/* * This file is part of the coreboot project. * * Copyright (C) 2013 Google, Inc. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; version 2 of the License. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied wacbmem_entryanty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA */ #include #include #include #include #include #include #include #if CONFIG_HAVE_ACPI_RESUME && !defined(__PRE_RAM__) #include #endif #ifndef UINT_MAX #define UINT_MAX 4294967295U #endif /* * The dynamic cbmem code uses a root region. The root region boundary * addresses are determined by cbmem_top() and ROOT_MIN_SIZE. Just below * the address returned by cbmem_top() is a pointer that points to the * root data structure. The root data structure provides the book keeping * for each large entry. */ /* The root region is at least DYN_CBMEM_ALIGN_SIZE . */ #define ROOT_MIN_SIZE DYN_CBMEM_ALIGN_SIZE #define CBMEM_POINTER_MAGIC 0xc0389479 #define CBMEM_ENTRY_MAGIC ~(CBMEM_POINTER_MAGIC) /* The cbmem_root_pointer structure lives just below address returned * from cbmem_top(). It points to the root data structure that * maintains the entries. */ struct cbmem_root_pointer { u32 magic; u32 root; } __attribute__((packed)); struct cbmem_entry { u32 magic; u32 start; u32 size; u32 id; } __attribute__((packed)); struct cbmem_root { u32 max_entries; u32 num_entries; u32 locked; u32 size; struct cbmem_entry entries[0]; } __attribute__((packed)); static inline void *cbmem_top_cached(void) { #if !defined(__PRE_RAM__) static void *cached_cbmem_top; if (cached_cbmem_top == NULL) cached_cbmem_top = cbmem_top(); return cached_cbmem_top; #else return cbmem_top(); #endif } static inline uintptr_t get_top_aligned(void) { uintptr_t top; /* Align down what is returned from cbmem_top(). */ top = (uintptr_t)cbmem_top_cached(); top &= ~(DYN_CBMEM_ALIGN_SIZE - 1); return top; } static inline void *get_root(void) { uintptr_t pointer_addr; struct cbmem_root_pointer *pointer; pointer_addr = get_top_aligned(); pointer_addr -= sizeof(struct cbmem_root_pointer); pointer = (void *)pointer_addr; if (pointer->magic != CBMEM_POINTER_MAGIC) return NULL; pointer_addr = pointer->root; return (void *)pointer_addr; } static inline void cbmem_entry_assign(struct cbmem_entry *entry, u32 id, u32 start, u32 size) { entry->magic = CBMEM_ENTRY_MAGIC; entry->start = start; entry->size = size; entry->id = id; } static inline const struct cbmem_entry * cbmem_entry_append(struct cbmem_root *root, u32 id, u32 start, u32 size) { struct cbmem_entry *cbmem_entry; cbmem_entry = &root->entries[root->num_entries]; root->num_entries++; cbmem_entry_assign(cbmem_entry, id, start, size); return cbmem_entry; } void cbmem_initialize_empty(void) { uintptr_t pointer_addr; uintptr_t root_addr; unsigned long max_entries; struct cbmem_root *root; struct cbmem_root_pointer *pointer; /* Place the root pointer and the root. The number of entries is * dictated by difference between the root address and the pointer * where the root address is aligned down to * DYN_CBMEM_ALIGN_SIZE. The pointer falls just below the * address returned by get_top_aligned(). */ pointer_addr = get_top_aligned(); root_addr = pointer_addr - ROOT_MIN_SIZE; root_addr &= ~(DYN_CBMEM_ALIGN_SIZE - 1); pointer_addr -= sizeof(struct cbmem_root_pointer); max_entries = (pointer_addr - (root_addr + sizeof(*root))) / sizeof(struct cbmem_entry); pointer = (void *)pointer_addr; pointer->magic = CBMEM_POINTER_MAGIC; pointer->root = root_addr; root = (void *)root_addr; root->max_entries = max_entries; root->num_entries = 0; root->locked = 0; root->size = pointer_addr - root_addr + sizeof(struct cbmem_root_pointer); /* Add an entry covering the root region. */ cbmem_entry_append(root, CBMEM_ID_ROOT, root_addr, root->size); printk(BIOS_DEBUG, "CBMEM: root @ %p %d entries.\n", root, root->max_entries); /* Complete migration to CBMEM. */ cbmem_run_init_hooks(); } static inline int cbmem_fail_recovery(void) { cbmem_initialize_empty(); cbmem_fail_resume(); return 1; } static int validate_entries(struct cbmem_root *root) { unsigned int i; uintptr_t current_end; current_end = get_top_aligned(); printk(BIOS_DEBUG, "CBMEM: recovering %d/%d entries from root @ %p\n", root->num_entries, root->max_entries, root); /* Check that all regions are properly aligned and are just below * the previous entry */ for (i = 0; i < root->num_entries; i++) { struct cbmem_entry *entry = &root->entries[i]; if (entry->magic != CBMEM_ENTRY_MAGIC) return -1; if (entry->start & (DYN_CBMEM_ALIGN_SIZE - 1)) return -1; if (entry->start + entry->size != current_end) return -1; current_end = entry->start; } return 0; } int cbmem_initialize(void) { struct cbmem_root *root; uintptr_t top_according_to_root; root = get_root(); /* No recovery possible since root couldn't be recovered. */ if (root == NULL) return cbmem_fail_recovery(); /* Sanity check the root. */ top_according_to_root = (root->size + (uintptr_t)root); if (get_top_aligned() != top_according_to_root) return cbmem_fail_recovery(); if (root->num_entries > root->max_entries) return cbmem_fail_recovery(); if ((root->max_entries * sizeof(struct cbmem_entry)) > (root->size - sizeof(struct cbmem_root_pointer) - sizeof(*root))) return cbmem_fail_recovery(); /* Validate current entries. */ if (validate_entries(root)) return cbmem_fail_recovery(); #if defined(__PRE_RAM__) /* Lock the root in the romstage on a recovery. The assumption is that * recovery is called during romstage on the S3 resume path. */ root->locked = 1; #endif /* Complete migration to CBMEM. */ cbmem_run_init_hooks(); /* Recovery successful. */ return 0; } int cbmem_recovery(int is_wakeup) { int rv = 0; if (!is_wakeup) cbmem_initialize_empty(); else rv = cbmem_initialize(); return rv; } static uintptr_t cbmem_base(void) { struct cbmem_root *root; uintptr_t low_addr; root = get_root(); if (root == NULL) return 0; low_addr = (uintptr_t)root; /* a low address is low. */ low_addr &= 0xffffffff; /* Assume the lowest address is the last one added. */ if (root->num_entries > 0) { low_addr = root->entries[root->num_entries - 1].start; } return low_addr; } const struct cbmem_entry *cbmem_entry_add(u32 id, u64 size64) { struct cbmem_root *root; const struct cbmem_entry *entry; uintptr_t base; u32 size; u32 aligned_size; entry = cbmem_entry_find(id); if (entry != NULL) return entry; /* Only handle sizes <= UINT_MAX internally. */ if (size64 > (u64)UINT_MAX) return NULL; size = size64; root = get_root(); if (root == NULL) return NULL; /* Nothing can be added once it is locked down. */ if (root->locked) return NULL; if (root->max_entries == root->num_entries) return NULL; aligned_size = ALIGN(size, DYN_CBMEM_ALIGN_SIZE); base = cbmem_base(); base -= aligned_size; return cbmem_entry_append(root, id, base, aligned_size); } void *cbmem_add(u32 id, u64 size) { const struct cbmem_entry *entry; entry = cbmem_entry_add(id, size); if (entry == NULL) return NULL; return cbmem_entry_start(entry); } /* Retrieve a region provided a given id. */ const struct cbmem_entry *cbmem_entry_find(u32 id) { struct cbmem_root *root; const struct cbmem_entry *entry; unsigned int i; root = get_root(); if (root == NULL) return NULL; entry = NULL; for (i = 0; i < root->num_entries; i++) { if (root->entries[i].id == id) { entry = &root->entries[i]; break; } } return entry; } void *cbmem_find(u32 id) { const struct cbmem_entry *entry; entry = cbmem_entry_find(id); if (entry == NULL) return NULL; return cbmem_entry_start(entry); } /* Remove a reserved region. Returns 0 on success, < 0 on error. Note: A region * cannot be removed unless it was the last one added. */ int cbmem_entry_remove(const struct cbmem_entry *entry) { unsigned long entry_num; struct cbmem_root *root; root = get_root(); if (root == NULL) return -1; if (root->num_entries == 0) return -1; /* Nothing can be removed. */ if (root->locked) return -1; entry_num = entry - &root->entries[0]; /* If the entry is the last one in the root it can be removed. */ if (entry_num == (root->num_entries - 1)) { root->num_entries--; return 0; } return -1; } u64 cbmem_entry_size(const struct cbmem_entry *entry) { return entry->size; } void *cbmem_entry_start(const struct cbmem_entry *entry) { uintptr_t addr = entry->start; return (void *)addr; } #if !defined(__PRE_RAM__) /* selected cbmem can be initialized early in ramstage. Additionally, that * means cbmem console can be reinitialized early as well. The post_device * function is empty since cbmem was initialized early in ramstage. */ static void init_cbmem_pre_device(void *unused) { cbmem_initialize(); } BOOT_STATE_INIT_ENTRIES(cbmem_bscb) = { BOOT_STATE_INIT_ENTRY(BS_PRE_DEVICE, BS_ON_ENTRY, init_cbmem_pre_device, NULL), }; void cbmem_add_bootmem(void) { uintptr_t base; uintptr_t top; base = cbmem_base(); top = get_top_aligned(); bootmem_add_range(base, top - base, LB_MEM_TABLE); } void cbmem_list(void) { unsigned int i; struct cbmem_root *root; root = get_root(); if (root == NULL) return; for (i = 0; i < root->num_entries; i++) { struct cbmem_entry *entry; entry = &root->entries[i]; cbmem_print_entry(i, entry->id, entry->start, entry->size); } } #endif /* __PRE_RAM__ */