /*@-sizeoftype@*/ te += sizeof(int_16); src += sizeof(int_16); /*@=sizeoftype@*/ } /*@switchbreak@*/ break; default: memcpy(te, entry->data, entry->length); te += entry->length; /*@switchbreak@*/ break; } pe++; } /* Insure that there are no memcpy underruns/overruns. */ if (((char *)pe) != dataStart) goto errxit; if ((((char *)ei)+len) != te) goto errxit; if (lengthPtr) *lengthPtr = len; h->flags &= ~HEADERFLAG_SORTED; headerSort(h); return (void *) ei; errxit: /*@-usereleased@*/ ei = _free(ei); /*@=usereleased@*/ return (void *) ei; } /** \ingroup header * Convert header to on-disk representation. * @param h header (with pointers) * @return on-disk header blob (i.e. with offsets) */ static /*@only@*/ /*@null@*/ void * headerUnload(Header h) /*@modifies h @*/ { int length; void * uh = doHeaderUnload(h, &length); return uh; } /** * Find matching (tag,type) entry in header. * @param h header * @param tag entry tag * @param type entry type * @return header entry */ static /*@null@*/ indexEntry findEntry(/*@null@*/ Header h, int_32 tag, int_32 type) /*@modifies h @*/ { if (h == NULL) return NULL; if (!(h->flags & HEADERFLAG_SORTED)) headerSort(h); int found = 0; indexEntry entry = NULL; int l = 0; int u = h->indexUsed; while (l < u) { int i = (l + u) / 2; entry = h->index + i; if (tag < entry->info.tag) u = i; else if (tag > entry->info.tag) l = i + 1; else { found = 1; break; } } if (!found) return NULL; if (type == RPM_NULL_TYPE) return entry; /* look backwards */ while (entry->info.tag == tag && entry->info.type != type && entry > h->index) entry--; if (entry->info.tag == tag && entry->info.type == type) return entry; return NULL; } /** \ingroup header * Delete tag in header. * Removes all entries of type tag from the header, returns 1 if none were * found. * * @param h header * @param tag tag * @return 0 on success, 1 on failure (INCONSISTENT) */ static int headerRemoveEntry(Header h, int_32 tag) /*@modifies h @*/ { indexEntry last = h->index + h->indexUsed; indexEntry entry, first; int ne; entry = findEntry(h, tag, RPM_NULL_TYPE); if (!entry) return 1; /* Make sure entry points to the first occurence of this tag. */ while (entry > h->index && (entry - 1)->info.tag == tag) entry--; /* Free data for tags being removed. */ for (first = entry; first < last; first++) { void * data; if (first->info.tag != tag) break; data = first->data; first->data = NULL; first->length = 0; if (ENTRY_IN_REGION(first)) continue; data = _free(data); } ne = (first - entry); if (ne > 0) { h->indexUsed -= ne; ne = last - first; if (ne > 0) memmove(entry, first, (ne * sizeof(*entry))); } return 0; } /** \ingroup header * Convert header to in-memory representation. * @param uh on-disk header blob (i.e. with offsets) * @return header */ static /*@null@*/ Header headerLoad(/*@kept@*/ void * uh) /*@modifies uh @*/ { int_32 * ei = (int_32 *) uh; int_32 il = ntohl(ei[0]); /* index length */ int_32 dl = ntohl(ei[1]); /* data length */ /*@-sizeoftype@*/ size_t pvlen = sizeof(il) + sizeof(dl) + (il * sizeof(struct entryInfo)) + dl; /*@=sizeoftype@*/ void * pv = uh; Header h = NULL; entryInfo pe; char * dataStart; indexEntry entry; int rdlen; /* Sanity checks on header intro. */ if (hdrchkTags(il) || hdrchkData(dl)) goto errxit; ei = (int_32 *) pv; /*@-castexpose@*/ pe = (entryInfo) &ei[2]; /*@=castexpose@*/ dataStart = (char *) (pe + il); h = xcalloc(1, sizeof(*h)); /*@-assignexpose@*/ h->hv = *hdrVec; /* structure assignment */ /*@=assignexpose@*/ /*@-assignexpose -kepttrans@*/ h->blob = uh; /*@=assignexpose =kepttrans@*/ h->indexAlloced = il + 1; h->indexUsed = il; h->instance = 0; h->index = xcalloc(h->indexAlloced, sizeof(*h->index)); h->flags = HEADERFLAG_SORTED; h->nrefs = 0; h = headerLink(h); /* * XXX XFree86-libs, ash, and pdksh from Red Hat 5.2 have bogus * %verifyscript tag that needs to be diddled. */ if (ntohl(pe->tag) == 15 && ntohl(pe->type) == RPM_STRING_TYPE && ntohl(pe->count) == 1) { pe->tag = htonl(1079); } entry = h->index; if (!(htonl(pe->tag) < HEADER_I18NTABLE)) { h->flags |= HEADERFLAG_LEGACY; entry->info.type = REGION_TAG_TYPE; entry->info.tag = HEADER_IMAGE; /*@-sizeoftype@*/ entry->info.count = REGION_TAG_COUNT; /*@=sizeoftype@*/ entry->info.offset = ((char *)pe - dataStart); /* negative offset */ /*@-assignexpose@*/ entry->data = pe; /*@=assignexpose@*/ entry->length = pvlen - sizeof(il) - sizeof(dl); rdlen = regionSwab(entry+1, il, 0, pe, dataStart, entry->info.offset); #if 0 /* XXX don't check, the 8/98 i18n bug fails here. */ if (rdlen != dl) goto errxit; #endif entry->rdlen = rdlen; entry++; h->indexUsed++; } else { int nb = ntohl(pe->count); int_32 rdl; int_32 ril; h->flags &= ~HEADERFLAG_LEGACY; entry->info.type = htonl(pe->type); if (entry->info.type < RPM_MIN_TYPE || entry->info.type > RPM_MAX_TYPE) goto errxit; entry->info.count = htonl(pe->count); if (hdrchkTags(entry->info.count)) goto errxit; { int off = ntohl(pe->offset); if (hdrchkData(off) || hdrchkRange(dl, off)) goto errxit; if (off) { int_32 * stei = memcpy(alloca(nb), dataStart + off, nb); rdl = -ntohl(stei[2]); /* negative offset */ ril = rdl/sizeof(*pe); if (hdrchkTags(ril) || hdrchkData(rdl)) goto errxit; entry->info.tag = htonl(pe->tag); } else { ril = il; /*@-sizeoftype@*/ rdl = (ril * sizeof(struct entryInfo)); /*@=sizeoftype@*/ entry->info.tag = HEADER_IMAGE; } } entry->info.offset = -rdl; /* negative offset */ /*@-assignexpose@*/ entry->data = pe; /*@=assignexpose@*/ entry->length = pvlen - sizeof(il) - sizeof(dl); rdlen = regionSwab(entry+1, ril-1, 0, pe+1, dataStart, entry->info.offset); if (rdlen < 0) goto errxit; entry->rdlen = rdlen; if (ril < h->indexUsed) { indexEntry newEntry = entry + ril; int ne = (h->indexUsed - ril); int rid = entry->info.offset+1; int rc; /* Load dribble entries from region. */ rc = regionSwab(newEntry, ne, 0, pe+ril, dataStart, rid); if (rc < 0) goto errxit; rdlen += rc; { indexEntry firstEntry = newEntry; int save = h->indexUsed; int j; /* Dribble entries replace duplicate region entries. */ h->indexUsed -= ne; for (j = 0; j < ne; j++, newEntry++) { (void) headerRemoveEntry(h, newEntry->info.tag); if (newEntry->info.tag == HEADER_BASENAMES) (void) headerRemoveEntry(h, HEADER_OLDFILENAMES); } /* If any duplicate entries were replaced, move new entries down. */ if (h->indexUsed < (save - ne)) { memmove(h->index + h->indexUsed, firstEntry, (ne * sizeof(*entry))); } h->indexUsed += ne; } } } /* See if the header needs sorting. */ entry = h->index; indexEntry end = entry + h->indexUsed; int prevtag = -1; while (entry < end) { int tag = entry->info.tag; if (prevtag > tag) { h->flags &= ~HEADERFLAG_SORTED; headerSort(h); break; } prevtag = tag; entry++; } /*@-globstate -observertrans @*/ return h; /*@=globstate =observertrans @*/ errxit: /*@-usereleased@*/ if (h) { h->index = _free(h->index); /*@-refcounttrans@*/ h = _free(h); /*@=refcounttrans@*/ } /*@=usereleased@*/ /*@-refcounttrans -globstate@*/ return h; /*@=refcounttrans =globstate@*/ } /** \ingroup header * Convert header to on-disk representation, and then reload. * This is used to insure that all header data is in one chunk. * @param h header (with pointers) * @param tag region tag * @return on-disk header (with offsets) */ static /*@null@*/ Header headerReload(/*@only@*/ Header h, int tag) /*@modifies h @*/ { Header nh; int length; /*@-onlytrans@*/ void * uh = doHeaderUnload(h, &length); h = headerFree(h); /*@=onlytrans@*/ if (uh == NULL) return NULL; nh = headerLoad(uh); if (nh == NULL) { uh = _free(uh); return NULL; } if (nh->flags & HEADERFLAG_ALLOCATED) uh = _free(uh); nh->flags |= HEADERFLAG_ALLOCATED; if (ENTRY_IS_REGION(nh->index)) { if (tag == HEADER_SIGNATURES || tag == HEADER_IMMUTABLE) nh->index[0].info.tag = tag; } return nh; } /** \ingroup header * Make a copy and convert header to in-memory representation. * @param uh on-disk header blob (i.e. with offsets) * @return header */ static /*@null@*/ Header headerCopyLoad(const void * uh) /*@*/ { int_32 * ei = (int_32 *) uh; int_32 il = ntohl(ei[0]); /* index length */ int_32 dl = ntohl(ei[1]); /* data length */ /*@-sizeoftype@*/ size_t pvlen = sizeof(il) + sizeof(dl) + (il * sizeof(struct entryInfo)) + dl; /*@=sizeoftype@*/ void * nuh = NULL; Header h = NULL; /* Sanity checks on header intro. */ /*@-branchstate@*/ if (!(hdrchkTags(il) || hdrchkData(dl)) && pvlen < headerMaxbytes) { nuh = memcpy(xmalloc(pvlen), uh, pvlen); if ((h = headerLoad(nuh)) != NULL) h->flags |= HEADERFLAG_ALLOCATED; } /*@=branchstate@*/ /*@-branchstate@*/ if (h == NULL) nuh = _free(nuh); /*@=branchstate@*/ return h; } /** \ingroup header * Read (and load) header from file handle. * @param fd file handle * @param magicp read (and verify) 8 bytes of (magic, 0)? * @return header (or NULL on error) */ static /*@null@*/ Header headerRead(FD_t fd, enum hMagic magicp) /*@modifies fd @*/ { int_32 block[4]; int_32 * ei = NULL; int_32 il; int_32 dl; Header h = NULL; size_t len; int i; memset(block, 0, sizeof(block)); i = 2; if (magicp == HEADER_MAGIC_YES) i += 2; /*@-type@*/ /* FIX: cast? */ if (timedRead(fd, (char *)block, i*sizeof(*block)) != (i * sizeof(*block))) goto exit; /*@=type@*/ i = 0; if (magicp == HEADER_MAGIC_YES) { int_32 magic = block[i++]; if (memcmp(&magic, header_magic, sizeof(magic))) goto exit; i++; } il = ntohl(block[i]); i++; dl = ntohl(block[i]); i++; /*@-sizeoftype@*/ len = sizeof(il) + sizeof(dl) + (il * sizeof(struct entryInfo)) + dl; /*@=sizeoftype@*/ /* Sanity checks on header intro. */ if (hdrchkTags(il) || hdrchkData(dl) || len > headerMaxbytes) goto exit; ei = xmalloc(len); ei[0] = htonl(il); ei[1] = htonl(dl); len -= sizeof(il) + sizeof(dl); /*@-type@*/ /* FIX: cast? */ if (timedRead(fd, (char *)&ei[2], len) != len) goto exit; /*@=type@*/ h = headerLoad(ei); exit: if (h) { if (h->flags & HEADERFLAG_ALLOCATED) ei = _free(ei); h->flags |= HEADERFLAG_ALLOCATED; } else if (ei) ei = _free(ei); /*@-mustmod@*/ /* FIX: timedRead macro obscures annotation */ return h; /*@-mustmod@*/ } /** \ingroup header * Write (with unload) header to file handle. * @param fd file handle * @param h header * @param magicp prefix write with 8 bytes of (magic, 0)? * @return 0 on success, 1 on error */ static int headerWrite(FD_t fd, /*@null@*/ Header h, enum hMagic magicp) /*@globals fileSystem @*/ /*@modifies fd, h, fileSystem @*/ { ssize_t nb; int length; const void * uh; if (h == NULL) return 1; uh = doHeaderUnload(h, &length); if (uh == NULL) return 1; switch (magicp) { case HEADER_MAGIC_YES: /*@-sizeoftype@*/ nb = Fwrite(header_magic, sizeof(char), sizeof(header_magic), fd); /*@=sizeoftype@*/ if (nb != sizeof(header_magic)) goto exit; break; case HEADER_MAGIC_NO: break; } /*@-sizeoftype@*/ nb = Fwrite(uh, sizeof(char), length, fd); /*@=sizeoftype@*/ exit: uh = _free(uh); return (nb == length ? 0 : 1); } /** \ingroup header * Check if tag is in header. * @param h header * @param tag tag * @return 1 on success, 0 on failure */ static int headerIsEntry(/*@null@*/Header h, int_32 tag) /*@*/ { /*@-mods@*/ /*@ FIX: h modified by sort. */ return (findEntry(h, tag, RPM_NULL_TYPE) ? 1 : 0); /*@=mods@*/ } /** \ingroup header * Retrieve data from header entry. * @todo Permit retrieval of regions other than HEADER_IMUTABLE. * @param entry header entry * @retval type address of type (or NULL) * @retval p address of data (or NULL) * @retval c address of count (or NULL) * @param minMem string pointers refer to header memory? * @return 1 on success, otherwise error. */ static int copyEntry(const indexEntry entry, /*@null@*/ /*@out@*/ hTYP_t type, /*@null@*/ /*@out@*/ hPTR_t * p, /*@null@*/ /*@out@*/ hCNT_t c, int minMem) /*@modifies *type, *p, *c @*/ { int_32 count = entry->info.count; int rc = 1; /* XXX 1 on success. */ if (p) switch (entry->info.type) { case RPM_BIN_TYPE: /* * XXX This only works for * XXX "sealed" HEADER_IMMUTABLE/HEADER_SIGNATURES/HEADER_IMAGE. * XXX This will *not* work for unsealed legacy HEADER_IMAGE (i.e. * XXX a legacy header freshly read, but not yet unloaded to the rpmdb). */ if (ENTRY_IS_REGION(entry)) { int_32 * ei = ((int_32 *)entry->data) - 2; /*@-castexpose@*/ entryInfo pe = (entryInfo) (ei + 2); /*@=castexpose@*/ char * dataStart = (char *) (pe + ntohl(ei[0])); int_32 rdl = -entry->info.offset; /* negative offset */ int_32 ril = rdl/sizeof(*pe); /*@-sizeoftype@*/ rdl = entry->rdlen; count = 2 * sizeof(*ei) + (ril * sizeof(*pe)) + rdl; if (entry->info.tag == HEADER_IMAGE) { ril -= 1; pe += 1; } else { count += REGION_TAG_COUNT; rdl += REGION_TAG_COUNT; } *p = xmalloc(count); ei = (int_32 *) *p; ei[0] = htonl(ril); ei[1] = htonl(rdl); /*@-castexpose@*/ pe = (entryInfo) memcpy(ei + 2, pe, (ril * sizeof(*pe))); /*@=castexpose@*/ dataStart = (char *) memcpy(pe + ril, dataStart, rdl); /*@=sizeoftype@*/ rc = regionSwab(NULL, ril, 0, pe, dataStart, 0); /* XXX 1 on success. */ rc = (rc < 0) ? 0 : 1; } else { count = entry->length; *p = (!minMem ? memcpy(xmalloc(count), entry->data, count) : entry->data); } break; case RPM_STRING_TYPE: if (count == 1) { *p = entry->data; break; } /*@fallthrough@*/ case RPM_STRING_ARRAY_TYPE: case RPM_I18NSTRING_TYPE: { const char ** ptrEntry; /*@-sizeoftype@*/ int tableSize = count * sizeof(char *); /*@=sizeoftype@*/ char * t; int i; /*@-mods@*/ if (minMem) { *p = xmalloc(tableSize); ptrEntry = (const char **) *p; t = entry->data; } else { t = xmalloc(tableSize + entry->length); *p = (void *)t; ptrEntry = (const char **) *p; t += tableSize; memcpy(t, entry->data, entry->length); } /*@=mods@*/ for (i = 0; i < count; i++) { *ptrEntry++ = t; t = strchr(t, 0); t++; } } break; default: *p = entry->data; break; } if (type) *type = entry->info.type; if (c) *c = count; return rc; } /* Guess value of current locale from value of the environment variables. */ static const char * guess_category_value (int category) { const char *language; const char *retval; language = getenv ("RPM_LANGUAGE_I18NSTRING"); if (language && *language) return language; /* The highest priority value is the `LANGUAGE' environment variable. But we don't use the value if the currently selected locale is the C locale. This is a GNU extension. */ language = getenv ("LANGUAGE"); if (language != NULL && language[0] == '\0') language = NULL; /* We have to proceed with the POSIX methods of looking to `LC_ALL', `LC_xxx', and `LANG'. On some systems this can be done by the `setlocale' function itself. */ retval = setlocale (category, NULL); /* Ignore LANGUAGE if the locale is set to "C" because 1. "C" locale usually uses the ASCII encoding, and most international messages use non-ASCII characters. These characters get displayed as question marks (if using glibc's iconv()) or as invalid 8-bit characters (because other iconv()s refuse to convert most non-ASCII characters to ASCII). In any case, the output is ugly. 2. The precise output of some programs in the "C" locale is specified by POSIX and should not depend on environment variables like "LANGUAGE". We allow such programs to use gettext(). */ return language != NULL && strcmp (retval, "C") != 0 ? language : retval; } static int locale_match (const char *sample, const char *l_b, const char *l_e, char delim) { const char *p = l_b; for (; p < l_e && *p != delim; ++p) ; if (p < l_e && !strncmp (sample, l_b, (p - l_b))) return 1; return 0; } /** * Does locale match entry in header i18n table? * * \verbatim * The range [l,le) contains the next locale to match: * ll[_CC][.EEEEE][@dddd] * where * ll ISO language code (in lowercase). * CC (optional) ISO coutnry code (in uppercase). * EEEEE (optional) encoding (not really standardized). * dddd (optional) dialect. * \endverbatim * * @param td header i18n table data, NUL terminated * @param l start of locale to match * @param le end of locale to match * @return 1 on match, 0 on no match */ static int headerMatchLocale (const char *td, const char *l, const char *le, int strip_lang) /*@ */ { switch (strip_lang) { case 0: /* First try a complete match. */ if (strlen (td) == (le - l) && !memcmp (td, l, (le - l))) return 1; return 0; case 1: /* Next, try stripping optional dialect and matching. */ return locale_match (td, l, le, '@'); case 2: /* Next, try stripping optional codeset and matching. */ return locale_match (td, l, le, '.'); default: /* Finally, try stripping optional country code and matching. */ return locale_match (td, l, le, '_'); } } static char * convert (char *ed, const char *td) { char *saved_ctype = 0, *from_codeset = 0, *to_codeset = 0; char *saved_ctype1, *from_codeset1, *to_codeset1, *result = 0; iconv_t icd; if (!*ed) return ed; if ((saved_ctype1 = setlocale (LC_CTYPE, 0)) && (saved_ctype = strdup (saved_ctype1)) && (to_codeset1 = nl_langinfo (CODESET)) && (to_codeset = strdup (to_codeset1)) && setlocale (LC_CTYPE, td) && (from_codeset1 = nl_langinfo (CODESET)) && (from_codeset = strdup (from_codeset1)) && strcmp (from_codeset, to_codeset) && ((icd = iconv_open (to_codeset, from_codeset)) != (iconv_t) - 1)) { size_t insize = strlen (ed); size_t inbufleft = insize, outbufleft = insize * 4 + 1; char buf[outbufleft]; char *inbuf = ed, *outbuf = buf; if (iconv (icd, &inbuf, &inbufleft, &outbuf, &outbufleft) >= 0) { *outbuf = '\0'; if (strcmp (ed, buf)) /* XXX memory leak */ result = strdup (buf); } iconv_close (icd); } if (saved_ctype) setlocale (LC_CTYPE, saved_ctype); from_codeset = _free (from_codeset); to_codeset = _free (to_codeset); saved_ctype = _free (saved_ctype); return result ? : ed; } /** * Return i18n string from header that matches locale. * @param h header * @param entry i18n string data * @return matching i18n string (or 1st string if no match) */ /*@dependent@*/ /*@exposed@*/ static char * headerFindI18NString (Header h, indexEntry entry) { const char *l, *le; indexEntry table; int strip_lang; static int guessed; static const char *lang; if (!guessed) { lang = guess_category_value (LC_MESSAGES); if (lang) { if (strcmp(lang, "C") == 0) lang = NULL; else lang = xstrdup (lang); } guessed = 1; } if (!entry->data || !*(const char *) entry->data || !lang) return entry->data; /*@-mods@ */ if ((table = findEntry (h, HEADER_I18NTABLE, RPM_STRING_ARRAY_TYPE)) == NULL) return entry->data; /*@=mods@ */ for (strip_lang = 0; strip_lang < 4; strip_lang++) { for (l = lang; *l; l = le) { const char *td; char *ed; int langNum; while (*l && *l == ':') /* skip leading colons */ l++; if (*l == '\0') break; for (le = l; *le && *le != ':'; le++) /* find end of this locale */ ; /* For each entry in the header ... */ for (langNum = 0, td = table->data, ed = entry->data; langNum < entry->info.count; langNum++, td += strlen (td) + 1, ed += strlen (ed) + 1) { if (headerMatchLocale (td, l, le, strip_lang)) return convert (ed, td); } } } return gettext (entry->data); } /** * Retrieve tag data from header. * @param h header * @param tag tag to retrieve * @retval type address of type (or NULL) * @retval p address of data (or NULL) * @retval c address of count (or NULL) * @param minMem string pointers reference header memory? * @return 1 on success, 0 on not found */ static int intGetEntry(Header h, int_32 tag, /*@null@*/ /*@out@*/ hTAG_t type, /*@null@*/ /*@out@*/ hPTR_t * p, /*@null@*/ /*@out@*/ hCNT_t c, int minMem) /*@modifies *type, *p, *c @*/ { indexEntry entry; int rc; /* First find the tag */ /*@-mods@*/ /*@ FIX: h modified by sort. */ entry = findEntry(h, tag, RPM_NULL_TYPE); /*@mods@*/ if (entry == NULL) { if (type) type = 0; if (p) *p = NULL; if (c) *c = 0; return 0; } switch (entry->info.type) { case RPM_I18NSTRING_TYPE: rc = 1; if (type) *type = RPM_STRING_TYPE; if (c) *c = 1; /*@-dependenttrans@*/ if (p) *p = headerFindI18NString(h, entry); /*@=dependenttrans@*/ break; default: rc = copyEntry(entry, type, p, c, minMem); break; } /* XXX 1 on success */ return ((rc == 1) ? 1 : 0); } /** \ingroup header * Free data allocated when retrieved from header. * @param h header * @param data address of data (or NULL) * @param type type of data (or -1 to force free) * @return NULL always */ static /*@null@*/ void * headerFreeTag(/*@unused@*/ Header h, /*@only@*/ /*@null@*/ const void * data, rpmTagType type) /*@modifies data @*/ { if (data) { /*@-branchstate@*/ if (type == -1 || type == RPM_STRING_ARRAY_TYPE || type == RPM_I18NSTRING_TYPE || type == RPM_BIN_TYPE) data = _free(data); /*@=branchstate@*/ } return NULL; } /** \ingroup header * Retrieve tag value. * Will never return RPM_I18NSTRING_TYPE! RPM_STRING_TYPE elements with * RPM_I18NSTRING_TYPE equivalent entries are translated (if HEADER_I18NTABLE * entry is present). * * @param h header * @param tag tag * @retval type address of tag value data type (or NULL) * @retval p address of pointer to tag value(s) (or NULL) * @retval c address of number of values (or NULL) * @return 1 on success, 0 on failure */ static int headerGetEntry(Header h, int_32 tag, /*@null@*/ /*@out@*/ hTYP_t type, /*@null@*/ /*@out@*/ void ** p, /*@null@*/ /*@out@*/ hCNT_t c) /*@modifies *type, *p, *c @*/ { return intGetEntry(h, tag, type, (hPTR_t *)p, c, 0); } /** \ingroup header * Retrieve tag value using header internal array. * Get an entry using as little extra RAM as possible to return the tag value. * This is only an issue for RPM_STRING_ARRAY_TYPE. * * @param h header * @param tag tag * @retval type address of tag value data type (or NULL) * @retval p address of pointer to tag value(s) (or NULL) * @retval c address of number of values (or NULL) * @return 1 on success, 0 on failure */ static int headerGetEntryMinMemory(Header h, int_32 tag, /*@null@*/ /*@out@*/ hTYP_t type, /*@null@*/ /*@out@*/ hPTR_t * p, /*@null@*/ /*@out@*/ hCNT_t c) /*@modifies *type, *p, *c @*/ { return intGetEntry(h, tag, type, p, c, 1); } int headerGetRawEntry(Header h, int_32 tag, int_32 * type, hPTR_t * p, int_32 * c) { indexEntry entry; int rc; if (p == NULL) return headerIsEntry(h, tag); /* First find the tag */ /*@-mods@*/ /*@ FIX: h modified by sort. */ entry = findEntry(h, tag, RPM_NULL_TYPE); /*@=mods@*/ if (!entry) { if (p) *p = NULL; if (c) *c = 0; return 0; } rc = copyEntry(entry, type, p, c, 0); /* XXX 1 on success */ return ((rc == 1) ? 1 : 0); } /** */ static void copyData(int_32 type, /*@out@*/ void * dstPtr, const void * srcPtr, int_32 c, int dataLength) /*@modifies *dstPtr @*/ { const char ** src; char * dst; int i; switch (type) { case RPM_STRING_ARRAY_TYPE: case RPM_I18NSTRING_TYPE: /* Otherwise, p is char** */ i = c; src = (const char **) srcPtr; dst = dstPtr; while (i--) { if (*src) { int len = strlen(*src) + 1; memcpy(dst, *src, len); dst += len; } src++; } break; default: memmove(dstPtr, srcPtr, dataLength); break; } } /** * Return (malloc'ed) copy of entry data. * @param type entry data type * @param p entry data * @param c entry item count * @retval lengthPtr no. bytes in returned data * @return (malloc'ed) copy of entry data */ static void * grabData(int_32 type, hPTR_t p, int_32 c, /*@out@*/ int * lengthPtr) /*@modifies *lengthPtr @*/ { int length = dataLength(type, p, c, 0); void * data = xmalloc(length); copyData(type, data, p, c, length); if (lengthPtr) *lengthPtr = length; return data; } /** \ingroup header * Add tag to header. * Duplicate tags are okay, but only defined for iteration (with the * exceptions noted below). While you are allowed to add i18n string * arrays through this function, you probably don't mean to. See * headerAddI18NString() instead. * * @param h header * @param tag tag * @param type tag value data type * @param p pointer to tag value(s) * @param c number of values * @return 1 on success, 0 on failure */ static int headerAddEntry(Header h, int_32 tag, int_32 type, const void * p, int_32 c) /*@modifies h @*/ { indexEntry entry; /* Count must always be >= 1 for headerAddEntry. */ if (c <= 0) return 0; /* Allocate more index space if necessary */ if (h->indexUsed == h->indexAlloced) { h->indexAlloced += INDEX_MALLOC_SIZE; h->index = xrealloc(h->index, h->indexAlloced * sizeof(*h->index)); } /* Fill in the index */ entry = h->index + h->indexUsed; entry->info.tag = tag; entry->info.type = type; entry->info.count = c; entry->info.offset = 0; entry->data = grabData(type, p, c, &entry->length); if (h->indexUsed > 0 && tag < h->index[h->indexUsed-1].info.tag) h->flags &= ~HEADERFLAG_SORTED; h->indexUsed++; return 1; } /** \ingroup header * Append element to tag array in header. * Appends item p to entry w/ tag and type as passed. Won't work on * RPM_STRING_TYPE. Any pointers into header memory returned from * headerGetEntryMinMemory() for this entry are invalid after this * call has been made! * * @param h header * @param tag tag * @param type tag value data type * @param p pointer to tag value(s) * @param c number of values * @return 1 on success, 0 on failure */ static int headerAppendEntry(Header h, int_32 tag, int_32 type, const void * p, int_32 c) /*@modifies h @*/ { indexEntry entry; int length; /* First find the tag */ entry = findEntry(h, tag, type); if (!entry) return 0; if (type == RPM_STRING_TYPE || type == RPM_I18NSTRING_TYPE) { /* we can't do this */ return 0; } length = dataLength(type, p, c, 0); if (ENTRY_IN_REGION(entry)) { char * t = xmalloc(entry->length + length); memcpy(t, entry->data, entry->length); entry->data = t; entry->info.offset = 0; } else entry->data = xrealloc(entry->data, entry->length + length); copyData(type, ((char *) entry->data) + entry->length, p, c, length); entry->length += length; entry->info.count += c; return 1; } /** \ingroup header * Add or append element to tag array in header. * @todo Arg "p" should have const. * @param h header * @param tag tag * @param type tag value data type * @param p pointer to tag value(s) * @param c number of values * @return 1 on success, 0 on failure */ static int headerAddOrAppendEntry(Header h, int_32 tag, int_32 type, const void * p, int_32 c) /*@modifies h @*/ { return (findEntry(h, tag, type) ? headerAppendEntry(h, tag, type, p, c) : headerAddEntry(h, tag, type, p, c)); } /** \ingroup header * Add locale specific tag to header. * A NULL lang is interpreted as the C locale. Here are the rules: * \verbatim * - If the tag isn't in the header, it's added with the passed string * as new value. * - If the tag occurs multiple times in entry, which tag is affected * by the operation is undefined. * - If the tag is in the header w/ this language, the entry is * *replaced* (like headerModifyEntry()). * \endverbatim * This function is intended to just "do the right thing". If you need * more fine grained control use headerAddEntry() and headerModifyEntry(). * * @param h header * @param tag tag * @param string tag value * @param lang locale * @return 1 on success, 0 on failure */ static int headerAddI18NString(Header h, int_32 tag, const char * string, const char * lang) /*@modifies h @*/ { indexEntry table, entry; const char ** strArray; int length; int ghosts; int i, langNum; char * buf; table = findEntry(h, HEADER_I18NTABLE, RPM_STRING_ARRAY_TYPE); entry = findEntry(h, tag, RPM_I18NSTRING_TYPE); if (!table && entry) return 0; /* this shouldn't ever happen!! */ if (!table && !entry) { const char * charArray[2]; int count = 0; if (!lang || (lang[0] == 'C' && lang[1] == '\0')) { /*@-observertrans -readonlytrans@*/ charArray[count++] = "C"; /*@=observertrans =readonlytrans@*/ } else { /*@-observertrans -readonlytrans@*/ charArray[count++] = "C"; /*@=observertrans =readonlytrans@*/ charArray[count++] = lang; } if (!headerAddEntry(h, HEADER_I18NTABLE, RPM_STRING_ARRAY_TYPE, &charArray, count)) return 0; table = findEntry(h, HEADER_I18NTABLE, RPM_STRING_ARRAY_TYPE); } if (!table) return 0; /*@-branchstate@*/ if (!lang) lang = "C"; /*@=branchstate@*/ { const char * l = table->data; for (langNum = 0; langNum < table->info.count; langNum++) { if (!strcmp(l, lang)) break; l += strlen(l) + 1; } } if (langNum >= table->info.count) { length = strlen(lang) + 1; if (ENTRY_IN_REGION(table)) { char * t = xmalloc(table->length + length); memcpy(t, table->data, table->length); table->data = t; table->info.offset = 0; } else table->data = xrealloc(table->data, table->length + length); memmove(((char *)table->data) + table->length, lang, length); table->length += length; table->info.count++; } if (!entry) { strArray = alloca(sizeof(*strArray) * (langNum + 1)); for (i = 0; i < langNum; i++) strArray[i] = ""; strArray[langNum] = string; return headerAddEntry(h, tag, RPM_I18NSTRING_TYPE, strArray, langNum + 1); } else if (langNum >= entry->info.count) { ghosts = langNum - entry->info.count; length = strlen(string) + 1 + ghosts; if (ENTRY_IN_REGION(entry)) { char * t = xmalloc(entry->length + length); memcpy(t, entry->data, entry->length); entry->data = t; entry->info.offset = 0; } else entry->data = xrealloc(entry->data, entry->length + length); memset(((char *)entry->data) + entry->length, '\0', ghosts); memmove(((char *)entry->data) + entry->length + ghosts, string, strlen(string)+1); entry->length += length; entry->info.count = langNum + 1; } else { char *b, *be, *e, *ee, *t; size_t bn, sn, en; /* Set beginning/end pointers to previous data */ b = be = e = ee = entry->data; for (i = 0; i < table->info.count; i++) { if (i == langNum) be = ee; ee += strlen(ee) + 1; if (i == langNum) e = ee; } /* Get storage for new buffer */ bn = (be-b); sn = strlen(string) + 1; en = (ee-e); length = bn + sn + en; t = buf = xmalloc(length); /* Copy values into new storage */ memcpy(t, b, bn); t += bn; /*@-mayaliasunique@*/ memcpy(t, string, sn); t += sn; memcpy(t, e, en); t += en; /*@=mayaliasunique@*/ /* Replace I18N string array */ entry->length -= strlen(be) + 1; entry->length += sn; if (ENTRY_IN_REGION(entry)) { entry->info.offset = 0; } else entry->data = _free(entry->data); /*@-dependenttrans@*/ entry->data = buf; /*@=dependenttrans@*/ } return 0; } /** \ingroup header * Modify tag in header. * If there are multiple entries with this tag, the first one gets replaced. * @param h header * @param tag tag * @param type tag value data type * @param p pointer to tag value(s) * @param c number of values * @return 1 on success, 0 on failure */ static int headerModifyEntry(Header h, int_32 tag, int_32 type, const void * p, int_32 c) /*@modifies h @*/ { indexEntry entry; void * oldData; /* First find the tag */ entry = findEntry(h, tag, type); if (!entry) return 0; /* make sure entry points to the first occurence of this tag */ while (entry > h->index && (entry - 1)->info.tag == tag) entry--; /* free after we've grabbed the new data in case the two are intertwined; that's a bad idea but at least we won't break */ oldData = entry->data; entry->info.count = c; entry->info.type = type; entry->data = grabData(type, p, c, &entry->length); /*@-branchstate@*/ if (ENTRY_IN_REGION(entry)) { entry->info.offset = 0; } else oldData = _free(oldData); /*@=branchstate@*/ return 1; } /** */ static char escapedChar(const char ch) /*@*/ { switch (ch) { case 'a': return '\a'; case 'b': return '\b'; case 'f': return '\f'; case 'n': return '\n'; case 'r': return '\r'; case 't': return '\t'; case 'v': return '\v'; default: return ch; } } /** * Destroy headerSprintf format array. * @param format sprintf format array * @param num number of elements * @return NULL always */ static /*@null@*/ sprintfToken freeFormat( /*@only@*/ /*@null@*/ sprintfToken format, int num) /*@modifies *format @*/ { int i; if (format == NULL) return NULL; for (i = 0; i < num; i++) { switch (format[i].type) { case PTOK_ARRAY: format[i].u.array.format = freeFormat(format[i].u.array.format, format[i].u.array.numTokens); /*@switchbreak@*/ break; case PTOK_COND: format[i].u.cond.ifFormat = freeFormat(format[i].u.cond.ifFormat, format[i].u.cond.numIfTokens); format[i].u.cond.elseFormat = freeFormat(format[i].u.cond.elseFormat, format[i].u.cond.numElseTokens); switch (format[i].u.cond.test.type) { case TRIVIAL: /* the usual old way; format[i].test.u.tag is a struct */ break; case StringTAG_String3: /* the added option */ format[i].u.cond.test.u.tag_str3.headFormat = freeFormat(format[i].u.cond.test.u.tag_str3.headFormat, format[i].u.cond.test.u.tag_str3.numHeadTokens); /* We don't need to free the strings; we have not allocated them. And PTOK_STRING case is analogous and also doesn't free the string. */ break; default: /* report an error */ rpmMessage(RPMMESS_WARNING, _("Unknown test type in \%|?:|; perhaps some memory is leaking right now.\n")); break; } /*@switchbreak@*/ break; case PTOK_NONE: case PTOK_TAG: case PTOK_STRING: default: /*@switchbreak@*/ break; } } format = _free(format); return NULL; } /** */ static void findTag(char * name, const headerTagTableEntry tags, const headerSprintfExtension extensions, /*@out@*/ headerTagTableEntry * tagMatch, /*@out@*/ headerSprintfExtension * extMatch) /*@modifies *tagMatch, *extMatch @*/ { headerTagTableEntry entry; headerSprintfExtension ext; const char * tagname; *tagMatch = NULL; *extMatch = NULL; if (strncmp("RPMTAG_", name, sizeof("RPMTAG_")-1)) { char * t = alloca(strlen(name) + sizeof("RPMTAG_")); (void) stpcpy( stpcpy(t, "RPMTAG_"), name); tagname = t; } else { tagname = name; } /* Search extensions first to permit overriding header tags. */ ext = extensions; while (ext->type != HEADER_EXT_LAST) { if (ext->name != NULL && ext->type == HEADER_EXT_TAG && !xstrcasecmp(ext->name, tagname)) break; if (ext->type == HEADER_EXT_MORE) ext = ext->u.more; else ext++; } if (ext->type == HEADER_EXT_TAG) { *extMatch = ext; return; } /* Search header tags. */ for (entry = tags; entry->name; entry++) if (entry->name && !xstrcasecmp(entry->name, tagname)) break; if (entry->name) { *tagMatch = entry; return; } } /* forward ref */ static int parseExpression(sprintfToken token, char * str, const headerTagTableEntry tags, const headerSprintfExtension extensions, /*@out@*/char ** endPtr, /*@null@*/ /*@out@*/ errmsg_t * errmsg) /*@modifies str, *str, *token, *endPtr, *errmsg @*/; /** */ static int parseFormat(char * str, const headerTagTableEntry tags, const headerSprintfExtension extensions, /*@out@*/sprintfToken * formatPtr, /*@out@*/int * numTokensPtr, /*@null@*/ /*@out@*/ char ** endPtr, int state, /*@null@*/ /*@out@*/ errmsg_t * errmsg) /*@modifies str, *str, *formatPtr, *numTokensPtr, *endPtr, *errmsg @*/ { char * chptr, * start, * next, * dst; sprintfToken format; int numTokens; int currToken; headerTagTableEntry tag; headerSprintfExtension ext; int i; int done = 0; /* upper limit on number of individual formats */ numTokens = 0; for (chptr = str; *chptr != '\0'; chptr++) if (*chptr == '%' || *chptr == '[') numTokens++; numTokens = numTokens * 2 + 1; format = xcalloc(numTokens, sizeof(*format)); if (endPtr) *endPtr = NULL; /*@-infloops@*/ /* LCL: can't detect done termination */ dst = start = str; currToken = -1; while (*start != '\0') { switch (*start) { case '%': /* handle %% */ if (*(start + 1) == '%') { if (currToken < 0 || format[currToken].type != PTOK_STRING) { currToken++; format[currToken].type = PTOK_STRING; /*@-temptrans -assignexpose@*/ dst = format[currToken].u.string.string = start; /*@=temptrans =assignexpose@*/ } start++; *dst++ = *start++; /*@switchbreak@*/ break; } currToken++; *dst++ = '\0'; start++; if (*start == '|') { char * newEnd; start++; if (parseExpression(format + currToken, start, tags, extensions, &newEnd, errmsg)) { format = freeFormat(format, numTokens); return 1; } start = newEnd; /*@switchbreak@*/ break; } /*@-assignexpose@*/ format[currToken].u.tag.format = start; /*@=assignexpose@*/ format[currToken].u.tag.pad = 0; format[currToken].u.tag.justOne = 0; format[currToken].u.tag.arrayCount = 0; chptr = start; while (*chptr && *chptr != '{' && *chptr != '%') chptr++; if (!*chptr || *chptr == '%') { /*@-observertrans -readonlytrans@*/ if (errmsg) *errmsg = _("missing { after %"); /*@=observertrans =readonlytrans@*/ format = freeFormat(format, numTokens); return 1; } *chptr++ = '\0'; while (start < chptr) { if (xisdigit(*start)) { i = strtoul(start, &start, 10); format[currToken].u.tag.pad += i; } else { start++; } } if (*start == '=') { format[currToken].u.tag.justOne = 1; start++; } else if (*start == '#') { format[currToken].u.tag.justOne = 1; format[currToken].u.tag.arrayCount = 1; start++; } next = start; while (*next && *next != '}') next++; if (!*next) { /*@-observertrans -readonlytrans@*/ if (errmsg) *errmsg = _("missing } after %{"); /*@=observertrans =readonlytrans@*/ format = freeFormat(format, numTokens); return 1; } *next++ = '\0'; chptr = start; while (*chptr && *chptr != ':') chptr++; if (*chptr != '\0') { *chptr++ = '\0'; if (!*chptr) { /*@-observertrans -readonlytrans@*/ if (errmsg) *errmsg = _("empty tag format"); /*@=observertrans =readonlytrans@*/ format = freeFormat(format, numTokens); return 1; } /*@-assignexpose@*/ format[currToken].u.tag.type = chptr; /*@=assignexpose@*/ } else { format[currToken].u.tag.type = NULL; } if (!*start) { /*@-observertrans -readonlytrans@*/ if (errmsg) *errmsg = _("empty tag name"); /*@=observertrans =readonlytrans@*/ format = freeFormat(format, numTokens); return 1; } i = 0; findTag(start, tags, extensions, &tag, &ext); if (tag) { format[currToken].u.tag.ext = NULL; format[currToken].u.tag.tag = tag->val; } else if (ext) { format[currToken].u.tag.ext = ext->u.tagFunction; format[currToken].u.tag.extNum = ext - extensions; } else { /*@-observertrans -readonlytrans@*/ if (errmsg) *errmsg = _("unknown tag"); /*@=observertrans =readonlytrans@*/ format = freeFormat(format, numTokens); return 1; } format[currToken].type = PTOK_TAG; start = next; /*@switchbreak@*/ break; case '[': *dst++ = '\0'; *start++ = '\0'; currToken++; if (parseFormat(start, tags, extensions, &format[currToken].u.array.format, &format[currToken].u.array.numTokens, &start, PARSER_IN_ARRAY, errmsg)) { format = freeFormat(format, numTokens); return 1; } if (!start) { /*@-observertrans -readonlytrans@*/ if (errmsg) *errmsg = _("] expected at end of array"); /*@=observertrans =readonlytrans@*/ format = freeFormat(format, numTokens); return 1; } dst = start; format[currToken].type = PTOK_ARRAY; /*@switchbreak@*/ break; case ']': case '}': if ((*start == ']' && state != PARSER_IN_ARRAY) || (*start == '}' && state != PARSER_IN_EXPR)) { if (*start == ']') { /*@-observertrans -readonlytrans@*/ if (errmsg) *errmsg = _("unexpected ]"); /*@=observertrans =readonlytrans@*/ } else { /*@-observertrans -readonlytrans@*/ if (errmsg) *errmsg = _("unexpected }"); /*@=observertrans =readonlytrans@*/ } format = freeFormat(format, numTokens); return 1; } *start++ = '\0'; if (endPtr) *endPtr = start; done = 1; /*@switchbreak@*/ break; default: if (currToken < 0 || format[currToken].type != PTOK_STRING) { currToken++; format[currToken].type = PTOK_STRING; /*@-temptrans -assignexpose@*/ dst = format[currToken].u.string.string = start; /*@=temptrans =assignexpose@*/ } if (*start == '\\') { start++; *dst++ = escapedChar(*start++); } else { *dst++ = *start++; } /*@switchbreak@*/ break; } if (done) break; } /*@=infloops@*/ *dst = '\0'; currToken++; for (i = 0; i < currToken; i++) { if (format[i].type == PTOK_STRING) format[i].u.string.len = strlen(format[i].u.string.string); } *numTokensPtr = currToken; *formatPtr = format; return 0; } /** */ static int parseExpression(sprintfToken token, char * str, const headerTagTableEntry tags, const headerSprintfExtension extensions, /*@out@*/ char ** endPtr, /*@null@*/ /*@out@*/ errmsg_t * errmsg) { headerTagTableEntry tag; headerSprintfExtension ext; char * chptr; char * end; if (errmsg) *errmsg = NULL; chptr = str; while (*chptr && *chptr != '?') chptr++; if (*chptr != '?') { /*@-observertrans -readonlytrans@*/ if (errmsg) *errmsg = _("? expected in expression"); /*@=observertrans =readonlytrans@*/ return 1; } *chptr++ = '\0';; if (*chptr != '{') { /*@-observertrans -readonlytrans@*/ if (errmsg) *errmsg = _("{ expected after ? in expression"); /*@=observertrans =readonlytrans@*/ return 1; } chptr++; if (parseFormat(chptr, tags, extensions, &token->u.cond.ifFormat, &token->u.cond.numIfTokens, &end, PARSER_IN_EXPR, errmsg)) return 1; if (!end || !*end) { /*@-observertrans -readonlytrans@*/ if (errmsg) *errmsg = _("} expected in expression"); /*@=observertrans =readonlytrans@*/ token->u.cond.ifFormat = freeFormat(token->u.cond.ifFormat, token->u.cond.numIfTokens); return 1; } chptr = end; if (*chptr != ':' && *chptr != '|') { /*@-observertrans -readonlytrans@*/ if (errmsg) *errmsg = _(": expected following ? subexpression"); /*@=observertrans =readonlytrans@*/ token->u.cond.ifFormat = freeFormat(token->u.cond.ifFormat, token->u.cond.numIfTokens); return 1; } if (*chptr == '|') { (void) parseFormat(xstrdup(""), tags, extensions, &token->u.cond.elseFormat, &token->u.cond.numElseTokens, &end, PARSER_IN_EXPR, errmsg); } else { chptr++; if (*chptr != '{') { /*@-observertrans -readonlytrans@*/ if (errmsg) *errmsg = _("{ expected after : in expression"); /*@=observertrans =readonlytrans@*/ token->u.cond.ifFormat = freeFormat(token->u.cond.ifFormat, token->u.cond.numIfTokens); return 1; } chptr++; if (parseFormat(chptr, tags, extensions, &token->u.cond.elseFormat, &token->u.cond.numElseTokens, &end, PARSER_IN_EXPR, errmsg)) return 1; if (!end || !*end) { /*@-observertrans -readonlytrans@*/ if (errmsg) *errmsg = _("} expected in expression"); /*@=observertrans =readonlytrans@*/ token->u.cond.ifFormat = freeFormat(token->u.cond.ifFormat, token->u.cond.numIfTokens); return 1; } chptr = end; if (*chptr != '|') { /*@-observertrans -readonlytrans@*/ if (errmsg) *errmsg = _("| expected at end of expression"); /*@=observertrans =readonlytrans@*/ token->u.cond.ifFormat = freeFormat(token->u.cond.ifFormat, token->u.cond.numIfTokens); token->u.cond.elseFormat = freeFormat(token->u.cond.elseFormat, token->u.cond.numElseTokens); return 1; } } chptr++; *endPtr = chptr; { /* branching between the trivial old test for the conditional and the added test for EVR comparison. */ char * str2 = strchr(str,'>'); if (str2) { char * endOfParsed = NULL; rpmMessage(RPMMESS_WARNING, _("Parsing non-standard test (>) for \%|?{}:{}|.\n")); *str2 ='\0'; ++str2; /* str2 is the beginning of the second part: after the > sign. */ if ( parseFormat(str, tags, extensions, &token->u.cond.test.u.tag_str3.headFormat, &token->u.cond.test.u.tag_str3.numHeadTokens, &endOfParsed, PARSER_IN_EXPR, errmsg) /* this doesn't work, NULL is returned: || ( endOfParsed != str2 ) */ ) { /*@-observertrans -readonlytrans@*/ if (errmsg && ! *errmsg /* *errmsg was set to NULL at the function beginnging */ ) *errmsg = _("the left part of >-expr finished before the > sign"); /*@=observertrans =readonlytrans@*/ token->u.cond.ifFormat = freeFormat(token->u.cond.ifFormat, token->u.cond.numIfTokens); token->u.cond.elseFormat = freeFormat(token->u.cond.elseFormat, token->u.cond.numElseTokens); return 1; } token->u.cond.test.type = StringTAG_String3; token->u.cond.test.u.tag_str3.predicate = &isChangeNameMoreFresh; parseEVR(str2, &token->u.cond.test.u.tag_str3.tail[0], &token->u.cond.test.u.tag_str3.tail[1], &token->u.cond.test.u.tag_str3.tail[2]); /* We could strdup tail[j], but it seems we don't need this: the rest of similar code doesn't perform this. And we don't have to free them. */ rpmMessage(RPMMESS_DEBUG, "Will cmp with e=%s, v=%s, r=%s\n", token->u.cond.test.u.tag_str3.tail[0], token->u.cond.test.u.tag_str3.tail[1], token->u.cond.test.u.tag_str3.tail[2]); } else { struct sprintfTag head; rpmMessage(RPMMESS_DEBUG, _("The usual way of parsing the test part for \%|?:|\n")); findTag(str, tags, extensions, &tag, &ext); if (tag) { head.ext = NULL; head.tag = tag->val; } else if (ext) { head.ext = ext->u.tagFunction; head.extNum = ext - extensions; } else { head.ext = NULL; head.tag = -1; } token->u.cond.test.type = TRIVIAL; token->u.cond.test.u.tag = head; } } token->type = PTOK_COND; return 0; } /** * @return 0 on success, 1 on failure */ static int getExtension(Header h, headerTagTagFunction fn, /*@out@*/ hTYP_t typeptr, /*@out@*/ hPTR_t * data, /*@out@*/ hCNT_t countptr, extensionCache ext) /*@modifies *typeptr, *data, *countptr, ext @*/ { if (!ext->avail) { if (fn(h, &ext->type, &ext->data, &ext->count, &ext->freeit)) return 1; ext->avail = 1; } if (typeptr) *typeptr = ext->type; if (data) *data = ext->data; if (countptr) *countptr = ext->count; return 0; } /** */ static char * formatValue(sprintfTag tag, Header h, const headerSprintfExtension extensions, extensionCache extCache, int element, char ** valp, int * vallenp, int * allocedp) /*@modifies extCache, *valp, *vallenp, *allocedp @*/ { char * val = NULL; int need = 0; char * t, * te; char buf[20]; int_32 count, type; hPTR_t data; unsigned int intVal; const char ** strarray; int datafree = 0; int countBuf; headerTagFormatFunction tagtype = NULL; headerSprintfExtension ext; memset(buf, 0, sizeof(buf)); /*@-branchstate@*/ if (tag->ext) { if (getExtension(h, tag->ext, &type, &data, &count, extCache + tag->extNum)) { count = 1; type = RPM_STRING_TYPE; data = "(none)"; } } else { if (!headerGetEntry(h, tag->tag, &type, (void **)&data, &count)) { count = 1; type = RPM_STRING_TYPE; data = "(none)"; } datafree = 1; } /*@=branchstate@*/ if (tag->arrayCount) { /*@-observertrans -modobserver@*/ data = headerFreeData(data, type); /*@=observertrans =modobserver@*/ countBuf = count; data = &countBuf; count = 1; type = RPM_INT32_TYPE; } (void) stpcpy( stpcpy(buf, "%"), tag->format); if (tag->type) { ext = extensions; while (ext->type != HEADER_EXT_LAST) { if (ext->name != NULL && ext->type == HEADER_EXT_FORMAT && !strcmp(ext->name, tag->type)) { tagtype = ext->u.formatFunction; break; } if (ext->type == HEADER_EXT_MORE) ext = ext->u.more; else ext++; } } /*@-branchstate@*/ switch (type) { case RPM_STRING_ARRAY_TYPE: strarray = (const char **)data; if (tagtype) val = tagtype(RPM_STRING_TYPE, strarray[element], buf, tag->pad, 0); if (val) { need = strlen(val); } else if (strarray && strarray[element]) { need = strlen(strarray[element]) + tag->pad + 20; val = xmalloc(need+1); strcat(buf, "s"); /*@-formatconst@*/ sprintf(val, buf, strarray[element]); /*@=formatconst@*/ } /*@-observertrans -modobserver@*/ if (datafree) data = _free(data); /*@=observertrans =modobserver@*/ break; case RPM_STRING_TYPE: if (tagtype) val = tagtype(RPM_STRING_ARRAY_TYPE, data, buf, tag->pad, 0); if (val) { need = strlen(val); } else if (data) { need = strlen(data) + tag->pad + 20; val = xmalloc(need+1); strcat(buf, "s"); /*@-formatconst@*/ sprintf(val, buf, data); /*@=formatconst@*/ } break; case RPM_CHAR_TYPE: case RPM_INT8_TYPE: case RPM_INT16_TYPE: case RPM_INT32_TYPE: switch (type) { case RPM_CHAR_TYPE: case RPM_INT8_TYPE: intVal = *(((int_8 *) data) + element); /*@innerbreak@*/ break; case RPM_INT16_TYPE: intVal = *(((uint_16 *) data) + element); /*@innerbreak@*/ break; default: /* keep -Wall quiet */ case RPM_INT32_TYPE: intVal = *(((int_32 *) data) + element); /*@innerbreak@*/ break; } if (tagtype) val = tagtype(RPM_INT32_TYPE, &intVal, buf, tag->pad, element); if (val) { need = strlen(val); } else { need = 10 + tag->pad + 20; val = xmalloc(need+1); strcat(buf, "u"); /*@-formatconst@*/ sprintf(val, buf, intVal); /*@=formatconst@*/ } break; case RPM_BIN_TYPE: if (tagtype) val = tagtype(RPM_BIN_TYPE, data, buf, tag->pad, count); if (val) { need = count; /* XXX broken iff RPM_BIN_TYPE extension */ } else { #ifdef NOTYET val = memcpy(xmalloc(count), data, count); #else /* XXX format string not used */ static char hex[] = "0123456789abcdef"; const char * s = data; need = 2*count + tag->pad; val = t = xmalloc(need+1); while (count-- > 0) { unsigned int i; i = *s++; *t++ = hex[ (i >> 4) & 0xf ]; *t++ = hex[ (i ) & 0xf ]; } *t = '\0'; #endif } break; default: need = sizeof("(unknown type)") - 1; val = xstrdup("(unknown type)"); break; } /*@=branchstate@*/ if (val && need > 0) { if (((*vallenp) + need) >= (*allocedp)) { if ((*allocedp) <= need) (*allocedp) += need; (*allocedp) <<= 1; (*valp) = xrealloc((*valp), (*allocedp)+1); } t = (*valp) + (*vallenp); te = stpcpy(t, val); (*vallenp) += (te - t); val = _free(val); } return ((*valp) + (*vallenp)); } /** */ static char * singleSprintf(Header h, sprintfToken token, const headerSprintfExtension extensions, extensionCache extCache, int element, char ** valp, int * vallenp, int * allocedp) /*@modifies h, extCache, *valp, *vallenp, *allocedp @*/ { char * t, * te; int i, j; int numElements; int type; sprintfToken condFormat; int condNumFormats; int need; /* we assume the token and header have been validated already! */ switch (token->type) { case PTOK_NONE: break; case PTOK_STRING: need = token->u.string.len; if (need <= 0) break; if (((*vallenp) + need) >= (*allocedp)) { if ((*allocedp) <= need) (*allocedp) += need; (*allocedp) <<= 1; (*valp) = xrealloc((*valp), (*allocedp)+1); } t = (*valp) + (*vallenp); te = stpcpy(t, token->u.string.string); (*vallenp) += (te - t); break; case PTOK_TAG: t = (*valp) + (*vallenp); te = formatValue(&token->u.tag, h, extensions, extCache, (token->u.tag.justOne ? 0 : element), valp, vallenp, allocedp); break; case PTOK_COND: { int testResult = 0; /* false by default */ switch (token->u.cond.test.type) { case TRIVIAL: testResult = token->u.cond.test.u.tag.ext || headerIsEntry(h, token->u.cond.test.u.tag.tag); break; case StringTAG_String3: { /* this piece if code is based on headerSprintf() */ char * head = NULL; int head_en = 0; int head_alloced = 0; head = xstrdup(""); for (i = 0; i < token->u.cond.test.u.tag_str3.numHeadTokens; i++) /* head_t = -- what do we need the return value for? headerSprintf() discards it. */ singleSprintf(h, token->u.cond.test.u.tag_str3.headFormat + i, extensions, extCache, element, &head, &head_en, &head_alloced); if (head != NULL && head_en < head_alloced) head = xrealloc(head, head_en+1); testResult = head && token->u.cond.test.u.tag_str3.predicate(head, token->u.cond.test.u.tag_str3.tail); /* Do we free all the alloced data heer? */ _free(head); } break; default: /* report an error */ rpmMessage(RPMMESS_WARNING, _("Unknown test type in \%|?:|; assuming false.\n")); testResult = 0; break; } if (testResult) { condFormat = token->u.cond.ifFormat; condNumFormats = token->u.cond.numIfTokens; } else { condFormat = token->u.cond.elseFormat; condNumFormats = token->u.cond.numElseTokens; } } need = condNumFormats * 20; if (condFormat == NULL || need <= 0) break; if (((*vallenp) + need) >= (*allocedp)) { if ((*allocedp) <= need) (*allocedp) += need; (*allocedp) <<= 1; (*valp) = xrealloc((*valp), (*allocedp)+1); } t = (*valp) + (*vallenp); for (i = 0; i < condNumFormats; i++) te = singleSprintf(h, condFormat + i, extensions, extCache, element, valp, vallenp, allocedp); break; case PTOK_ARRAY: numElements = -1; for (i = 0; i < token->u.array.numTokens; i++) { if (token->u.array.format[i].type != PTOK_TAG || token->u.array.format[i].u.tag.arrayCount || token->u.array.format[i].u.tag.justOne) continue; if (token->u.array.format[i].u.tag.ext) { const void * data; if (getExtension(h, token->u.array.format[i].u.tag.ext, &type, &data, &numElements, extCache + token->u.array.format[i].u.tag.extNum)) continue; } else { if (!headerGetEntry(h, token->u.array.format[i].u.tag.tag, &type, NULL, &numElements)) continue; } /*@loopbreak@*/ break; } if (numElements == -1) { need = sizeof("(none)") - 1; if (((*vallenp) + need) >= (*allocedp)) { if ((*allocedp) <= need) (*allocedp) += need; (*allocedp) <<= 1; (*valp) = xrealloc((*valp), (*allocedp)+1); } t = (*valp) + (*vallenp); te = stpcpy(t, "(none)"); (*vallenp) += (te - t); } else { need = numElements * token->u.array.numTokens * 10; if (need <= 0) break; if (((*vallenp) + need) >= (*allocedp)) { if ((*allocedp) <= need) (*allocedp) += need; (*allocedp) <<= 1; (*valp) = xrealloc((*valp), (*allocedp)+1); } t = (*valp) + (*vallenp); for (j = 0; j < numElements; j++) { for (i = 0; i < token->u.array.numTokens; i++) te = singleSprintf(h, token->u.array.format + i, extensions, extCache, j, valp, vallenp, allocedp); } } break; } return ((*valp) + (*vallenp)); } /** */ static /*@only@*/ extensionCache allocateExtensionCache(const headerSprintfExtension extensions) /*@*/ { headerSprintfExtension ext = extensions; int i = 0; while (ext->type != HEADER_EXT_LAST) { i++; if (ext->type == HEADER_EXT_MORE) ext = ext->u.more; else ext++; } /*@-sizeoftype@*/ return xcalloc(i, sizeof(struct extensionCache)); /*@=sizeoftype@*/ } /** * @return NULL always */ static /*@null@*/ extensionCache freeExtensionCache(const headerSprintfExtension extensions, /*@only@*/ extensionCache cache) /*@*/ { headerSprintfExtension ext = extensions; int i = 0; while (ext->type != HEADER_EXT_LAST) { if (cache[i].freeit) cache[i].data = _free(cache[i].data); i++; if (ext->type == HEADER_EXT_MORE) ext = ext->u.more; else ext++; } cache = _free(cache); return NULL; } /** \ingroup header * Return formatted output string from header tags. * The returned string must be free()d. * * @param h header * @param fmt format to use * @param tbltags array of tag name/value pairs * @param extensions chained table of formatting extensions. * @retval errmsg error message (if any) * @return formatted output string (malloc'ed) */ static /*@only@*/ /*@null@*/ char * headerSprintf(Header h, const char * fmt, const struct headerTagTableEntry_s * tbltags, const struct headerSprintfExtension_s * extensions, /*@null@*/ /*@out@*/ errmsg_t * errmsg) /*@modifies *errmsg @*/ { /*@-castexpose@*/ /* FIX: legacy API shouldn't change. */ headerSprintfExtension exts = (headerSprintfExtension) extensions; headerTagTableEntry tags = (headerTagTableEntry) tbltags; /*@=castexpose@*/ char * fmtString; sprintfToken format; int numTokens; char * val = NULL; int vallen = 0; int alloced = 0; int i; extensionCache extCache; /*fmtString = escapeString(fmt);*/ fmtString = xstrdup(fmt); if (parseFormat(fmtString, tags, exts, &format, &numTokens, NULL, PARSER_BEGIN, errmsg)) { fmtString = _free(fmtString); return NULL; } extCache = allocateExtensionCache(exts); val = xstrdup(""); for (i = 0; i < numTokens; i++) { /*@-mods@*/ singleSprintf(h, format + i, exts, extCache, 0, &val, &vallen, &alloced); /*@=mods@*/ } if (val != NULL && vallen < alloced) val = xrealloc(val, vallen+1); fmtString = _free(fmtString); extCache = freeExtensionCache(exts, extCache); format = _free(format); return val; } /** */ static char * octalFormat(int_32 type, hPTR_t data, char * formatPrefix, int padding, /*@unused@*/int element) /*@modifies formatPrefix @*/ { char * val; if (type != RPM_INT32_TYPE) { val = xstrdup(_("(not a number)")); } else { val = xmalloc(20 + padding); strcat(formatPrefix, "o"); /*@-formatconst@*/ sprintf(val, formatPrefix, *((int_32 *) data)); /*@=formatconst@*/ } return val; } /** */ static char * hexFormat(int_32 type, hPTR_t data, char * formatPrefix, int padding, /*@unused@*/int element) /*@modifies formatPrefix @*/ { char * val; if (type != RPM_INT32_TYPE) { val = xstrdup(_("(not a number)")); } else { val = xmalloc(20 + padding); strcat(formatPrefix, "x"); /*@-formatconst@*/ sprintf(val, formatPrefix, *((int_32 *) data)); /*@=formatconst@*/ } return val; } /** */ static char * realDateFormat(int_32 type, hPTR_t data, char * formatPrefix, int padding, /*@unused@*/int element, const char * strftimeFormat) /*@modifies formatPrefix @*/ { char * val; if (type != RPM_INT32_TYPE) { val = xstrdup(_("(not a number)")); } else { struct tm * tstruct; char buf[50]; val = xmalloc(50 + padding); strcat(formatPrefix, "s"); /* this is important if sizeof(int_32) ! sizeof(time_t) */ { time_t dateint = *((int_32 *) data); tstruct = localtime(&dateint); } buf[0] = '\0'; if (tstruct) (void) strftime(buf, sizeof(buf) - 1, strftimeFormat, tstruct); /*@-formatconst@*/ sprintf(val, formatPrefix, buf); /*@=formatconst@*/ } return val; } /** */ static char * dateFormat(int_32 type, hPTR_t data, char * formatPrefix, int padding, int element) /*@modifies formatPrefix @*/ { return realDateFormat(type, data, formatPrefix, padding, element, "%c"); } /** */ static char * dayFormat(int_32 type, hPTR_t data, char * formatPrefix, int padding, int element) /*@modifies formatPrefix @*/ { return realDateFormat(type, data, formatPrefix, padding, element, "%a %b %d %Y"); } /** */ static char * shescapeFormat(int_32 type, hPTR_t data, char * formatPrefix, int padding, /*@unused@*/int element) /*@modifies formatPrefix @*/ { char * result, * dst, * src, * buf; if (type == RPM_INT32_TYPE) { result = xmalloc(padding + 20); strcat(formatPrefix, "u"); /*@-formatconst@*/ sprintf(result, formatPrefix, *((int_32 *) data)); /*@=formatconst@*/ } else { buf = alloca(strlen(data) + padding + 2); strcat(formatPrefix, "s"); /*@-formatconst@*/ sprintf(buf, formatPrefix, data); /*@=formatconst@*/ result = dst = xmalloc(strlen(buf) * 4 + 3); *dst++ = '\''; for (src = buf; *src != '\0'; src++) { if (*src == '\'') { *dst++ = '\''; *dst++ = '\\'; *dst++ = '\''; *dst++ = '\''; } else { *dst++ = *src; } } *dst++ = '\''; *dst = '\0'; } return result; } /*@-type@*/ /* FIX: cast? */ const struct headerSprintfExtension_s headerDefaultFormats[] = { { HEADER_EXT_FORMAT, "octal", { octalFormat } }, { HEADER_EXT_FORMAT, "hex", { hexFormat } }, { HEADER_EXT_FORMAT, "date", { dateFormat } }, { HEADER_EXT_FORMAT, "day", { dayFormat } }, { HEADER_EXT_FORMAT, "shescape", { shescapeFormat } }, { HEADER_EXT_LAST, NULL, { NULL } } }; /*@=type@*/ /** \ingroup header * Duplicate tag values from one header into another. * @param headerFrom source header * @param headerTo destination header * @param tagstocopy array of tags that are copied */ static void headerCopyTags(Header headerFrom, Header headerTo, hTAG_t tagstocopy) /*@modifies headerTo @*/ { int * p; if (headerFrom == headerTo) return; for (p = tagstocopy; *p != 0; p++) { char *s; int_32 type; int_32 count; if (headerIsEntry(headerTo, *p)) continue; if (!headerGetEntryMinMemory(headerFrom, *p, &type, (hPTR_t *) &s, &count)) continue; (void) headerAddEntry(headerTo, *p, type, s, count); s = headerFreeData(s, type); } } /** * Header tag iterator data structure. */ struct headerIteratorS { /*@unused@*/ Header h; /*!< Header being iterated. */ /*@unused@*/ int next_index; /*!< Next tag index. */ }; /** \ingroup header * Destroy header tag iterator. * @param hi header tag iterator * @return NULL always */ static /*@null@*/ HeaderIterator headerFreeIterator(/*@only@*/ HeaderIterator hi) /*@modifies hi @*/ { hi->h = headerFree(hi->h); hi = _free(hi); return hi; } /** \ingroup header * Create header tag iterator. * @param h header * @return header tag iterator */ static HeaderIterator headerInitIterator(Header h) /*@modifies h */ { HeaderIterator hi = xmalloc(sizeof(*hi)); headerSort(h); hi->h = headerLink(h); hi->next_index = 0; return hi; } /** \ingroup header * Return next tag from header. * @param hi header tag iterator * @retval tag address of tag * @retval type address of tag value data type * @retval p address of pointer to tag value(s) * @retval c address of number of values * @return 1 on success, 0 on failure */ static int headerNextIterator(HeaderIterator hi, /*@null@*/ /*@out@*/ hTAG_t tag, /*@null@*/ /*@out@*/ hTYP_t type, /*@null@*/ /*@out@*/ hPTR_t * p, /*@null@*/ /*@out@*/ hCNT_t c) /*@modifies hi, *tag, *type, *p, *c @*/ { Header h = hi->h; int slot = hi->next_index; indexEntry entry = NULL; int rc; for (slot = hi->next_index; slot < h->indexUsed; slot++) { entry = h->index + slot; if (!ENTRY_IS_REGION(entry)) break; } hi->next_index = slot; if (entry == NULL || slot >= h->indexUsed) return 0; /*@-noeffect@*/ /* LCL: no clue */ hi->next_index++; /*@=noeffect@*/ if (tag) *tag = entry->info.tag; rc = copyEntry(entry, type, p, c, 0); /* XXX 1 on success */ return ((rc == 1) ? 1 : 0); } unsigned int headerGetInstance(Header h) { return h ? h->instance : 0; } void headerSetInstance(Header h, unsigned int instance) { h->instance = instance; } /** \ingroup header * Duplicate a header. * @param h header * @return new header instance */ static /*@null@*/ Header headerCopy(Header h) /*@modifies h @*/ { Header nh = headerNew(); HeaderIterator hi; int_32 tag, type, count; hPTR_t ptr; /*@-branchstate@*/ for (hi = headerInitIterator(h); headerNextIterator(hi, &tag, &type, &ptr, &count); ptr = headerFreeData((void *)ptr, type)) { if (ptr) (void) headerAddEntry(nh, tag, type, ptr, count); } hi = headerFreeIterator(hi); /*@=branchstate@*/ return headerReload(nh, HEADER_IMAGE); } /*@observer@*/ /*@unchecked@*/ static struct HV_s hdrVec1 = { headerNew, headerFree, headerLink, headerSort, headerUnsort, headerSizeof, headerUnload, headerReload, headerCopy, headerLoad, headerCopyLoad, headerRead, headerWrite, headerIsEntry, headerFreeTag, headerGetEntry, headerGetEntryMinMemory, headerAddEntry, headerAppendEntry, headerAddOrAppendEntry, headerAddI18NString, headerModifyEntry, headerRemoveEntry, headerSprintf, headerCopyTags, headerFreeIterator, headerInitIterator, headerNextIterator, headerUnlink, NULL, NULL, 1 }; /*@-compmempass -redef@*/ /*@observer@*/ /*@unchecked@*/ HV_t hdrVec = &hdrVec1; /*@=compmempass =redef@*/