/* * Copyright 2000-2016 The OpenSSL Project Authors. All Rights Reserved. * * Licensed under the OpenSSL license (the "License"). You may not use * this file except in compliance with the License. You can obtain a copy * in the file LICENSE in the source distribution or at * https://www.openssl.org/source/license.html */ #include "internal/cryptlib.h" #include "bn_lcl.h" /*- * TODO list * * 1. Check a bunch of "(words+1)" type hacks in various bignum functions and * check they can be safely removed. * - Check +1 and other ugliness in BN_from_montgomery() * * 2. Consider allowing a BN_new_ex() that, at least, lets you specify an * appropriate 'block' size that will be honoured by bn_expand_internal() to * prevent piddly little reallocations. OTOH, profiling bignum expansions in * BN_CTX doesn't show this to be a big issue. */ /* How many bignums are in each "pool item"; */ #define BN_CTX_POOL_SIZE 16 /* The stack frame info is resizing, set a first-time expansion size; */ #define BN_CTX_START_FRAMES 32 /***********/ /* BN_POOL */ /***********/ /* A bundle of bignums that can be linked with other bundles */ typedef struct bignum_pool_item { /* The bignum values */ BIGNUM vals[BN_CTX_POOL_SIZE]; /* Linked-list admin */ struct bignum_pool_item *prev, *next; } BN_POOL_ITEM; /* A linked-list of bignums grouped in bundles */ typedef struct bignum_pool { /* Linked-list admin */ BN_POOL_ITEM *head, *current, *tail; /* Stack depth and allocation size */ unsigned used, size; } BN_POOL; static void BN_POOL_init(BN_POOL *); static void BN_POOL_finish(BN_POOL *); static BIGNUM *BN_POOL_get(BN_POOL *, int); static void BN_POOL_release(BN_POOL *, unsigned int); /************/ /* BN_STACK */ /************/ /* A wrapper to manage the "stack frames" */ typedef struct bignum_ctx_stack { /* Array of indexes into the bignum stack */ unsigned int *indexes; /* Number of stack frames, and the size of the allocated array */ unsigned int depth, size; } BN_STACK; static void BN_STACK_init(BN_STACK *); static void BN_STACK_finish(BN_STACK *); static int BN_STACK_push(BN_STACK *, unsigned int); static unsigned int BN_STACK_pop(BN_STACK *); /**********/ /* BN_CTX */ /**********/ /* The opaque BN_CTX type */ struct bignum_ctx { /* The bignum bundles */ BN_POOL pool; /* The "stack frames", if you will */ BN_STACK stack; /* The number of bignums currently assigned */ unsigned int used; /* Depth of stack overflow */ int err_stack; /* Block "gets" until an "end" (compatibility behaviour) */ int too_many; /* Flags. */ int flags; }; /* Enable this to find BN_CTX bugs */ #ifdef BN_CTX_DEBUG static const char *ctxdbg_cur = NULL; static void ctxdbg(BN_CTX *ctx) { unsigned int bnidx = 0, fpidx = 0; BN_POOL_ITEM *item = ctx->pool.head; BN_STACK *stack = &ctx->stack; fprintf(stderr, "(%16p): ", ctx); while (bnidx < ctx->used) { fprintf(stderr, "%03x ", item->vals[bnidx++ % BN_CTX_POOL_SIZE].dmax); if (!(bnidx % BN_CTX_POOL_SIZE)) item = item->next; } fprintf(stderr, "\n"); bnidx = 0; fprintf(stderr, " : "); while (fpidx < stack->depth) { while (bnidx++ < stack->indexes[fpidx]) fprintf(stderr, " "); fprintf(stderr, "^^^ "); bnidx++; fpidx++; } fprintf(stderr, "\n"); } # define CTXDBG_ENTRY(str, ctx) do { \ ctxdbg_cur = (str); \ fprintf(stderr,"Starting %s\n", ctxdbg_cur); \ ctxdbg(ctx); \ } while(0) # define CTXDBG_EXIT(ctx) do { \ fprintf(stderr,"Ending %s\n", ctxdbg_cur); \ ctxdbg(ctx); \ } while(0) # define CTXDBG_RET(ctx,ret) #else # define CTXDBG_ENTRY(str, ctx) # define CTXDBG_EXIT(ctx) # define CTXDBG_RET(ctx,ret) #endif BN_CTX *BN_CTX_new(void) { BN_CTX *ret; if ((ret = OPENSSL_zalloc(sizeof(*ret))) == NULL) { BNerr(BN_F_BN_CTX_NEW, ERR_R_MALLOC_FAILURE); return NULL; } /* Initialise the structure */ BN_POOL_init(&ret->pool); BN_STACK_init(&ret->stack); return ret; } BN_CTX *BN_CTX_secure_new(void) { BN_CTX *ret = BN_CTX_new(); if (ret != NULL) ret->flags = BN_FLG_SECURE; return ret; } void BN_CTX_free(BN_CTX *ctx) { if (ctx == NULL) return; #ifdef BN_CTX_DEBUG { BN_POOL_ITEM *pool = ctx->pool.head; fprintf(stderr, "BN_CTX_free, stack-size=%d, pool-bignums=%d\n", ctx->stack.size, ctx->pool.size); fprintf(stderr, "dmaxs: "); while (pool) { unsigned loop = 0; while (loop < BN_CTX_POOL_SIZE) fprintf(stderr, "%02x ", pool->vals[loop++].dmax); pool = pool->next; } fprintf(stderr, "\n"); } #endif BN_STACK_finish(&ctx->stack); BN_POOL_finish(&ctx->pool); OPENSSL_free(ctx); } void BN_CTX_start(BN_CTX *ctx) { CTXDBG_ENTRY("BN_CTX_start", ctx); /* If we're already overflowing ... */ if (ctx->err_stack || ctx->too_many) ctx->err_stack++; /* (Try to) get a new frame pointer */ else if (!BN_STACK_push(&ctx->stack, ctx->used)) { BNerr(BN_F_BN_CTX_START, BN_R_TOO_MANY_TEMPORARY_VARIABLES); ctx->err_stack++; } CTXDBG_EXIT(ctx); } void BN_CTX_end(BN_CTX *ctx) { CTXDBG_ENTRY("BN_CTX_end", ctx); if (ctx->err_stack) ctx->err_stack--; else { unsigned int fp = BN_STACK_pop(&ctx->stack); /* Does this stack frame have anything to release? */ if (fp < ctx->used) BN_POOL_release(&ctx->pool, ctx->used - fp); ctx->used = fp; /* Unjam "too_many" in case "get" had failed */ ctx->too_many = 0; } CTXDBG_EXIT(ctx); } BIGNUM *BN_CTX_get(BN_CTX *ctx) { BIGNUM *ret; CTXDBG_ENTRY("BN_CTX_get", ctx); if (ctx->err_stack || ctx->too_many) return NULL; if ((ret = BN_POOL_get(&ctx->pool, ctx->flags)) == NULL) { /* * Setting too_many prevents repeated "get" attempts from cluttering * the error stack. */ ctx->too_many = 1; BNerr(BN_F_BN_CTX_GET, BN_R_TOO_MANY_TEMPORARY_VARIABLES); return NULL; } /* OK, make sure the returned bignum is "zero" */ BN_zero(ret); ctx->used++; CTXDBG_RET(ctx, ret); return ret; } /************/ /* BN_STACK */ /************/ static void BN_STACK_init(BN_STACK *st) { st->indexes = NULL; st->depth = st->size = 0; } static void BN_STACK_finish(BN_STACK *st) { OPENSSL_free(st->indexes); st->indexes = NULL; } static int BN_STACK_push(BN_STACK *st, unsigned int idx) { if (st->depth == st->size) { /* Need to expand */ unsigned int newsize = st->size ? (st->size * 3 / 2) : BN_CTX_START_FRAMES; unsigned int *newitems = OPENSSL_malloc(sizeof(*newitems) * newsize); if (newitems == NULL) return 0; if (st->depth) memcpy(newitems, st->indexes, sizeof(*newitems) * st->depth); OPENSSL_free(st->indexes); st->indexes = newitems; st->size = newsize; } st->indexes[(st->depth)++] = idx; return 1; } static unsigned int BN_STACK_pop(BN_STACK *st) { return st->indexes[--(st->depth)]; } /***********/ /* BN_POOL */ /***********/ static void BN_POOL_init(BN_POOL *p) { p->head = p->current = p->tail = NULL; p->used = p->size = 0; } static void BN_POOL_finish(BN_POOL *p) { unsigned int loop; BIGNUM *bn; while (p->head) { for (loop = 0, bn = p->head->vals; loop++ < BN_CTX_POOL_SIZE; bn++) if (bn->d) BN_clear_free(bn); p->current = p->head->next; OPENSSL_free(p->head); p->head = p->current; } } static BIGNUM *BN_POOL_get(BN_POOL *p, int flag) { BIGNUM *bn; unsigned int loop; /* Full; allocate a new pool item and link it in. */ if (p->used == p->size) { BN_POOL_ITEM *item = OPENSSL_malloc(sizeof(*item)); if (item == NULL) return NULL; for (loop = 0, bn = item->vals; loop++ < BN_CTX_POOL_SIZE; bn++) { bn_init(bn); if ((flag & BN_FLG_SECURE) != 0) BN_set_flags(bn, BN_FLG_SECURE); } item->prev = p->tail; item->next = NULL; if (p->head == NULL) p->head = p->current = p->tail = item; else { p->tail->next = item; p->tail = item; p->current = item; } p->size += BN_CTX_POOL_SIZE; p->used++; /* Return the first bignum from the new pool */ return item->vals; } if (!p->used) p->current = p->head; else if ((p->used % BN_CTX_POOL_SIZE) == 0) p->current = p->current->next; return p->current->vals + ((p->used++) % BN_CTX_POOL_SIZE); } static void BN_POOL_release(BN_POOL *p, unsigned int num) { unsigned int offset = (p->used - 1) % BN_CTX_POOL_SIZE; p->used -= num; while (num--) { bn_check_top(p->current->vals + offset); if (offset == 0) { offset = BN_CTX_POOL_SIZE - 1; p->current = p->current->prev; } else offset--; } }