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Author SHA1 Message Date
Ryan Summers 0ea7499543
Merge pull request #3 from quartiq/release/0.3.0
Prepping for release
2023-07-03 14:51:20 +02:00
Ryan Summers 237009b628 Reverting repo update 2023-07-03 14:48:02 +02:00
Ryan Summers b1f98c3622 Prepping for release 2023-07-03 13:50:06 +02:00
Ryan Summers 753112e7b0
Merge pull request #1 from quartiq/feature/nal-removal
Removing NAL, reordering dependencies
2023-07-03 13:45:28 +02:00
Ryan Summers 0ecfe84ea0 Fixing smoltcp features 2023-07-03 13:43:12 +02:00
Ryan Summers 207a75358f Merge branch 'master' into feature/nal-removal 2023-07-03 13:39:50 +02:00
Ryan Summers 21ab601b0d
Merge pull request #2 from quartiq/feature/ci
Adding CI, format
2023-07-03 13:37:12 +02:00
Ryan Summers fc43e3b5c5 Fixing example features 2023-07-03 12:32:54 +02:00
Ryan Summers e94d1df1ec Adding dummy commit 2023-07-03 12:28:47 +02:00
Ryan Summers 0fa5c8f81c Enabling features in examples 2023-07-03 12:27:35 +02:00
Ryan Summers ed42d185df Updating example features 2023-07-03 12:26:47 +02:00
Ryan Summers 253a1f6f1d Adding format 2023-07-03 12:25:46 +02:00
Ryan Summers 273cf09ad2 Removing nal module 2023-07-03 12:23:44 +02:00
Ryan Summers fb2fd17277 Removing NAL, reordering dependencies 2023-07-03 12:21:26 +02:00
Harry Ho 512fd154bd nix: Use lib in place of deprecated stdenv.lib 2021-09-02 17:10:03 +08:00
Harry Ho fbcc3778d2 spi: Always delay for NSS setup time
* Fixes the lack of setup time delay of an fixed-byte command that immediately follows an N-byte command.
* Extra 50ns will be inserted in-between fixed-byte commands but should be acceptable.
2021-06-23 12:49:21 +08:00
Harry Ho bb6824b944 nal: Remove delay_ns func pointer 2021-06-04 13:21:02 +08:00
Harry Ho d8b1132b8a examples: Replace delay_ns with cortex-m delay 2021-06-03 15:06:24 +08:00
Harry Ho 999ca5f08a spi: Replace delay_ns func pointer with delay on cortex-m
* SPI NSS nanosecond delays now only takes place on Cortex-M CPUs
2021-06-03 15:03:43 +08:00
Harry Ho 9de8d77a24 Restore embedded_hal DelayUs for device init 2021-06-03 13:38:59 +08:00
Harry Ho ec20970a50 spi: Impose stricter NSS timing 2021-06-03 12:03:35 +08:00
Harry Ho 35b7924431 spi: Add back NSS high delay conditionally based on opcode type 2021-06-03 11:51:09 +08:00
Harry Ho d05d7f91e2 spi: Simplify all reg reads/writes as rw_n() 2021-06-03 11:51:09 +08:00
Harry Ho 27ba42c4fb spi: Introduce certain 1 & 3-byte opcodes to replace reg read/writes 2021-06-03 11:51:09 +08:00
Harry Ho edb1f64f26 nix: Use itm-tools from nixpkgs-21.05 2021-06-02 14:15:07 +08:00
Harry Ho 40a53cc0d6 spi: Fix Rx/Tx buffer logic & simplify
* tx/rx: Rename wrap_addr to start_addr for clarity
* Fix RX logic, when advancing the tail pointer, not retrieving the stored RX buffer start address but the default value instead
* Fix TX logic, when advancing the head pointer for next transmission, not retrieving the stored TX buffer end address but the default value instead
* Rename SPI-related const's to match the datasheet: RERXDATA→RRXDATA, WEGPDATA→WGPDATA
* Remove useless const's for SRAM default addresses for TX buffer
* Simplify code
2021-04-30 17:30:25 +08:00
Harry Ho 6d17703e6b Add Enc424j600::init() for complete initialisation 2021-04-29 17:08:19 +08:00
Harry Ho 78e4d82660 examples: Simplify & fix naming 2021-04-29 17:08:18 +08:00
Harry Ho b9b28f0725 Rename functions & classes for clarity
* EthController → EthPhy
  * ::receive_next() → ::recv_packet()
  * ::send_raw_packet() → ::send_packet()
* SpiEth -> Enc424j600
  * ::read_from_mac() → ::read_mac_addr()
  * ::write_mac_address() → ::write_mac_addr()
* EthControllerError → Error
  * ::GeneralError → ::RegisterError
* spi::SpiPortError -> spi::Error
2021-04-29 17:07:28 +08:00
Harry Ho 3529fcd192 Turn EthController trait methods unrelated to PHY into instance methods 2021-04-29 17:03:51 +08:00
Harry Ho 232a08f110 nal: Fix comments & styling 2021-03-17 10:21:18 +08:00
Harry Ho 2eadb652ff nal: Fix infinite loop when TX buffer is full
* For example, if the PHY linkup is down, instead of looping until resumption of the linkup, a write operation now closes the socket for re-connection in the future
2021-03-16 10:25:23 +08:00
Harry Ho 6de19f43cc nal: Prevent pushing duplicate handles for the same TcpSocket 2021-03-12 12:36:30 +08:00
Harry Ho 66c3aa534f nal: socket (TcpSocket) → handle; internal_socket → socket 2021-03-12 11:26:07 +08:00
Harry Ho 99899e6657 nal: Fix read/write not pushing erroneous socket back to the stack
* Based on quartiq's minimq as of 933687c2e4
* In minimq applications, a socket is expected to be returned when `nal::TcpStack::open()` is called
  * `MqttClient::read()`/`write()` takes away the TCP socket handle (wrapped as an `Option`) from its `RefCell`, and then calls `nal::TcpStack::read()`/`write()`; if NAL returns `nb::Error`, then the MQTT client will propagate and return the error, leaving `None` behind
  * Afterwards, when `MqttClient::socket_is_connected()` gets called (e.g. while polling the interface), it will detect that the socket handle is `None`, and attempt to call `nal::TcpStack::open()`
  * Since `open()` pops a socket from the array (`unused_handles`), when implementing this NAL the socket should have been pushed back to the stack, i.e. by `close()`; this prevents any future calls of `open()` from returning `NetworkError::NoSocket` due to emptiness of the array of socket handles
2021-03-11 17:32:44 +08:00
Harry Ho d9e50bbcb6 nal: Prevent looping until the stack successfully connects to remote
* `NetworkStack::connect()`:
  * Add timeout for connection attempt
  * Now returns the socket at TCP ESTABLISHED or CLOSED states, or after connection timeout
* Split `NetworkStack::update()` into `update()` (for controlling the clock) and `poll()` (for polling the smoltcp EthernetInterface)
* Also remove option `auto_time_update`; the main application is responsible for what values `embedded_time::clock::Clock::try_now()` should return
2021-03-05 14:52:57 +08:00
Harry Ho 6506562c3a cargo: fix [package] meta 2021-01-28 17:56:14 +08:00
Harry Ho 3d471bff0a cargo: cleanup features 2021-01-28 17:56:13 +08:00
13 changed files with 579 additions and 723 deletions

117
.github/workflows/ci.yml vendored Normal file
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@ -0,0 +1,117 @@
name: Continuous Integration
on:
push:
branches: [master]
pull_request:
branches: [master]
env:
CARGO_TERM_COLOR: always
jobs:
style:
runs-on: ubuntu-latest
steps:
- uses: actions/checkout@v2
- uses: actions-rs/toolchain@v1
with:
profile: minimal
toolchain: stable
override: true
components: rustfmt
- name: Style Check
uses: actions-rs/cargo@v1
with:
command: fmt
args: --all -- --check
clippy:
runs-on: ubuntu-latest
steps:
- uses: actions/checkout@v2
- uses: actions-rs/toolchain@v1
with:
profile: minimal
toolchain: stable
target: thumbv7em-none-eabihf
override: true
components: clippy
- name: Clippy Check
uses: actions-rs/cargo@v1
with:
command: clippy
args: --all-features
documentation:
runs-on: ubuntu-latest
steps:
- uses: actions/checkout@v2
- uses: actions-rs/toolchain@v1
with:
profile: minimal
toolchain: stable
target: thumbv7em-none-eabihf
override: true
- name: Cargo Doc
uses: actions-rs/cargo@v1
with:
command: doc
args: --all-features
audit:
runs-on: ubuntu-latest
steps:
- uses: actions/checkout@v2
- name: Cargo Audit
uses: actions-rs/audit-check@v1
with:
token: ${{ secrets.GITHUB_TOKEN }}
compile:
runs-on: ubuntu-latest
strategy:
matrix:
toolchain:
- stable
- beta
steps:
- uses: actions/checkout@v2
- name: Install Rust ${{ matrix.toolchain }}
uses: actions-rs/toolchain@v1
with:
toolchain: ${{ matrix.toolchain }}
target: thumbv7em-none-eabihf
override: true
- name: Cargo Check
uses: actions-rs/cargo@v1
with:
command: check
args: --verbose --all-features
- name: Cargo Build
uses: actions-rs/cargo@v1
with:
command: build
args: --all-features
- name: Cargo Build [Release]
uses: actions-rs/cargo@v1
with:
command: build
args: --release --all-features
- name: Cargo Build [Examples]
uses: actions-rs/cargo@v1
with:
command: build
args: --examples --all-features

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@ -1,9 +1,9 @@
[package]
categories = ["embedded", "no-std"]
name = "enc424j600"
description = "Embbeded Rust Ethernet driver for ENC424J600 Ethernet controller with SPI interface, compatible with STM32F4xx"
authors = ["Harry Ho <hh@m-labs.hk>"]
version = "0.2.0"
description = "Embbeded Rust Ethernet driver for ENC424J600 Ethernet controller with SPI interface"
authors = ["Harry Ho <hh@m-labs.hk>", "Dip Cheung <dc@m-labs.hk>"]
version = "0.3.0"
keywords = ["ethernet", "eth", "enc424j600", "stm32", "stm32f4xx"]
repository = "https://git.m-labs.hk/M-Labs/ENC424J600"
edition = "2018"
@ -13,37 +13,30 @@ license = "BSD-2-Clause"
volatile-register = "0.2"
aligned = "0.3"
embedded-hal = "0.2"
smoltcp = { version = "0.7.0", default-features = false, features = ["proto-ipv4", "proto-ipv6", "socket-icmp", "socket-udp", "socket-tcp", "log", "verbose", "ethernet"], optional = true }
smoltcp = { version = "0.7.0", default-features = false, features = [ "socket-raw", "proto-ipv4",
"proto-ipv6", "socket-tcp", "ethernet"], optional = true }
cortex-m = {version = "0.5", optional = true }
# Optional dependencies for building examples
stm32f4xx-hal = { version = "0.8", optional = true }
cortex-m = { version = "0.5", optional = true }
cortex-m-rt = { version = "0.6", optional = true }
cortex-m-rtic = { version = "0.5.3", optional = true }
panic-itm = { version = "0.4", optional = true }
log = { version = "0.4", optional = true }
embedded-time = { version = "0.10.1", optional = true }
embedded-nal = { version = "0.1.0", optional = true }
heapless = { version = "0.5.6", optional = true }
[dev-dependencies]
stm32f4xx-hal = { version = "0.8", features = ["stm32f407", "rt"] }
cortex-m-rt = "0.6"
cortex-m-rtic = "0.5.3"
panic-itm = "0.4"
log = "0.4"
[features]
smoltcp-phy = ["smoltcp"]
smoltcp-phy-all = [
"smoltcp/socket-raw", "smoltcp/socket-udp", "smoltcp/socket-tcp",
"smoltcp/proto-ipv4", "smoltcp/proto-ipv6"
]
# Example-based features
tx_stm32f407 = ["stm32f4xx-hal/stm32f407", "cortex-m", "cortex-m-rtic", "panic-itm", "log"]
tcp_stm32f407 = ["stm32f4xx-hal/stm32f407", "cortex-m", "cortex-m-rt", "cortex-m-rtic", "smoltcp-phy-all", "smoltcp/log", "panic-itm", "log"]
nal = [ "embedded-time", "embedded-nal", "smoltcp-phy", "heapless" ]
cortex-m-cpu = ["cortex-m"]
default = []
[[example]]
name = "tx_stm32f407"
required-features = ["tx_stm32f407"]
required-features = ["smoltcp", "cortex-m-cpu"]
[[example]]
name = "tcp_stm32f407"
required-features = ["tcp_stm32f407"]
required-features = ["smoltcp", "cortex-m-cpu"]
[profile.release]
codegen-units = 1

View File

@ -2,43 +2,31 @@
#![no_main]
extern crate panic_itm;
use cortex_m::{iprintln, iprint};
use cortex_m::{iprint, iprintln};
use embedded_hal::{
digital::v2::OutputPin,
blocking::delay::DelayMs
};
use embedded_hal::{blocking::delay::DelayMs, digital::v2::OutputPin};
use enc424j600::smoltcp_phy;
use stm32f4xx_hal::{
rcc::RccExt,
gpio::GpioExt,
time::U32Ext,
stm32::ITM,
delay::Delay,
spi::Spi,
time::Hertz
delay::Delay, gpio::GpioExt, rcc::RccExt, spi::Spi, stm32::ITM, time::Hertz, time::U32Ext,
};
use enc424j600;
use enc424j600::{smoltcp_phy, EthController};
use smoltcp::wire::{
EthernetAddress, IpAddress, IpCidr, Ipv6Cidr
};
use smoltcp::iface::{NeighborCache, EthernetInterfaceBuilder, EthernetInterface};
use smoltcp::socket::{SocketSet, TcpSocket, TcpSocketBuffer};
use core::str;
use core::fmt::Write;
use core::str;
use smoltcp::iface::{EthernetInterface, EthernetInterfaceBuilder, NeighborCache};
use smoltcp::socket::{SocketSet, TcpSocket, TcpSocketBuffer};
use smoltcp::wire::{EthernetAddress, IpAddress, IpCidr, Ipv6Cidr};
/// Timer
use core::cell::RefCell;
use cortex_m::interrupt::Mutex;
use cortex_m_rt::exception;
use smoltcp::time::Instant;
use stm32f4xx_hal::{
rcc::Clocks,
stm32::SYST,
time::MilliSeconds,
timer::{Timer, Event as TimerEvent},
stm32::SYST
timer::{Event as TimerEvent, Timer},
};
use smoltcp::time::Instant;
/// Rate in Hz
const TIMER_RATE: u32 = 20;
/// Interval duration in milliseconds
@ -56,32 +44,34 @@ fn timer_setup(syst: SYST, clocks: Clocks) {
#[exception]
fn SysTick() {
cortex_m::interrupt::free(|cs| {
*TIMER_MS.borrow(cs)
.borrow_mut() += TIMER_DELTA;
*TIMER_MS.borrow(cs).borrow_mut() += TIMER_DELTA;
});
}
/// Obtain current time in milliseconds
pub fn timer_now() -> MilliSeconds {
let ms = cortex_m::interrupt::free(|cs| {
*TIMER_MS.borrow(cs)
.borrow()
});
let ms = cortex_m::interrupt::free(|cs| *TIMER_MS.borrow(cs).borrow());
ms.ms()
}
///
use stm32f4xx_hal::{
stm32::SPI1,
gpio::{
gpioa::{PA5, PA6, PA7, PA4},
Alternate, AF5, Output, PushPull
}
gpioa::{PA4, PA5, PA6, PA7},
Alternate, Output, PushPull, AF5,
},
stm32::SPI1,
};
type BoosterSpiEth = enc424j600::SpiEth<
Spi<SPI1, (PA5<Alternate<AF5>>, PA6<Alternate<AF5>>, PA7<Alternate<AF5>>)>,
type SpiEth = enc424j600::Enc424j600<
Spi<
SPI1,
(
PA5<Alternate<AF5>>,
PA6<Alternate<AF5>>,
PA7<Alternate<AF5>>,
),
>,
PA4<Output<PushPull>>,
fn(u32) -> ()
>;
pub struct NetStorage {
@ -91,19 +81,15 @@ pub struct NetStorage {
static mut NET_STORE: NetStorage = NetStorage {
// Placeholder for the real IP address, which is initialized at runtime.
ip_addrs: [IpCidr::Ipv6(
Ipv6Cidr::SOLICITED_NODE_PREFIX,
)],
ip_addrs: [IpCidr::Ipv6(Ipv6Cidr::SOLICITED_NODE_PREFIX)],
neighbor_cache: [None; 8],
};
#[rtic::app(device = stm32f4xx_hal::stm32, peripherals = true, monotonic = rtic::cyccnt::CYCCNT)]
const APP: () = {
struct Resources {
eth_iface: EthernetInterface<
'static,
smoltcp_phy::SmoltcpDevice<BoosterSpiEth>>,
itm: ITM
eth_iface: EthernetInterface<'static, smoltcp_phy::SmoltcpDevice<SpiEth>>,
itm: ITM,
}
#[init()]
@ -115,7 +101,10 @@ const APP: () = {
c.core.DWT.enable_cycle_counter();
c.core.DCB.enable_trace();
let clocks = c.device.RCC.constrain()
let clocks = c
.device
.RCC
.constrain()
.cfgr
.sysclk(168.mhz())
.hclk(168.mhz())
@ -128,8 +117,7 @@ const APP: () = {
let mut itm = c.core.ITM;
let stim0 = &mut itm.stim[0];
iprintln!(stim0,
"Eth TCP Server on STM32-F407 via NIC100/ENC424J600");
iprintln!(stim0, "Eth TCP Server on STM32-F407 via NIC100/ENC424J600");
// NIC100 / ENC424J600 Set-up
let spi1 = c.device.SPI1;
@ -149,19 +137,18 @@ const APP: () = {
let eth_iface = {
let mut spi_eth = {
let spi_eth_port = Spi::spi1(
spi1, (spi1_sck, spi1_miso, spi1_mosi),
spi1,
(spi1_sck, spi1_miso, spi1_mosi),
enc424j600::spi::interfaces::SPI_MODE,
Hertz(enc424j600::spi::interfaces::SPI_CLOCK_FREQ),
clocks);
clocks,
);
let delay_ns_fp: fn(u32) -> () = |time_ns| {
cortex_m::asm::delay((time_ns*21)/125 + 1)
};
enc424j600::SpiEth::new(spi_eth_port, spi1_nss, delay_ns_fp)
SpiEth::new(spi_eth_port, spi1_nss).cpu_freq_mhz(168)
};
// Init controller
match spi_eth.init_dev() {
match spi_eth.reset(&mut delay) {
Ok(_) => {
iprintln!(stim0, "Initializing Ethernet...")
}
@ -172,14 +159,14 @@ const APP: () = {
// Read MAC
let mut eth_mac_addr: [u8; 6] = [0; 6];
spi_eth.read_from_mac(&mut eth_mac_addr);
spi_eth.read_mac_addr(&mut eth_mac_addr);
for i in 0..6 {
let byte = eth_mac_addr[i];
match i {
0 => iprint!(stim0, "MAC Address = {:02x}-", byte),
1..=4 => iprint!(stim0, "{:02x}-", byte),
5 => iprint!(stim0, "{:02x}\n", byte),
_ => ()
_ => (),
};
}
@ -212,10 +199,7 @@ const APP: () = {
timer_setup(delay.free(), clocks);
iprintln!(stim0, "Timer initialized");
init::LateResources {
eth_iface,
itm
}
init::LateResources { eth_iface, itm }
}
#[idle(resources=[eth_iface, itm])]
@ -245,8 +229,11 @@ const APP: () = {
let greet_handle = socket_set.add(greet_socket);
{
let store = unsafe { &mut NET_STORE };
iprintln!(stim0,
"TCP sockets will listen at {}", store.ip_addrs[0].address());
iprintln!(
stim0,
"TCP sockets will listen at {}",
store.ip_addrs[0].address()
);
}
// Copied / modified from:
@ -258,8 +245,7 @@ const APP: () = {
let now = timer_now().0;
let instant = Instant::from_millis(now as i64);
match iface.poll(&mut socket_set, instant) {
Ok(_) => {
},
Ok(_) => {}
Err(e) => {
iprintln!(stim0, "[{}] Poll error: {:?}", instant, e)
}
@ -268,33 +254,40 @@ const APP: () = {
{
let mut socket = socket_set.get::<TcpSocket>(echo_handle);
if !socket.is_open() {
iprintln!(stim0,
"[{}] Listening to port 1234 for echoing, time-out in 10s", instant);
iprintln!(
stim0,
"[{}] Listening to port 1234 for echoing, time-out in 10s",
instant
);
socket.listen(1234).unwrap();
socket.set_timeout(Some(smoltcp::time::Duration::from_millis(10000)));
}
if socket.can_recv() {
iprintln!(stim0,
"[{}] Received packet: {:?}", instant, socket.recv(|buffer| {
(buffer.len(), str::from_utf8(buffer).unwrap())
}));
iprintln!(
stim0,
"[{}] Received packet: {:?}",
instant,
socket.recv(|buffer| { (buffer.len(), str::from_utf8(buffer).unwrap()) })
);
}
}
// Control the "greeting" socket (:4321)
{
let mut socket = socket_set.get::<TcpSocket>(greet_handle);
if !socket.is_open() {
iprintln!(stim0,
iprintln!(
stim0,
"[{}] Listening to port 4321 for greeting, \
please connect to the port", instant);
please connect to the port",
instant
);
socket.listen(4321).unwrap();
}
if socket.can_send() {
let greeting = "Welcome to the server demo for STM32-F407!";
write!(socket, "{}\n", greeting).unwrap();
iprintln!(stim0,
"[{}] Greeting sent, socket closed", instant);
iprintln!(stim0, "[{}] Greeting sent, socket closed", instant);
socket.close();
}
}

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@ -2,41 +2,38 @@
#![no_main]
extern crate panic_itm;
use cortex_m::{iprintln, iprint};
use cortex_m::{iprint, iprintln};
use embedded_hal::{
digital::v2::OutputPin,
blocking::delay::DelayMs
};
use embedded_hal::{blocking::delay::DelayMs, digital::v2::OutputPin};
use enc424j600::EthPhy;
use stm32f4xx_hal::{
rcc::RccExt,
gpio::GpioExt,
time::U32Ext,
stm32::ITM,
delay::Delay,
spi::Spi,
time::Hertz
delay::Delay, gpio::GpioExt, rcc::RccExt, spi::Spi, stm32::ITM, time::Hertz, time::U32Ext,
};
use enc424j600;
use enc424j600::EthController;
///
use stm32f4xx_hal::{
stm32::SPI1,
gpio::{
gpioa::{PA5, PA6, PA7, PA4},
Alternate, AF5, Output, PushPull
gpioa::{PA4, PA5, PA6, PA7},
Alternate, Output, PushPull, AF5,
},
stm32::SPI1,
};
type BoosterSpiEth = enc424j600::SpiEth<
Spi<SPI1, (PA5<Alternate<AF5>>, PA6<Alternate<AF5>>, PA7<Alternate<AF5>>)>,
type SpiEth = enc424j600::Enc424j600<
Spi<
SPI1,
(
PA5<Alternate<AF5>>,
PA6<Alternate<AF5>>,
PA7<Alternate<AF5>>,
),
>,
PA4<Output<PushPull>>,
fn(u32)>;
>;
#[rtic::app(device = stm32f4xx_hal::stm32, peripherals = true, monotonic = rtic::cyccnt::CYCCNT)]
const APP: () = {
struct Resources {
spi_eth: BoosterSpiEth,
spi_eth: SpiEth,
delay: Delay,
itm: ITM,
}
@ -46,7 +43,10 @@ const APP: () = {
c.core.SCB.enable_icache();
c.core.SCB.enable_dcache(&mut c.core.CPUID);
let clocks = c.device.RCC.constrain()
let clocks = c
.device
.RCC
.constrain()
.cfgr
.sysclk(168.mhz())
.hclk(168.mhz())
@ -60,8 +60,7 @@ const APP: () = {
// Init ITM
let mut itm = c.core.ITM;
let stim0 = &mut itm.stim[0];
iprintln!(stim0,
"Eth TX Pinging on STM32-F407 via NIC100/ENC424J600");
iprintln!(stim0, "Eth TX Pinging on STM32-F407 via NIC100/ENC424J600");
// NIC100 / ENC424J600 Set-up
let spi1 = c.device.SPI1;
@ -79,19 +78,18 @@ const APP: () = {
// Create SPI1 for HAL
let mut spi_eth = {
let spi_eth_port = Spi::spi1(
spi1, (spi1_sck, spi1_miso, spi1_mosi),
spi1,
(spi1_sck, spi1_miso, spi1_mosi),
enc424j600::spi::interfaces::SPI_MODE,
Hertz(enc424j600::spi::interfaces::SPI_CLOCK_FREQ),
clocks);
clocks,
);
let delay_ns: fn(u32) -> () = |time_ns| {
cortex_m::asm::delay((time_ns*21)/125 + 1)
};
enc424j600::SpiEth::new(spi_eth_port, spi1_nss, delay_ns)
SpiEth::new(spi_eth_port, spi1_nss).cpu_freq_mhz(168)
};
// Init
match spi_eth.init_dev() {
match spi_eth.reset(&mut delay) {
Ok(_) => {
iprintln!(stim0, "Initializing Ethernet...")
}
@ -102,14 +100,14 @@ const APP: () = {
// Read MAC
let mut eth_mac_addr: [u8; 6] = [0; 6];
spi_eth.read_from_mac(&mut eth_mac_addr);
spi_eth.read_mac_addr(&mut eth_mac_addr);
for i in 0..6 {
let byte = eth_mac_addr[i];
match i {
0 => iprint!(stim0, "MAC Address = {:02x}-", byte),
1..=4 => iprint!(stim0, "{:02x}-", byte),
5 => iprint!(stim0, "{:02x}\n", byte),
_ => ()
_ => (),
};
}
@ -130,20 +128,20 @@ const APP: () = {
let stim0 = &mut c.resources.itm.stim[0];
// Testing Eth TX
let eth_tx_dat: [u8; 64] = [
0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0x08, 0x60,
0x6e, 0x44, 0x42, 0x95, 0x08, 0x06, 0x00, 0x01,
0x08, 0x00, 0x06, 0x04, 0x00, 0x01, 0x08, 0x60,
0x6e, 0x44, 0x42, 0x95, 0xc0, 0xa8, 0x01, 0x64,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0xc0, 0xa8,
0x01, 0xe7, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00, 0x69, 0xd0, 0x85, 0x9f
0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0x08, 0x60, 0x6e, 0x44, 0x42, 0x95, 0x08, 0x06,
0x00, 0x01, 0x08, 0x00, 0x06, 0x04, 0x00, 0x01, 0x08, 0x60, 0x6e, 0x44, 0x42, 0x95,
0xc0, 0xa8, 0x01, 0x64, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0xc0, 0xa8, 0x01, 0xe7,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00, 0x69, 0xd0, 0x85, 0x9f,
];
loop {
let mut eth_tx_packet = enc424j600::tx::TxPacket::new();
eth_tx_packet.update_frame(&eth_tx_dat, 64);
iprint!(stim0,
"Sending packet (len={:}): ", eth_tx_packet.get_frame_length());
iprint!(
stim0,
"Sending packet (len={:}): ",
eth_tx_packet.get_frame_length()
);
for i in 0..20 {
let byte = eth_tx_packet.get_frame_byte(i);
match i {
@ -154,10 +152,10 @@ const APP: () = {
13..=14 | 16..=18 => iprint!(stim0, "{:02x}", byte),
5 | 11 | 15 => iprint!(stim0, "{:02x} ", byte),
19 => iprint!(stim0, "{:02x} ...\n", byte),
_ => ()
_ => (),
};
}
c.resources.spi_eth.send_raw_packet(&eth_tx_packet);
c.resources.spi_eth.send_packet(&eth_tx_packet);
iprintln!(stim0, "Packet sent");
c.resources.delay.delay_ms(100_u32);
}

View File

@ -1,21 +0,0 @@
{ stdenv, fetchFromGitHub, rustPlatform, pkg-config }:
rustPlatform.buildRustPackage rec {
version = "2019-11-15";
pname = "itm-tools";
src = fetchFromGitHub {
owner = "japaric";
repo = "itm-tools";
rev = "e94155e44019d893ac8e6dab51cc282d344ab700";
sha256 = "19xkjym0i7y52cfhvis49c59nzvgw4906cd8bkz8ka38mbgfqgiy";
};
cargoPatches = [ ./itm-tools-cargo-lock.patch ];
cargoSha256 = "0is702s14pgvd5i2m8aaw3zcsshqrwj97mjgg3wikbc627pagzg7";
nativeBuildInputs = [ pkg-config ];
doCheck = false;
}

View File

@ -10,7 +10,7 @@ let
];
rustChannel =
lib.rustLib.fromManifestFile rustManifest {
inherit stdenv fetchurl patchelf;
inherit stdenv lib fetchurl patchelf;
};
rust =
rustChannel.rust.override {

View File

@ -8,8 +8,6 @@ with pkgs;
let
rustPlatform = callPackage ./nix/rustPlatform.nix {};
itm-tools = callPackage ./nix/itm-tools.nix { inherit rustPlatform; };
runHelp = writeShellScriptBin "run-help" ''
echo "[Common Tools]"
echo " run-openocd-f4x"
@ -103,7 +101,7 @@ in
stdenv.mkDerivation {
name = "enc424j600-stm32-env";
buildInputs = with rustPlatform.rust; [
rustc cargo pkgs.gdb pkgs.openocd pkgs.tmux itm-tools
rustc cargo pkgs.gdb pkgs.openocd pkgs.tmux pkgs.itm-tools
runHelp runTmuxEnv killTmuxEnv
runOpenOcdF4x runItmDemuxFollow
exTxStm32f407 exTcpStm32f407

View File

@ -2,137 +2,175 @@
pub mod spi;
use embedded_hal::{
blocking::{
spi::Transfer,
},
blocking::{delay::DelayUs, spi::Transfer},
digital::v2::OutputPin,
};
pub mod rx;
pub mod tx;
#[cfg(feature="smoltcp")]
#[cfg(feature = "smoltcp")]
pub mod smoltcp_phy;
#[cfg(feature="nal")]
pub mod nal;
/// Max raw frame array size
pub const RAW_FRAME_LENGTH_MAX: usize = 1518;
pub trait EthController {
fn init_dev(&mut self) -> Result<(), EthControllerError>;
fn init_rxbuf(&mut self) -> Result<(), EthControllerError>;
fn init_txbuf(&mut self) -> Result<(), EthControllerError>;
fn receive_next(&mut self, is_poll: bool) -> Result<rx::RxPacket, EthControllerError>;
fn send_raw_packet(&mut self, packet: &tx::TxPacket) -> Result<(), EthControllerError>;
fn set_promiscuous(&mut self) -> Result<(), EthControllerError>;
fn read_from_mac(&mut self, mac: &mut [u8]) -> Result<(), EthControllerError>;
fn write_mac_address(&mut self, mac: &[u8]) -> Result<(), EthControllerError>;
/// Trait representing PHY layer of ENC424J600
pub trait EthPhy {
fn recv_packet(&mut self, is_poll: bool) -> Result<rx::RxPacket, Error>;
fn send_packet(&mut self, packet: &tx::TxPacket) -> Result<(), Error>;
}
/// TODO: Improve these error types
#[derive(Debug)]
pub enum EthControllerError {
pub enum Error {
SpiPortError,
GeneralError,
RegisterError,
// TODO: Better name?
NoRxPacketError
NoRxPacketError,
}
impl From<spi::SpiPortError> for EthControllerError {
fn from(_: spi::SpiPortError) -> EthControllerError {
EthControllerError::SpiPortError
impl From<spi::Error> for Error {
fn from(_: spi::Error) -> Error {
Error::SpiPortError
}
}
/// Ethernet controller using SPI interface
pub struct SpiEth<SPI: Transfer<u8>,
NSS: OutputPin,
F: FnMut(u32) -> ()> {
spi_port: spi::SpiPort<SPI, NSS, F>,
/// ENC424J600 controller in SPI mode
pub struct Enc424j600<SPI: Transfer<u8>, NSS: OutputPin> {
spi_port: spi::SpiPort<SPI, NSS>,
rx_buf: rx::RxBuffer,
tx_buf: tx::TxBuffer
tx_buf: tx::TxBuffer,
}
impl <SPI: Transfer<u8>,
NSS: OutputPin,
F: FnMut(u32) -> ()> SpiEth<SPI, NSS, F> {
pub fn new(spi: SPI, nss: NSS, delay_ns: F) -> Self {
SpiEth {
spi_port: spi::SpiPort::new(spi, nss, delay_ns),
impl<SPI: Transfer<u8>, NSS: OutputPin> Enc424j600<SPI, NSS> {
pub fn new(spi: SPI, nss: NSS) -> Self {
Enc424j600 {
spi_port: spi::SpiPort::new(spi, nss),
rx_buf: rx::RxBuffer::new(),
tx_buf: tx::TxBuffer::new()
tx_buf: tx::TxBuffer::new(),
}
}
}
impl <SPI: Transfer<u8>,
NSS: OutputPin,
F: FnMut(u32) -> ()> EthController for SpiEth<SPI, NSS, F> {
fn init_dev(&mut self) -> Result<(), EthControllerError> {
#[cfg(feature = "cortex-m-cpu")]
pub fn cpu_freq_mhz(mut self, freq: u32) -> Self {
self.spi_port = self.spi_port.cpu_freq_mhz(freq);
self
}
pub fn init(&mut self, delay: &mut impl DelayUs<u16>) -> Result<(), Error> {
self.reset(delay)?;
self.init_rxbuf()?;
self.init_txbuf()?;
Ok(())
}
pub fn reset(&mut self, delay: &mut impl DelayUs<u16>) -> Result<(), Error> {
// Write 0x1234 to EUDAST
self.spi_port.write_reg_16b(spi::addrs::EUDAST, 0x1234)?;
// Verify that EUDAST is 0x1234
let mut eudast = self.spi_port.read_reg_16b(spi::addrs::EUDAST)?;
if eudast != 0x1234 {
return Err(EthControllerError::GeneralError)
return Err(Error::RegisterError);
}
// Poll CLKRDY (ESTAT<12>) to check if it is set
loop {
let estat = self.spi_port.read_reg_16b(spi::addrs::ESTAT)?;
if estat & 0x1000 == 0x1000 { break }
if estat & 0x1000 == 0x1000 {
break;
}
// Set ETHRST (ECON2<4>) to 1
let econ2 = self.spi_port.read_reg_8b(spi::addrs::ECON2)?;
self.spi_port.write_reg_8b(spi::addrs::ECON2, 0x10 | (econ2 & 0b11101111))?;
self.spi_port.delay_us(25);
}
// Issue system reset - set ETHRST (ECON2<4>) to 1
self.spi_port.send_opcode(spi::opcodes::SETETHRST)?;
delay.delay_us(25);
// Verify that EUDAST is 0x0000
eudast = self.spi_port.read_reg_16b(spi::addrs::EUDAST)?;
if eudast != 0x0000 {
return Err(EthControllerError::GeneralError)
return Err(Error::RegisterError);
}
self.spi_port.delay_us(256);
delay.delay_us(256);
Ok(())
}
fn init_rxbuf(&mut self) -> Result<(), EthControllerError> {
pub fn init_rxbuf(&mut self) -> Result<(), Error> {
// Set ERXST pointer
self.spi_port.write_reg_16b(spi::addrs::ERXST, self.rx_buf.get_wrap_addr())?;
self.spi_port
.write_reg_16b(spi::addrs::ERXST, self.rx_buf.get_start_addr())?;
// Set ERXTAIL pointer
self.spi_port.write_reg_16b(spi::addrs::ERXTAIL, self.rx_buf.get_tail_addr())?;
self.spi_port
.write_reg_16b(spi::addrs::ERXTAIL, self.rx_buf.get_tail_addr())?;
// Set MAMXFL to maximum number of bytes in each accepted packet
self.spi_port.write_reg_16b(spi::addrs::MAMXFL, RAW_FRAME_LENGTH_MAX as u16)?;
// Enable RXEN (ECON1<0>)
let econ1 = self.spi_port.read_reg_16b(spi::addrs::ECON1)?;
self.spi_port.write_reg_16b(spi::addrs::ECON1, 0x1 | (econ1 & 0xfffe))?;
self.spi_port
.write_reg_16b(spi::addrs::MAMXFL, RAW_FRAME_LENGTH_MAX as u16)?;
// Enable RX - set RXEN (ECON1<0>) to 1
self.spi_port.send_opcode(spi::opcodes::ENABLERX)?;
Ok(())
}
fn init_txbuf(&mut self) -> Result<(), EthControllerError> {
pub fn init_txbuf(&mut self) -> Result<(), Error> {
// Set EGPWRPT pointer
self.spi_port.write_reg_16b(spi::addrs::EGPWRPT, 0x0000)?;
Ok(())
}
/// Set controller to Promiscuous Mode
pub fn set_promiscuous(&mut self) -> Result<(), Error> {
// From Section 10.12, ENC424J600 Data Sheet:
// "To accept all incoming frames regardless of content (Promiscuous mode),
// set the CRCEN, RUNTEN, UCEN, NOTMEEN and MCEN bits."
let erxfcon_lo = self.spi_port.read_reg_8b(spi::addrs::ERXFCON)?;
self.spi_port.write_reg_8b(
spi::addrs::ERXFCON,
0b0101_1110 | (erxfcon_lo & 0b1010_0001),
)?;
Ok(())
}
/// Read MAC to [u8; 6]
pub fn read_mac_addr(&mut self, mac: &mut [u8]) -> Result<(), Error> {
mac[0] = self.spi_port.read_reg_8b(spi::addrs::MAADR1)?;
mac[1] = self.spi_port.read_reg_8b(spi::addrs::MAADR1 + 1)?;
mac[2] = self.spi_port.read_reg_8b(spi::addrs::MAADR2)?;
mac[3] = self.spi_port.read_reg_8b(spi::addrs::MAADR2 + 1)?;
mac[4] = self.spi_port.read_reg_8b(spi::addrs::MAADR3)?;
mac[5] = self.spi_port.read_reg_8b(spi::addrs::MAADR3 + 1)?;
Ok(())
}
pub fn write_mac_addr(&mut self, mac: &[u8]) -> Result<(), Error> {
self.spi_port.write_reg_8b(spi::addrs::MAADR1, mac[0])?;
self.spi_port.write_reg_8b(spi::addrs::MAADR1 + 1, mac[1])?;
self.spi_port.write_reg_8b(spi::addrs::MAADR2, mac[2])?;
self.spi_port.write_reg_8b(spi::addrs::MAADR2 + 1, mac[3])?;
self.spi_port.write_reg_8b(spi::addrs::MAADR3, mac[4])?;
self.spi_port.write_reg_8b(spi::addrs::MAADR3 + 1, mac[5])?;
Ok(())
}
}
impl<SPI: Transfer<u8>, NSS: OutputPin> EthPhy for Enc424j600<SPI, NSS> {
/// Receive the next packet and return it
/// Set is_poll to true for returning until PKTIF is set;
/// Set is_poll to false for returning Err when PKTIF is not set
fn receive_next(&mut self, is_poll: bool) -> Result<rx::RxPacket, EthControllerError> {
fn recv_packet(&mut self, is_poll: bool) -> Result<rx::RxPacket, Error> {
// Poll PKTIF (EIR<4>) to check if it is set
loop {
let eir = self.spi_port.read_reg_16b(spi::addrs::EIR)?;
if eir & 0x40 == 0x40 { break }
if eir & 0x40 == 0x40 {
break;
}
if !is_poll {
return Err(EthControllerError::NoRxPacketError)
return Err(Error::NoRxPacketError);
}
}
// Set ERXRDPT pointer to next_addr
self.spi_port.write_reg_16b(spi::addrs::ERXRDPT, self.rx_buf.get_next_addr())?;
self.spi_port
.write_reg_16b(spi::addrs::ERXRDPT, self.rx_buf.get_next_addr())?;
// Read 2 bytes to update next_addr
let mut next_addr_buf = [0; 3];
self.spi_port.read_rxdat(&mut next_addr_buf, 2)?;
self.rx_buf.set_next_addr((next_addr_buf[1] as u16) | ((next_addr_buf[2] as u16) << 8));
self.rx_buf
.set_next_addr((next_addr_buf[1] as u16) | ((next_addr_buf[2] as u16) << 8));
// Read 6 bytes to update rsv
let mut rsv_buf = [0; 7];
self.spi_port.read_rxdat(&mut rsv_buf, 6)?;
@ -144,78 +182,61 @@ impl <SPI: Transfer<u8>,
rx_packet.update_frame_length();
// Read frame bytes
let mut frame_buf = [0; RAW_FRAME_LENGTH_MAX];
self.spi_port.read_rxdat(&mut frame_buf, rx_packet.get_frame_length())?;
self.spi_port
.read_rxdat(&mut frame_buf, rx_packet.get_frame_length())?;
rx_packet.copy_frame_from(&frame_buf[1..]);
// Set ERXTAIL pointer to (next_addr - 2)
if self.rx_buf.get_next_addr() > rx::ERXST_DEFAULT {
self.spi_port.write_reg_16b(spi::addrs::ERXTAIL, self.rx_buf.get_next_addr() - 2)?;
// * Assume head, tail, next and wrap addresses are word-aligned (even)
// - If next_addr is at least (start_addr+2), then set tail pointer to the word right before next_addr
if self.rx_buf.get_next_addr() > self.rx_buf.get_start_addr() {
self.spi_port
.write_reg_16b(spi::addrs::ERXTAIL, self.rx_buf.get_next_addr() - 2)?;
// - Otherwise, next_addr will wrap, so set tail pointer to the last word address of RX buffer
} else {
self.spi_port.write_reg_16b(spi::addrs::ERXTAIL, rx::RX_MAX_ADDRESS - 1)?;
self.spi_port
.write_reg_16b(spi::addrs::ERXTAIL, rx::RX_MAX_ADDRESS - 1)?;
}
// Set PKTDEC (ECON1<88>) to decrement PKTCNT
let econ1_hi = self.spi_port.read_reg_8b(spi::addrs::ECON1 + 1)?;
self.spi_port.write_reg_8b(spi::addrs::ECON1 + 1, 0x01 | (econ1_hi & 0xfe))?;
// Decrement PKTCNT - set PKTDEC (ECON1<8>)
self.spi_port.send_opcode(spi::opcodes::SETPKTDEC)?;
// Return the RxPacket
Ok(rx_packet)
}
/// Send an established packet
fn send_raw_packet(&mut self, packet: &tx::TxPacket) -> Result<(), EthControllerError> {
fn send_packet(&mut self, packet: &tx::TxPacket) -> Result<(), Error> {
// Set EGPWRPT pointer to next_addr
self.spi_port.write_reg_16b(spi::addrs::EGPWRPT, self.tx_buf.get_next_addr())?;
self.spi_port
.write_reg_16b(spi::addrs::EGPWRPT, self.tx_buf.get_next_addr())?;
// Copy packet data to SRAM Buffer
// 1-byte Opcode is included
let mut txdat_buf: [u8; RAW_FRAME_LENGTH_MAX + 1] = [0; RAW_FRAME_LENGTH_MAX + 1];
packet.write_frame_to(&mut txdat_buf[1..]);
self.spi_port.write_txdat(&mut txdat_buf, packet.get_frame_length())?;
self.spi_port
.write_txdat(&mut txdat_buf, packet.get_frame_length())?;
// Set ETXST to packet start address
self.spi_port.write_reg_16b(spi::addrs::ETXST, self.tx_buf.get_next_addr())?;
self.spi_port
.write_reg_16b(spi::addrs::ETXST, self.tx_buf.get_next_addr())?;
// Set ETXLEN to packet length
self.spi_port.write_reg_16b(spi::addrs::ETXLEN, packet.get_frame_length() as u16)?;
// Set TXRTS (ECON1<1>) to start transmission
let mut econ1_lo = self.spi_port.read_reg_8b(spi::addrs::ECON1)?;
self.spi_port.write_reg_8b(spi::addrs::ECON1, 0x02 | (econ1_lo & 0xfd))?;
self.spi_port
.write_reg_16b(spi::addrs::ETXLEN, packet.get_frame_length() as u16)?;
// Send packet - set TXRTS (ECON1<1>) to start transmission
self.spi_port.send_opcode(spi::opcodes::SETTXRTS)?;
// Poll TXRTS (ECON1<1>) to check if it is reset
loop {
econ1_lo = self.spi_port.read_reg_8b(spi::addrs::ECON1)?;
if econ1_lo & 0x02 == 0 { break }
let econ1_lo = self.spi_port.read_reg_8b(spi::addrs::ECON1)?;
if econ1_lo & 0x02 == 0 {
break;
}
}
// TODO: Read ETXSTAT to understand Ethernet transmission status
// (See: Register 9-2, ENC424J600 Data Sheet)
// Update TX buffer start address
self.tx_buf.set_next_addr((self.tx_buf.get_next_addr() + packet.get_frame_length() as u16) %
tx::GPBUFEN_DEFAULT);
Ok(())
}
/// Set controller to Promiscuous Mode
fn set_promiscuous(&mut self) -> Result<(), EthControllerError> {
// From Section 10.12, ENC424J600 Data Sheet:
// "To accept all incoming frames regardless of content (Promiscuous mode),
// set the CRCEN, RUNTEN, UCEN, NOTMEEN and MCEN bits."
let erxfcon_lo = self.spi_port.read_reg_8b(spi::addrs::ERXFCON)?;
self.spi_port.write_reg_8b(spi::addrs::ERXFCON, 0b0101_1110 | (erxfcon_lo & 0b1010_0001))?;
Ok(())
}
/// Read MAC to [u8; 6]
fn read_from_mac(&mut self, mac: &mut [u8]) -> Result<(), EthControllerError> {
mac[0] = self.spi_port.read_reg_8b(spi::addrs::MAADR1)?;
mac[1] = self.spi_port.read_reg_8b(spi::addrs::MAADR1 + 1)?;
mac[2] = self.spi_port.read_reg_8b(spi::addrs::MAADR2)?;
mac[3] = self.spi_port.read_reg_8b(spi::addrs::MAADR2 + 1)?;
mac[4] = self.spi_port.read_reg_8b(spi::addrs::MAADR3)?;
mac[5] = self.spi_port.read_reg_8b(spi::addrs::MAADR3 + 1)?;
Ok(())
}
fn write_mac_address(&mut self, mac: &[u8]) -> Result<(), EthControllerError> {
self.spi_port.write_reg_8b(spi::addrs::MAADR1, mac[0])?;
self.spi_port.write_reg_8b(spi::addrs::MAADR1 + 1, mac[1])?;
self.spi_port.write_reg_8b(spi::addrs::MAADR2, mac[2])?;
self.spi_port.write_reg_8b(spi::addrs::MAADR2 + 1, mac[3])?;
self.spi_port.write_reg_8b(spi::addrs::MAADR3, mac[4])?;
self.spi_port.write_reg_8b(spi::addrs::MAADR3 + 1, mac[5])?;
// * Assume TX buffer consumes the entire general-purpose SRAM block
self.tx_buf.set_next_addr(
(self.tx_buf.get_next_addr() + packet.get_frame_length() as u16)
% self.rx_buf.get_start_addr()
- self.tx_buf.get_start_addr(),
);
Ok(())
}
}

View File

@ -1,245 +0,0 @@
use core::cell::RefCell;
use core::convert::TryFrom;
use heapless::{consts, Vec};
use embedded_nal as nal;
use nal::nb;
use smoltcp as net;
use embedded_hal::{
blocking::spi::Transfer,
digital::v2::OutputPin
};
pub use embedded_time as time;
use time::duration::*;
#[derive(Debug)]
pub enum NetworkError {
NoSocket,
ConnectionFailure,
ReadFailure,
WriteFailure,
Unsupported,
TimeFault,
}
pub type NetworkInterface<SPI, NSS> = net::iface::EthernetInterface<
'static,
crate::smoltcp_phy::SmoltcpDevice<
crate::SpiEth<SPI, NSS, fn(u32)>
>,
>;
pub struct NetworkStack<'a, SPI, NSS, IntClock>
where
SPI: 'static + Transfer<u8>,
NSS: 'static + OutputPin,
IntClock: time::Clock<T = u32>,
{
network_interface: RefCell<NetworkInterface<SPI, NSS>>,
sockets: RefCell<net::socket::SocketSet<'a>>,
next_port: RefCell<u16>,
unused_handles: RefCell<Vec<net::socket::SocketHandle, consts::U16>>,
time_ms: RefCell<u32>,
last_update_instant: RefCell<Option<time::Instant<IntClock>>>,
clock: IntClock
}
impl<'a, SPI, NSS, IntClock> NetworkStack<'a, SPI, NSS, IntClock>
where
SPI: Transfer<u8>,
NSS: OutputPin,
IntClock: time::Clock<T = u32>,
{
pub fn new(interface: NetworkInterface<SPI, NSS>, sockets: net::socket::SocketSet<'a>, clock: IntClock) -> Self {
let mut unused_handles: Vec<net::socket::SocketHandle, consts::U16> = Vec::new();
for socket in sockets.iter() {
unused_handles.push(socket.handle()).unwrap();
}
NetworkStack {
network_interface: RefCell::new(interface),
sockets: RefCell::new(sockets),
next_port: RefCell::new(49152),
unused_handles: RefCell::new(unused_handles),
time_ms: RefCell::new(0),
last_update_instant: RefCell::new(None),
clock,
}
}
// Include auto_time_update to allow Instant::now() to not be called
// Instant::now() is not safe to call in `init()` context
pub fn update(&self, auto_time_update: bool) -> Result<bool, NetworkError> {
if auto_time_update {
// Check if it is the first time the stack has updated the time itself
let now = match *self.last_update_instant.borrow() {
// If it is the first time, do not advance time
// Simply store the current instant to initiate time updating
None => self.clock.try_now().map_err(|_| NetworkError::TimeFault)?,
// If it was updated before, advance time and update last_update_instant
Some(instant) => {
// Calculate elapsed time
let now = self.clock.try_now().map_err(|_| NetworkError::TimeFault)?;
let duration = now.checked_duration_since(&instant).ok_or(NetworkError::TimeFault)?;
let duration_ms = time::duration::Milliseconds::<u32>::try_from(duration).map_err(|_| NetworkError::TimeFault)?;
// Adjust duration into ms (note: decimal point truncated)
self.advance_time(*duration_ms.integer());
now
}
};
self.last_update_instant.replace(Some(now));
}
match self.network_interface.borrow_mut().poll(
&mut self.sockets.borrow_mut(),
net::time::Instant::from_millis(*self.time_ms.borrow() as i64),
) {
Ok(changed) => Ok(!changed),
Err(_e) => {
Ok(true)
}
}
}
pub fn advance_time(&self, duration: u32) {
let time = self.time_ms.try_borrow().unwrap().wrapping_add(duration);
self.time_ms.replace(time);
}
fn get_ephemeral_port(&self) -> u16 {
// Get the next ephemeral port
let current_port = self.next_port.borrow().clone();
let (next, wrap) = self.next_port.borrow().overflowing_add(1);
*self.next_port.borrow_mut() = if wrap { 49152 } else { next };
return current_port;
}
}
impl<'a, SPI, NSS, IntClock> nal::TcpStack for NetworkStack<'a, SPI, NSS, IntClock>
where
SPI: Transfer<u8>,
NSS: OutputPin,
IntClock: time::Clock<T = u32>,
{
type TcpSocket = net::socket::SocketHandle;
type Error = NetworkError;
fn open(&self, _mode: nal::Mode) -> Result<Self::TcpSocket, Self::Error> {
match self.unused_handles.borrow_mut().pop() {
Some(handle) => {
// Abort any active connections on the handle.
let mut sockets = self.sockets.borrow_mut();
let internal_socket: &mut net::socket::TcpSocket = &mut *sockets.get(handle);
internal_socket.abort();
Ok(handle)
}
None => Err(NetworkError::NoSocket),
}
}
// Ideally connect is only to be performed in `init()` of `main.rs`
// Calling `Instant::now()` of `rtic::cyccnt` would face correctness issue during `init()`
fn connect(
&self,
socket: Self::TcpSocket,
remote: nal::SocketAddr,
) -> Result<Self::TcpSocket, Self::Error> {
let address = {
let mut sockets = self.sockets.borrow_mut();
let internal_socket: &mut net::socket::TcpSocket = &mut *sockets.get(socket);
// If we're already in the process of connecting, ignore the request silently.
if internal_socket.is_open() {
return Ok(socket);
}
match remote.ip() {
nal::IpAddr::V4(addr) => {
let address =
net::wire::Ipv4Address::from_bytes(&addr.octets()[..]);
internal_socket
.connect((address, remote.port()), self.get_ephemeral_port())
.map_err(|_| NetworkError::ConnectionFailure)?;
net::wire::IpAddress::Ipv4(address)
}
nal::IpAddr::V6(addr) => {
let address = net::wire::Ipv6Address::from_parts(&addr.segments()[..]);
internal_socket.connect((address, remote.port()), self.get_ephemeral_port())
.map_err(|_| NetworkError::ConnectionFailure)?;
net::wire::IpAddress::Ipv6(address)
}
}
};
// Blocking connect
loop {
match self.is_connected(&socket) {
Ok(true) => break,
_ => {
let mut sockets = self.sockets.borrow_mut();
let internal_socket: &mut net::socket::TcpSocket = &mut *sockets.get(socket);
// If the connect got ACK->RST, it will end up in Closed TCP state
// Perform reconnection in this case
if internal_socket.state() == net::socket::TcpState::Closed {
internal_socket.close();
internal_socket
.connect((address, remote.port()), self.get_ephemeral_port())
.map_err(|_| NetworkError::ConnectionFailure)?;
}
}
}
// Avoid using Instant::now() and Advance time manually
self.update(false)?;
{
self.advance_time(1);
}
}
Ok(socket)
}
fn is_connected(&self, socket: &Self::TcpSocket) -> Result<bool, Self::Error> {
let mut sockets = self.sockets.borrow_mut();
let socket: &mut net::socket::TcpSocket = &mut *sockets.get(*socket);
Ok(socket.may_send() && socket.may_recv())
}
fn write(&self, socket: &mut Self::TcpSocket, buffer: &[u8]) -> nb::Result<usize, Self::Error> {
let mut non_queued_bytes = &buffer[..];
while non_queued_bytes.len() != 0 {
let result = {
let mut sockets = self.sockets.borrow_mut();
let socket: &mut net::socket::TcpSocket = &mut *sockets.get(*socket);
let result = socket.send_slice(non_queued_bytes);
result
};
match result {
Ok(num_bytes) => {
// In case the buffer is filled up, push bytes into ethernet driver
if num_bytes != non_queued_bytes.len() {
self.update(true)?;
}
// Process the unwritten bytes again, if any
non_queued_bytes = &non_queued_bytes[num_bytes..]
}
Err(_) => return Err(nb::Error::Other(NetworkError::WriteFailure)),
}
}
Ok(buffer.len())
}
fn read(
&self,
socket: &mut Self::TcpSocket,
buffer: &mut [u8],
) -> nb::Result<usize, Self::Error> {
// Enqueue received bytes into the TCP socket buffer
self.update(true)?;
let mut sockets = self.sockets.borrow_mut();
let socket: &mut net::socket::TcpSocket = &mut *sockets.get(*socket);
let result = socket.recv_slice(buffer);
match result {
Ok(num_bytes) => Ok(num_bytes),
Err(_) => Err(nb::Error::Other(NetworkError::ReadFailure)),
}
}
fn close(&self, socket: Self::TcpSocket) -> Result<(), Self::Error> {
let mut sockets = self.sockets.borrow_mut();
let internal_socket: &mut net::socket::TcpSocket = &mut *sockets.get(socket);
internal_socket.close();
self.unused_handles.borrow_mut().push(socket).unwrap();
Ok(())
}
}

View File

@ -11,38 +11,38 @@ pub const RSV_LENGTH: usize = 6;
/// Struct for RX Buffer on the hardware
/// TODO: Should be a singleton
pub struct RxBuffer {
wrap_addr: u16,
start_addr: u16,
next_addr: u16,
tail_addr: u16
tail_addr: u16,
}
impl RxBuffer {
pub fn new() -> Self {
RxBuffer {
wrap_addr: ERXST_DEFAULT,
start_addr: ERXST_DEFAULT,
next_addr: ERXST_DEFAULT,
tail_addr: ERXTAIL_DEFAULT
tail_addr: ERXTAIL_DEFAULT,
}
}
pub fn set_wrap_addr(&mut self, addr: u16) {
self.wrap_addr = addr;
pub fn set_start_addr(&mut self, addr: u16) {
self.start_addr = addr;
}
pub fn get_wrap_addr(& self) -> u16{
self.wrap_addr
pub fn get_start_addr(&self) -> u16 {
self.start_addr
}
pub fn set_next_addr(&mut self, addr: u16) {
self.next_addr = addr;
}
pub fn get_next_addr(& self) -> u16{
pub fn get_next_addr(&self) -> u16 {
self.next_addr
}
pub fn set_tail_addr(&mut self, addr: u16) {
self.tail_addr = addr;
}
pub fn get_tail_addr(& self) -> u16{
pub fn get_tail_addr(&self) -> u16 {
self.tail_addr
}
}
@ -52,7 +52,7 @@ impl RxBuffer {
pub struct RxPacket {
rsv: Rsv,
frame: [u8; RAW_FRAME_LENGTH_MAX],
frame_length: usize
frame_length: usize,
}
impl RxPacket {
@ -60,7 +60,7 @@ impl RxPacket {
RxPacket {
rsv: Rsv::new(),
frame: [0; RAW_FRAME_LENGTH_MAX],
frame_length: 0
frame_length: 0,
}
}
@ -106,14 +106,14 @@ impl RxPacket {
struct Rsv {
raw_rsv: [u8; RSV_LENGTH],
// TODO: Add more definitions
frame_length: u16
frame_length: u16,
}
impl Rsv {
fn new() -> Self {
Rsv {
raw_rsv: [0; RSV_LENGTH],
frame_length: 0_u16
frame_length: 0_u16,
}
}

View File

@ -1,32 +1,30 @@
use crate::{
EthController, tx, RAW_FRAME_LENGTH_MAX
};
use crate::{tx, EthPhy, RAW_FRAME_LENGTH_MAX};
use core::cell;
use smoltcp::{
phy::{Device, DeviceCapabilities, RxToken, TxToken},
time::Instant,
Error
Error,
};
pub struct SmoltcpDevice<EC: EthController> {
pub eth_controller: cell::RefCell<EC>,
pub struct SmoltcpDevice<E: EthPhy> {
pub eth_phy: cell::RefCell<E>,
rx_packet_buf: [u8; RAW_FRAME_LENGTH_MAX],
tx_packet_buf: [u8; RAW_FRAME_LENGTH_MAX]
tx_packet_buf: [u8; RAW_FRAME_LENGTH_MAX],
}
impl<EC: EthController> SmoltcpDevice<EC> {
pub fn new(eth_controller: EC) -> Self {
impl<E: EthPhy> SmoltcpDevice<E> {
pub fn new(eth_phy: E) -> Self {
SmoltcpDevice {
eth_controller: cell::RefCell::new(eth_controller),
eth_phy: cell::RefCell::new(eth_phy),
rx_packet_buf: [0; RAW_FRAME_LENGTH_MAX],
tx_packet_buf: [0; RAW_FRAME_LENGTH_MAX]
tx_packet_buf: [0; RAW_FRAME_LENGTH_MAX],
}
}
}
impl<'a, EC: 'a + EthController> Device<'a> for SmoltcpDevice<EC> {
impl<'a, E: 'a + EthPhy> Device<'a> for SmoltcpDevice<E> {
type RxToken = EthRxToken<'a>;
type TxToken = EthTxToken<'a, EC>;
type TxToken = EthTxToken<'a, E>;
fn capabilities(&self) -> DeviceCapabilities {
let mut caps = DeviceCapabilities::default();
@ -35,33 +33,33 @@ impl<'a, EC: 'a + EthController> Device<'a> for SmoltcpDevice<EC> {
}
fn receive(&'a mut self) -> Option<(Self::RxToken, Self::TxToken)> {
let self_p = (&mut *self) as *mut SmoltcpDevice<EC>;
match self.eth_controller.borrow_mut().receive_next(false) {
let self_p = (&mut *self) as *mut SmoltcpDevice<E>;
match self.eth_phy.borrow_mut().recv_packet(false) {
Ok(rx_packet) => {
// Write received packet to RX packet buffer
rx_packet.write_frame_to(&mut self.rx_packet_buf);
// Construct a RxToken
let rx_token = EthRxToken {
buf: &mut self.rx_packet_buf,
len: rx_packet.get_frame_length()
len: rx_packet.get_frame_length(),
};
// Construct a blank TxToken
let tx_token = EthTxToken {
buf: &mut self.tx_packet_buf,
dev: self_p
dev: self_p,
};
Some((rx_token, tx_token))
},
Err(_) => None
}
Err(_) => None,
}
}
fn transmit(&'a mut self) -> Option<Self::TxToken> {
let self_p = (&mut *self) as *mut SmoltcpDevice<EC>;
let self_p = (&mut *self) as *mut SmoltcpDevice<E>;
// Construct a blank TxToken
let tx_token = EthTxToken {
buf: &mut self.tx_packet_buf,
dev: self_p
dev: self_p,
};
Some(tx_token)
}
@ -69,7 +67,7 @@ impl<'a, EC: 'a + EthController> Device<'a> for SmoltcpDevice<EC> {
pub struct EthRxToken<'a> {
buf: &'a mut [u8],
len: usize
len: usize,
}
impl<'a> RxToken for EthRxToken<'a> {
@ -81,12 +79,12 @@ impl<'a> RxToken for EthRxToken<'a> {
}
}
pub struct EthTxToken<'a, EC: EthController> {
pub struct EthTxToken<'a, E: EthPhy> {
buf: &'a mut [u8],
dev: *mut SmoltcpDevice<EC>
dev: *mut SmoltcpDevice<E>,
}
impl<'a, EC: 'a + EthController> TxToken for EthTxToken<'a, EC> {
impl<'a, E: 'a + EthPhy> TxToken for EthTxToken<'a, E> {
fn consume<R, F>(self, _timestamp: Instant, len: usize, f: F) -> Result<R, Error>
where
F: FnOnce(&mut [u8]) -> Result<R, Error>,
@ -97,12 +95,10 @@ impl<'a, EC: 'a + EthController> TxToken for EthTxToken<'a, EC> {
// Update frame length and write frame bytes
tx_packet.update_frame(&mut self.buf[..len], len);
// Send the packet as raw
let eth_controller = unsafe {
&mut (*self.dev).eth_controller
};
match eth_controller.borrow_mut().send_raw_packet(&tx_packet) {
Ok(_) => { result },
Err(_) => Err(Error::Exhausted)
let eth_phy = unsafe { &mut (*self.dev).eth_phy };
match eth_phy.borrow_mut().send_packet(&tx_packet) {
Ok(_) => result,
Err(_) => Err(Error::Exhausted),
}
}
}

View File

@ -1,7 +1,4 @@
use embedded_hal::{
blocking::spi::Transfer,
digital::v2::OutputPin,
};
use embedded_hal::{blocking::spi::Transfer, digital::v2::OutputPin};
pub mod interfaces {
use embedded_hal::spi;
@ -15,11 +12,21 @@ pub mod interfaces {
}
pub mod opcodes {
/// SPI Opcodes
/// 1-byte Instructions
pub const SETETHRST: u8 = 0b1100_1010;
pub const SETPKTDEC: u8 = 0b1100_1100;
pub const SETTXRTS: u8 = 0b1101_0100;
pub const ENABLERX: u8 = 0b1110_1000;
/// 3-byte Instructions
pub const WRXRDPT: u8 = 0b0110_0100; // 8-bit opcode followed by data
pub const RRXRDPT: u8 = 0b0110_0110; // 8-bit opcode followed by data
pub const WGPWRPT: u8 = 0b0110_1100; // 8-bit opcode followed by data
pub const RGPWRPT: u8 = 0b0110_1110; // 8-bit opcode followed by data
/// N-byte Instructions
pub const RCRU: u8 = 0b0010_0000;
pub const WCRU: u8 = 0b0010_0010;
pub const RERXDATA: u8 = 0b0010_1100; // 8-bit opcode followed by data
pub const WEGPDATA: u8 = 0b0010_1010; // 8-bit opcode followed by data
pub const RRXDATA: u8 = 0b0010_1100; // 8-bit opcode followed by data
pub const WGPDATA: u8 = 0b0010_1010; // 8-bit opcode followed by data
}
pub mod addrs {
@ -51,157 +58,160 @@ pub mod addrs {
/// Struct for SPI I/O interface on ENC424J600
/// Note: stm32f4xx_hal::spi's pins include: SCK, MISO, MOSI
pub struct SpiPort<SPI: Transfer<u8>,
NSS: OutputPin,
F: FnMut(u32) -> ()> {
pub struct SpiPort<SPI: Transfer<u8>, NSS: OutputPin> {
spi: SPI,
nss: NSS,
delay_ns: F,
#[cfg(feature = "cortex-m-cpu")]
cpu_freq_mhz: f32,
}
pub enum SpiPortError {
TransferError
pub enum Error {
OpcodeError,
TransferError,
}
#[allow(unused_must_use)]
impl <SPI: Transfer<u8>,
NSS: OutputPin,
F: FnMut(u32) -> ()> SpiPort<SPI, NSS, F> {
impl<SPI: Transfer<u8>, NSS: OutputPin> SpiPort<SPI, NSS> {
// TODO: return as Result()
pub fn new(spi: SPI, mut nss: NSS, delay_ns: F) -> Self {
pub fn new(spi: SPI, mut nss: NSS) -> Self {
nss.set_high();
SpiPort {
spi,
nss,
delay_ns,
#[cfg(feature = "cortex-m-cpu")]
cpu_freq_mhz: 0.,
}
}
pub fn read_reg_8b(&mut self, addr: u8) -> Result<u8, SpiPortError> {
#[cfg(feature = "cortex-m-cpu")]
pub fn cpu_freq_mhz(mut self, freq: u32) -> Self {
self.cpu_freq_mhz = freq as f32;
self
}
pub fn read_reg_8b(&mut self, addr: u8) -> Result<u8, Error> {
// Using RCRU instruction to read using unbanked (full) address
let r_data = self.rw_addr_u8(opcodes::RCRU, addr, 0)?;
Ok(r_data)
let mut buf: [u8; 4] = [0; 4];
buf[1] = addr;
self.rw_n(&mut buf, opcodes::RCRU, 2)?;
Ok(buf[2])
}
pub fn read_reg_16b(&mut self, lo_addr: u8) -> Result<u16, SpiPortError> {
let r_data_lo = self.read_reg_8b(lo_addr)?;
let r_data_hi = self.read_reg_8b(lo_addr + 1)?;
// Combine top and bottom 8-bit to return 16-bit
Ok(((r_data_hi as u16) << 8) | r_data_lo as u16)
pub fn read_reg_16b(&mut self, lo_addr: u8) -> Result<u16, Error> {
// Unless the register can be written with specific opcode,
// use WCRU instruction to write using unbanked (full) address
let mut buf: [u8; 4] = [0; 4];
let mut data_offset = 0; // number of bytes separating
// actual data from opcode
match lo_addr {
addrs::ERXRDPT | addrs::EGPWRPT => {}
_ => {
buf[1] = lo_addr;
data_offset = 1;
}
}
self.rw_n(
&mut buf,
match lo_addr {
addrs::ERXRDPT => opcodes::RRXRDPT,
addrs::EGPWRPT => opcodes::RGPWRPT,
_ => opcodes::RCRU,
},
2 + data_offset, // extra 8-bit lo_addr before data
)?;
Ok(buf[data_offset + 1] as u16 | (buf[data_offset + 2] as u16) << 8)
}
// Currently requires manual slicing (buf[1..]) for the data read back
pub fn read_rxdat<'a>(&mut self, buf: &'a mut [u8], data_length: usize)
-> Result<(), SpiPortError> {
let r_valid = self.r_n(buf, opcodes::RERXDATA, data_length)?;
Ok(r_valid)
pub fn read_rxdat<'a>(&mut self, buf: &'a mut [u8], data_length: usize) -> Result<(), Error> {
self.rw_n(buf, opcodes::RRXDATA, data_length)
}
// Currenly requires actual data to be stored in buf[1..] instead of buf[0..]
// Currently requires actual data to be stored in buf[1..] instead of buf[0..]
// TODO: Maybe better naming?
pub fn write_txdat<'a>(&mut self, buf: &'a mut [u8], data_length: usize)
-> Result<(), SpiPortError> {
let w_valid = self.w_n(buf, opcodes::WEGPDATA, data_length)?;
Ok(w_valid)
pub fn write_txdat<'a>(&mut self, buf: &'a mut [u8], data_length: usize) -> Result<(), Error> {
self.rw_n(buf, opcodes::WGPDATA, data_length)
}
pub fn write_reg_8b(&mut self, addr: u8, data: u8) -> Result<(), SpiPortError> {
// TODO: addr should be separated from w_data
pub fn write_reg_8b(&mut self, addr: u8, data: u8) -> Result<(), Error> {
// Using WCRU instruction to write using unbanked (full) address
self.rw_addr_u8(opcodes::WCRU, addr, data)?;
Ok(())
}
pub fn write_reg_16b(&mut self, lo_addr: u8, data: u16) -> Result<(), SpiPortError> {
self.write_reg_8b(lo_addr, (data & 0xff) as u8)?;
self.write_reg_8b(lo_addr + 1, ((data & 0xff00) >> 8) as u8)?;
Ok(())
}
pub fn delay_us(&mut self, duration: u32) {
(self.delay_ns)(duration * 1000)
}
// TODO: Generalise transfer functions
// TODO: (Make data read/write as reference to array)
// Currently requires 1-byte addr, read/write data is only 1-byte
fn rw_addr_u8(&mut self, opcode: u8, addr: u8, data: u8)
-> Result<u8, SpiPortError> {
// Enable chip select
self.nss.set_low();
// Start writing to SLAVE
// TODO: don't just use 3 bytes
let mut buf: [u8; 3] = [0; 3];
buf[0] = opcode;
buf[1] = addr;
buf[2] = data;
match self.spi.transfer(&mut buf) {
Ok(_) => {
// Disable chip select
(self.delay_ns)(60);
self.nss.set_high();
(self.delay_ns)(30);
Ok(buf[2])
},
// TODO: Maybe too naive?
Err(_) => {
// Disable chip select
(self.delay_ns)(60);
self.nss.set_high();
(self.delay_ns)(30);
Err(SpiPortError::TransferError)
self.rw_n(&mut buf, opcodes::WCRU, 2)
}
pub fn write_reg_16b(&mut self, lo_addr: u8, data: u16) -> Result<(), Error> {
// Unless the register can be written with specific opcode,
// use WCRU instruction to write using unbanked (full) address
let mut buf: [u8; 4] = [0; 4];
let mut data_offset = 0; // number of bytes separating
// actual data from opcode
match lo_addr {
addrs::ERXRDPT | addrs::EGPWRPT => {}
_ => {
buf[1] = lo_addr;
data_offset = 1;
}
}
buf[1 + data_offset] = data as u8;
buf[2 + data_offset] = (data >> 8) as u8;
self.rw_n(
&mut buf,
match lo_addr {
addrs::ERXRDPT => opcodes::WRXRDPT,
addrs::EGPWRPT => opcodes::WGPWRPT,
_ => opcodes::WCRU,
},
2 + data_offset, // extra 8-bit lo_addr before data
)
}
pub fn send_opcode(&mut self, opcode: u8) -> Result<(), Error> {
match opcode {
opcodes::SETETHRST | opcodes::SETPKTDEC | opcodes::SETTXRTS | opcodes::ENABLERX => {
let mut buf: [u8; 1] = [0];
self.rw_n(&mut buf, opcode, 0)
}
_ => Err(Error::OpcodeError),
}
}
// TODO: Generalise transfer functions
// Currently does NOT accept addr, read data is N-byte long
// Returns a reference to the data returned
// Note: buf must be at least (data_length + 1)-byte long
// TODO: Check and raise error for array size < (data_length + 1)
fn r_n<'a>(&mut self, buf: &'a mut [u8], opcode: u8, data_length: usize)
-> Result<(), SpiPortError> {
// Enable chip select
self.nss.set_low();
// Start writing to SLAVE
buf[0] = opcode;
match self.spi.transfer(&mut buf[..data_length+1]) {
Ok(_) => {
// Disable chip select
self.nss.set_high();
Ok(())
},
// TODO: Maybe too naive?
Err(_) => {
// Disable chip select
self.nss.set_high();
Err(SpiPortError::TransferError)
}
}
}
// Note: buf[0] is currently reserved for opcode to overwrite
// TODO: Actual data should start from buf[0], not buf[1]
fn w_n<'a>(&mut self, buf: &'a mut [u8], opcode: u8, data_length: usize)
-> Result<(), SpiPortError> {
// Completes an SPI transfer for reading data to the given buffer,
// or writing data from the buffer.
// It sends an 8-bit instruction, followed by either
// receiving or sending n*8-bit data.
// The slice of buffer provided must begin with the 8-bit instruction.
// If n = 0, the transfer will only involve sending the instruction.
fn rw_n<'a>(&mut self, buf: &'a mut [u8], opcode: u8, data_length: usize) -> Result<(), Error> {
assert!(buf.len() > data_length);
// Enable chip select
self.nss.set_low();
// >=50ns min. CS_n setup time
#[cfg(feature = "cortex-m-cpu")]
cortex_m::asm::delay((0.05 * (self.cpu_freq_mhz + 1.)) as u32);
// Start writing to SLAVE
buf[0] = opcode;
// TODO: Maybe need to copy data to buf later on
match self.spi.transfer(&mut buf[..data_length+1]) {
Ok(_) => {
let result = self.spi.transfer(&mut buf[..data_length + 1]);
match opcode {
opcodes::RCRU | opcodes::WCRU | opcodes::RRXDATA | opcodes::WGPDATA => {
// Disable chip select
// >=50ns min. CS_n hold time
#[cfg(feature = "cortex-m-cpu")]
cortex_m::asm::delay((0.05 * (self.cpu_freq_mhz + 1.)) as u32);
self.nss.set_high();
Ok(())
},
// TODO: Maybe too naive?
Err(_) => {
// Disable chip select
self.nss.set_high();
Err(SpiPortError::TransferError)
// >=20ns min. CS_n disable time
#[cfg(feature = "cortex-m-cpu")]
cortex_m::asm::delay((0.02 * (self.cpu_freq_mhz + 1.)) as u32);
}
_ => {}
}
match result {
Ok(_) => Ok(()),
// TODO: Maybe too naive?
Err(_) => Err(Error::TransferError),
}
}
}

View File

@ -1,45 +1,41 @@
use crate::RAW_FRAME_LENGTH_MAX;
/// SRAM Addresses
pub const GPBUFST_DEFAULT: u16 = 0x0000; // Start of General-Purpose SRAM Buffer
pub const GPBUFEN_DEFAULT: u16 = 0x5340; // End of General-Purpose SRAM Buffer == ERXST default
/// Struct for TX Buffer on the hardware
/// TODO: Should be a singleton
pub struct TxBuffer {
wrap_addr: u16,
start_addr: u16,
// The following two fields are controlled by firmware
next_addr: u16,
tail_addr: u16
tail_addr: u16,
}
impl TxBuffer {
pub fn new() -> Self {
TxBuffer {
wrap_addr: GPBUFST_DEFAULT,
next_addr: GPBUFST_DEFAULT + 1,
tail_addr: GPBUFST_DEFAULT
start_addr: 0x0000,
next_addr: 0x0001,
tail_addr: 0x0000,
}
}
pub fn set_wrap_addr(&mut self, addr: u16) {
self.wrap_addr = addr;
pub fn set_start_addr(&mut self, addr: u16) {
self.start_addr = addr;
}
pub fn get_wrap_addr(& self) -> u16{
self.wrap_addr
pub fn get_start_addr(&self) -> u16 {
self.start_addr
}
pub fn set_next_addr(&mut self, addr: u16) {
self.next_addr = addr;
}
pub fn get_next_addr(& self) -> u16{
pub fn get_next_addr(&self) -> u16 {
self.next_addr
}
pub fn set_tail_addr(&mut self, addr: u16) {
self.tail_addr = addr;
}
pub fn get_tail_addr(& self) -> u16{
pub fn get_tail_addr(&self) -> u16 {
self.tail_addr
}
}
@ -48,14 +44,14 @@ impl TxBuffer {
/// TODO: Generalise MAC addresses
pub struct TxPacket {
frame: [u8; RAW_FRAME_LENGTH_MAX],
frame_length: usize
frame_length: usize,
}
impl TxPacket {
pub fn new() -> Self {
TxPacket {
frame: [0; RAW_FRAME_LENGTH_MAX],
frame_length: 0
frame_length: 0,
}
}