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hafnium / hafnium / b5ab43c61ec9eb410a922f9056df961b37c29e48 / . / src / manifest.c
blob: 460494c6cc8134f46e4febd434e09bc365da03c1 [file] [log] [blame]
/*
* Copyright 2019 The Hafnium Authors.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* https://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include "hf/manifest.h"
#include "hf/addr.h"
#include "hf/check.h"
#include "hf/dlog.h"
#include "hf/fdt.h"
#include "hf/static_assert.h"
#include "hf/std.h"
#define TRY(expr) \
do { \
enum manifest_return_code ret_code = (expr); \
if (ret_code != MANIFEST_SUCCESS) { \
return ret_code; \
} \
} while (0)
#define VM_ID_MAX (HF_VM_ID_OFFSET + MAX_VMS - 1)
#define VM_ID_MAX_DIGITS (5)
#define VM_NAME_EXTRA_CHARS (3) /* "vm" + number + '\0' */
#define VM_NAME_MAX_SIZE (VM_ID_MAX_DIGITS + VM_NAME_EXTRA_CHARS)
static_assert(VM_NAME_MAX_SIZE <= STRING_MAX_SIZE,
"VM name does not fit into a struct string.");
static_assert(VM_ID_MAX <= 99999, "Insufficient VM_NAME_BUF_SIZE");
static_assert(HF_TEE_VM_ID > VM_ID_MAX,
"TrustZone VM ID clashes with normal VM range.");
static inline size_t count_digits(ffa_vm_id_t vm_id)
{
size_t digits = 0;
do {
digits++;
vm_id /= 10;
} while (vm_id);
return digits;
}
/**
* Generates a string with the two letters "vm" followed by an integer.
* Assumes `buf` is of size VM_NAME_BUF_SIZE.
*/
static void generate_vm_node_name(struct string *str, ffa_vm_id_t vm_id)
{
static const char *digits = "0123456789";
size_t vm_id_digits = count_digits(vm_id);
char *base = str->data;
char *ptr = base + (VM_NAME_EXTRA_CHARS + vm_id_digits);
CHECK(vm_id_digits <= VM_ID_MAX_DIGITS);
*(--ptr) = '\0';
do {
*(--ptr) = digits[vm_id % 10];
vm_id /= 10;
} while (vm_id);
*(--ptr) = 'm';
*(--ptr) = 'v';
CHECK(ptr == base);
}
/**
* Read a boolean property: true if present; false if not. If present, the value
* of the property must be empty else it is considered malformed.
*/
static enum manifest_return_code read_bool(const struct fdt_node *node,
const char *property, bool *out)
{
struct memiter data;
bool present = fdt_read_property(node, property, &data);
if (present && memiter_size(&data) != 0) {
return MANIFEST_ERROR_MALFORMED_BOOLEAN;
}
*out = present;
return MANIFEST_SUCCESS;
}
static enum manifest_return_code read_string(const struct fdt_node *node,
const char *property,
struct string *out)
{
struct memiter data;
if (!fdt_read_property(node, property, &data)) {
return MANIFEST_ERROR_PROPERTY_NOT_FOUND;
}
switch (string_init(out, &data)) {
case STRING_SUCCESS:
return MANIFEST_SUCCESS;
case STRING_ERROR_INVALID_INPUT:
return MANIFEST_ERROR_MALFORMED_STRING;
case STRING_ERROR_TOO_LONG:
return MANIFEST_ERROR_STRING_TOO_LONG;
}
}
static enum manifest_return_code read_optional_string(
const struct fdt_node *node, const char *property, struct string *out)
{
enum manifest_return_code ret;
ret = read_string(node, property, out);
if (ret == MANIFEST_ERROR_PROPERTY_NOT_FOUND) {
string_init_empty(out);
ret = MANIFEST_SUCCESS;
}
return ret;
}
static enum manifest_return_code read_uint64(const struct fdt_node *node,
const char *property,
uint64_t *out)
{
struct memiter data;
if (!fdt_read_property(node, property, &data)) {
return MANIFEST_ERROR_PROPERTY_NOT_FOUND;
}
if (!fdt_parse_number(&data, memiter_size(&data), out)) {
return MANIFEST_ERROR_MALFORMED_INTEGER;
}
return MANIFEST_SUCCESS;
}
static enum manifest_return_code read_optional_uint64(
const struct fdt_node *node, const char *property,
uint64_t default_value, uint64_t *out)
{
enum manifest_return_code ret;
ret = read_uint64(node, property, out);
if (ret == MANIFEST_ERROR_PROPERTY_NOT_FOUND) {
*out = default_value;
return MANIFEST_SUCCESS;
}
return ret;
}
static enum manifest_return_code read_uint16(const struct fdt_node *node,
const char *property,
uint16_t *out)
{
uint64_t value;
TRY(read_uint64(node, property, &value));
if (value > UINT16_MAX) {
return MANIFEST_ERROR_INTEGER_OVERFLOW;
}
*out = (uint16_t)value;
return MANIFEST_SUCCESS;
}
struct uint32list_iter {
struct memiter mem_it;
};
static enum manifest_return_code read_optional_uint32list(
const struct fdt_node *node, const char *property,
struct uint32list_iter *out)
{
struct memiter data;
if (!fdt_read_property(node, property, &data)) {
memiter_init(&out->mem_it, NULL, 0);
return MANIFEST_SUCCESS;
}
if ((memiter_size(&data) % sizeof(uint32_t)) != 0) {
return MANIFEST_ERROR_MALFORMED_INTEGER_LIST;
}
out->mem_it = data;
return MANIFEST_SUCCESS;
}
static bool uint32list_has_next(const struct uint32list_iter *list)
{
return memiter_size(&list->mem_it) > 0;
}
static enum manifest_return_code uint32list_get_next(
struct uint32list_iter *list, uint32_t *out)
{
uint64_t num;
CHECK(uint32list_has_next(list));
if (!fdt_parse_number(&list->mem_it, sizeof(uint32_t), &num)) {
return MANIFEST_ERROR_MALFORMED_INTEGER;
}
*out = (uint32_t)num;
return MANIFEST_SUCCESS;
}
static enum manifest_return_code parse_vm(const struct fdt_node *node,
struct manifest_vm *vm,
ffa_vm_id_t vm_id)
{
struct uint32list_iter smcs;
size_t idx;
TRY(read_string(node, "debug_name", &vm->debug_name));
TRY(read_optional_string(node, "kernel_filename",
&vm->kernel_filename));
TRY(read_optional_uint32list(node, "smc_whitelist", &smcs));
while (uint32list_has_next(&smcs) &&
vm->smc_whitelist.smc_count < MAX_SMCS) {
idx = vm->smc_whitelist.smc_count++;
TRY(uint32list_get_next(&smcs, &vm->smc_whitelist.smcs[idx]));
}
if (uint32list_has_next(&smcs)) {
dlog_warning("%s SMC whitelist too long.\n", vm->debug_name);
}
TRY(read_bool(node, "smc_whitelist_permissive",
&vm->smc_whitelist.permissive));
if (vm_id == HF_PRIMARY_VM_ID) {
TRY(read_optional_string(node, "ramdisk_filename",
&vm->primary.ramdisk_filename));
TRY(read_optional_uint64(node, "boot_address",
MANIFEST_INVALID_ADDRESS,
&vm->primary.boot_address));
} else {
TRY(read_uint64(node, "mem_size", &vm->secondary.mem_size));
TRY(read_uint16(node, "vcpu_count", &vm->secondary.vcpu_count));
}
return MANIFEST_SUCCESS;
}
/**
* Parse manifest from FDT.
*/
enum manifest_return_code manifest_init(struct manifest *manifest,
struct memiter *manifest_fdt)
{
struct string vm_name;
struct fdt fdt;
struct fdt_node hyp_node;
size_t i = 0;
bool found_primary_vm = false;
memset_s(manifest, sizeof(*manifest), 0, sizeof(*manifest));
if (!fdt_init_from_memiter(&fdt, manifest_fdt)) {
return MANIFEST_ERROR_FILE_SIZE; /* TODO */
}
/* Find hypervisor node. */
if (!fdt_find_node(&fdt, "/hypervisor", &hyp_node)) {
return MANIFEST_ERROR_NO_HYPERVISOR_FDT_NODE;
}
/* Check "compatible" property. */
if (!fdt_is_compatible(&hyp_node, "hafnium,hafnium")) {
return MANIFEST_ERROR_NOT_COMPATIBLE;
}
TRY(read_bool(&hyp_node, "ffa_tee", &manifest->ffa_tee_enabled));
/* Iterate over reserved VM IDs and check no such nodes exist. */
for (i = 0; i < HF_VM_ID_OFFSET; i++) {
ffa_vm_id_t vm_id = (ffa_vm_id_t)i;
struct fdt_node vm_node = hyp_node;
generate_vm_node_name(&vm_name, vm_id);
if (fdt_find_child(&vm_node, &vm_name)) {
return MANIFEST_ERROR_RESERVED_VM_ID;
}
}
/* Iterate over VM nodes until we find one that does not exist. */
for (i = 0; i <= MAX_VMS; ++i) {
ffa_vm_id_t vm_id = HF_VM_ID_OFFSET + i;
struct fdt_node vm_node = hyp_node;
generate_vm_node_name(&vm_name, vm_id);
if (!fdt_find_child(&vm_node, &vm_name)) {
break;
}
if (i == MAX_VMS) {
return MANIFEST_ERROR_TOO_MANY_VMS;
}
if (vm_id == HF_PRIMARY_VM_ID) {
CHECK(found_primary_vm == false); /* sanity check */
found_primary_vm = true;
}
manifest->vm_count = i + 1;
TRY(parse_vm(&vm_node, &manifest->vm[i], vm_id));
}
if (!found_primary_vm) {
return MANIFEST_ERROR_NO_PRIMARY_VM;
}
return MANIFEST_SUCCESS;
}
const char *manifest_strerror(enum manifest_return_code ret_code)
{
switch (ret_code) {
case MANIFEST_SUCCESS:
return "Success";
case MANIFEST_ERROR_FILE_SIZE:
return "Total size in header does not match file size";
case MANIFEST_ERROR_NO_ROOT_NODE:
return "Could not find root node in manifest";
case MANIFEST_ERROR_NO_HYPERVISOR_FDT_NODE:
return "Could not find \"hypervisor\" node in manifest";
case MANIFEST_ERROR_NOT_COMPATIBLE:
return "Hypervisor manifest entry not compatible with Hafnium";
case MANIFEST_ERROR_RESERVED_VM_ID:
return "Manifest defines a VM with a reserved ID";
case MANIFEST_ERROR_NO_PRIMARY_VM:
return "Manifest does not contain a primary VM entry";
case MANIFEST_ERROR_TOO_MANY_VMS:
return "Manifest specifies more VMs than Hafnium has "
"statically allocated space for";
case MANIFEST_ERROR_PROPERTY_NOT_FOUND:
return "Property not found";
case MANIFEST_ERROR_MALFORMED_STRING:
return "Malformed string property";
case MANIFEST_ERROR_STRING_TOO_LONG:
return "String too long";
case MANIFEST_ERROR_MALFORMED_INTEGER:
return "Malformed integer property";
case MANIFEST_ERROR_INTEGER_OVERFLOW:
return "Integer overflow";
case MANIFEST_ERROR_MALFORMED_INTEGER_LIST:
return "Malformed integer list property";
case MANIFEST_ERROR_MALFORMED_BOOLEAN:
return "Malformed boolean property";
}
panic("Unexpected manifest return code.");
}