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review.trustedfirmware.org / mirror / mcuboot / 253bf0f5e2fc47ec1384cbee9baab3d0d746eb3d / . / sim / src / main.rs
blob: a2b1a934b40265286cfd748e08f848e1d04aa251 [file] [log] [blame]
#[macro_use] extern crate log;
extern crate ring;
extern crate env_logger;
#[macro_use] extern crate bitflags;
extern crate docopt;
extern crate libc;
extern crate pem;
extern crate rand;
#[macro_use] extern crate serde_derive;
extern crate serde;
extern crate simflash;
extern crate untrusted;
extern crate mcuboot_sys;
use docopt::Docopt;
use rand::{Rng, SeedableRng, XorShiftRng};
use rand::distributions::{IndependentSample, Range};
use std::fmt;
use std::mem;
use std::process;
use std::slice;
mod caps;
mod tlv;
use simflash::{Flash, SimFlash};
use mcuboot_sys::{c, AreaDesc, FlashId};
use caps::Caps;
use tlv::TlvGen;
const USAGE: &'static str = "
Mcuboot simulator
Usage:
bootsim sizes
bootsim run --device TYPE [--align SIZE]
bootsim runall
bootsim (--help | --version)
Options:
-h, --help Show this message
--version Version
--device TYPE MCU to simulate
Valid values: stm32f4, k64f
--align SIZE Flash write alignment
";
#[derive(Debug, Deserialize)]
struct Args {
flag_help: bool,
flag_version: bool,
flag_device: Option<DeviceName>,
flag_align: Option<AlignArg>,
cmd_sizes: bool,
cmd_run: bool,
cmd_runall: bool,
}
#[derive(Copy, Clone, Debug, Deserialize)]
enum DeviceName { Stm32f4, K64f, K64fBig, Nrf52840 }
static ALL_DEVICES: &'static [DeviceName] = &[
DeviceName::Stm32f4,
DeviceName::K64f,
DeviceName::K64fBig,
DeviceName::Nrf52840,
];
impl fmt::Display for DeviceName {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
let name = match *self {
DeviceName::Stm32f4 => "stm32f4",
DeviceName::K64f => "k64f",
DeviceName::K64fBig => "k64fbig",
DeviceName::Nrf52840 => "nrf52840",
};
f.write_str(name)
}
}
#[derive(Debug)]
struct AlignArg(u8);
struct AlignArgVisitor;
impl<'de> serde::de::Visitor<'de> for AlignArgVisitor {
type Value = AlignArg;
fn expecting(&self, formatter: &mut fmt::Formatter) -> fmt::Result {
formatter.write_str("1, 2, 4 or 8")
}
fn visit_u8<E>(self, n: u8) -> Result<Self::Value, E>
where E: serde::de::Error
{
Ok(match n {
1 | 2 | 4 | 8 => AlignArg(n),
n => {
let err = format!("Could not deserialize '{}' as alignment", n);
return Err(E::custom(err));
}
})
}
}
impl<'de> serde::de::Deserialize<'de> for AlignArg {
fn deserialize<D>(d: D) -> Result<AlignArg, D::Error>
where D: serde::de::Deserializer<'de>
{
d.deserialize_u8(AlignArgVisitor)
}
}
fn main() {
env_logger::init().unwrap();
let args: Args = Docopt::new(USAGE)
.and_then(|d| d.deserialize())
.unwrap_or_else(|e| e.exit());
// println!("args: {:#?}", args);
if args.cmd_sizes {
show_sizes();
return;
}
let mut status = RunStatus::new();
if args.cmd_run {
let align = args.flag_align.map(|x| x.0).unwrap_or(1);
let device = match args.flag_device {
None => panic!("Missing mandatory device argument"),
Some(dev) => dev,
};
status.run_single(device, align);
}
if args.cmd_runall {
for &dev in ALL_DEVICES {
for &align in &[1, 2, 4, 8] {
status.run_single(dev, align);
}
}
}
if status.failures > 0 {
error!("{} Tests ran with {} failures", status.failures + status.passes, status.failures);
process::exit(1);
} else {
error!("{} Tests ran successfully", status.passes);
process::exit(0);
}
}
struct RunStatus {
failures: usize,
passes: usize,
}
impl RunStatus {
fn new() -> RunStatus {
RunStatus {
failures: 0,
passes: 0,
}
}
fn run_single(&mut self, device: DeviceName, align: u8) {
warn!("Running on device {} with alignment {}", device, align);
let (mut flash, areadesc) = match device {
DeviceName::Stm32f4 => {
// STM style flash. Large sectors, with a large scratch area.
let flash = SimFlash::new(vec![16 * 1024, 16 * 1024, 16 * 1024, 16 * 1024,
64 * 1024,
128 * 1024, 128 * 1024, 128 * 1024],
align as usize);
let mut areadesc = AreaDesc::new(&flash);
areadesc.add_image(0x020000, 0x020000, FlashId::Image0);
areadesc.add_image(0x040000, 0x020000, FlashId::Image1);
areadesc.add_image(0x060000, 0x020000, FlashId::ImageScratch);
(flash, areadesc)
}
DeviceName::K64f => {
// NXP style flash. Small sectors, one small sector for scratch.
let flash = SimFlash::new(vec![4096; 128], align as usize);
let mut areadesc = AreaDesc::new(&flash);
areadesc.add_image(0x020000, 0x020000, FlashId::Image0);
areadesc.add_image(0x040000, 0x020000, FlashId::Image1);
areadesc.add_image(0x060000, 0x001000, FlashId::ImageScratch);
(flash, areadesc)
}
DeviceName::K64fBig => {
// Simulating an STM style flash on top of an NXP style flash. Underlying flash device
// uses small sectors, but we tell the bootloader they are large.
let flash = SimFlash::new(vec![4096; 128], align as usize);
let mut areadesc = AreaDesc::new(&flash);
areadesc.add_simple_image(0x020000, 0x020000, FlashId::Image0);
areadesc.add_simple_image(0x040000, 0x020000, FlashId::Image1);
areadesc.add_simple_image(0x060000, 0x020000, FlashId::ImageScratch);
(flash, areadesc)
}
DeviceName::Nrf52840 => {
// Simulating the flash on the nrf52840 with partitions set up so that the scratch size
// does not divide into the image size.
let flash = SimFlash::new(vec![4096; 128], align as usize);
let mut areadesc = AreaDesc::new(&flash);
areadesc.add_image(0x008000, 0x034000, FlashId::Image0);
areadesc.add_image(0x03c000, 0x034000, FlashId::Image1);
areadesc.add_image(0x070000, 0x00d000, FlashId::ImageScratch);
(flash, areadesc)
}
};
let (slot0_base, slot0_len) = areadesc.find(FlashId::Image0);
let (slot1_base, slot1_len) = areadesc.find(FlashId::Image1);
let (scratch_base, _) = areadesc.find(FlashId::ImageScratch);
// Code below assumes that the slots are consecutive.
assert_eq!(slot1_base, slot0_base + slot0_len);
assert_eq!(scratch_base, slot1_base + slot1_len);
let offset_from_end = c::boot_magic_sz() + c::boot_max_align() * 2;
// println!("Areas: {:#?}", areadesc.get_c());
// Install the boot trailer signature, so that the code will start an upgrade.
// TODO: This must be a multiple of flash alignment, add support for an image that is smaller,
// and just gets padded.
// Create original and upgrade images
let slot0 = SlotInfo {
base_off: slot0_base as usize,
trailer_off: slot1_base - offset_from_end,
};
let slot1 = SlotInfo {
base_off: slot1_base as usize,
trailer_off: scratch_base - offset_from_end,
};
// Set an alignment, and position the magic value.
c::set_sim_flash_align(align);
let mut failed = false;
// Creates a badly signed image in slot1 to check that it is not
// upgraded to
let mut bad_flash = flash.clone();
let bad_slot1_image = Images {
slot0: &slot0,
slot1: &slot1,
primary: install_image(&mut bad_flash, slot0_base, 32784, false),
upgrade: install_image(&mut bad_flash, slot1_base, 41928, true),
};
failed |= run_signfail_upgrade(&bad_flash, &areadesc, &bad_slot1_image);
let images = Images {
slot0: &slot0,
slot1: &slot1,
primary: install_image(&mut flash, slot0_base, 32784, false),
upgrade: install_image(&mut flash, slot1_base, 41928, false),
};
failed |= run_norevert_newimage(&flash, &areadesc, &images);
mark_upgrade(&mut flash, &images.slot1);
// upgrades without fails, counts number of flash operations
let total_count = match run_basic_upgrade(&flash, &areadesc, &images) {
Ok(v) => v,
Err(_) => {
self.failures += 1;
return;
},
};
failed |= run_basic_revert(&flash, &areadesc, &images);
failed |= run_revert_with_fails(&flash, &areadesc, &images, total_count);
failed |= run_perm_with_fails(&flash, &areadesc, &images, total_count);
failed |= run_perm_with_random_fails(&flash, &areadesc, &images,
total_count, 5);
failed |= run_norevert(&flash, &areadesc, &images);
//show_flash(&flash);
if failed {
self.failures += 1;
} else {
self.passes += 1;
}
}
}
/// A simple upgrade without forced failures.
///
/// Returns the number of flash operations which can later be used to
/// inject failures at chosen steps.
fn run_basic_upgrade(flash: &SimFlash, areadesc: &AreaDesc, images: &Images)
-> Result<i32, ()> {
let (fl, total_count) = try_upgrade(&flash, &areadesc, &images, None);
info!("Total flash operation count={}", total_count);
if !verify_image(&fl, images.slot0.base_off, &images.upgrade) {
warn!("Image mismatch after first boot");
Err(())
} else {
Ok(total_count)
}
}
fn run_basic_revert(flash: &SimFlash, areadesc: &AreaDesc, images: &Images) -> bool {
let mut fails = 0;
// FIXME: this test would also pass if no swap is ever performed???
if Caps::SwapUpgrade.present() {
for count in 2 .. 5 {
info!("Try revert: {}", count);
let fl = try_revert(&flash, &areadesc, count);
if !verify_image(&fl, images.slot0.base_off, &images.primary) {
error!("Revert failure on count {}", count);
fails += 1;
}
}
}
fails > 0
}
fn run_perm_with_fails(flash: &SimFlash, areadesc: &AreaDesc, images: &Images,
total_flash_ops: i32) -> bool {
let mut fails = 0;
// Let's try an image halfway through.
for i in 1 .. total_flash_ops {
info!("Try interruption at {}", i);
let (fl, count) = try_upgrade(&flash, &areadesc, &images, Some(i));
info!("Second boot, count={}", count);
if !verify_image(&fl, images.slot0.base_off, &images.upgrade) {
warn!("FAIL at step {} of {}", i, total_flash_ops);
fails += 1;
}
if !verify_trailer(&fl, images.slot0.trailer_off, MAGIC_VALID, IMAGE_OK,
COPY_DONE) {
warn!("Mismatched trailer for Slot 0");
fails += 1;
}
if !verify_trailer(&fl, images.slot1.trailer_off, MAGIC_UNSET, UNSET,
UNSET) {
warn!("Mismatched trailer for Slot 1");
fails += 1;
}
if Caps::SwapUpgrade.present() {
if !verify_image(&fl, images.slot1.base_off, &images.primary) {
warn!("Slot 1 FAIL at step {} of {}", i, total_flash_ops);
fails += 1;
}
}
}
if fails > 0 {
error!("{} out of {} failed {:.2}%", fails, total_flash_ops,
fails as f32 * 100.0 / total_flash_ops as f32);
}
fails > 0
}
fn run_perm_with_random_fails(flash: &SimFlash, areadesc: &AreaDesc,
images: &Images, total_flash_ops: i32,
total_fails: usize) -> bool {
let mut fails = 0;
let (fl, total_counts) = try_random_fails(&flash, &areadesc, &images,
total_flash_ops, total_fails);
info!("Random interruptions at reset points={:?}", total_counts);
let slot0_ok = verify_image(&fl, images.slot0.base_off, &images.upgrade);
let slot1_ok = if Caps::SwapUpgrade.present() {
verify_image(&fl, images.slot1.base_off, &images.primary)
} else {
true
};
if !slot0_ok || !slot1_ok {
error!("Image mismatch after random interrupts: slot0={} slot1={}",
if slot0_ok { "ok" } else { "fail" },
if slot1_ok { "ok" } else { "fail" });
fails += 1;
}
if !verify_trailer(&fl, images.slot0.trailer_off, MAGIC_VALID, IMAGE_OK,
COPY_DONE) {
error!("Mismatched trailer for Slot 0");
fails += 1;
}
if !verify_trailer(&fl, images.slot1.trailer_off, MAGIC_UNSET, UNSET,
UNSET) {
error!("Mismatched trailer for Slot 1");
fails += 1;
}
if fails > 0 {
error!("Error testing perm upgrade with {} fails", total_fails);
}
fails > 0
}
fn run_revert_with_fails(flash: &SimFlash, areadesc: &AreaDesc, images: &Images,
total_count: i32) -> bool {
let mut fails = 0;
if Caps::SwapUpgrade.present() {
for i in 1 .. (total_count - 1) {
info!("Try interruption at {}", i);
if try_revert_with_fail_at(&flash, &areadesc, &images, i) {
error!("Revert failed at interruption {}", i);
fails += 1;
}
}
}
fails > 0
}
fn run_norevert(flash: &SimFlash, areadesc: &AreaDesc, images: &Images) -> bool {
let mut fl = flash.clone();
let mut fails = 0;
info!("Try norevert");
c::set_flash_counter(0);
// First do a normal upgrade...
if c::boot_go(&mut fl, &areadesc) != 0 {
warn!("Failed first boot");
fails += 1;
}
//FIXME: copy_done is written by boot_go, is it ok if no copy
// was ever done?
if !verify_image(&fl, images.slot0.base_off, &images.upgrade) {
warn!("Slot 0 image verification FAIL");
fails += 1;
}
if !verify_trailer(&fl, images.slot0.trailer_off, MAGIC_VALID, UNSET,
COPY_DONE) {
warn!("Mismatched trailer for Slot 0");
fails += 1;
}
if !verify_trailer(&fl, images.slot1.trailer_off, MAGIC_UNSET, UNSET,
UNSET) {
warn!("Mismatched trailer for Slot 1");
fails += 1;
}
// Marks image in slot0 as permanent, no revert should happen...
mark_permanent_upgrade(&mut fl, &images.slot0);
if !verify_trailer(&fl, images.slot0.trailer_off, MAGIC_VALID, IMAGE_OK,
COPY_DONE) {
warn!("Mismatched trailer for Slot 0");
fails += 1;
}
if c::boot_go(&mut fl, &areadesc) != 0 {
warn!("Failed second boot");
fails += 1;
}
if !verify_trailer(&fl, images.slot0.trailer_off, MAGIC_VALID, IMAGE_OK,
COPY_DONE) {
warn!("Mismatched trailer for Slot 0");
fails += 1;
}
if !verify_image(&fl, images.slot0.base_off, &images.upgrade) {
warn!("Failed image verification");
fails += 1;
}
if fails > 0 {
error!("Error running upgrade without revert");
}
fails > 0
}
// Tests a new image written to slot0 that already has magic and image_ok set
// while there is no image on slot1, so no revert should ever happen...
fn run_norevert_newimage(flash: &SimFlash, areadesc: &AreaDesc,
images: &Images) -> bool {
let mut fl = flash.clone();
let mut fails = 0;
info!("Try non-revert on imgtool generated image");
c::set_flash_counter(0);
mark_upgrade(&mut fl, &images.slot0);
// This simulates writing an image created by imgtool to Slot 0
if !verify_trailer(&fl, images.slot0.trailer_off, MAGIC_VALID, UNSET, UNSET) {
warn!("Mismatched trailer for Slot 0");
fails += 1;
}
// Run the bootloader...
if c::boot_go(&mut fl, &areadesc) != 0 {
warn!("Failed first boot");
fails += 1;
}
// State should not have changed
if !verify_image(&fl, images.slot0.base_off, &images.primary) {
warn!("Failed image verification");
fails += 1;
}
if !verify_trailer(&fl, images.slot0.trailer_off, MAGIC_VALID, UNSET,
UNSET) {
warn!("Mismatched trailer for Slot 0");
fails += 1;
}
if !verify_trailer(&fl, images.slot1.trailer_off, MAGIC_UNSET, UNSET,
UNSET) {
warn!("Mismatched trailer for Slot 1");
fails += 1;
}
if fails > 0 {
error!("Expected a non revert with new image");
}
fails > 0
}
// Tests a new image written to slot0 that already has magic and image_ok set
// while there is no image on slot1, so no revert should ever happen...
fn run_signfail_upgrade(flash: &SimFlash, areadesc: &AreaDesc,
images: &Images) -> bool {
let mut fl = flash.clone();
let mut fails = 0;
info!("Try upgrade image with bad signature");
c::set_flash_counter(0);
mark_upgrade(&mut fl, &images.slot0);
mark_permanent_upgrade(&mut fl, &images.slot0);
mark_upgrade(&mut fl, &images.slot1);
if !verify_trailer(&fl, images.slot0.trailer_off, MAGIC_VALID, IMAGE_OK,
UNSET) {
warn!("Mismatched trailer for Slot 0");
fails += 1;
}
// Run the bootloader...
if c::boot_go(&mut fl, &areadesc) != 0 {
warn!("Failed first boot");
fails += 1;
}
// State should not have changed
if !verify_image(&fl, images.slot0.base_off, &images.primary) {
warn!("Failed image verification");
fails += 1;
}
if !verify_trailer(&fl, images.slot0.trailer_off, MAGIC_VALID, IMAGE_OK,
UNSET) {
warn!("Mismatched trailer for Slot 0");
fails += 1;
}
if fails > 0 {
error!("Expected an upgrade failure when image has bad signature");
}
fails > 0
}
/// Test a boot, optionally stopping after 'n' flash options. Returns a count
/// of the number of flash operations done total.
fn try_upgrade(flash: &SimFlash, areadesc: &AreaDesc, images: &Images,
stop: Option<i32>) -> (SimFlash, i32) {
// Clone the flash to have a new copy.
let mut fl = flash.clone();
mark_permanent_upgrade(&mut fl, &images.slot1);
c::set_flash_counter(stop.unwrap_or(0));
let (first_interrupted, count) = match c::boot_go(&mut fl, &areadesc) {
-0x13579 => (true, stop.unwrap()),
0 => (false, -c::get_flash_counter()),
x => panic!("Unknown return: {}", x),
};
c::set_flash_counter(0);
if first_interrupted {
// fl.dump();
match c::boot_go(&mut fl, &areadesc) {
-0x13579 => panic!("Shouldn't stop again"),
0 => (),
x => panic!("Unknown return: {}", x),
}
}
(fl, count - c::get_flash_counter())
}
fn try_revert(flash: &SimFlash, areadesc: &AreaDesc, count: usize) -> SimFlash {
let mut fl = flash.clone();
c::set_flash_counter(0);
// fl.write_file("image0.bin").unwrap();
for i in 0 .. count {
info!("Running boot pass {}", i + 1);
assert_eq!(c::boot_go(&mut fl, &areadesc), 0);
}
fl
}
fn try_revert_with_fail_at(flash: &SimFlash, areadesc: &AreaDesc, images: &Images,
stop: i32) -> bool {
let mut fl = flash.clone();
let mut x: i32;
let mut fails = 0;
c::set_flash_counter(stop);
x = c::boot_go(&mut fl, &areadesc);
if x != -0x13579 {
warn!("Should have stopped at interruption point");
fails += 1;
}
if !verify_trailer(&fl, images.slot0.trailer_off, None, None, UNSET) {
warn!("copy_done should be unset");
fails += 1;
}
c::set_flash_counter(0);
x = c::boot_go(&mut fl, &areadesc);
if x != 0 {
warn!("Should have finished upgrade");
fails += 1;
}
if !verify_image(&fl, images.slot0.base_off, &images.upgrade) {
warn!("Image in slot 0 before revert is invalid at stop={}", stop);
fails += 1;
}
if !verify_image(&fl, images.slot1.base_off, &images.primary) {
warn!("Image in slot 1 before revert is invalid at stop={}", stop);
fails += 1;
}
if !verify_trailer(&fl, images.slot0.trailer_off, MAGIC_VALID, UNSET,
COPY_DONE) {
warn!("Mismatched trailer for Slot 0 before revert");
fails += 1;
}
if !verify_trailer(&fl, images.slot1.trailer_off, MAGIC_UNSET, UNSET,
UNSET) {
warn!("Mismatched trailer for Slot 1 before revert");
fails += 1;
}
// Do Revert
c::set_flash_counter(0);
x = c::boot_go(&mut fl, &areadesc);
if x != 0 {
warn!("Should have finished a revert");
fails += 1;
}
if !verify_image(&fl, images.slot0.base_off, &images.primary) {
warn!("Image in slot 0 after revert is invalid at stop={}", stop);
fails += 1;
}
if !verify_image(&fl, images.slot1.base_off, &images.upgrade) {
warn!("Image in slot 1 after revert is invalid at stop={}", stop);
fails += 1;
}
if !verify_trailer(&fl, images.slot0.trailer_off, MAGIC_VALID, IMAGE_OK,
COPY_DONE) {
warn!("Mismatched trailer for Slot 1 after revert");
fails += 1;
}
if !verify_trailer(&fl, images.slot1.trailer_off, MAGIC_UNSET, UNSET,
UNSET) {
warn!("Mismatched trailer for Slot 1 after revert");
fails += 1;
}
fails > 0
}
fn try_random_fails(flash: &SimFlash, areadesc: &AreaDesc, images: &Images,
total_ops: i32, count: usize) -> (SimFlash, Vec<i32>) {
let mut fl = flash.clone();
mark_permanent_upgrade(&mut fl, &images.slot1);
let mut rng = rand::thread_rng();
let mut resets = vec![0i32; count];
let mut remaining_ops = total_ops;
for i in 0 .. count {
let ops = Range::new(1, remaining_ops / 2);
let reset_counter = ops.ind_sample(&mut rng);
c::set_flash_counter(reset_counter);
match c::boot_go(&mut fl, &areadesc) {
0 | -0x13579 => (),
x => panic!("Unknown return: {}", x),
}
remaining_ops -= reset_counter;
resets[i] = reset_counter;
}
c::set_flash_counter(0);
match c::boot_go(&mut fl, &areadesc) {
-0x13579 => panic!("Should not be have been interrupted!"),
0 => (),
x => panic!("Unknown return: {}", x),
}
(fl, resets)
}
/// Show the flash layout.
#[allow(dead_code)]
fn show_flash(flash: &Flash) {
println!("---- Flash configuration ----");
for sector in flash.sector_iter() {
println!(" {:3}: 0x{:08x}, 0x{:08x}",
sector.num, sector.base, sector.size);
}
println!("");
}
/// Install a "program" into the given image. This fakes the image header, or at least all of the
/// fields used by the given code. Returns a copy of the image that was written.
fn install_image(flash: &mut Flash, offset: usize, len: usize,
bad_sig: bool) -> Vec<u8> {
let offset0 = offset;
let mut tlv = make_tlv();
// Generate a boot header. Note that the size doesn't include the header.
let header = ImageHeader {
magic: 0x96f3b83c,
tlv_size: tlv.get_size(),
_pad1: 0,
hdr_size: 32,
key_id: 0,
_pad2: 0,
img_size: len as u32,
flags: tlv.get_flags(),
ver: ImageVersion {
major: (offset / (128 * 1024)) as u8,
minor: 0,
revision: 1,
build_num: offset as u32,
},
_pad3: 0,
};
let b_header = header.as_raw();
tlv.add_bytes(&b_header);
/*
let b_header = unsafe { slice::from_raw_parts(&header as *const _ as *const u8,
mem::size_of::<ImageHeader>()) };
*/
assert_eq!(b_header.len(), 32);
flash.write(offset, &b_header).unwrap();
let offset = offset + b_header.len();
// The core of the image itself is just pseudorandom data.
let mut buf = vec![0; len];
splat(&mut buf, offset);
tlv.add_bytes(&buf);
// Get and append the TLV itself.
if bad_sig {
let good_sig = &mut tlv.make_tlv();
buf.append(&mut vec![0; good_sig.len()]);
} else {
buf.append(&mut tlv.make_tlv());
}
// Pad the block to a flash alignment (8 bytes).
while buf.len() % 8 != 0 {
buf.push(0xFF);
}
flash.write(offset, &buf).unwrap();
let offset = offset + buf.len();
// Copy out the image so that we can verify that the image was installed correctly later.
let mut copy = vec![0u8; offset - offset0];
flash.read(offset0, &mut copy).unwrap();
copy
}
// The TLV in use depends on what kind of signature we are verifying.
#[cfg(feature = "sig-rsa")]
fn make_tlv() -> TlvGen {
TlvGen::new_rsa_pss()
}
#[cfg(not(feature = "sig-rsa"))]
fn make_tlv() -> TlvGen {
TlvGen::new_hash_only()
}
/// Verify that given image is present in the flash at the given offset.
fn verify_image(flash: &Flash, offset: usize, buf: &[u8]) -> bool {
let mut copy = vec![0u8; buf.len()];
flash.read(offset, &mut copy).unwrap();
if buf != &copy[..] {
for i in 0 .. buf.len() {
if buf[i] != copy[i] {
info!("First failure at {:#x}", offset + i);
break;
}
}
false
} else {
true
}
}
fn verify_trailer(flash: &Flash, offset: usize,
magic: Option<&[u8]>, image_ok: Option<u8>,
copy_done: Option<u8>) -> bool {
let mut copy = vec![0u8; c::boot_magic_sz() + c::boot_max_align() * 2];
let mut failed = false;
flash.read(offset, &mut copy).unwrap();
failed |= match magic {
Some(v) => {
if &copy[16..] != v {
warn!("\"magic\" mismatch at {:#x}", offset);
true
} else {
false
}
},
None => false,
};
failed |= match image_ok {
Some(v) => {
if copy[8] != v {
warn!("\"image_ok\" mismatch at {:#x}", offset);
true
} else {
false
}
},
None => false,
};
failed |= match copy_done {
Some(v) => {
if copy[0] != v {
warn!("\"copy_done\" mismatch at {:#x}", offset);
true
} else {
false
}
},
None => false,
};
!failed
}
/// The image header
#[repr(C)]
pub struct ImageHeader {
magic: u32,
tlv_size: u16,
key_id: u8,
_pad1: u8,
hdr_size: u16,
_pad2: u16,
img_size: u32,
flags: u32,
ver: ImageVersion,
_pad3: u32,
}
impl AsRaw for ImageHeader {}
#[repr(C)]
pub struct ImageVersion {
major: u8,
minor: u8,
revision: u16,
build_num: u32,
}
struct SlotInfo {
base_off: usize,
trailer_off: usize,
}
struct Images<'a> {
slot0: &'a SlotInfo,
slot1: &'a SlotInfo,
primary: Vec<u8>,
upgrade: Vec<u8>,
}
const MAGIC_VALID: Option<&[u8]> = Some(&[0x77, 0xc2, 0x95, 0xf3,
0x60, 0xd2, 0xef, 0x7f,
0x35, 0x52, 0x50, 0x0f,
0x2c, 0xb6, 0x79, 0x80]);
const MAGIC_UNSET: Option<&[u8]> = Some(&[0xff; 16]);
const COPY_DONE: Option<u8> = Some(1);
const IMAGE_OK: Option<u8> = Some(1);
const UNSET: Option<u8> = Some(0xff);
/// Write out the magic so that the loader tries doing an upgrade.
fn mark_upgrade(flash: &mut Flash, slot: &SlotInfo) {
let offset = slot.trailer_off + c::boot_max_align() * 2;
flash.write(offset, MAGIC_VALID.unwrap()).unwrap();
}
/// Writes the image_ok flag which, guess what, tells the bootloader
/// the this image is ok (not a test, and no revert is to be performed).
fn mark_permanent_upgrade(flash: &mut Flash, slot: &SlotInfo) {
let ok = [1u8, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff];
let align = c::get_sim_flash_align() as usize;
let off = slot.trailer_off + c::boot_max_align();
flash.write(off, &ok[..align]).unwrap();
}
// Drop some pseudo-random gibberish onto the data.
fn splat(data: &mut [u8], seed: usize) {
let seed_block = [0x135782ea, 0x92184728, data.len() as u32, seed as u32];
let mut rng: XorShiftRng = SeedableRng::from_seed(seed_block);
rng.fill_bytes(data);
}
/// Return a read-only view into the raw bytes of this object
trait AsRaw : Sized {
fn as_raw<'a>(&'a self) -> &'a [u8] {
unsafe { slice::from_raw_parts(self as *const _ as *const u8,
mem::size_of::<Self>()) }
}
}
fn show_sizes() {
// This isn't panic safe.
let old_align = c::get_sim_flash_align();
for min in &[1, 2, 4, 8] {
c::set_sim_flash_align(*min);
let msize = c::boot_trailer_sz();
println!("{:2}: {} (0x{:x})", min, msize, msize);
}
c::set_sim_flash_align(old_align);
}