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/* SPDX-License-Identifier: LGPL-2.1-or-later */
#include "devicetree.h"
#include "proto/dt-fixup.h"
#include "util.h"
#define FDT_V1_SIZE (7*4)
static EFI_STATUS devicetree_allocate(struct devicetree_state *state, size_t size) {
size_t pages = DIV_ROUND_UP(size, EFI_PAGE_SIZE);
EFI_STATUS err;
assert(state);
err = BS->AllocatePages(AllocateAnyPages, EfiACPIReclaimMemory, pages, &state->addr);
if (err != EFI_SUCCESS)
return err;
state->pages = pages;
return err;
}
static size_t devicetree_allocated(const struct devicetree_state *state) {
assert(state);
return state->pages * EFI_PAGE_SIZE;
}
static EFI_STATUS devicetree_fixup(struct devicetree_state *state, size_t len) {
EFI_DT_FIXUP_PROTOCOL *fixup;
size_t size;
EFI_STATUS err;
assert(state);
err = BS->LocateProtocol(MAKE_GUID_PTR(EFI_DT_FIXUP_PROTOCOL), NULL, (void **) &fixup);
/* Skip fixup if we cannot locate device tree fixup protocol */
if (err != EFI_SUCCESS)
return EFI_SUCCESS;
size = devicetree_allocated(state);
err = fixup->Fixup(fixup, PHYSICAL_ADDRESS_TO_POINTER(state->addr), &size,
EFI_DT_APPLY_FIXUPS | EFI_DT_RESERVE_MEMORY);
if (err == EFI_BUFFER_TOO_SMALL) {
EFI_PHYSICAL_ADDRESS oldaddr = state->addr;
size_t oldpages = state->pages;
void *oldptr = PHYSICAL_ADDRESS_TO_POINTER(state->addr);
err = devicetree_allocate(state, size);
if (err != EFI_SUCCESS)
return err;
memcpy(PHYSICAL_ADDRESS_TO_POINTER(state->addr), oldptr, len);
err = BS->FreePages(oldaddr, oldpages);
if (err != EFI_SUCCESS)
return err;
size = devicetree_allocated(state);
err = fixup->Fixup(fixup, PHYSICAL_ADDRESS_TO_POINTER(state->addr), &size,
EFI_DT_APPLY_FIXUPS | EFI_DT_RESERVE_MEMORY);
}
return err;
}
EFI_STATUS devicetree_install(struct devicetree_state *state, EFI_FILE *root_dir, char16_t *name) {
_cleanup_(file_closep) EFI_FILE *handle = NULL;
_cleanup_free_ EFI_FILE_INFO *info = NULL;
size_t len;
EFI_STATUS err;
assert(state);
assert(root_dir);
assert(name);
/* Capture the original value for the devicetree table. NULL is not an error in this case so we don't
* need to check the return value. NULL simply means the system fw had no devicetree initially (and
* is the correct value to use to return to the initial state if needed). */
state->orig = find_configuration_table(MAKE_GUID_PTR(EFI_DTB_TABLE));
err = root_dir->Open(root_dir, &handle, name, EFI_FILE_MODE_READ, EFI_FILE_READ_ONLY);
if (err != EFI_SUCCESS)
return err;
err = get_file_info(handle, &info, NULL);
if (err != EFI_SUCCESS)
return err;
if (info->FileSize < FDT_V1_SIZE || info->FileSize > 32 * 1024 * 1024)
/* 32MB device tree blob doesn't seem right */
return EFI_INVALID_PARAMETER;
len = info->FileSize;
err = devicetree_allocate(state, len);
if (err != EFI_SUCCESS)
return err;
err = handle->Read(handle, &len, PHYSICAL_ADDRESS_TO_POINTER(state->addr));
if (err != EFI_SUCCESS)
return err;
err = devicetree_fixup(state, len);
if (err != EFI_SUCCESS)
return err;
return BS->InstallConfigurationTable(
MAKE_GUID_PTR(EFI_DTB_TABLE), PHYSICAL_ADDRESS_TO_POINTER(state->addr));
}
static const char* devicetree_get_compatible(const void *dtb) {
if ((uintptr_t) dtb % alignof(FdtHeader) != 0)
return NULL;
const FdtHeader *dt_header = ASSERT_PTR(dtb);
if (be32toh(dt_header->magic) != UINT32_C(0xd00dfeed))
return NULL;
uint32_t dt_size = be32toh(dt_header->total_size);
uint32_t struct_off = be32toh(dt_header->off_dt_struct);
uint32_t struct_size = be32toh(dt_header->size_dt_struct);
uint32_t strings_off = be32toh(dt_header->off_dt_strings);
uint32_t strings_size = be32toh(dt_header->size_dt_strings);
uint32_t end;
if (PTR_TO_SIZE(dtb) > SIZE_MAX - dt_size)
return NULL;
if (!ADD_SAFE(&end, strings_off, strings_size) || end > dt_size)
return NULL;
const char *strings_block = (const char *) ((const uint8_t *) dt_header + strings_off);
if (struct_off % sizeof(uint32_t) != 0)
return NULL;
if (struct_size % sizeof(uint32_t) != 0 ||
!ADD_SAFE(&end, struct_off, struct_size) ||
end > strings_off)
return NULL;
const uint32_t *cursor = (const uint32_t *) ((const uint8_t *) dt_header + struct_off);
size_t size_words = struct_size / sizeof(uint32_t);
size_t len, name_off, len_words, s;
for (size_t i = 0; i < end; i++) {
switch (be32toh(cursor[i])) {
case FDT_BEGIN_NODE:
if (i >= size_words || cursor[++i] != 0)
return NULL;
break;
case FDT_NOP:
break;
case FDT_PROP:
/* At least 3 words should present: len, name_off, c (nul-terminated string always has non-zero length) */
if (i + 3 >= size_words)
return NULL;
len = be32toh(cursor[++i]);
name_off = be32toh(cursor[++i]);
len_words = DIV_ROUND_UP(len, sizeof(uint32_t));
if (ADD_SAFE(&s, name_off, STRLEN("compatible")) &&
s < strings_size && streq8(strings_block + name_off, "compatible")) {
const char *c = (const char *) &cursor[++i];
if (len == 0 || i + len_words > size_words || c[len - 1] != '\0')
c = NULL;
return c;
}
i += len_words;
break;
default:
return NULL;
}
}
return NULL;
}
bool firmware_devicetree_exists(void) {
return !!find_configuration_table(MAKE_GUID_PTR(EFI_DTB_TABLE));
}
/* This function checks if the firmware provided DeviceTree
* and a UKI provided DeviceTree contain the same first entry
* on their respective "compatible" fields (which usually defines
* the actual device model). More specifically, given the FW/UKI
* "compatible" property pair:
*
* compatible = "string1", "string2";
* compatible = "string1", "string3";
*
* the function reports a match, while for
*
* compatible = "string1", "string3";
* compatible = "string2", "string1";
*
* it reports a mismatch.
*
* Other entries might refer to SoC and therefore can't be used for matching
*/
EFI_STATUS devicetree_match(const void *uki_dtb, size_t uki_dtb_length) {
const void *fw_dtb = find_configuration_table(MAKE_GUID_PTR(EFI_DTB_TABLE));
if (!fw_dtb)
return EFI_UNSUPPORTED;
const char *fw_compat = devicetree_get_compatible(fw_dtb);
if (!fw_compat)
return EFI_UNSUPPORTED;
return devicetree_match_by_compatible(uki_dtb, uki_dtb_length, fw_compat);
}
EFI_STATUS devicetree_match_by_compatible(const void *uki_dtb, size_t uki_dtb_length, const char *compat) {
if ((uintptr_t) uki_dtb % alignof(FdtHeader) != 0)
return EFI_INVALID_PARAMETER;
const FdtHeader *dt_header = ASSERT_PTR(uki_dtb);
if (uki_dtb_length < sizeof(FdtHeader) ||
uki_dtb_length < be32toh(dt_header->total_size))
return EFI_INVALID_PARAMETER;
if (!compat)
return EFI_INVALID_PARAMETER;
const char *dt_compat = devicetree_get_compatible(uki_dtb);
if (!dt_compat)
return EFI_INVALID_PARAMETER;
/* Only matches the first compatible string from each DT */
return streq8(dt_compat, compat) ? EFI_SUCCESS : EFI_NOT_FOUND;
}
EFI_STATUS devicetree_install_from_memory(
struct devicetree_state *state, const void *dtb_buffer, size_t dtb_length) {
EFI_STATUS err;
assert(state);
assert(dtb_buffer && dtb_length > 0);
/* Capture the original value for the devicetree table. NULL is not an error in this case so we don't
* need to check the return value. NULL simply means the system fw had no devicetree initially (and
* is the correct value to use to return to the initial state if needed). */
state->orig = find_configuration_table(MAKE_GUID_PTR(EFI_DTB_TABLE));
err = devicetree_allocate(state, dtb_length);
if (err != EFI_SUCCESS)
return err;
memcpy(PHYSICAL_ADDRESS_TO_POINTER(state->addr), dtb_buffer, dtb_length);
err = devicetree_fixup(state, dtb_length);
if (err != EFI_SUCCESS)
return err;
return BS->InstallConfigurationTable(
MAKE_GUID_PTR(EFI_DTB_TABLE), PHYSICAL_ADDRESS_TO_POINTER(state->addr));
}
void devicetree_cleanup(struct devicetree_state *state) {
EFI_STATUS err;
if (!state->pages)
return;
err = BS->InstallConfigurationTable(MAKE_GUID_PTR(EFI_DTB_TABLE), state->orig);
/* don't free the current device tree if we can't reinstate the old one */
if (err != EFI_SUCCESS)
return;
BS->FreePages(state->addr, state->pages);
state->pages = 0;
}
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