/** \ingroup header * \file rpmdb/header.c */ /* RPM - Copyright (C) 1995-2002 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" #define __HEADER_PROTOTYPES__ #include #include "debug.h" int _hdr_debug = 0; #define PARSER_BEGIN 0 #define PARSER_IN_ARRAY 1 #define PARSER_IN_EXPR 2 /** \ingroup header */ static unsigned char header_magic[8] = { 0x8e, 0xad, 0xe8, 0x01, 0x00, 0x00, 0x00, 0x00 }; /** \ingroup header * Alignment needed for header data types. */ static int typeAlign[16] = { 1, /*!< RPM_NULL_TYPE */ 1, /*!< RPM_CHAR_TYPE */ 1, /*!< RPM_INT8_TYPE */ 2, /*!< RPM_INT16_TYPE */ 4, /*!< RPM_INT32_TYPE */ 8, /*!< RPM_INT64_TYPE */ 1, /*!< RPM_STRING_TYPE */ 1, /*!< RPM_BIN_TYPE */ 1, /*!< RPM_STRING_ARRAY_TYPE */ 1, /*!< RPM_I18NSTRING_TYPE */ 0, 0, 0, 0, 0, 0 }; /** \ingroup header * Size of header data types. */ static int typeSizes[16] = { 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 */ 0, 0, 0, 0, 0, 0 }; /** \ingroup header * Maximum no. of bytes permitted in a header. */ 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 type values. */ #define hdrchkType(_type) ((_type) < RPM_MIN_TYPE || (_type) > RPM_MAX_TYPE) /** * Sanity check on data size and/or offset and/or count. * This check imposes a limit of 16Mb, more than enough. */ #define hdrchkData(_nbytes) ((_nbytes) & 0xff000000) /** * Sanity check on alignment for data type. */ #define hdrchkAlign(_type, _off) ((_off) & (typeAlign[_type]-1)) /** * Sanity check on range of data offset. */ #define hdrchkRange(_dl, _off) ((_off) < 0 || (_off) > (_dl)) HV_t hdrVec; /* forward reference */ /** * Wrapper to free(3), hides const compilation noise, permit NULL, return NULL. * @param p memory to free * @return NULL always */ static inline void * _free(const void * p) { if (p != NULL) free((void *)p); return NULL; } /** \ingroup header * Reference a header instance. * @param h header * @return referenced header instance */ static Header headerLink(Header h) { if (h == NULL) return NULL; h->nrefs++; if (_hdr_debug) fprintf(stderr, "--> h %p ++ %d at %s:%u\n", h, h->nrefs, __FILE__, __LINE__); return h; } /** \ingroup header * Dereference a header instance. * @param h header * @return NULL always */ static Header headerUnlink(Header h) { if (h == NULL) return NULL; if (_hdr_debug) fprintf(stderr, "--> h %p -- %d at %s:%u\n", h, h->nrefs, __FILE__, __LINE__); h->nrefs--; return NULL; } /** \ingroup header * Dereference a header instance. * @param h header * @return NULL always */ static Header headerFree(Header h) { (void) headerUnlink(h); 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); } h = _free(h); return h; } /** \ingroup header * Create new (empty) header instance. * @return header */ static Header headerNew(void) { Header h = xcalloc(1, sizeof(*h)); h->hv = *hdrVec; /* structure assignment */ h->blob = NULL; h->indexAlloced = INDEX_MALLOC_SIZE; h->indexUsed = 0; h->flags |= HEADERFLAG_SORTED; h->index = (h->indexAlloced ? xcalloc(h->indexAlloced, sizeof(*h->index)) : NULL); h->nrefs = 0; return headerLink(h); } /** */ static int indexCmp(const void * avp, const void * bvp) { indexEntry ap = (indexEntry) avp, bp = (indexEntry) bvp; return (ap->info.tag - bp->info.tag); } /** \ingroup header * Sort tags in header. * @param h header */ static void headerSort(Header 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) { indexEntry ap = (indexEntry) avp, bp = (indexEntry) bvp; 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) { 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(Header h, enum hMagic magicp) { 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; } size += 2 * sizeof(int_32); /* count of index entries */ 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. */ if (i == 0 && (h->flags & HEADERFLAG_LEGACY)) size += sizeof(struct entryInfo_s) + entry->info.count; 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; } } size += sizeof(struct entryInfo_s) + entry->length; } return size; } /** * Return length of entry data. * @param type entry data type * @param p entry data * @param count entry item count * @param onDisk data is concatenated strings (with NUL's))? * @param pend pointer to end of data (or NULL) * @return no. bytes in data, -1 on failure */ static int dataLength(int_32 type, hPTR_t p, int_32 count, int onDisk, hPTR_t pend) { const unsigned char * s = p; const unsigned char * se = pend; int length = 0; switch (type) { case RPM_STRING_TYPE: if (count != 1) return -1; while (*s++) { if (se && s > se) return -1; length++; } length++; /* count nul terminator too. */ break; case RPM_STRING_ARRAY_TYPE: case RPM_I18NSTRING_TYPE: /* These are like RPM_STRING_TYPE, except they're *always* an array */ /* Compute sum of length of all strings, including nul terminators */ if (onDisk) { while (count--) { length++; /* count nul terminator too */ while (*s++) { if (se && s > se) return -1; length++; } } } else { const char ** av = (const char **)p; while (count--) { /* add one for null termination */ length += strlen(*av++) + 1; } } break; default: if (typeSizes[type] == -1) return -1; length = typeSizes[(type & 0xf)] * count; if (length < 0 || (se && (s + length) > se)) return -1; 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 start * @param dataEnd header data end * @param regionid region offset * @return no. bytes of data in region, -1 on error */ static int regionSwab(indexEntry entry, int il, int dl, entryInfo pe, unsigned char * dataStart, const unsigned char * dataEnd, int regionid) { unsigned char * tprev = NULL; unsigned char * t = NULL; int tdel = 0; int tl = dl; struct indexEntry_s ieprev; memset(&ieprev, 0, sizeof(ieprev)); for (; il > 0; il--, pe++) { struct indexEntry_s ie; int_32 type; ie.info.tag = ntohl(pe->tag); ie.info.type = ntohl(pe->type); ie.info.count = ntohl(pe->count); ie.info.offset = ntohl(pe->offset); if (hdrchkType(ie.info.type)) return -1; if (hdrchkData(ie.info.count)) return -1; if (hdrchkData(ie.info.offset)) return -1; if (hdrchkAlign(ie.info.type, ie.info.offset)) return -1; ie.data = t = dataStart + ie.info.offset; if (dataEnd && t >= dataEnd) return -1; ie.length = dataLength(ie.info.type, ie.data, ie.info.count, 1, dataEnd); if (ie.length < 0 || hdrchkData(ie.length)) return -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. */ if (ie.info.tag == HEADER_IMAGE) tprev -= REGION_TAG_COUNT; } /* Perform endian conversions */ switch (ntohl(pe->type)) { case RPM_INT32_TYPE: { int_32 * it = (int_32 *)t; for (; ie.info.count > 0; ie.info.count--, it += 1) { if (dataEnd && ((unsigned char *)it) >= dataEnd) return -1; *it = htonl(*it); } t = (unsigned char *) it; } break; case RPM_INT16_TYPE: { int_16 * it = (int_16 *) t; for (; ie.info.count > 0; ie.info.count--, it += 1) { if (dataEnd && ((unsigned char *)it) >= dataEnd) return -1; *it = htons(*it); } t = (unsigned char *) it; } break; default: t += ie.length; 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. */ if (tl+REGION_TAG_COUNT == dl) tl += REGION_TAG_COUNT; return dl; } /** \ingroup header * @param h header * @retval *lengthPtr no. bytes in unloaded header blob * @return unloaded header blob (NULL on error) */ static void * doHeaderUnload(Header h, int * 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; int legacy = 0; /* 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) 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; unsigned char *t; int count; int rdlen; if (entry->data == NULL || entry->length <= 0) continue; t = (unsigned char*)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]; legacy = 1; 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, NULL, 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; { entryInfo se = (entryInfo)src; 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, NULL, 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)); te += sizeof(int_32); src += sizeof(int_32); } break; case RPM_INT16_TYPE: count = entry->info.count; src = entry->data; while (count--) { *((int_16 *)te) = htons(*((int_16 *)src)); te += sizeof(int_16); src += sizeof(int_16); } break; default: memcpy(te, entry->data, entry->length); te += entry->length; 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: ei = _free(ei); 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 void * headerUnload(Header 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 indexEntry findEntry(Header h, int_32 tag, int_32 type) { indexEntry entry, entry2, last; struct indexEntry_s key; if (h == NULL) return NULL; if (!(h->flags & HEADERFLAG_SORTED)) headerSort(h); key.info.tag = tag; entry2 = entry = bsearch(&key, h->index, h->indexUsed, sizeof(*h->index), indexCmp); if (entry == NULL) 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; last = h->index + h->indexUsed; /* FIX: entry2 = entry. Code looks bogus as well. */ while (entry2->info.tag == tag && entry2->info.type != type && entry2 < last) entry2++; 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) { 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 Header headerLoad(void * uh) { int_32 * ei = (int_32 *) uh; int_32 il = ntohl(ei[0]); /* index length */ int_32 dl = ntohl(ei[1]); /* data length */ size_t pvlen = sizeof(il) + sizeof(dl) + (il * sizeof(struct entryInfo_s)) + dl; void * pv = uh; Header h = NULL; entryInfo pe; unsigned char * dataStart; unsigned char * dataEnd; indexEntry entry; int rdlen; int i; /* Sanity checks on header intro. */ if (hdrchkTags(il) || hdrchkData(dl)) goto errxit; ei = (int_32 *) pv; pe = (entryInfo) &ei[2]; dataStart = (unsigned char *) (pe + il); dataEnd = dataStart + dl; h = xcalloc(1, sizeof(*h)); h->hv = *hdrVec; /* structure assignment */ h->blob = uh; h->indexAlloced = il + 1; h->indexUsed = il; h->index = xcalloc(h->indexAlloced, sizeof(*h->index)); h->flags |= HEADERFLAG_SORTED; h->nrefs = 0; h = headerLink(h); entry = h->index; i = 0; if (!(htonl(pe->tag) < HEADER_I18NTABLE)) { h->flags |= HEADERFLAG_LEGACY; entry->info.type = REGION_TAG_TYPE; entry->info.tag = HEADER_IMAGE; entry->info.count = REGION_TAG_COUNT; entry->info.offset = ((unsigned char *)pe - dataStart); /* negative offset */ entry->data = pe; entry->length = pvlen - sizeof(il) - sizeof(dl); rdlen = regionSwab(entry+1, il, 0, pe, dataStart, dataEnd, 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_32 rdl; int_32 ril; h->flags &= ~HEADERFLAG_LEGACY; entry->info.type = htonl(pe->type); entry->info.count = htonl(pe->count); if (hdrchkType(entry->info.type)) goto errxit; if (hdrchkTags(entry->info.count)) goto errxit; { int off = ntohl(pe->offset); if (hdrchkData(off)) goto errxit; if (off) { size_t nb = REGION_TAG_COUNT; 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; rdl = (ril * sizeof(struct entryInfo_s)); entry->info.tag = HEADER_IMAGE; } } entry->info.offset = -rdl; /* negative offset */ entry->data = pe; entry->length = pvlen - sizeof(il) - sizeof(dl); rdlen = regionSwab(entry+1, ril-1, 0, pe+1, dataStart, dataEnd, 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, dataEnd, 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; } } } h->flags &= ~HEADERFLAG_SORTED; headerSort(h); return h; errxit: if (h) { h->index = _free(h->index); h = _free(h); } return h; } /** \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 Header headerReload(Header h, int tag) { Header nh; int length; void * uh = doHeaderUnload(h, &length); h = headerFree(h); 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 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 */ size_t pvlen = sizeof(il) + sizeof(dl) + (il * sizeof(struct entryInfo_s)) + dl; void * nuh = NULL; Header h = NULL; /* Sanity checks on header intro. */ if (!(hdrchkTags(il) || hdrchkData(dl)) && pvlen < headerMaxbytes) { nuh = memcpy(xmalloc(pvlen), uh, pvlen); if ((h = headerLoad(nuh)) != NULL) h->flags |= HEADERFLAG_ALLOCATED; } if (h == NULL) nuh = _free(nuh); 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 Header headerRead(FD_t fd, enum hMagic magicp) { int_32 block[4]; int_32 reserved; int_32 * ei = NULL; int_32 il; int_32 dl; int_32 magic; Header h = NULL; size_t len; int i; memset(block, 0, sizeof(block)); i = 2; if (magicp == HEADER_MAGIC_YES) i += 2; /* FIX: cast? */ if (timedRead(fd, (char *)block, i*sizeof(*block)) != (i * sizeof(*block))) goto exit; i = 0; if (magicp == HEADER_MAGIC_YES) { magic = block[i++]; if (memcmp(&magic, header_magic, sizeof(magic))) goto exit; reserved = block[i++]; } il = ntohl(block[i]); i++; dl = ntohl(block[i]); i++; len = sizeof(il) + sizeof(dl) + (il * sizeof(struct entryInfo_s)) + dl; /* 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); /* FIX: cast? */ if (timedRead(fd, (char *)&ei[2], len) != len) goto exit; h = headerLoad(ei); exit: if (h) { if (h->flags & HEADERFLAG_ALLOCATED) ei = _free(ei); h->flags |= HEADERFLAG_ALLOCATED; } else if (ei) ei = _free(ei); /* FIX: timedRead macro obscures annotation */ return h; } /** \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, Header h, enum hMagic magicp) { 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: nb = Fwrite(header_magic, sizeof(char), sizeof(header_magic), fd); if (nb != sizeof(header_magic)) goto exit; break; case HEADER_MAGIC_NO: break; } nb = Fwrite(uh, sizeof(char), length, fd); 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(Header h, int_32 tag) { /* FIX: h modified by sort. */ return (findEntry(h, tag, RPM_NULL_TYPE) ? 1 : 0); } /** \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, hTYP_t type, hPTR_t * p, hCNT_t c, int minMem) { 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; entryInfo pe = (entryInfo) (ei + 2); unsigned char * dataStart = (unsigned char *) (pe + ntohl(ei[0])); int_32 rdl = -entry->info.offset; /* negative offset */ int_32 ril = rdl/sizeof(*pe); 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); pe = (entryInfo) memcpy(ei + 2, pe, (ril * sizeof(*pe))); dataStart = (unsigned char *) memcpy(pe + ril, dataStart, rdl); rc = regionSwab(NULL, ril, 0, pe, dataStart, NULL, 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; } case RPM_STRING_ARRAY_TYPE: case RPM_I18NSTRING_TYPE: { const char ** ptrEntry; int tableSize = count * sizeof(char *); char * t; int i; 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); } 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; } /** * 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) { const char *fe; #if 0 { const char *s, *ll, *CC, *EE, *dd; char *lbuf, *t. /* Copy the buffer and parse out components on the fly. */ lbuf = alloca(le - l + 1); for (s = l, ll = t = lbuf; *s; s++, t++) { switch (*s) { case '_': *t = '\0'; CC = t + 1; break; case '.': *t = '\0'; EE = t + 1; break; case '@': *t = '\0'; dd = t + 1; break; default: *t = *s; break; } } if (ll) /* ISO language should be lower case */ for (t = ll; *t; t++) *t = tolower(*t); if (CC) /* ISO country code should be upper case */ for (t = CC; *t; t++) *t = toupper(*t); /* There are a total of 16 cases to attempt to match. */ } #endif /* First try a complete match. */ if (strlen(td) == (le-l) && !strncmp(td, l, (le - l))) return 1; /* Next, try stripping optional dialect and matching. */ for (fe = l; fe < le && *fe != '@'; fe++) {}; if (fe < le && !strncmp(td, l, (fe - l))) return 1; /* Next, try stripping optional codeset and matching. */ for (fe = l; fe < le && *fe != '.'; fe++) {}; if (fe < le && !strncmp(td, l, (fe - l))) return 1; /* Finally, try stripping optional country code and matching. */ for (fe = l; fe < le && *fe != '_'; fe++) {}; if (fe < le && !strncmp(td, l, (fe - l))) return 1; return 0; } /** * 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) */ static char * headerFindI18NString(Header h, indexEntry entry) { const char *lang, *l, *le; indexEntry table; /* XXX Drepper sez' this is the order. */ if ((lang = getenv("LANGUAGE")) == NULL && (lang = getenv("LC_ALL")) == NULL && (lang = getenv("LC_MESSAGES")) == NULL && (lang = getenv("LANG")) == NULL) return entry->data; if ((table = findEntry(h, HEADER_I18NTABLE, RPM_STRING_ARRAY_TYPE)) == NULL) return entry->data; for (l = lang; *l != '\0'; 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)) return ed; } } return 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, hTAG_t type, hPTR_t * p, hCNT_t c, int minMem) { indexEntry entry; int rc; /* First find the tag */ /* FIX: h modified by sort. */ entry = findEntry(h, tag, RPM_NULL_TYPE); 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; if (p) *p = headerFindI18NString(h, entry); 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 void * headerFreeTag(Header h, const void * data, rpmTagType type) { if (data) { if (type == -1 || type == RPM_STRING_ARRAY_TYPE || type == RPM_I18NSTRING_TYPE || type == RPM_BIN_TYPE) data = _free(data); } 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, hTYP_t type, void ** p, hCNT_t 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, hTYP_t type, hPTR_t * p, hCNT_t 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 */ /* FIX: h modified by sort. */ entry = findEntry(h, tag, RPM_NULL_TYPE); 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, void * dstPtr, const void * srcPtr, int_32 cnt, int dataLength) { switch (type) { case RPM_STRING_ARRAY_TYPE: case RPM_I18NSTRING_TYPE: { const char ** av = (const char **) srcPtr; char * t = dstPtr; while (cnt-- > 0 && dataLength > 0) { const char * s; if ((s = *av++) == NULL) continue; do { *t++ = *s++; } while (s[-1] && --dataLength > 0); } } 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, NULL on error */ static void * grabData(int_32 type, hPTR_t p, int_32 c, int * lengthPtr) { void * data = NULL; int length; length = dataLength(type, p, c, 0, NULL); if (length > 0) { 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) { indexEntry entry; void * data; int length; /* Count must always be >= 1 for headerAddEntry. */ if (c <= 0) return 0; if (hdrchkType(type)) return 0; if (hdrchkData(c)) return 0; length = 0; data = grabData(type, p, c, &length); if (data == NULL || length <= 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 = data; entry->length = 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) { indexEntry entry; int length; if (type == RPM_STRING_TYPE || type == RPM_I18NSTRING_TYPE) { /* we can't do this */ return 0; } /* Find the tag entry in the header. */ entry = findEntry(h, tag, type); if (!entry) return 0; length = dataLength(type, p, c, 0, NULL); if (length < 0) return 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) { 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) { 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')) { charArray[count++] = "C"; } else { charArray[count++] = "C"; 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; if (!lang) lang = "C"; { 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; memcpy(t, string, sn); t += sn; memcpy(t, e, en); t += en; /* 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); entry->data = buf; } 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) { indexEntry entry; void * oldData; void * data; int length; /* First find the tag */ entry = findEntry(h, tag, type); if (!entry) return 0; length = 0; data = grabData(type, p, c, &length); if (data == NULL || length <= 0) 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 = data; entry->length = length; if (ENTRY_IN_REGION(entry)) { entry->info.offset = 0; } else oldData = _free(oldData); 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 sprintfToken freeFormat( sprintfToken format, int num) { 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); 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); break; case PTOK_NONE: case PTOK_TAG: case PTOK_STRING: default: break; } } format = _free(format); return NULL; } /** * Header tag iterator data structure. */ struct headerIterator_s { Header h; /*!< Header being iterated. */ int next_index; /*!< Next tag index. */ }; /** \ingroup header * Destroy header tag iterator. * @param hi header tag iterator * @return NULL always */ static HeaderIterator headerFreeIterator(HeaderIterator hi) { if (hi != NULL) { 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) { 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 tag * @retval *type tag value data type * @retval *p pointer to tag value(s) * @retval *c number of values * @return 1 on success, 0 on failure */ static int headerNextIterator(HeaderIterator hi, hTAG_t tag, hTYP_t type, hPTR_t * p, hCNT_t 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; /* LCL: no clue */ hi->next_index++; if (tag) *tag = entry->info.tag; rc = copyEntry(entry, type, p, c, 0); /* XXX 1 on success */ return ((rc == 1) ? 1 : 0); } /** \ingroup header * Duplicate a header. * @param h header * @return new header instance */ static Header headerCopy(Header h) { Header nh = headerNew(); HeaderIterator hi; int_32 tag, type, count; hPTR_t ptr; 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); return headerReload(nh, HEADER_IMAGE); } /** */ typedef struct headerSprintfArgs_s { Header h; char * fmt; headerTagTableEntry tags; headerSprintfExtension exts; const char * errmsg; rpmec ec; sprintfToken format; HeaderIterator hi; char * val; size_t vallen; size_t alloced; int numTokens; int i; } * headerSprintfArgs; /** * Initialize an hsa iteration. * @param hsa headerSprintf args * @return headerSprintf args */ static headerSprintfArgs hsaInit(headerSprintfArgs hsa) { sprintfTag tag = (hsa->format->type == PTOK_TAG ? &hsa->format->u.tag : (hsa->format->type == PTOK_ARRAY ? &hsa->format->u.array.format->u.tag : NULL)); if (hsa != NULL) { hsa->i = 0; if (tag != NULL && tag->tag == -2) hsa->hi = headerInitIterator(hsa->h); } return hsa; } /** * Return next hsa iteration item. * @param hsa headerSprintf args * @return next sprintfToken (or NULL) */ static sprintfToken hsaNext(headerSprintfArgs hsa) { sprintfToken fmt = NULL; sprintfTag tag = (hsa->format->type == PTOK_TAG ? &hsa->format->u.tag : (hsa->format->type == PTOK_ARRAY ? &hsa->format->u.array.format->u.tag : NULL)); if (hsa != NULL && hsa->i >= 0 && hsa->i < hsa->numTokens) { fmt = hsa->format + hsa->i; if (hsa->hi == NULL) { hsa->i++; } else { int_32 tagno; int_32 type; int_32 count; if (!headerNextIterator(hsa->hi, &tagno, &type, NULL, &count)) fmt = NULL; tag->tag = tagno; } } return fmt; } /** * Finish an hsa iteration. * @param hsa headerSprintf args * @return headerSprintf args */ static headerSprintfArgs hsaFini(headerSprintfArgs hsa) { if (hsa != NULL) { hsa->hi = headerFreeIterator(hsa->hi); hsa->i = 0; } return hsa; } /** * Reserve sufficient buffer space for next output value. * @param hsa headerSprintf args * @param need no. of bytes to reserve * @return pointer to reserved space */ static char * hsaReserve(headerSprintfArgs hsa, size_t need) { if ((hsa->vallen + need) >= hsa->alloced) { if (hsa->alloced <= need) hsa->alloced += need; hsa->alloced <<= 1; hsa->val = xrealloc(hsa->val, hsa->alloced+1); } return hsa->val + hsa->vallen; } /** * Return tag name from value. * @todo bsearch on sorted value table. * @param tbl tag table * @param val tag value to find * @return tag name, NULL on not found */ static const char * myTagName(headerTagTableEntry tbl, int val) { static char name[128]; const char * s; char *t; for (; tbl->name != NULL; tbl++) { if (tbl->val == val) break; } if ((s = tbl->name) == NULL) return NULL; s += sizeof("RPMTAG_") - 1; t = name; *t++ = *s++; while (*s != '\0') *t++ = xtolower(*s++); *t = '\0'; return name; } /** * Return tag value from name. * @todo bsearch on sorted name table. * @param tbl tag table * @param name tag name to find * @return tag value, 0 on not found */ static int myTagValue(headerTagTableEntry tbl, const char * name) { for (; tbl->name != NULL; tbl++) { if (!xstrcasecmp(tbl->name, name)) return tbl->val; } return 0; } /** * @param hsa headerSprintf args * @param token parsed fields * @param name name to find * @return 0 on success, 1 on not found */ static int findTag(headerSprintfArgs hsa, sprintfToken token, const char * name) { headerSprintfExtension ext; sprintfTag stag = (token->type == PTOK_COND ? &token->u.cond.tag : &token->u.tag); stag->fmt = NULL; stag->ext = NULL; stag->extNum = 0; stag->tag = -1; if (!strcmp(name, "*")) { stag->tag = -2; goto bingo; } if (strncmp("RPMTAG_", name, sizeof("RPMTAG_")-1)) { char * t = alloca(strlen(name) + sizeof("RPMTAG_")); (void) stpcpy( stpcpy(t, "RPMTAG_"), name); name = t; } /* Search extensions for specific tag override. */ for (ext = hsa->exts; ext != NULL && ext->type != HEADER_EXT_LAST; ext = (ext->type == HEADER_EXT_MORE ? ext->u.more : ext+1)) { if (ext->name == NULL || ext->type != HEADER_EXT_TAG) continue; if (!xstrcasecmp(ext->name, name)) { stag->ext = ext->u.tagFunction; stag->extNum = ext - hsa->exts; goto bingo; } } /* Search tag names. */ stag->tag = myTagValue(hsa->tags, name); if (stag->tag != 0) goto bingo; return 1; bingo: /* Search extensions for specific format. */ if (stag->type != NULL) for (ext = hsa->exts; ext != NULL && ext->type != HEADER_EXT_LAST; ext = (ext->type == HEADER_EXT_MORE ? ext->u.more : ext+1)) { if (ext->name == NULL || ext->type != HEADER_EXT_FORMAT) continue; if (!strcmp(ext->name, stag->type)) { stag->fmt = ext->u.formatFunction; break; } } return 0; } /* forward ref */ /** * @param hsa headerSprintf args * @param token * @param str * @retval *endPtr * @return 0 on success */ static int parseExpression(headerSprintfArgs hsa, sprintfToken token, char * str,char ** endPtr); /** * @param hsa headerSprintf args * @param str * @retval *formatPtr * @retval *numTokensPtr * @retval *endPtr * @param state * @return 0 on success */ static int parseFormat(headerSprintfArgs hsa, char * str, sprintfToken * formatPtr,int * numTokensPtr, char ** endPtr, int state) { char * chptr, * start, * next, * dst; sprintfToken format; sprintfToken token; int numTokens; int i; int done = 0; /* upper limit on number of individual formats */ numTokens = 0; if (str != NULL) for (chptr = str; *chptr != '\0'; chptr++) if (*chptr == '%') numTokens++; numTokens = numTokens * 2 + 1; format = xcalloc(numTokens, sizeof(*format)); if (endPtr) *endPtr = NULL; /* LCL: can't detect done termination */ dst = start = str; numTokens = 0; token = NULL; if (start != NULL) while (*start != '\0') { switch (*start) { case '%': /* handle %% */ if (*(start + 1) == '%') { if (token == NULL || token->type != PTOK_STRING) { token = format + numTokens++; token->type = PTOK_STRING; dst = token->u.string.string = start; } start++; *dst++ = *start++; break; } token = format + numTokens++; *dst++ = '\0'; start++; if (*start == '|') { char * newEnd; start++; if (parseExpression(hsa, token, start, &newEnd)) { format = freeFormat(format, numTokens); return 1; } start = newEnd; break; } token->u.tag.format = start; token->u.tag.pad = 0; token->u.tag.justOne = 0; token->u.tag.arrayCount = 0; chptr = start; while (*chptr && *chptr != '{' && *chptr != '%') chptr++; if (!*chptr || *chptr == '%') { hsa->errmsg = _("missing { after %"); format = freeFormat(format, numTokens); return 1; } *chptr++ = '\0'; while (start < chptr) { if (xisdigit(*start)) { i = strtoul(start, &start, 10); token->u.tag.pad += i; } else { start++; } } if (*start == '=') { token->u.tag.justOne = 1; start++; } else if (*start == '#') { token->u.tag.justOne = 1; token->u.tag.arrayCount = 1; start++; } next = start; while (*next && *next != '}') next++; if (!*next) { hsa->errmsg = _("missing } after %{"); format = freeFormat(format, numTokens); return 1; } *next++ = '\0'; chptr = start; while (*chptr && *chptr != ':') chptr++; if (*chptr != '\0') { *chptr++ = '\0'; if (!*chptr) { hsa->errmsg = _("empty tag format"); format = freeFormat(format, numTokens); return 1; } token->u.tag.type = chptr; } else { token->u.tag.type = NULL; } if (!*start) { hsa->errmsg = _("empty tag name"); format = freeFormat(format, numTokens); return 1; } i = 0; token->type = PTOK_TAG; if (findTag(hsa, token, start)) { hsa->errmsg = _("unknown tag"); format = freeFormat(format, numTokens); return 1; } start = next; break; case '[': *dst++ = '\0'; *start++ = '\0'; token = format + numTokens++; if (parseFormat(hsa, start, &token->u.array.format, &token->u.array.numTokens, &start, PARSER_IN_ARRAY)) { format = freeFormat(format, numTokens); return 1; } if (!start) { hsa->errmsg = _("] expected at end of array"); format = freeFormat(format, numTokens); return 1; } dst = start; token->type = PTOK_ARRAY; break; case ']': if (state != PARSER_IN_ARRAY) { hsa->errmsg = _("unexpected ]"); format = freeFormat(format, numTokens); return 1; } *start++ = '\0'; if (endPtr) *endPtr = start; done = 1; break; case '}': if (state != PARSER_IN_EXPR) { hsa->errmsg = _("unexpected }"); format = freeFormat(format, numTokens); return 1; } *start++ = '\0'; if (endPtr) *endPtr = start; done = 1; break; default: if (token == NULL || token->type != PTOK_STRING) { token = format + numTokens++; token->type = PTOK_STRING; dst = token->u.string.string = start; } if (*start == '\\') { start++; *dst++ = escapedChar(*start++); } else { *dst++ = *start++; } break; } if (done) break; } if (dst != NULL) *dst = '\0'; for (i = 0; i < numTokens; i++) { token = format + i; if (token->type == PTOK_STRING) token->u.string.len = strlen(token->u.string.string); } *numTokensPtr = numTokens; *formatPtr = format; return 0; } static int parseExpression(headerSprintfArgs hsa, sprintfToken token, char * str, char ** endPtr) { char * chptr; char * end; hsa->errmsg = NULL; chptr = str; while (*chptr && *chptr != '?') chptr++; if (*chptr != '?') { hsa->errmsg = _("? expected in expression"); return 1; } *chptr++ = '\0';; if (*chptr != '{') { hsa->errmsg = _("{ expected after ? in expression"); return 1; } chptr++; if (parseFormat(hsa, chptr, &token->u.cond.ifFormat, &token->u.cond.numIfTokens, &end, PARSER_IN_EXPR)) return 1; /* XXX fix segfault on "rpm -q rpm --qf='%|NAME?{%}:{NAME}|\n'"*/ if (!(end && *end)) { hsa->errmsg = _("} expected in expression"); token->u.cond.ifFormat = freeFormat(token->u.cond.ifFormat, token->u.cond.numIfTokens); return 1; } chptr = end; if (*chptr != ':' && *chptr != '|') { hsa->errmsg = _(": expected following ? subexpression"); token->u.cond.ifFormat = freeFormat(token->u.cond.ifFormat, token->u.cond.numIfTokens); return 1; } if (*chptr == '|') { if (parseFormat(hsa, NULL, &token->u.cond.elseFormat, &token->u.cond.numElseTokens, &end, PARSER_IN_EXPR)) { token->u.cond.ifFormat = freeFormat(token->u.cond.ifFormat, token->u.cond.numIfTokens); return 1; } } else { chptr++; if (*chptr != '{') { hsa->errmsg = _("{ expected after : in expression"); token->u.cond.ifFormat = freeFormat(token->u.cond.ifFormat, token->u.cond.numIfTokens); return 1; } chptr++; if (parseFormat(hsa, chptr, &token->u.cond.elseFormat, &token->u.cond.numElseTokens, &end, PARSER_IN_EXPR)) return 1; /* XXX fix segfault on "rpm -q rpm --qf='%|NAME?{a}:{%}|{NAME}\n'" */ if (!(end && *end)) { hsa->errmsg = _("} expected in expression"); token->u.cond.ifFormat = freeFormat(token->u.cond.ifFormat, token->u.cond.numIfTokens); return 1; } chptr = end; if (*chptr != '|') { hsa->errmsg = _("| expected at end of expression"); 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; token->type = PTOK_COND; (void) findTag(hsa, token, str); return 0; } /** * Call a header extension only once, saving results. * @param hsa headerSprintf args * @param fn * @retval *typeptr * @retval *data * @retval *countptr * @retval ec extension cache * @return 0 on success, 1 on failure */ static int getExtension(headerSprintfArgs hsa, headerTagTagFunction fn, hTYP_t typeptr, hPTR_t * data, hCNT_t countptr, rpmec ec) { if (!ec->avail) { if (fn(hsa->h, &ec->type, &ec->data, &ec->count, &ec->freeit)) return 1; ec->avail = 1; } if (typeptr) *typeptr = ec->type; if (data) *data = ec->data; if (countptr) *countptr = ec->count; return 0; } /** * @param hsa headerSprintf args * @param tag * @param element * @return end of formatted string (NULL on error) */ static char * formatValue(headerSprintfArgs hsa, sprintfTag tag, int element) { char * val = NULL; size_t 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; memset(buf, 0, sizeof(buf)); if (tag->ext) { if (getExtension(hsa, tag->ext, &type, &data, &count, hsa->ec + tag->extNum)) { count = 1; type = RPM_STRING_TYPE; data = "(none)"; } } else { if (!headerGetEntry(hsa->h, tag->tag, &type, (void **)&data, &count)) { count = 1; type = RPM_STRING_TYPE; data = "(none)"; } /* XXX this test is unnecessary, array sizes are checked */ switch (type) { default: if (element >= count) { data = headerFreeData(data, type); hsa->errmsg = _("(index out of range)"); return NULL; } break; case RPM_BIN_TYPE: case RPM_STRING_TYPE: break; } datafree = 1; } if (tag->arrayCount) { if (datafree) data = headerFreeData(data, type); countBuf = count; data = &countBuf; count = 1; type = RPM_INT32_TYPE; } (void) stpcpy( stpcpy(buf, "%"), tag->format); if (data) switch (type) { case RPM_STRING_ARRAY_TYPE: strarray = (const char **)data; if (tag->fmt) val = tag->fmt(RPM_STRING_TYPE, strarray[element], buf, tag->pad, element); if (val) { need = strlen(val); } else { need = strlen(strarray[element]) + tag->pad + 20; val = xmalloc(need+1); strcat(buf, "s"); sprintf(val, buf, strarray[element]); } break; case RPM_STRING_TYPE: if (tag->fmt) val = tag->fmt(RPM_STRING_TYPE, data, buf, tag->pad, 0); if (val) { need = strlen(val); } else { need = strlen(data) + tag->pad + 20; val = xmalloc(need+1); strcat(buf, "s"); sprintf(val, buf, data); } 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); break; case RPM_INT16_TYPE: intVal = *(((uint_16 *) data) + element); break; default: /* keep -Wall quiet */ case RPM_INT32_TYPE: intVal = *(((int_32 *) data) + element); break; } if (tag->fmt) val = tag->fmt(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, "d"); sprintf(val, buf, intVal); } break; case RPM_BIN_TYPE: /* XXX HACK ALERT: element field abused as no. bytes of binary data. */ if (tag->fmt) val = tag->fmt(RPM_BIN_TYPE, data, buf, tag->pad, count); if (val) { need = strlen(val); } else { val = bin2hex(data, count); need = strlen(val) + tag->pad; } break; default: need = sizeof("(unknown type)") - 1; val = xstrdup("(unknown type)"); break; } if (datafree) data = headerFreeData(data, type); if (val && need > 0) { t = hsaReserve(hsa, need); te = stpcpy(t, val); hsa->vallen += (te - t); val = _free(val); } return (hsa->val + hsa->vallen); } /** * @param hsa headerSprintf args * @param token * @param element * @return end of formatted string (NULL on error) */ static char * singleSprintf(headerSprintfArgs hsa, sprintfToken token, int element) { char * t, * te; int i, j; int numElements; int_32 type; int_32 count; sprintfToken spft; int condNumFormats; size_t 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; t = hsaReserve(hsa, need); te = stpcpy(t, token->u.string.string); hsa->vallen += (te - t); break; case PTOK_TAG: t = hsa->val + hsa->vallen; te = formatValue(hsa, &token->u.tag, (token->u.tag.justOne ? 0 : element)); if (te == NULL) return NULL; break; case PTOK_COND: if (token->u.cond.tag.ext || headerIsEntry(hsa->h, token->u.cond.tag.tag)) { spft = token->u.cond.ifFormat; condNumFormats = token->u.cond.numIfTokens; } else { spft = token->u.cond.elseFormat; condNumFormats = token->u.cond.numElseTokens; } need = condNumFormats * 20; if (spft == NULL || need == 0) break; t = hsaReserve(hsa, need); for (i = 0; i < condNumFormats; i++, spft++) { te = singleSprintf(hsa, spft, element); if (te == NULL) return NULL; } break; case PTOK_ARRAY: numElements = -1; spft = token->u.array.format; for (i = 0; i < token->u.array.numTokens; i++, spft++) { if (spft->type != PTOK_TAG || spft->u.tag.arrayCount || spft->u.tag.justOne) continue; if (spft->u.tag.ext) { if (getExtension(hsa, spft->u.tag.ext, &type, NULL, &count, hsa->ec + spft->u.tag.extNum)) continue; } else { if (!headerGetEntry(hsa->h, spft->u.tag.tag, &type, NULL, &count)) continue; } if (type == RPM_BIN_TYPE) count = 1; /* XXX count abused as no. of bytes. */ if (numElements > 1 && count != numElements) switch (type) { default: hsa->errmsg = _("array iterator used with different sized arrays"); return NULL; break; case RPM_BIN_TYPE: case RPM_STRING_TYPE: break; } if (count > numElements) numElements = count; } if (numElements == -1) { need = sizeof("(none)") - 1; t = hsaReserve(hsa, need); te = stpcpy(t, "(none)"); hsa->vallen += (te - t); } else { int isxml; need = numElements * token->u.array.numTokens * 10; if (need == 0) break; spft = token->u.array.format; isxml = (spft->type == PTOK_TAG && spft->u.tag.type != NULL && !strcmp(spft->u.tag.type, "xml")); if (isxml) { const char * tagN = myTagName(hsa->tags, spft->u.tag.tag); need = sizeof(" \n") - 1; if (tagN != NULL) need += strlen(tagN); t = hsaReserve(hsa, need); te = stpcpy(t, " \n"); hsa->vallen += (te - t); } t = hsaReserve(hsa, need); for (j = 0; j < numElements; j++) { spft = token->u.array.format; for (i = 0; i < token->u.array.numTokens; i++, spft++) { te = singleSprintf(hsa, spft, j); if (te == NULL) return NULL; } } if (isxml) { need = sizeof(" \n") - 1; t = hsaReserve(hsa, need); te = stpcpy(t, " \n"); hsa->vallen += (te - t); } } break; } return (hsa->val + hsa->vallen); } /** * Create an extension cache. * @param exts headerSprintf extensions * @return new extension cache */ static rpmec rpmecNew(const headerSprintfExtension exts) { headerSprintfExtension ext; rpmec ec; int i = 0; for (ext = exts; ext != NULL && ext->type != HEADER_EXT_LAST; ext = (ext->type == HEADER_EXT_MORE ? ext->u.more : ext+1)) { i++; } ec = xcalloc(i, sizeof(*ec)); return ec; } /** * Destroy an extension cache. * @param exts headerSprintf extensions * @param ec extension cache * @return NULL always */ static rpmec rpmecFree(const headerSprintfExtension exts, rpmec ec) { headerSprintfExtension ext; int i = 0; for (ext = exts; ext != NULL && ext->type != HEADER_EXT_LAST; ext = (ext->type == HEADER_EXT_MORE ? ext->u.more : ext+1)) { if (ec[i].freeit) ec[i].data = _free(ec[i].data); i++; } ec = _free(ec); 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 char * headerSprintf(Header h, const char * fmt, const struct headerTagTableEntry_s * tbltags, const struct headerSprintfExtension_s * extensions, errmsg_t * errmsg) { headerSprintfArgs hsa = memset(alloca(sizeof(*hsa)), 0, sizeof(*hsa)); sprintfToken nextfmt; sprintfTag tag; char * t, * te; int isxml; int need; hsa->h = headerLink(h); hsa->fmt = xstrdup(fmt); hsa->exts = (headerSprintfExtension) extensions; hsa->tags = (headerTagTableEntry) tbltags; hsa->errmsg = NULL; if (parseFormat(hsa, hsa->fmt, &hsa->format, &hsa->numTokens, NULL, PARSER_BEGIN)) goto exit; hsa->ec = rpmecNew(hsa->exts); hsa->val = xstrdup(""); tag = (hsa->format->type == PTOK_TAG ? &hsa->format->u.tag : (hsa->format->type == PTOK_ARRAY ? &hsa->format->u.array.format->u.tag : NULL)); isxml = (tag != NULL && tag->tag == -2 && tag->type != NULL && !strcmp(tag->type, "xml")); if (isxml) { need = sizeof("\n") - 1; t = hsaReserve(hsa, need); te = stpcpy(t, "\n"); hsa->vallen += (te - t); } hsa = hsaInit(hsa); while ((nextfmt = hsaNext(hsa)) != NULL) { te = singleSprintf(hsa, nextfmt, 0); if (te == NULL) { hsa->val = _free(hsa->val); break; } } hsa = hsaFini(hsa); if (isxml) { need = sizeof("\n") - 1; t = hsaReserve(hsa, need); te = stpcpy(t, "\n"); hsa->vallen += (te - t); } if (hsa->val != NULL && hsa->vallen < hsa->alloced) hsa->val = xrealloc(hsa->val, hsa->vallen+1); hsa->ec = rpmecFree(hsa->exts, hsa->ec); hsa->format = freeFormat(hsa->format, hsa->numTokens); exit: if (errmsg) *errmsg = hsa->errmsg; hsa->h = headerFree(hsa->h); hsa->fmt = _free(hsa->fmt); return hsa->val; } /** * @param type tag type * @param data tag value * @param formatPrefix sprintf format string * @param padding no. additional bytes needed by format string * @param element (unused) * @return formatted string */ static char * octalFormat(int_32 type, hPTR_t data, char * formatPrefix, int padding,int element) { char * val; if (type != RPM_INT32_TYPE) { val = xstrdup(_("(not a number)")); } else { val = xmalloc(20 + padding); strcat(formatPrefix, "o"); sprintf(val, formatPrefix, *((int_32 *) data)); } return val; } /** * @param type tag type * @param data tag value * @param formatPrefix sprintf format string * @param padding no. additional bytes needed by format string * @param element (unused) * @return formatted string */ static char * hexFormat(int_32 type, hPTR_t data, char * formatPrefix, int padding,int element) { char * val; if (type != RPM_INT32_TYPE) { val = xstrdup(_("(not a number)")); } else { val = xmalloc(20 + padding); strcat(formatPrefix, "x"); sprintf(val, formatPrefix, *((int_32 *) data)); } return val; } /** */ static char * realDateFormat(int_32 type, hPTR_t data, char * formatPrefix, int padding,int element, const char * strftimeFormat) { 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); sprintf(val, formatPrefix, buf); } return val; } /** * @param type tag type * @param data tag value * @param formatPrefix sprintf format string * @param padding no. additional bytes needed by format string * @param element (unused) * @return formatted string */ static char * dateFormat(int_32 type, hPTR_t data, char * formatPrefix, int padding, int element) { return realDateFormat(type, data, formatPrefix, padding, element, _("%c")); } /** * @param type tag type * @param data tag value * @param formatPrefix sprintf format string * @param padding no. additional bytes needed by format string * @param element (unused) * @return formatted string */ static char * dayFormat(int_32 type, hPTR_t data, char * formatPrefix, int padding, int element) { return realDateFormat(type, data, formatPrefix, padding, element, _("%a %b %d %Y")); } /** * @param type tag type * @param data tag value * @param formatPrefix sprintf format string * @param padding no. additional bytes needed by format string * @param element (unused) * @return formatted string */ static char * shescapeFormat(int_32 type, hPTR_t data, char * formatPrefix, int padding,int element) { char * result, * dst, * src, * buf; if (type == RPM_INT32_TYPE) { result = xmalloc(padding + 20); strcat(formatPrefix, "d"); sprintf(result, formatPrefix, *((int_32 *) data)); } else { buf = alloca(strlen(data) + padding + 2); strcat(formatPrefix, "s"); sprintf(buf, formatPrefix, data); 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; } /* 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 } } }; /** \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) { 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); } } static struct HV_s hdrVec1 = { headerLink, headerUnlink, headerFree, headerNew, 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, NULL, NULL, 1 }; HV_t hdrVec = &hdrVec1;