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https://github.com/embassy-rs/embassy.git
synced 2024-11-25 16:23:10 +00:00
Added hash module with blocking implementation. Included SHA256 example.
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@ -68,7 +68,7 @@ rand_core = "0.6.3"
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sdio-host = "0.5.0"
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critical-section = "1.1"
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#stm32-metapac = { version = "15" }
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stm32-metapac = { git = "https://github.com/embassy-rs/stm32-data-generated", tag = "stm32-data-ab2bc2a739324793656ca1640e1caee2d88df72d" }
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stm32-metapac = { git = "https://github.com/embassy-rs/stm32-data-generated", tag = "stm32-data-0cb3a4fcaec702c93b3700715de796636d562b15" }
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vcell = "0.1.3"
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bxcan = "0.7.0"
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nb = "1.0.0"
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@ -87,7 +87,7 @@ critical-section = { version = "1.1", features = ["std"] }
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proc-macro2 = "1.0.36"
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quote = "1.0.15"
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#stm32-metapac = { version = "15", default-features = false, features = ["metadata"]}
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stm32-metapac = { git = "https://github.com/embassy-rs/stm32-data-generated", tag = "stm32-data-ab2bc2a739324793656ca1640e1caee2d88df72d", default-features = false, features = ["metadata"]}
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stm32-metapac = { git = "https://github.com/embassy-rs/stm32-data-generated", tag = "stm32-data-0cb3a4fcaec702c93b3700715de796636d562b15", default-features = false, features = ["metadata"]}
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[features]
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260
embassy-stm32/src/hash/mod.rs
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260
embassy-stm32/src/hash/mod.rs
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@ -0,0 +1,260 @@
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//! Hash generator (HASH)
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use core::cmp::min;
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use embassy_hal_internal::{into_ref, PeripheralRef};
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use stm32_metapac::hash::regs::*;
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use crate::pac::HASH as PAC_HASH;
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use crate::peripherals::HASH;
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use crate::rcc::sealed::RccPeripheral;
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use crate::Peripheral;
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const NUM_CONTEXT_REGS: usize = 54;
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const HASH_BUFFER_LEN: usize = 68;
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const DIGEST_BLOCK_SIZE: usize = 64;
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///Hash algorithm selection
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#[derive(PartialEq)]
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pub enum Algorithm {
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/// SHA-1 Algorithm
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SHA1 = 0,
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/// MD5 Algorithm
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MD5 = 1,
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/// SHA-224 Algorithm
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SHA224 = 2,
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/// SHA-256 Algorithm
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SHA256 = 3,
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}
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/// Input data width selection
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#[repr(u8)]
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#[derive(Clone, Copy)]
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pub enum DataType {
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///32-bit data, no data is swapped.
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Width32 = 0,
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///16-bit data, each half-word is swapped.
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Width16 = 1,
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///8-bit data, all bytes are swapped.
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Width8 = 2,
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///1-bit data, all bits are swapped.
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Width1 = 3,
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}
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/// Stores the state of the HASH peripheral for suspending/resuming
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/// digest calculation.
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pub struct Context {
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first_word_sent: bool,
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buffer: [u8; HASH_BUFFER_LEN],
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buflen: usize,
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algo: Algorithm,
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format: DataType,
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imr: u32,
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str: u32,
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cr: u32,
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csr: [u32; NUM_CONTEXT_REGS],
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}
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/// HASH driver.
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pub struct Hash<'d> {
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_peripheral: PeripheralRef<'d, HASH>,
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}
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impl<'d> Hash<'d> {
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/// Instantiates, resets, and enables the HASH peripheral.
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pub fn new(peripheral: impl Peripheral<P = HASH> + 'd) -> Self {
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HASH::enable_and_reset();
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into_ref!(peripheral);
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let instance = Self {
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_peripheral: peripheral,
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};
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instance
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}
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/// Starts computation of a new hash and returns the saved peripheral state.
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pub fn start(&mut self, algorithm: Algorithm, format: DataType) -> Context {
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// Define a context for this new computation.
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let mut ctx = Context {
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first_word_sent: false,
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buffer: [0; 68],
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buflen: 0,
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algo: algorithm,
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format: format,
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imr: 0,
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str: 0,
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cr: 0,
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csr: [0; NUM_CONTEXT_REGS],
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};
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// Set the data type in the peripheral.
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PAC_HASH.cr().modify(|w| w.set_datatype(ctx.format as u8));
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// Select the algorithm.
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let mut algo0 = false;
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let mut algo1 = false;
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if ctx.algo == Algorithm::MD5 || ctx.algo == Algorithm::SHA256 {
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algo0 = true;
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}
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if ctx.algo == Algorithm::SHA224 || ctx.algo == Algorithm::SHA256 {
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algo1 = true;
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}
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PAC_HASH.cr().modify(|w| w.set_algo0(algo0));
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PAC_HASH.cr().modify(|w| w.set_algo1(algo1));
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PAC_HASH.cr().modify(|w| w.set_init(true));
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// Store and return the state of the peripheral.
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self.store_context(&mut ctx);
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ctx
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}
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/// Restores the peripheral state using the given context,
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/// then updates the state with the provided data.
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pub fn update(&mut self, ctx: &mut Context, input: &[u8]) {
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let mut data_waiting = input.len() + ctx.buflen;
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if data_waiting < DIGEST_BLOCK_SIZE || (data_waiting < ctx.buffer.len() && !ctx.first_word_sent) {
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// There isn't enough data to digest a block, so append it to the buffer.
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ctx.buffer[ctx.buflen..ctx.buflen + input.len()].copy_from_slice(input);
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ctx.buflen += input.len();
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return;
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}
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//Restore the peripheral state.
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self.load_context(&ctx);
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let mut ilen_remaining = input.len();
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let mut input_start = 0;
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// Handle first block.
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if !ctx.first_word_sent {
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let empty_len = ctx.buffer.len() - ctx.buflen;
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let copy_len = min(empty_len, ilen_remaining);
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// Fill the buffer.
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if copy_len > 0 {
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ctx.buffer[ctx.buflen..ctx.buflen + copy_len].copy_from_slice(&input[0..copy_len]);
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ctx.buflen += copy_len;
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ilen_remaining -= copy_len;
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input_start += copy_len;
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}
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assert_eq!(ctx.buflen, HASH_BUFFER_LEN);
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self.accumulate(ctx.buffer.as_slice());
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data_waiting -= ctx.buflen;
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ctx.buflen = 0;
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ctx.first_word_sent = true;
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}
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if data_waiting < 64 {
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// There isn't enough data remaining to process another block, so store it.
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assert_eq!(ctx.buflen, 0);
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ctx.buffer[0..ilen_remaining].copy_from_slice(&input[input_start..input_start + ilen_remaining]);
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ctx.buflen += ilen_remaining;
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} else {
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let mut total_data_sent = 0;
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// First ingest the data in the buffer.
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let empty_len = DIGEST_BLOCK_SIZE - ctx.buflen;
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if empty_len > 0 {
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let copy_len = min(empty_len, ilen_remaining);
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ctx.buffer[ctx.buflen..ctx.buflen + copy_len]
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.copy_from_slice(&input[input_start..input_start + copy_len]);
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ctx.buflen += copy_len;
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ilen_remaining -= copy_len;
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input_start += copy_len;
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}
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assert_eq!(ctx.buflen % 64, 0);
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self.accumulate(&ctx.buffer[0..64]);
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total_data_sent += ctx.buflen;
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ctx.buflen = 0;
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// Move any extra data to the now-empty buffer.
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let leftovers = ilen_remaining % 64;
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if leftovers > 0 {
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assert!(ilen_remaining >= leftovers);
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ctx.buffer[0..leftovers].copy_from_slice(&input[input.len() - leftovers..input.len()]);
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ctx.buflen += leftovers;
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ilen_remaining -= leftovers;
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}
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assert_eq!(ilen_remaining % 64, 0);
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// Hash the remaining data.
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self.accumulate(&input[input_start..input_start + ilen_remaining]);
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total_data_sent += ilen_remaining;
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assert_eq!(total_data_sent % 64, 0);
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assert!(total_data_sent >= 64);
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}
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// Save the peripheral context.
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self.store_context(ctx);
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}
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/// Computes a digest for the given context. A slice of the provided digest buffer is returned.
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/// The length of the returned slice is dependent on the digest length of the selected algorithm.
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pub fn finish<'a>(&mut self, mut ctx: Context, digest: &'a mut [u8; 32]) -> &'a [u8] {
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// Restore the peripheral state.
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self.load_context(&ctx);
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// Hash the leftover bytes, if any.
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self.accumulate(&ctx.buffer[0..ctx.buflen]);
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ctx.buflen = 0;
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//Start the digest calculation.
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PAC_HASH.str().write(|w| w.set_dcal(true));
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//Wait for completion.
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while !PAC_HASH.sr().read().dcis() {}
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//Return the digest.
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let digest_words = match ctx.algo {
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Algorithm::SHA1 => 5,
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Algorithm::MD5 => 4,
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Algorithm::SHA224 => 7,
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Algorithm::SHA256 => 8,
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};
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let mut i = 0;
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while i < digest_words {
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let word = PAC_HASH.hr(i).read();
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digest[(i * 4)..((i * 4) + 4)].copy_from_slice(word.to_be_bytes().as_slice());
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i += 1;
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}
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&digest[0..digest_words * 4]
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}
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fn accumulate(&mut self, input: &[u8]) {
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//Set the number of valid bits.
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let num_valid_bits: u8 = (8 * (input.len() % 4)) as u8;
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PAC_HASH.str().modify(|w| w.set_nblw(num_valid_bits));
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let mut i = 0;
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while i < input.len() {
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let mut word: [u8; 4] = [0; 4];
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let copy_idx = min(i + 4, input.len());
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word[0..copy_idx - i].copy_from_slice(&input[i..copy_idx]);
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PAC_HASH.din().write_value(u32::from_ne_bytes(word));
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i += 4;
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}
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}
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/// Save the peripheral state to a context.
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fn store_context(&mut self, ctx: &mut Context) {
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while !PAC_HASH.sr().read().dinis() {}
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ctx.imr = PAC_HASH.imr().read().0;
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ctx.str = PAC_HASH.str().read().0;
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ctx.cr = PAC_HASH.cr().read().0;
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let mut i = 0;
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while i < NUM_CONTEXT_REGS {
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ctx.csr[i] = PAC_HASH.csr(i).read();
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i += 1;
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}
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}
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/// Restore the peripheral state from a context.
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fn load_context(&mut self, ctx: &Context) {
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// Restore the peripheral state from the context.
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PAC_HASH.imr().write_value(Imr { 0: ctx.imr });
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PAC_HASH.str().write_value(Str { 0: ctx.str });
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PAC_HASH.cr().write_value(Cr { 0: ctx.cr });
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PAC_HASH.cr().modify(|w| w.set_init(true));
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let mut i = 0;
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while i < NUM_CONTEXT_REGS {
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PAC_HASH.csr(i).write_value(ctx.csr[i]);
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i += 1;
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}
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}
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}
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@ -45,6 +45,8 @@ pub mod exti;
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pub mod flash;
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#[cfg(fmc)]
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pub mod fmc;
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#[cfg(hash)]
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pub mod hash;
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#[cfg(hrtim)]
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pub mod hrtim;
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#[cfg(i2c)]
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@ -5,8 +5,8 @@ version = "0.1.0"
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license = "MIT OR Apache-2.0"
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[dependencies]
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# Change stm32f767zi to your chip name, if necessary.
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embassy-stm32 = { version = "0.1.0", path = "../../embassy-stm32", features = ["defmt", "stm32f767zi", "memory-x", "unstable-pac", "time-driver-any", "exti"] }
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# Change stm32f777zi to your chip name, if necessary.
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embassy-stm32 = { version = "0.1.0", path = "../../embassy-stm32", features = ["defmt", "stm32f777zi", "memory-x", "unstable-pac", "time-driver-any", "exti"] }
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embassy-sync = { version = "0.5.0", path = "../../embassy-sync", features = ["defmt"] }
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embassy-executor = { version = "0.5.0", path = "../../embassy-executor", features = ["task-arena-size-32768", "arch-cortex-m", "executor-thread", "defmt", "integrated-timers"] }
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embassy-time = { version = "0.3.0", path = "../../embassy-time", features = ["defmt", "defmt-timestamp-uptime", "tick-hz-32_768"] }
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@ -28,6 +28,7 @@ rand_core = "0.6.3"
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critical-section = "1.1"
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embedded-storage = "0.3.1"
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static_cell = "2"
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sha2 = { version = "0.10.8", default-features = false }
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[profile.release]
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debug = 2
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49
examples/stm32f7/src/bin/hash.rs
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49
examples/stm32f7/src/bin/hash.rs
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@ -0,0 +1,49 @@
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#![no_std]
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#![no_main]
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use defmt::info;
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use embassy_executor::Spawner;
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use embassy_stm32::Config;
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use embassy_time::{Duration, Instant};
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use {defmt_rtt as _, panic_probe as _};
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use embassy_stm32::hash::*;
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use sha2::{Digest, Sha256};
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const TEST_STRING_1: &[u8] = b"hello world";
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#[embassy_executor::main]
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async fn main(_spawner: Spawner) -> ! {
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let config = Config::default();
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let p = embassy_stm32::init(config);
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let hw_start_time = Instant::now();
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// Compute a digest in hardware.
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let mut hw_hasher = Hash::new(p.HASH);
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let mut context = hw_hasher.start(Algorithm::SHA256, DataType::Width8);
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hw_hasher.update(&mut context, TEST_STRING_1);
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let mut buffer: [u8; 32] = [0; 32];
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let hw_digest = hw_hasher.finish(context, &mut buffer);
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let hw_end_time = Instant::now();
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let hw_execution_time = hw_end_time - hw_start_time;
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let sw_start_time = Instant::now();
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// Compute a digest in software.
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let mut sw_hasher = Sha256::new();
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sw_hasher.update(TEST_STRING_1);
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let sw_digest = sw_hasher.finalize();
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let sw_end_time = Instant::now();
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let sw_execution_time = sw_end_time - sw_start_time;
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info!("Hardware Digest: {:?}", hw_digest);
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info!("Software Digest: {:?}", sw_digest[..]);
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info!("Hardware Execution Time: {:?}", hw_execution_time);
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info!("Software Execution Time: {:?}", sw_execution_time);
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assert_eq!(*hw_digest, sw_digest[..]);
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loop {}
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}
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