Crates.io | usbd-dfu |
lib.rs | usbd-dfu |
version | 0.4.0 |
source | src |
created_at | 2021-04-17 13:35:49.06484 |
updated_at | 2024-03-09 17:47:32.692537 |
description | DFU protocol for a `usb-device` device. |
homepage | |
repository | https://github.com/vitalyvb/usbd-dfu |
max_upload_size | |
id | 385748 |
size | 122,293 |
Implements DFU protocol version 1.1a for a usb-device
device.
DFU protocol aims to provide a standard how USB device's firmware can be upgraded. Often, in this case firmware of the device consists of two parts: a large main firmware, and a smaller bootloader. When device is powered on, bootloader starts and either runs main firmware, or enters "firmware update" mode.
Protocol implementation tries to follows DFU 1.1a protocol as specified by AN3156 by STMicroelectronics and USB Device Firmware Upgrade Specification, Revision 1.1.
This library is a protocol implementation only, actual code that programs, erases, or reads memory or flash in not a of the library and is expected to be provided by library user.
Maximum USB transfer size is limited to what usb-device
supports
for control enpoint transfers, which is 128
bytes by default.
iString field in DFU_GETSTATUS
is always 0
. Vendor-specific string
error descriptions are not supported.
There are many implementations of tools to flash USB device supporting DFU protocol, for example:
This project is licensed under MIT License (LICENSE).
Unless you explicitly state otherwise, any contribution intentionally submitted for inclusion in the work by you shall be licensed as above, without any additional terms or conditions.
The example below tries to focus on DFUClass
, parts related to a target
controller initialization and configuration (USB, interrupts, GPIO, etc.)
are not in the scope of the example.
Check examples for more information.
Also see documentation for usb-device
crate, crates that supports
target microcontroller and provide a corresponding HAL.
use usb_device::prelude::*;
use usbd_dfu::*;
// DFUClass will use MyMem to actually read, erase or program the memory.
// Here, a set of constant parameters must be set. These parameters
// either change how DFUClass behaves, or define host's expectations.
struct MyMem {
buffer: [u8; 64],
flash_memory: [u8; 1024],
}
impl DFUMemIO for MyMem {
const MEM_INFO_STRING: &'static str = "@Flash/0x00000000/1*1Kg";
const INITIAL_ADDRESS_POINTER: u32 = 0x0;
const PROGRAM_TIME_MS: u32 = 8;
const ERASE_TIME_MS: u32 = 50;
const FULL_ERASE_TIME_MS: u32 = 50;
const TRANSFER_SIZE: u16 = 64;
fn read(&mut self, address: u32, length: usize) -> Result<&[u8], DFUMemError> {
// TODO: check address value
let offset = address as usize;
Ok(&self.flash_memory[offset..offset+length])
}
fn erase(&mut self, address: u32) -> Result<(), DFUMemError> {
// TODO: check address value
self.flash_memory.fill(0xff);
// TODO: verify that block is erased successfully
Ok(())
}
fn erase_all(&mut self) -> Result<(), DFUMemError> {
// There is only one block, erase it.
self.erase(0)
}
fn store_write_buffer(&mut self, src:&[u8]) -> Result<(), ()>{
self.buffer[..src.len()].copy_from_slice(src);
Ok(())
}
fn program(&mut self, address: u32, length: usize) -> Result<(), DFUMemError>{
// TODO: check address value
let offset = address as usize;
// Write buffer to a memory
self.flash_memory[offset..offset+length].copy_from_slice(&self.buffer[..length]);
// TODO: verify that memory is programmed correctly
Ok(())
}
fn manifestation(&mut self) -> Result<(), DFUManifestationError> {
// Nothing to do to activate FW
Ok(())
}
}
let mut my_mem = MyMem {
buffer: [0u8; 64],
flash_memory: [0u8; 1024],
};
// Create USB device for a target device:
// let usb_bus_alloc = UsbBus::new(peripheral);
// let usb_dev = UsbDeviceBuilder::new().build();
// Create DFUClass
let mut dfu = DFUClass::new(&usb_bus_alloc, my_mem);
// usb_dev.poll() must be called periodically, usually from USB interrupt handlers.
// When USB input/output is done, handlers in MyMem may be called.
usb_dev.poll(&mut [&mut dfu]);
See usbd-dfu-example for a functioning example.