/* * 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 warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. */ #include #include #include #include #include #include #include #include #include #include /* * We need special handling on x86 where CAR global migration is employed. One * cannot use true globals in that circumstance because CAR is where the globals * are backed -- creating a circular dependency. For non CAR platforms globals * are free to be used as well as any stages that are purely executing out of * RAM. For CAR platforms that don't migrate globals the as-linked globals can * be used, but they need special decoration using CAR_GLOBAL. That ensures * proper object placement in conjunction with the linker. * * For the CAR global migration platforms we have to always try to partially * recover CBMEM from cbmem_top() whenever we try to access it. In other * environments we're not so constrained and just keep the backing imd struct * in a global. This also means that we can easily tell whether CBMEM has * explicitly been initialized or recovered yet on those platforms, and don't * need to put the burden on board or chipset code to tell us by returning * NULL from cbmem_top() before that point. */ #define CAN_USE_GLOBALS \ (!IS_ENABLED(CONFIG_ARCH_X86) || ENV_RAMSTAGE || ENV_POSTCAR || \ IS_ENABLED(CONFIG_NO_CAR_GLOBAL_MIGRATION)) static inline struct imd *cbmem_get_imd(void) { if (CAN_USE_GLOBALS) { static struct imd imd_cbmem CAR_GLOBAL; return &imd_cbmem; } return NULL; } static inline const struct cbmem_entry *imd_to_cbmem(const struct imd_entry *e) { return (const struct cbmem_entry *)e; } static inline const struct imd_entry *cbmem_to_imd(const struct cbmem_entry *e) { return (const struct imd_entry *)e; } /* These are the different situations to handle: * CONFIG_EARLY_CBMEM_INIT: * In ramstage cbmem_initialize() attempts a recovery of the * cbmem region set up by romstage. It uses cbmem_top() as the * starting point of recovery. * * In romstage, similar to ramstage, cbmem_initialize() needs to * attempt recovery of the cbmem area using cbmem_top() as the limit. * cbmem_initialize_empty() initializes an empty cbmem area from * cbmem_top(); * */ static struct imd *imd_init_backing(struct imd *backing) { struct imd *imd; imd = cbmem_get_imd(); if (imd != NULL) return imd; imd = backing; return imd; } static struct imd *imd_init_backing_with_recover(struct imd *backing) { struct imd *imd; imd = imd_init_backing(backing); if (!CAN_USE_GLOBALS) { /* Always partially recover if we can't keep track of whether * we have already initialized CBMEM in this stage. */ imd_handle_init(imd, cbmem_top()); imd_handle_init_partial_recovery(imd); } return imd; } void cbmem_initialize_empty(void) { cbmem_initialize_empty_id_size(0, 0); } void __weak cbmem_top_init(void) { } static void cbmem_top_init_once(void) { /* Call one-time hook on expected cbmem init during boot. This sequence assumes first init call is in romstage for early cbmem init and ramstage for late cbmem init. */ if (IS_ENABLED(CONFIG_EARLY_CBMEM_INIT) && !ENV_ROMSTAGE) return; if (IS_ENABLED(CONFIG_LATE_CBMEM_INIT) && !ENV_RAMSTAGE) return; cbmem_top_init(); } void cbmem_initialize_empty_id_size(u32 id, u64 size) { struct imd *imd; struct imd imd_backing; const int no_recovery = 0; cbmem_top_init_once(); imd = imd_init_backing(&imd_backing); imd_handle_init(imd, cbmem_top()); printk(BIOS_DEBUG, "CBMEM:\n"); if (imd_create_tiered_empty(imd, CBMEM_ROOT_MIN_SIZE, CBMEM_LG_ALIGN, CBMEM_SM_ROOT_SIZE, CBMEM_SM_ALIGN)) { printk(BIOS_DEBUG, "failed.\n"); return; } /* Add the specified range first */ if (size) cbmem_add(id, size); /* Complete migration to CBMEM. */ cbmem_run_init_hooks(no_recovery); } int cbmem_initialize(void) { return cbmem_initialize_id_size(0, 0); } int cbmem_initialize_id_size(u32 id, u64 size) { struct imd *imd; struct imd imd_backing; const int recovery = 1; cbmem_top_init_once(); imd = imd_init_backing(&imd_backing); imd_handle_init(imd, cbmem_top()); if (imd_recover(imd)) return 1; #if defined(__PRE_RAM__) /* * Lock the imd in romstage on a recovery. The assumption is that * if the imd area was recovered in romstage then S3 resume path * is being taken. */ imd_lockdown(imd); #endif /* Add the specified range first */ if (size) cbmem_add(id, size); /* Complete migration to CBMEM. */ cbmem_run_init_hooks(recovery); /* 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; } const struct cbmem_entry *cbmem_entry_add(u32 id, u64 size64) { struct imd *imd; struct imd imd_backing; const struct imd_entry *e; imd = imd_init_backing_with_recover(&imd_backing); e = imd_entry_find_or_add(imd, id, size64); return imd_to_cbmem(e); } void *cbmem_add(u32 id, u64 size) { struct imd *imd; struct imd imd_backing; const struct imd_entry *e; imd = imd_init_backing_with_recover(&imd_backing); e = imd_entry_find_or_add(imd, id, size); if (e == NULL) return NULL; return imd_entry_at(imd, e); } /* Retrieve a region provided a given id. */ const struct cbmem_entry *cbmem_entry_find(u32 id) { struct imd *imd; struct imd imd_backing; const struct imd_entry *e; imd = imd_init_backing_with_recover(&imd_backing); e = imd_entry_find(imd, id); return imd_to_cbmem(e); } void *cbmem_find(u32 id) { struct imd *imd; struct imd imd_backing; const struct imd_entry *e; imd = imd_init_backing_with_recover(&imd_backing); e = imd_entry_find(imd, id); if (e == NULL) return NULL; return imd_entry_at(imd, e); } /* 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) { struct imd *imd; struct imd imd_backing; imd = imd_init_backing_with_recover(&imd_backing); return imd_entry_remove(imd, cbmem_to_imd(entry)); } u64 cbmem_entry_size(const struct cbmem_entry *entry) { struct imd *imd; struct imd imd_backing; imd = imd_init_backing_with_recover(&imd_backing); return imd_entry_size(imd, cbmem_to_imd(entry)); } void *cbmem_entry_start(const struct cbmem_entry *entry) { struct imd *imd; struct imd imd_backing; imd = imd_init_backing_with_recover(&imd_backing); return imd_entry_at(imd, cbmem_to_imd(entry)); } void cbmem_add_bootmem(void) { void *baseptr = NULL; size_t size = 0; cbmem_get_region(&baseptr, &size); bootmem_add_range((uintptr_t)baseptr, size, BM_MEM_TABLE); } void cbmem_get_region(void **baseptr, size_t *size) { imd_region_used(cbmem_get_imd(), baseptr, size); } #if ENV_RAMSTAGE || (IS_ENABLED(CONFIG_EARLY_CBMEM_LIST) \ && (ENV_POSTCAR || ENV_ROMSTAGE)) /* * -fdata-sections doesn't work so well on read only strings. They all * get put in the same section even though those strings may never be * referenced in the final binary. */ void cbmem_list(void) { static const struct imd_lookup lookup[] = { CBMEM_ID_TO_NAME_TABLE }; struct imd *imd; struct imd imd_backing; imd = imd_init_backing_with_recover(&imd_backing); imd_print_entries(imd, lookup, ARRAY_SIZE(lookup)); } #endif void cbmem_add_records_to_cbtable(struct lb_header *header) { struct imd_cursor cursor; struct imd *imd; imd = cbmem_get_imd(); if (imd_cursor_init(imd, &cursor)) return; while (1) { const struct imd_entry *e; struct lb_cbmem_entry *lbe; uint32_t id; e = imd_cursor_next(&cursor); if (e == NULL) break; id = imd_entry_id(imd, e); /* Don't add these metadata entries. */ if (id == CBMEM_ID_IMD_ROOT || id == CBMEM_ID_IMD_SMALL) continue; lbe = (struct lb_cbmem_entry *)lb_new_record(header); lbe->tag = LB_TAG_CBMEM_ENTRY; lbe->size = sizeof(*lbe); lbe->address = (uintptr_t)imd_entry_at(imd, e); lbe->entry_size = imd_entry_size(imd, e); lbe->id = id; } }