/* SPDX-License-Identifier: LGPL-2.1-or-later */ #pragma once #include "efi.h" #include "log.h" #include "proto/file-io.h" #include "string-util-fundamental.h" static inline void free(void *p) { if (!p) return; /* Debugging an invalid free requires trace logging to find the call site or a debugger attached. For * release builds it is not worth the bother to even warn when we cannot even print a call stack. */ #ifdef EFI_DEBUG assert_se(BS->FreePool(p) == EFI_SUCCESS); #else (void) BS->FreePool(p); #endif } static inline void freep(void *p) { free(*(void **) p); } #define _cleanup_free_ _cleanup_(freep) _malloc_ _alloc_(1) _returns_nonnull_ _warn_unused_result_ static inline void *xmalloc(size_t size) { void *p; assert_se(BS->AllocatePool(EfiLoaderData, size, &p) == EFI_SUCCESS); return p; } _malloc_ _alloc_(1, 2) _returns_nonnull_ _warn_unused_result_ static inline void *xmalloc_multiply(size_t size, size_t n) { assert_se(!__builtin_mul_overflow(size, n, &size)); return xmalloc(size); } /* Use malloc attribute as this never returns p like userspace realloc. */ _malloc_ _alloc_(3) _returns_nonnull_ _warn_unused_result_ static inline void *xrealloc(void *p, size_t old_size, size_t new_size) { void *t = xmalloc(new_size); new_size = MIN(old_size, new_size); if (new_size > 0) memcpy(t, p, new_size); free(p); return t; } #define xnew(type, n) ((type *) xmalloc_multiply(sizeof(type), (n))) typedef struct { EFI_PHYSICAL_ADDRESS addr; size_t n_pages; } Pages; static inline void cleanup_pages(Pages *p) { if (p->n_pages == 0) return; #ifdef EFI_DEBUG assert_se(BS->FreePages(p->addr, p->n_pages) == EFI_SUCCESS); #else (void) BS->FreePages(p->addr, p->n_pages); #endif } #define _cleanup_pages_ _cleanup_(cleanup_pages) static inline Pages xmalloc_pages( EFI_ALLOCATE_TYPE type, EFI_MEMORY_TYPE memory_type, size_t n_pages, EFI_PHYSICAL_ADDRESS addr) { assert_se(BS->AllocatePages(type, memory_type, n_pages, &addr) == EFI_SUCCESS); return (Pages) { .addr = addr, .n_pages = n_pages, }; } EFI_STATUS parse_boolean(const char *v, bool *b); EFI_STATUS efivar_set(const EFI_GUID *vendor, const char16_t *name, const char16_t *value, uint32_t flags); EFI_STATUS efivar_set_raw(const EFI_GUID *vendor, const char16_t *name, const void *buf, size_t size, uint32_t flags); EFI_STATUS efivar_set_uint_string(const EFI_GUID *vendor, const char16_t *name, size_t i, uint32_t flags); EFI_STATUS efivar_set_uint32_le(const EFI_GUID *vendor, const char16_t *NAME, uint32_t value, uint32_t flags); EFI_STATUS efivar_set_uint64_le(const EFI_GUID *vendor, const char16_t *name, uint64_t value, uint32_t flags); void efivar_set_time_usec(const EFI_GUID *vendor, const char16_t *name, uint64_t usec); EFI_STATUS efivar_get(const EFI_GUID *vendor, const char16_t *name, char16_t **ret); EFI_STATUS efivar_get_raw(const EFI_GUID *vendor, const char16_t *name, char **ret, size_t *ret_size); EFI_STATUS efivar_get_uint_string(const EFI_GUID *vendor, const char16_t *name, size_t *ret); EFI_STATUS efivar_get_uint32_le(const EFI_GUID *vendor, const char16_t *name, uint32_t *ret); EFI_STATUS efivar_get_uint64_le(const EFI_GUID *vendor, const char16_t *name, uint64_t *ret); EFI_STATUS efivar_get_boolean_u8(const EFI_GUID *vendor, const char16_t *name, bool *ret); void convert_efi_path(char16_t *path); char16_t *xstr8_to_path(const char *stra); void mangle_stub_cmdline(char16_t *cmdline); EFI_STATUS file_read(EFI_FILE *dir, const char16_t *name, size_t off, size_t size, char **content, size_t *content_size); static inline void file_closep(EFI_FILE **handle) { if (!*handle) return; (*handle)->Close(*handle); } static inline void unload_imagep(EFI_HANDLE *image) { if (*image) (void) BS->UnloadImage(*image); } /* * Allocated random UUID, intended to be shared across tools that implement * the (ESP)\loader\entries\-.conf convention and the * associated EFI variables. */ #define LOADER_GUID \ { 0x4a67b082, 0x0a4c, 0x41cf, { 0xb6, 0xc7, 0x44, 0x0b, 0x29, 0xbb, 0x8c, 0x4f } } /* Note that GUID is evaluated multiple times! */ #define GUID_FORMAT_STR "%08X-%04X-%04X-%02X%02X-%02X%02X%02X%02X%02X%02X" #define GUID_FORMAT_VAL(g) (g).Data1, (g).Data2, (g).Data3, (g).Data4[0], (g).Data4[1], \ (g).Data4[2], (g).Data4[3], (g).Data4[4], (g).Data4[5], (g).Data4[6], (g).Data4[7] void print_at(size_t x, size_t y, size_t attr, const char16_t *str); void clear_screen(size_t attr); typedef int (*compare_pointer_func_t)(const void *a, const void *b); void sort_pointer_array(void **array, size_t n_members, compare_pointer_func_t compare); EFI_STATUS get_file_info(EFI_FILE *handle, EFI_FILE_INFO **ret, size_t *ret_size); EFI_STATUS readdir(EFI_FILE *handle, EFI_FILE_INFO **buffer, size_t *buffer_size); bool is_ascii(const char16_t *f); char16_t **strv_free(char16_t **l); static inline void strv_freep(char16_t ***p) { strv_free(*p); } EFI_STATUS open_directory(EFI_FILE *root_dir, const char16_t *path, EFI_FILE **ret); /* Conversion between EFI_PHYSICAL_ADDRESS and pointers is not obvious. The former is always 64bit, even on * 32bit archs. And gcc complains if we cast a pointer to an integer of a different size. Hence let's do the * conversion indirectly: first into uintptr_t and then extended to EFI_PHYSICAL_ADDRESS. */ static inline EFI_PHYSICAL_ADDRESS POINTER_TO_PHYSICAL_ADDRESS(const void *p) { return (EFI_PHYSICAL_ADDRESS) (uintptr_t) p; } static inline void *PHYSICAL_ADDRESS_TO_POINTER(EFI_PHYSICAL_ADDRESS addr) { /* On 32bit systems the address might not be convertible (as pointers are 32bit but * EFI_PHYSICAL_ADDRESS 64bit) */ assert(addr <= UINTPTR_MAX); return (void *) (uintptr_t) addr; } uint64_t get_os_indications_supported(void); #ifdef EFI_DEBUG /* Report the relocated position of text and data sections so that a debugger * can attach to us. See debug-sd-boot.sh for how this can be done. */ void notify_debugger(const char *identity, bool wait); void hexdump(const char16_t *prefix, const void *data, size_t size); #else # define notify_debugger(i, w) #endif /* On x86 the compiler assumes a different incoming stack alignment than what we get. * This will cause long long variables to be misaligned when building with * '-mlong-double' (for correct struct layouts). Normally, the compiler realigns the * stack itself on entry, but we have to do this ourselves here as the compiler does * not know that this is our entry point. */ #ifdef __i386__ # define _realign_stack_ __attribute__((force_align_arg_pointer)) #else # define _realign_stack_ #endif #define DEFINE_EFI_MAIN_FUNCTION(func, identity, wait_for_debugger) \ EFI_SYSTEM_TABLE *ST; \ EFI_BOOT_SERVICES *BS; \ EFI_RUNTIME_SERVICES *RT; \ _realign_stack_ \ EFIAPI EFI_STATUS efi_main(EFI_HANDLE image, EFI_SYSTEM_TABLE *system_table); \ EFIAPI EFI_STATUS efi_main(EFI_HANDLE image, EFI_SYSTEM_TABLE *system_table) { \ ST = system_table; \ BS = system_table->BootServices; \ RT = system_table->RuntimeServices; \ __stack_chk_guard_init(); \ notify_debugger((identity), (wait_for_debugger)); \ EFI_STATUS err = func(image); \ log_wait(); \ return err; \ } #if defined(__i386__) || defined(__x86_64__) void beep(unsigned beep_count); #else static inline void beep(unsigned beep_count) {} #endif EFI_STATUS open_volume(EFI_HANDLE device, EFI_FILE **ret_file); static inline bool efi_guid_equal(const EFI_GUID *a, const EFI_GUID *b) { return memcmp(a, b, sizeof(EFI_GUID)) == 0; } void *find_configuration_table(const EFI_GUID *guid);