/* -*- Mode: C; indent-tabs-mode: t; c-basic-offset: 8; tab-width: 8 -*- */ /* gtksecurememory.c - API for allocating memory that is non-pageable Copyright 2007 Stefan Walter Copyright 2020 GNOME Foundation SPDX-License-Identifier: LGPL-2.0-or-later The Gnome Keyring Library is free software; you can redistribute it and/or modify it under the terms of the GNU Library General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. The Gnome Keyring Library is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Library General Public License for more details. You should have received a copy of the GNU Library General Public License along with the Gnome Library; see the file COPYING.LIB. If not, see . Author: Stef Walter */ /* * IMPORTANT: This is pure vanila standard C, no glib. We need this * because certain consumers of this protocol need to be built * without linking in any special libraries. ie: the PKCS#11 module. */ #include "config.h" #include "gtksecurememoryprivate.h" #include #if defined(HAVE_MLOCK) #include #endif #include #include #include #include #include #ifdef HAVE_UNISTD_H #include #endif #include #ifdef WITH_VALGRIND #include #include #endif #define DEBUG_SECURE_MEMORY 0 #if DEBUG_SECURE_MEMORY #define DEBUG_ALLOC(msg, n) fprintf(stderr, "%s %lu bytes\n", msg, n); #else #define DEBUG_ALLOC(msg, n) #endif #define DEFAULT_BLOCK_SIZE 16384 #define DO_LOCK() \ GTK_SECURE_GLOBALS.lock (); #define DO_UNLOCK() \ GTK_SECURE_GLOBALS.unlock (); typedef struct { void (* lock) (void); void (* unlock) (void); void * (* fallback_alloc) (void *pointer, size_t length); void (* fallback_free) (void *pointer); void * pool_data; const char * pool_version; } GtkSecureGlob; #include #ifdef G_OS_WIN32 # define WIN32_LEAN_AND_MEAN # include # include /* for CryptProtectMemory() */ #endif #define GTK_SECURE_POOL_VER_STR "1.0" static int show_warning = 1; static int gtk_secure_warnings = 1; static GMutex memory_mutex; static void gtk_memory_lock (void) { g_mutex_lock (&memory_mutex); } static void gtk_memory_unlock (void) { g_mutex_unlock (&memory_mutex); } static GtkSecureGlob GTK_SECURE_GLOBALS = { .lock = gtk_memory_lock, .unlock = gtk_memory_unlock, .fallback_alloc = g_realloc, .fallback_free = g_free, .pool_data = NULL, .pool_version = GTK_SECURE_POOL_VER_STR, }; /* * We allocate all memory in units of sizeof(void*). This * is our definition of 'word'. */ typedef void* word_t; /* The amount of extra words we can allocate */ #define WASTE 4 /* * Track allocated memory or a free block. This structure is not stored * in the secure memory area. It is allocated from a pool of other * memory. See meta_pool_xxx (). */ typedef struct _Cell { word_t *words; /* Pointer to secure memory */ size_t n_words; /* Amount of secure memory in words */ size_t requested; /* Amount actually requested by app, in bytes, 0 if unused */ const char *tag; /* Tag which describes the allocation */ struct _Cell *next; /* Next in memory ring */ struct _Cell *prev; /* Previous in memory ring */ } Cell; /* * A block of secure memory. This structure is the header in that block. */ typedef struct _Block { word_t *words; /* Actual memory hangs off here */ size_t n_words; /* Number of words in block */ size_t n_used; /* Number of used allocations */ struct _Cell* used_cells; /* Ring of used allocations */ struct _Cell* unused_cells; /* Ring of unused allocations */ struct _Block *next; /* Next block in list */ } Block; /* ----------------------------------------------------------------------------- * UNUSED STACK */ static inline void unused_push (void **stack, void *ptr) { g_assert (ptr); g_assert (stack); *((void**)ptr) = *stack; *stack = ptr; } static inline void* unused_pop (void **stack) { void *ptr; g_assert (stack); ptr = *stack; *stack = *(void**)ptr; return ptr; } static inline void* unused_peek (void **stack) { g_assert (stack); return *stack; } /* ----------------------------------------------------------------------------- * POOL META DATA ALLOCATION * * A pool for memory meta data. We allocate fixed size blocks. There are actually * two different structures stored in this pool: Cell and Block. Cell is allocated * way more often, and is bigger so we just allocate that size for both. */ /* Pool allocates this data type */ typedef union _Item { Cell cell; Block block; } Item; typedef struct _Pool { struct _Pool *next; /* Next pool in list */ size_t length; /* Length in bytes of the pool */ size_t used; /* Number of cells used in pool */ void *unused; /* Unused stack of unused stuff */ size_t n_items; /* Total number of items in pool */ Item items[1]; /* Actual items hang off here */ } Pool; static int check_pool_version (void) { if (GTK_SECURE_GLOBALS.pool_version == NULL || strcmp (GTK_SECURE_GLOBALS.pool_version, GTK_SECURE_POOL_VER_STR) != 0) { return 0; } return 1; } static void * pool_alloc (void) { if (!check_pool_version ()) { if (show_warning && gtk_secure_warnings) fprintf (stderr, "the secure memory pool version does not match the code '%s' != '%s'\n", GTK_SECURE_GLOBALS.pool_version ? GTK_SECURE_GLOBALS.pool_version : "(null)", GTK_SECURE_POOL_VER_STR); show_warning = 0; return NULL; } #ifdef HAVE_MMAP /* A pool with an available item */ Pool *pool = NULL; for (pool = GTK_SECURE_GLOBALS.pool_data; pool != NULL; pool = pool->next) { if (unused_peek (&pool->unused)) break; } void *item = NULL; /* Create a new pool */ if (pool == NULL) { size_t len = getpagesize () * 2; void *pages = mmap (0, len, PROT_READ | PROT_WRITE, MAP_PRIVATE | MAP_ANON, -1, 0); if (pages == MAP_FAILED) return NULL; /* Fill in the block header, and inlude in block list */ pool = pages; pool->next = GTK_SECURE_GLOBALS.pool_data; GTK_SECURE_GLOBALS.pool_data = pool; pool->length = len; pool->used = 0; pool->unused = NULL; /* Fill block with unused items */ pool->n_items = (len - sizeof (Pool)) / sizeof (Item); for (size_t i = 0; i < pool->n_items; ++i) unused_push (&pool->unused, pool->items + i); #ifdef WITH_VALGRIND VALGRIND_CREATE_MEMPOOL(pool, 0, 0); #endif } ++pool->used; g_assert (unused_peek (&pool->unused)); item = unused_pop (&pool->unused); #ifdef WITH_VALGRIND VALGRIND_MEMPOOL_ALLOC (pool, item, sizeof (Item)); #endif return memset (item, 0, sizeof (Item)); #else /* HAVE_MMAP */ return NULL; #endif } static void pool_free (void* item) { #ifdef HAVE_MMAP Pool *pool, **at; char *ptr, *beg, *end; ptr = item; /* Find which block this one belongs to */ for (at = (Pool **)>K_SECURE_GLOBALS.pool_data, pool = *at; pool != NULL; at = &pool->next, pool = *at) { beg = (char*)pool->items; end = (char*)pool + pool->length - sizeof (Item); if (ptr >= beg && ptr <= end) { g_assert ((ptr - beg) % sizeof (Item) == 0); break; } } /* Otherwise invalid meta */ g_assert (at); g_assert (pool); g_assert (pool->used > 0); /* No more meta cells used in this block, remove from list, destroy */ if (pool->used == 1) { *at = pool->next; #ifdef WITH_VALGRIND VALGRIND_DESTROY_MEMPOOL (pool); #endif munmap (pool, pool->length); return; } #ifdef WITH_VALGRIND VALGRIND_MEMPOOL_FREE (pool, item); VALGRIND_MAKE_MEM_UNDEFINED (item, sizeof (Item)); #endif --pool->used; memset (item, 0xCD, sizeof (Item)); unused_push (&pool->unused, item); #endif /* HAVE_MMAP */ } #ifndef G_DISABLE_ASSERT static int pool_valid (void* item) { Pool *pool; char *ptr, *beg, *end; ptr = item; /* Find which block this one belongs to */ for (pool = GTK_SECURE_GLOBALS.pool_data; pool; pool = pool->next) { beg = (char*)pool->items; end = (char*)pool + pool->length - sizeof (Item); if (ptr >= beg && ptr <= end) return (pool->used && (ptr - beg) % sizeof (Item) == 0); } return 0; } #endif /* G_DISABLE_g_assert */ /* ----------------------------------------------------------------------------- * SEC ALLOCATION * * Each memory cell begins and ends with a pointer to its metadata. These are also * used as guards or red zones. Since they're treated as redzones by valgrind we * have to jump through a few hoops before reading and/or writing them. */ static inline size_t sec_size_to_words (size_t length) { return (length % sizeof (void*) ? 1 : 0) + (length / sizeof (void*)); } static inline void sec_write_guards (Cell *cell) { #ifdef WITH_VALGRIND VALGRIND_MAKE_MEM_UNDEFINED (cell->words, sizeof (word_t)); VALGRIND_MAKE_MEM_UNDEFINED (cell->words + cell->n_words - 1, sizeof (word_t)); #endif ((void**)cell->words)[0] = (void*)cell; ((void**)cell->words)[cell->n_words - 1] = (void*)cell; #ifdef WITH_VALGRIND VALGRIND_MAKE_MEM_NOACCESS (cell->words, sizeof (word_t)); VALGRIND_MAKE_MEM_NOACCESS (cell->words + cell->n_words - 1, sizeof (word_t)); #endif } static inline void sec_check_guards (Cell *cell) { #ifdef WITH_VALGRIND VALGRIND_MAKE_MEM_DEFINED (cell->words, sizeof (word_t)); VALGRIND_MAKE_MEM_DEFINED (cell->words + cell->n_words - 1, sizeof (word_t)); #endif g_assert(((void**)cell->words)[0] == (void*)cell); g_assert(((void**)cell->words)[cell->n_words - 1] == (void*)cell); #ifdef WITH_VALGRIND VALGRIND_MAKE_MEM_NOACCESS (cell->words, sizeof (word_t)); VALGRIND_MAKE_MEM_NOACCESS (cell->words + cell->n_words - 1, sizeof (word_t)); #endif } static void sec_insert_cell_ring (Cell **ring, Cell *cell) { g_assert (ring); g_assert (cell); g_assert (cell != *ring); g_assert (cell->next == NULL); g_assert (cell->prev == NULL); /* Insert back into the mix of available memory */ if (*ring) { cell->next = (*ring)->next; cell->prev = *ring; cell->next->prev = cell; cell->prev->next = cell; } else { cell->next = cell; cell->prev = cell; } *ring = cell; g_assert (cell->next->prev == cell); g_assert (cell->prev->next == cell); } static void sec_remove_cell_ring (Cell **ring, Cell *cell) { g_assert (ring); g_assert (*ring); g_assert (cell->next); g_assert (cell->prev); g_assert (cell->next->prev == cell); g_assert (cell->prev->next == cell); if (cell == *ring) { /* The last meta? */ if (cell->next == cell) { g_assert (cell->prev == cell); *ring = NULL; /* Just pointing to this meta */ } else { g_assert (cell->prev != cell); *ring = cell->next; } } cell->next->prev = cell->prev; cell->prev->next = cell->next; cell->next = cell->prev = NULL; g_assert (*ring != cell); } static inline void* sec_cell_to_memory (Cell *cell) { return cell->words + 1; } static inline int sec_is_valid_word (Block *block, word_t *word) { return (word >= block->words && word < block->words + block->n_words); } static inline void sec_clear_undefined (void *memory, size_t from, size_t to) { char *ptr = memory; g_assert (from <= to); #ifdef WITH_VALGRIND VALGRIND_MAKE_MEM_UNDEFINED (ptr + from, to - from); #endif memset (ptr + from, 0, to - from); #ifdef WITH_VALGRIND VALGRIND_MAKE_MEM_UNDEFINED (ptr + from, to - from); #endif } static inline void sec_clear_noaccess (void *memory, size_t from, size_t to) { char *ptr = memory; g_assert (from <= to); #ifdef WITH_VALGRIND VALGRIND_MAKE_MEM_UNDEFINED (ptr + from, to - from); #endif memset (ptr + from, 0, to - from); #ifdef WITH_VALGRIND VALGRIND_MAKE_MEM_NOACCESS (ptr + from, to - from); #endif } static Cell* sec_neighbor_before (Block *block, Cell *cell) { word_t *word; g_assert (cell); g_assert (block); word = cell->words - 1; if (!sec_is_valid_word (block, word)) return NULL; #ifdef WITH_VALGRIND VALGRIND_MAKE_MEM_DEFINED (word, sizeof (word_t)); #endif cell = *word; sec_check_guards (cell); #ifdef WITH_VALGRIND VALGRIND_MAKE_MEM_NOACCESS (word, sizeof (word_t)); #endif return cell; } static Cell* sec_neighbor_after (Block *block, Cell *cell) { word_t *word; g_assert (cell); g_assert (block); word = cell->words + cell->n_words; if (!sec_is_valid_word (block, word)) return NULL; #ifdef WITH_VALGRIND VALGRIND_MAKE_MEM_DEFINED (word, sizeof (word_t)); #endif cell = *word; sec_check_guards (cell); #ifdef WITH_VALGRIND VALGRIND_MAKE_MEM_NOACCESS (word, sizeof (word_t)); #endif return cell; } static void* sec_alloc (Block *block, const char *tag, size_t length) { Cell *cell, *other; size_t n_words; void *memory; g_assert (block); g_assert (length); g_assert (tag); if (!block->unused_cells) return NULL; /* * Each memory allocation is aligned to a pointer size, and * then, sandwidched between two pointers to its meta data. * These pointers also act as guards. * * We allocate memory in units of sizeof (void*) */ n_words = sec_size_to_words (length) + 2; /* Look for a cell of at least our required size */ cell = block->unused_cells; while (cell->n_words < n_words) { cell = cell->next; if (cell == block->unused_cells) { cell = NULL; break; } } if (!cell) return NULL; g_assert (cell->tag == NULL); g_assert (cell->requested == 0); g_assert (cell->prev); g_assert (cell->words); sec_check_guards (cell); /* Steal from the cell if it's too long */ if (cell->n_words > n_words + WASTE) { other = pool_alloc (); if (!other) return NULL; other->n_words = n_words; other->words = cell->words; cell->n_words -= n_words; cell->words += n_words; sec_write_guards (other); sec_write_guards (cell); cell = other; } if (cell->next) sec_remove_cell_ring (&block->unused_cells, cell); ++block->n_used; cell->tag = tag; cell->requested = length; sec_insert_cell_ring (&block->used_cells, cell); memory = sec_cell_to_memory (cell); #ifdef WITH_VALGRIND VALGRIND_MAKE_MEM_UNDEFINED (memory, length); #endif return memset (memory, 0, length); } static void* sec_free (Block *block, void *memory) { Cell *cell, *other; word_t *word; g_assert (block); g_assert (memory); word = memory; --word; #ifdef WITH_VALGRIND VALGRIND_MAKE_MEM_DEFINED (word, sizeof (word_t)); #endif /* Lookup the meta for this memory block (using guard pointer) */ g_assert (sec_is_valid_word (block, word)); g_assert (pool_valid (*word)); cell = *word; #ifdef WITH_VALGRIND VALGRIND_MAKE_MEM_DEFINED (cell->words, cell->n_words * sizeof (word_t)); #endif sec_check_guards (cell); sec_clear_noaccess (memory, 0, cell->requested); sec_check_guards (cell); g_assert (cell->requested > 0); g_assert (cell->tag != NULL); /* Remove from the used cell ring */ sec_remove_cell_ring (&block->used_cells, cell); /* Find previous unallocated neighbor, and merge if possible */ other = sec_neighbor_before (block, cell); if (other && other->requested == 0) { g_assert (other->tag == NULL); g_assert (other->next && other->prev); other->n_words += cell->n_words; sec_write_guards (other); pool_free (cell); cell = other; } /* Find next unallocated neighbor, and merge if possible */ other = sec_neighbor_after (block, cell); if (other && other->requested == 0) { g_assert (other->tag == NULL); g_assert (other->next && other->prev); other->n_words += cell->n_words; other->words = cell->words; if (cell->next) sec_remove_cell_ring (&block->unused_cells, cell); sec_write_guards (other); pool_free (cell); cell = other; } /* Add to the unused list if not already there */ if (!cell->next) sec_insert_cell_ring (&block->unused_cells, cell); cell->tag = NULL; cell->requested = 0; --block->n_used; return NULL; } static void memcpy_with_vbits (void *dest, void *src, size_t length) { #ifdef WITH_VALGRIND int vbits_setup = 0; void *vbits = NULL; if (RUNNING_ON_VALGRIND) { vbits = malloc (length); if (vbits != NULL) vbits_setup = VALGRIND_GET_VBITS (src, vbits, length); VALGRIND_MAKE_MEM_DEFINED (src, length); } #endif memcpy (dest, src, length); #ifdef WITH_VALGRIND if (vbits_setup == 1) { VALGRIND_SET_VBITS (dest, vbits, length); VALGRIND_SET_VBITS (src, vbits, length); } free (vbits); #endif } static void* sec_realloc (Block *block, const char *tag, void *memory, size_t length) { Cell *cell, *other; word_t *word; size_t n_words; size_t valid; void *alloc; /* Standard realloc behavior, should have been handled elsewhere */ g_assert (memory != NULL); g_assert (length > 0); g_assert (tag != NULL); /* Dig out where the meta should be */ word = memory; --word; #ifdef WITH_VALGRIND VALGRIND_MAKE_MEM_DEFINED (word, sizeof (word_t)); #endif g_assert (sec_is_valid_word (block, word)); g_assert (pool_valid (*word)); cell = *word; /* Validate that it's actually for real */ sec_check_guards (cell); g_assert (cell->requested > 0); g_assert (cell->tag != NULL); /* The amount of valid data */ valid = cell->requested; /* How many words we actually want */ n_words = sec_size_to_words (length) + 2; /* Less memory is required than is in the cell */ if (n_words <= cell->n_words) { /* TODO: No shrinking behavior yet */ cell->requested = length; alloc = sec_cell_to_memory (cell); /* * Even though we may be reusing the same cell, that doesn't * mean that the allocation is shrinking. It could have shrunk * and is now expanding back some. */ if (length < valid) sec_clear_undefined (alloc, length, valid); return alloc; } /* Need braaaaaiiiiiinsss... */ while (cell->n_words < n_words) { /* See if we have a neighbor who can give us some memory */ other = sec_neighbor_after (block, cell); if (!other || other->requested != 0) break; /* Eat the whole neighbor if not too big */ if (n_words - cell->n_words + WASTE >= other->n_words) { cell->n_words += other->n_words; sec_write_guards (cell); sec_remove_cell_ring (&block->unused_cells, other); pool_free (other); /* Steal from the neighbor */ } else { other->words += n_words - cell->n_words; other->n_words -= n_words - cell->n_words; sec_write_guards (other); cell->n_words = n_words; sec_write_guards (cell); } } if (cell->n_words >= n_words) { cell->requested = length; cell->tag = tag; alloc = sec_cell_to_memory (cell); sec_clear_undefined (alloc, valid, length); return alloc; } /* That didn't work, try alloc/free */ alloc = sec_alloc (block, tag, length); if (alloc) { memcpy_with_vbits (alloc, memory, valid); sec_free (block, memory); } return alloc; } static size_t sec_allocated (Block *block, void *memory) { Cell *cell; word_t *word; g_assert (block); g_assert (memory); word = memory; --word; #ifdef WITH_VALGRIND VALGRIND_MAKE_MEM_DEFINED (word, sizeof (word_t)); #endif /* Lookup the meta for this memory block (using guard pointer) */ g_assert (sec_is_valid_word (block, word)); g_assert (pool_valid (*word)); cell = *word; sec_check_guards (cell); g_assert (cell->requested > 0); g_assert (cell->tag != NULL); #ifdef WITH_VALGRIND VALGRIND_MAKE_MEM_NOACCESS (word, sizeof (word_t)); #endif return cell->requested; } static void sec_validate (Block *block) { Cell *cell; word_t *word, *last; #ifdef WITH_VALGRIND if (RUNNING_ON_VALGRIND) return; #endif word = block->words; last = word + block->n_words; for (;;) { g_assert (word < last); g_assert (sec_is_valid_word (block, word)); g_assert (pool_valid (*word)); cell = *word; /* Validate that it's actually for real */ sec_check_guards (cell); /* Is it an allocated block? */ if (cell->requested > 0) { g_assert (cell->tag != NULL); g_assert (cell->next != NULL); g_assert (cell->prev != NULL); g_assert (cell->next->prev == cell); g_assert (cell->prev->next == cell); g_assert (cell->requested <= (cell->n_words - 2) * sizeof (word_t)); /* An unused block */ } else { g_assert (cell->tag == NULL); g_assert (cell->next != NULL); g_assert (cell->prev != NULL); g_assert (cell->next->prev == cell); g_assert (cell->prev->next == cell); } word += cell->n_words; if (word == last) break; } } /* ----------------------------------------------------------------------------- * LOCKED MEMORY */ static void* sec_acquire_pages (size_t *sz, const char *during_tag) { g_assert (sz); g_assert (*sz); g_assert (during_tag); #if defined(HAVE_MLOCK) && defined(HAVE_MMAP) /* Make sure sz is a multiple of the page size */ unsigned long pgsize = getpagesize (); *sz = (*sz + pgsize -1) & ~(pgsize - 1); void *pages = mmap (0, *sz, PROT_READ | PROT_WRITE, MAP_PRIVATE | MAP_ANON, -1, 0); if (pages == MAP_FAILED) { if (show_warning && gtk_secure_warnings) fprintf (stderr, "couldn't map %lu bytes of memory (%s): %s\n", (unsigned long)*sz, during_tag, strerror (errno)); show_warning = 0; return NULL; } if (mlock (pages, *sz) < 0) { if (show_warning && gtk_secure_warnings && errno != EPERM) { fprintf (stderr, "couldn't lock %lu bytes of memory (%s): %s\n", (unsigned long)*sz, during_tag, strerror (errno)); show_warning = 0; } munmap (pages, *sz); return NULL; } DEBUG_ALLOC ("gtk-secure-memory: new block ", *sz); show_warning = 1; return pages; #elif defined G_OS_WIN32 /* Make sure sz is a multiple of CRYPTPROTECTMEMORY_BLOCK_SIZE in wincrypt.h */ *sz = (*sz + CRYPTPROTECTMEMORY_BLOCK_SIZE - 1) & ~(CRYPTPROTECTMEMORY_BLOCK_SIZE - 1); void *data = (void *) LocalAlloc (LPTR, *sz); if (data == NULL) { if (show_warning && gtk_secure_warnings) fprintf (stderr, "couldn't allocate %lu bytes of memory (%s): %#010lX\n", (unsigned long)*sz, during_tag, GetLastError ()); show_warning = 0; return NULL; } if (!CryptProtectMemory (data, *sz, CRYPTPROTECTMEMORY_SAME_PROCESS)) { if (show_warning && gtk_secure_warnings) fprintf (stderr, "couldn't encrypt %lu bytes of memory (%s): %#010lX\n", (unsigned long)*sz, during_tag, GetLastError ()); show_warning = 0; return NULL; } DEBUG_ALLOC ("gtk-secure-memory: new block ", *sz); show_warning = 1; return data; #else if (show_warning && gtk_secure_warnings) fprintf (stderr, "your system does not support private memory"); show_warning = 0; return NULL; #endif } static void sec_release_pages (void *pages, size_t sz) { g_assert (pages); #if defined(HAVE_MLOCK) g_assert (sz % getpagesize () == 0); if (munlock (pages, sz) < 0 && gtk_secure_warnings) fprintf (stderr, "couldn't unlock private memory: %s\n", strerror (errno)); if (munmap (pages, sz) < 0 && gtk_secure_warnings) fprintf (stderr, "couldn't unmap private anonymous memory: %s\n", strerror (errno)); DEBUG_ALLOC ("gtk-secure-memory: freed block ", sz); #elif defined G_OS_WIN32 g_assert (sz % CRYPTPROTECTMEMORY_BLOCK_SIZE == 0); if (!CryptUnprotectMemory (pages, sz, CRYPTPROTECTMEMORY_SAME_PROCESS)) fprintf (stderr, "couldn't decrypt private memory: %#010lX\n", GetLastError ()); if (LocalFree (pages) != NULL) fprintf (stderr, "couldn't free private anonymous memory: %#010lX\n", GetLastError ()); DEBUG_ALLOC ("gtk-secure-memory: freed block ", sz); #else g_assert (FALSE); #endif } /* ----------------------------------------------------------------------------- * MANAGE DIFFERENT BLOCKS */ static Block *all_blocks = NULL; static Block* sec_block_create (size_t size, const char *during_tag) { Block *block; Cell *cell; g_assert (during_tag); /* We can force all all memory to be malloced */ if (getenv ("SECMEM_FORCE_FALLBACK")) return NULL; block = pool_alloc (); if (!block) return NULL; cell = pool_alloc (); if (!cell) { pool_free (block); return NULL; } /* The size above is a minimum, we're free to go bigger */ if (size < DEFAULT_BLOCK_SIZE) size = DEFAULT_BLOCK_SIZE; block->words = sec_acquire_pages (&size, during_tag); block->n_words = size / sizeof (word_t); if (!block->words) { pool_free (block); pool_free (cell); return NULL; } #ifdef WITH_VALGRIND VALGRIND_MAKE_MEM_DEFINED (block->words, size); #endif /* The first cell to allocate from */ cell->words = block->words; cell->n_words = block->n_words; cell->requested = 0; sec_write_guards (cell); sec_insert_cell_ring (&block->unused_cells, cell); block->next = all_blocks; all_blocks = block; return block; } static void sec_block_destroy (Block *block) { Block *bl, **at; Cell *cell; g_assert (block); g_assert (block->words); g_assert (block->n_used == 0); /* Remove from the list */ for (at = &all_blocks, bl = *at; bl; at = &bl->next, bl = *at) { if (bl == block) { *at = block->next; break; } } /* Must have been found */ g_assert (bl == block); g_assert (block->used_cells == NULL); /* Release all the meta data cells */ while (block->unused_cells) { cell = block->unused_cells; sec_remove_cell_ring (&block->unused_cells, cell); pool_free (cell); } /* Release all pages of secure memory */ sec_release_pages (block->words, block->n_words * sizeof (word_t)); pool_free (block); } /* ------------------------------------------------------------------------ * PUBLIC FUNCTIONALITY */ void* gtk_secure_alloc_full (const char *tag, size_t length, int flags) { Block *block; void *memory = NULL; if (tag == NULL) tag = "?"; if (length > 0xFFFFFFFF / 2) { if (gtk_secure_warnings) fprintf (stderr, "tried to allocate an insane amount of memory: %lu\n", (unsigned long)length); return NULL; } /* Can't allocate zero bytes */ if (length == 0) return NULL; DO_LOCK (); for (block = all_blocks; block; block = block->next) { memory = sec_alloc (block, tag, length); if (memory) break; } /* None of the current blocks have space, allocate new */ if (!memory) { block = sec_block_create (length, tag); if (block) memory = sec_alloc (block, tag, length); } #ifdef WITH_VALGRIND if (memory != NULL) VALGRIND_MALLOCLIKE_BLOCK (memory, length, sizeof (void*), 1); #endif DO_UNLOCK (); if (!memory && (flags & GTK_SECURE_USE_FALLBACK) && GTK_SECURE_GLOBALS.fallback_alloc != NULL) { memory = GTK_SECURE_GLOBALS.fallback_alloc (NULL, length); if (memory) /* Our returned memory is always zeroed */ memset (memory, 0, length); } if (!memory) errno = ENOMEM; return memory; } void* gtk_secure_realloc_full (const char *tag, void *memory, size_t length, int flags) { Block *block = NULL; size_t previous = 0; int donew = 0; void *alloc = NULL; if (tag == NULL) tag = "?"; if (length > 0xFFFFFFFF / 2) { if (gtk_secure_warnings) fprintf (stderr, "tried to allocate an excessive amount of memory: %lu\n", (unsigned long)length); return NULL; } if (memory == NULL) return gtk_secure_alloc_full (tag, length, flags); if (!length) { gtk_secure_free_full (memory, flags); return NULL; } DO_LOCK (); /* Find out where it belongs to */ for (block = all_blocks; block; block = block->next) { if (sec_is_valid_word (block, memory)) { previous = sec_allocated (block, memory); #ifdef WITH_VALGRIND /* Let valgrind think we are unallocating so that it'll validate */ VALGRIND_FREELIKE_BLOCK (memory, sizeof (word_t)); #endif alloc = sec_realloc (block, tag, memory, length); #ifdef WITH_VALGRIND /* Now tell valgrind about either the new block or old one */ VALGRIND_MALLOCLIKE_BLOCK (alloc ? alloc : memory, alloc ? length : previous, sizeof (word_t), 1); #endif break; } } /* If it didn't work we may need to allocate a new block */ if (block && !alloc) donew = 1; if (block && block->n_used == 0) sec_block_destroy (block); DO_UNLOCK (); if (!block) { if ((flags & GTK_SECURE_USE_FALLBACK) && GTK_SECURE_GLOBALS.fallback_alloc) { /* * In this case we can't zero the returned memory, * because we don't know what the block size was. */ return GTK_SECURE_GLOBALS.fallback_alloc (memory, length); } else { if (gtk_secure_warnings) fprintf (stderr, "memory does not belong to secure memory pool: 0x%08" G_GUINTPTR_FORMAT "x\n", (guintptr) memory); g_assert (0 && "memory does does not belong to secure memory pool"); return NULL; } } if (donew) { alloc = gtk_secure_alloc_full (tag, length, flags); if (alloc) { memcpy_with_vbits (alloc, memory, previous); gtk_secure_free_full (memory, flags); } } if (!alloc) errno = ENOMEM; return alloc; } void gtk_secure_free (void *memory) { gtk_secure_free_full (memory, GTK_SECURE_USE_FALLBACK); } void gtk_secure_free_full (void *memory, int flags) { Block *block = NULL; if (memory == NULL) return; DO_LOCK (); /* Find out where it belongs to */ for (block = all_blocks; block; block = block->next) { if (sec_is_valid_word (block, memory)) break; } #ifdef WITH_VALGRIND /* We like valgrind's warnings, so give it a first whack at checking for errors */ if (block != NULL || !(flags & GTK_SECURE_USE_FALLBACK)) VALGRIND_FREELIKE_BLOCK (memory, sizeof (word_t)); #endif if (block != NULL) { sec_free (block, memory); if (block->n_used == 0) sec_block_destroy (block); } DO_UNLOCK (); if (!block) { if ((flags & GTK_SECURE_USE_FALLBACK) && GTK_SECURE_GLOBALS.fallback_free) { GTK_SECURE_GLOBALS.fallback_free (memory); } else { if (gtk_secure_warnings) fprintf (stderr, "memory does not belong to secure memory pool: 0x%08" G_GUINTPTR_FORMAT "x\n", (guintptr) memory); g_assert (0 && "memory does does not belong to secure memory pool"); } } } int gtk_secure_check (const void *memory) { Block *block = NULL; DO_LOCK (); /* Find out where it belongs to */ for (block = all_blocks; block; block = block->next) { if (sec_is_valid_word (block, (word_t*)memory)) break; } DO_UNLOCK (); return block == NULL ? 0 : 1; } void gtk_secure_validate (void) { Block *block = NULL; DO_LOCK (); for (block = all_blocks; block; block = block->next) sec_validate (block); DO_UNLOCK (); } static gtk_secure_rec * records_for_ring (Cell *cell_ring, gtk_secure_rec *records, unsigned int *count, unsigned int *total) { gtk_secure_rec *new_rec; unsigned int allocated = *count; Cell *cell; cell = cell_ring; do { if (*count >= allocated) { new_rec = realloc (records, sizeof (gtk_secure_rec) * (allocated + 32)); if (new_rec == NULL) { *count = 0; free (records); return NULL; } else { records = new_rec; allocated += 32; } } if (cell != NULL) { records[*count].request_length = cell->requested; records[*count].block_length = cell->n_words * sizeof (word_t); records[*count].tag = cell->tag; (*count)++; (*total) += cell->n_words; cell = cell->next; } } while (cell != NULL && cell != cell_ring); return records; } gtk_secure_rec * gtk_secure_records (unsigned int *count) { gtk_secure_rec *records = NULL; Block *block = NULL; unsigned int total; *count = 0; DO_LOCK (); for (block = all_blocks; block != NULL; block = block->next) { total = 0; records = records_for_ring (block->unused_cells, records, count, &total); if (records == NULL) break; records = records_for_ring (block->used_cells, records, count, &total); if (records == NULL) break; /* Make sure this actualy accounts for all memory */ g_assert (total == block->n_words); } DO_UNLOCK (); return records; } char* gtk_secure_strdup_full (const char *tag, const char *str, int options) { size_t len; char *res; if (!str) return NULL; len = strlen (str) + 1; res = (char *)gtk_secure_alloc_full (tag, len, options); strcpy (res, str); return res; } char * gtk_secure_strndup_full (const char *tag, const char *str, size_t length, int options) { size_t len; char *res; const char *end; if (!str) return NULL; end = memchr (str, '\0', length); if (end != NULL) length = (end - str); len = length + 1; res = (char *)gtk_secure_alloc_full (tag, len, options); memcpy (res, str, len); return res; } void gtk_secure_clear (void *p, size_t length) { volatile char *vp; if (p == NULL) return; vp = (volatile char*)p; while (length) { *vp = 0xAA; vp++; length--; } } void gtk_secure_strclear (char *str) { if (!str) return; gtk_secure_clear ((unsigned char*)str, strlen (str)); } void gtk_secure_strfree (char *str) { /* * If we're using unpageable 'secure' memory, then the free call * should zero out the memory, but because on certain platforms * we may be using normal memory, zero it out here just in case. */ gtk_secure_strclear (str); gtk_secure_free_full (str, GTK_SECURE_USE_FALLBACK); }