/*- * See the file LICENSE for redistribution information. * * Copyright (c) 1996, 2010 Oracle and/or its affiliates. All rights reserved. * * $Id$ */ #include "db_config.h" #include "db_int.h" #include "dbinc/db_page.h" #include "dbinc/btree.h" static int __db_build_bi __P((DB *, DB_FH *, PAGE *, PAGE *, u_int32_t, int *)); static int __db_build_ri __P((DB *, DB_FH *, PAGE *, PAGE *, u_int32_t, int *)); static int __db_up_ovref __P((DB *, DB_FH *, db_pgno_t)); #define GET_PAGE(dbp, fhp, pgno, page) { \ if ((ret = __os_seek( \ dbp->env, fhp, pgno, (dbp)->pgsize, 0)) != 0) \ goto err; \ if ((ret = __os_read(dbp->env, \ fhp, page, (dbp)->pgsize, &n)) != 0) \ goto err; \ } #define PUT_PAGE(dbp, fhp, pgno, page) { \ if ((ret = __os_seek( \ dbp->env, fhp, pgno, (dbp)->pgsize, 0)) != 0) \ goto err; \ if ((ret = __os_write(dbp->env, \ fhp, page, (dbp)->pgsize, &n)) != 0) \ goto err; \ } /* * __db_31_offdup -- * Convert 3.0 off-page duplicates to 3.1 off-page duplicates. * * PUBLIC: int __db_31_offdup __P((DB *, char *, DB_FH *, int, db_pgno_t *)); */ int __db_31_offdup(dbp, real_name, fhp, sorted, pgnop) DB *dbp; char *real_name; DB_FH *fhp; int sorted; db_pgno_t *pgnop; { PAGE *ipage, *page; db_indx_t indx; db_pgno_t cur_cnt, i, next_cnt, pgno, *pgno_cur, pgno_last; db_pgno_t *pgno_next, pgno_max, *tmp; db_recno_t nrecs; size_t n; int level, nomem, ret; ipage = page = NULL; pgno_cur = pgno_next = NULL; /* Allocate room to hold a page. */ if ((ret = __os_malloc(dbp->env, dbp->pgsize, &page)) != 0) goto err; /* * Walk the chain of 3.0 off-page duplicates. Each one is converted * in place to a 3.1 off-page duplicate page. If the duplicates are * sorted, they are converted to a Btree leaf page, otherwise to a * Recno leaf page. */ for (nrecs = 0, cur_cnt = pgno_max = 0, pgno = *pgnop; pgno != PGNO_INVALID;) { if (pgno_max == cur_cnt) { pgno_max += 20; if ((ret = __os_realloc(dbp->env, pgno_max * sizeof(db_pgno_t), &pgno_cur)) != 0) goto err; } pgno_cur[cur_cnt++] = pgno; GET_PAGE(dbp, fhp, pgno, page); nrecs += NUM_ENT(page); LEVEL(page) = LEAFLEVEL; TYPE(page) = sorted ? P_LDUP : P_LRECNO; /* * !!! * DB didn't zero the LSNs on off-page duplicates pages. */ ZERO_LSN(LSN(page)); PUT_PAGE(dbp, fhp, pgno, page); pgno = NEXT_PGNO(page); } /* If we only have a single page, it's easy. */ if (cur_cnt <= 1) goto done; /* * pgno_cur is the list of pages we just converted. We're * going to walk that list, but we'll need to create a new * list while we do so. */ if ((ret = __os_malloc(dbp->env, cur_cnt * sizeof(db_pgno_t), &pgno_next)) != 0) goto err; /* Figure out where we can start allocating new pages. */ if ((ret = __db_lastpgno(dbp, real_name, fhp, &pgno_last)) != 0) goto err; /* Allocate room for an internal page. */ if ((ret = __os_malloc(dbp->env, dbp->pgsize, &ipage)) != 0) goto err; PGNO(ipage) = PGNO_INVALID; /* * Repeatedly walk the list of pages, building internal pages, until * there's only one page at a level. */ for (level = LEAFLEVEL + 1; cur_cnt > 1; ++level) { for (indx = 0, i = next_cnt = 0; i < cur_cnt;) { if (indx == 0) { P_INIT(ipage, dbp->pgsize, pgno_last, PGNO_INVALID, PGNO_INVALID, level, sorted ? P_IBTREE : P_IRECNO); ZERO_LSN(LSN(ipage)); pgno_next[next_cnt++] = pgno_last++; } GET_PAGE(dbp, fhp, pgno_cur[i], page); /* * If the duplicates are sorted, put the first item on * the lower-level page onto a Btree internal page. If * the duplicates are not sorted, create an internal * Recno structure on the page. If either case doesn't * fit, push out the current page and start a new one. */ nomem = 0; if (sorted) { if ((ret = __db_build_bi( dbp, fhp, ipage, page, indx, &nomem)) != 0) goto err; } else if ((ret = __db_build_ri( dbp, fhp, ipage, page, indx, &nomem)) != 0) goto err; if (nomem) { indx = 0; PUT_PAGE(dbp, fhp, PGNO(ipage), ipage); } else { ++indx; ++NUM_ENT(ipage); ++i; } } /* * Push out the last internal page. Set the top-level record * count if we've reached the top. */ if (next_cnt == 1) RE_NREC_SET(ipage, nrecs); PUT_PAGE(dbp, fhp, PGNO(ipage), ipage); /* Swap the current and next page number arrays. */ cur_cnt = next_cnt; tmp = pgno_cur; pgno_cur = pgno_next; pgno_next = tmp; } done: *pgnop = pgno_cur[0]; err: if (pgno_cur != NULL) __os_free(dbp->env, pgno_cur); if (pgno_next != NULL) __os_free(dbp->env, pgno_next); if (ipage != NULL) __os_free(dbp->env, ipage); if (page != NULL) __os_free(dbp->env, page); return (ret); } /* * __db_build_bi -- * Build a BINTERNAL entry for a parent page. */ static int __db_build_bi(dbp, fhp, ipage, page, indx, nomemp) DB *dbp; DB_FH *fhp; PAGE *ipage, *page; u_int32_t indx; int *nomemp; { BINTERNAL bi, *child_bi; BKEYDATA *child_bk; u_int8_t *p; int ret; db_indx_t *inp; inp = P_INP(dbp, ipage); switch (TYPE(page)) { case P_IBTREE: child_bi = GET_BINTERNAL(dbp, page, 0); if (P_FREESPACE(dbp, ipage) < BINTERNAL_PSIZE(child_bi->len)) { *nomemp = 1; return (0); } inp[indx] = HOFFSET(ipage) -= BINTERNAL_SIZE(child_bi->len); p = P_ENTRY(dbp, ipage, indx); bi.len = child_bi->len; B_TSET(bi.type, child_bi->type); bi.pgno = PGNO(page); bi.nrecs = __bam_total(dbp, page); memcpy(p, &bi, SSZA(BINTERNAL, data)); p += SSZA(BINTERNAL, data); memcpy(p, child_bi->data, child_bi->len); /* Increment the overflow ref count. */ if (B_TYPE(child_bi->type) == B_OVERFLOW) if ((ret = __db_up_ovref(dbp, fhp, ((BOVERFLOW *)(child_bi->data))->pgno)) != 0) return (ret); break; case P_LDUP: child_bk = GET_BKEYDATA(dbp, page, 0); switch (B_TYPE(child_bk->type)) { case B_KEYDATA: if (P_FREESPACE(dbp, ipage) < BINTERNAL_PSIZE(child_bk->len)) { *nomemp = 1; return (0); } inp[indx] = HOFFSET(ipage) -= BINTERNAL_SIZE(child_bk->len); p = P_ENTRY(dbp, ipage, indx); bi.len = child_bk->len; B_TSET(bi.type, child_bk->type); bi.pgno = PGNO(page); bi.nrecs = __bam_total(dbp, page); memcpy(p, &bi, SSZA(BINTERNAL, data)); p += SSZA(BINTERNAL, data); memcpy(p, child_bk->data, child_bk->len); break; case B_OVERFLOW: if (P_FREESPACE(dbp, ipage) < BINTERNAL_PSIZE(BOVERFLOW_SIZE)) { *nomemp = 1; return (0); } inp[indx] = HOFFSET(ipage) -= BINTERNAL_SIZE(BOVERFLOW_SIZE); p = P_ENTRY(dbp, ipage, indx); bi.len = BOVERFLOW_SIZE; B_TSET(bi.type, child_bk->type); bi.pgno = PGNO(page); bi.nrecs = __bam_total(dbp, page); memcpy(p, &bi, SSZA(BINTERNAL, data)); p += SSZA(BINTERNAL, data); memcpy(p, child_bk, BOVERFLOW_SIZE); /* Increment the overflow ref count. */ if ((ret = __db_up_ovref(dbp, fhp, ((BOVERFLOW *)child_bk)->pgno)) != 0) return (ret); break; default: return (__db_pgfmt(dbp->env, PGNO(page))); } break; default: return (__db_pgfmt(dbp->env, PGNO(page))); } return (0); } /* * __db_build_ri -- * Build a RINTERNAL entry for an internal parent page. */ static int __db_build_ri(dbp, fhp, ipage, page, indx, nomemp) DB *dbp; DB_FH *fhp; PAGE *ipage, *page; u_int32_t indx; int *nomemp; { RINTERNAL ri; db_indx_t *inp; COMPQUIET(fhp, NULL); inp = P_INP(dbp, ipage); if (P_FREESPACE(dbp, ipage) < RINTERNAL_PSIZE) { *nomemp = 1; return (0); } ri.pgno = PGNO(page); ri.nrecs = __bam_total(dbp, page); inp[indx] = HOFFSET(ipage) -= RINTERNAL_SIZE; memcpy(P_ENTRY(dbp, ipage, indx), &ri, RINTERNAL_SIZE); return (0); } /* * __db_up_ovref -- * Increment/decrement the reference count on an overflow page. */ static int __db_up_ovref(dbp, fhp, pgno) DB *dbp; DB_FH *fhp; db_pgno_t pgno; { PAGE *page; size_t n; int ret; /* Allocate room to hold a page. */ if ((ret = __os_malloc(dbp->env, dbp->pgsize, &page)) != 0) return (ret); GET_PAGE(dbp, fhp, pgno, page); ++OV_REF(page); PUT_PAGE(dbp, fhp, pgno, page); err: __os_free(dbp->env, page); return (ret); }