Merge branch 'master' into feature/livestream

2021-06-09 12:46:56 +02:00 · 2021-06-09 12:46:56 +02:00 · e01d430e8e
parent 14bfbbe2a1 b0052128e0
commit e01d430e8e
30 changed files with 562 additions and 620 deletions
--- a/Cargo.lock
+++ b/Cargo.lock
@ -63,7 +63,7 @@ version = "0.2.5"
 source = "registry+https://github.com/rust-lang/crates.io-index"
 checksum = "5deb64efa5bd81e31fcd1938615a6d98c82eafcbcd787162b6f63b91d6bac5b3"
 dependencies = [
- "rustc_version",
+ "rustc_version 0.2.3",
 ]
 [[package]]
@ -104,11 +104,11 @@ checksum = "14c189c53d098945499cdfa7ecc63567cf3886b3332b312a5b4585d8d3a6a610"
 [[package]]
 name = "cast"
-version = "0.2.3"
+version = "0.2.6"
 source = "registry+https://github.com/rust-lang/crates.io-index"
-checksum = "4b9434b9a5aa1450faa3f9cb14ea0e8c53bb5d2b3c1bfd1ab4fc03e9f33fbfb0"
+checksum = "57cdfa5d50aad6cb4d44dcab6101a7f79925bd59d82ca42f38a9856a28865374"
 dependencies = [
- "rustc_version",
+ "rustc_version 0.3.3",
 ]
 [[package]]
@ -214,7 +214,7 @@ dependencies = [
 "easybench",
 "miniconf",
 "ndarray",
- "num",
+ "num-complex",
 "rand",
 "serde",
 ]
@ -305,9 +305,9 @@ dependencies = [
 [[package]]
 name = "getrandom"
-version = "0.2.2"
+version = "0.2.3"
 source = "registry+https://github.com/rust-lang/crates.io-index"
-checksum = "c9495705279e7140bf035dde1f6e750c162df8b625267cd52cc44e0b156732c8"
+checksum = "7fcd999463524c52659517fe2cea98493cfe485d10565e7b0fb07dbba7ad2753"
 dependencies = [
 "cfg-if",
 "libc",
@ -374,9 +374,9 @@ dependencies = [
 [[package]]
 name = "libc"
-version = "0.2.93"
+version = "0.2.95"
 source = "registry+https://github.com/rust-lang/crates.io-index"
-checksum = "9385f66bf6105b241aa65a61cb923ef20efc665cb9f9bb50ac2f0c4b7f378d41"
+checksum = "789da6d93f1b866ffe175afc5322a4d76c038605a1c3319bb57b06967ca98a36"
 [[package]]
 name = "log"
@ -395,17 +395,18 @@ checksum = "c75de51135344a4f8ed3cfe2720dc27736f7711989703a0b43aadf3753c55577"
 [[package]]
 name = "matrixmultiply"
-version = "0.3.0"
+version = "0.3.1"
 source = "registry+https://github.com/rust-lang/crates.io-index"
-checksum = "1300bdbea33ec2836b01ff1f5a6eed8bad66d0c31f94d9b7993407a8b054c3a1"
+checksum = "5a8a15b776d9dfaecd44b03c5828c2199cddff5247215858aac14624f8d6b741"
 dependencies = [
 "rawpointer",
 ]
 [[package]]
 name = "mcp23017"
-version = "0.1.1"
+version = "1.0.0"
-source = "git+https://github.com/lucazulian/mcp23017.git?rev=523d71d#523d71dcb11fc0ea4bd9385ef2527ae7a7eee987"
+source = "registry+https://github.com/rust-lang/crates.io-index"
 checksum = "2c32fd6627e73f1cfa95c00ddcdcb5a6a6ddbd10b308d08588a502c018b6e12c"
 dependencies = [
 "embedded-hal",
 ]
@ -471,19 +472,6 @@ version = "0.5.0"
 source = "registry+https://github.com/rust-lang/crates.io-index"
 checksum = "1bcece43b12349917e096cddfa66107277f123e6c96a5aea78711dc601a47152"
 [[package]]
 name = "num"
 version = "0.4.0"
 source = "registry+https://github.com/rust-lang/crates.io-index"
 checksum = "43db66d1170d347f9a065114077f7dccb00c1b9478c89384490a3425279a4606"
 dependencies = [
 "num-complex",
 "num-integer",
 "num-iter",
 "num-rational",
 "num-traits",
 ]
 [[package]]
 name = "num-complex"
 version = "0.4.0"
@ -491,6 +479,7 @@ source = "registry+https://github.com/rust-lang/crates.io-index"
 checksum = "26873667bbbb7c5182d4a37c1add32cdf09f841af72da53318fdb81543c15085"
 dependencies = [
 "num-traits",
 "serde",
 ]
 [[package]]
@ -503,28 +492,6 @@ dependencies = [
 "num-traits",
 ]
 [[package]]
 name = "num-iter"
 version = "0.1.42"
 source = "registry+https://github.com/rust-lang/crates.io-index"
 checksum = "b2021c8337a54d21aca0d59a92577a029af9431cb59b909b03252b9c164fad59"
 dependencies = [
 "autocfg",
 "num-integer",
 "num-traits",
 ]
 [[package]]
 name = "num-rational"
 version = "0.4.0"
 source = "registry+https://github.com/rust-lang/crates.io-index"
 checksum = "d41702bd167c2df5520b384281bc111a4b5efcf7fbc4c9c222c815b07e0a6a6a"
 dependencies = [
 "autocfg",
 "num-integer",
 "num-traits",
 ]
 [[package]]
 name = "num-traits"
 version = "0.2.14"
@ -561,6 +528,15 @@ version = "1.0.5"
 source = "registry+https://github.com/rust-lang/crates.io-index"
 checksum = "acbf547ad0c65e31259204bd90935776d1c693cec2f4ff7abb7a1bbbd40dfe58"
 [[package]]
 name = "pest"
 version = "2.1.3"
 source = "registry+https://github.com/rust-lang/crates.io-index"
 checksum = "10f4872ae94d7b90ae48754df22fd42ad52ce740b8f370b03da4835417403e53"
 dependencies = [
 "ucd-trie",
 ]
 [[package]]
 name = "ppv-lite86"
 version = "0.2.10"
@ -569,9 +545,9 @@ checksum = "ac74c624d6b2d21f425f752262f42188365d7b8ff1aff74c82e45136510a4857"
 [[package]]
 name = "proc-macro2"
-version = "1.0.26"
+version = "1.0.27"
 source = "registry+https://github.com/rust-lang/crates.io-index"
-checksum = "a152013215dca273577e18d2bf00fa862b89b24169fb78c4c95aeb07992c9cec"
+checksum = "f0d8caf72986c1a598726adc988bb5984792ef84f5ee5aa50209145ee8077038"
 dependencies = [
 "unicode-xid",
 ]
@ -673,7 +649,16 @@ version = "0.2.3"
 source = "registry+https://github.com/rust-lang/crates.io-index"
 checksum = "138e3e0acb6c9fb258b19b67cb8abd63c00679d2851805ea151465464fe9030a"
 dependencies = [
- "semver",
+ "semver 0.9.0",
 ]
 [[package]]
 name = "rustc_version"
 version = "0.3.3"
 source = "registry+https://github.com/rust-lang/crates.io-index"
 checksum = "f0dfe2087c51c460008730de8b57e6a320782fbfb312e1f4d520e6c6fae155ee"
 dependencies = [
 "semver 0.11.0",
 ]
 [[package]]
@ -688,7 +673,16 @@ version = "0.9.0"
 source = "registry+https://github.com/rust-lang/crates.io-index"
 checksum = "1d7eb9ef2c18661902cc47e535f9bc51b78acd254da71d375c2f6720d9a40403"
 dependencies = [
- "semver-parser",
+ "semver-parser 0.7.0",
 ]
 [[package]]
 name = "semver"
 version = "0.11.0"
 source = "registry+https://github.com/rust-lang/crates.io-index"
 checksum = "f301af10236f6df4160f7c3f04eec6dbc70ace82d23326abad5edee88801c6b6"
 dependencies = [
 "semver-parser 0.10.2",
 ]
 [[package]]
@ -697,6 +691,15 @@ version = "0.7.0"
 source = "registry+https://github.com/rust-lang/crates.io-index"
 checksum = "388a1df253eca08550bef6c72392cfe7c30914bf41df5269b68cbd6ff8f570a3"
 [[package]]
 name = "semver-parser"
 version = "0.10.2"
 source = "registry+https://github.com/rust-lang/crates.io-index"
 checksum = "00b0bef5b7f9e0df16536d3961cfb6e84331c065b4066afb39768d0e319411f7"
 dependencies = [
 "pest",
 ]
 [[package]]
 name = "serde"
 version = "1.0.126"
@ -740,9 +743,9 @@ dependencies = [
 [[package]]
 name = "smoltcp"
-version = "0.7.1"
+version = "0.7.3"
 source = "registry+https://github.com/rust-lang/crates.io-index"
-checksum = "97173c1ef35b0a09304cb3882eba594761243005847cbbf6124f966e8da6519a"
+checksum = "11b5647cc4676e9358e6b15b6536b34e5b413e5ae946a06b3f85e713132bcdfa"
 dependencies = [
 "bitflags",
 "byteorder",
@ -809,8 +812,7 @@ dependencies = [
 [[package]]
 name = "stm32h7xx-hal"
 version = "0.9.0"
-source = "registry+https://github.com/rust-lang/crates.io-index"
+source = "git+https://github.com/quartiq/stm32h7xx-hal.git?rev=b0b8a93#b0b8a930b2c3bc5fcebc2e905b4c5e13360111a5"
 checksum = "67034b80041bc33a48df1c1c435b6ae3bb18c35e42aa7e702ce8363b96793398"
 dependencies = [
 "bare-metal 1.0.0",
 "cast",
@ -827,9 +829,9 @@ dependencies = [
 [[package]]
 name = "syn"
-version = "1.0.68"
+version = "1.0.72"
 source = "registry+https://github.com/rust-lang/crates.io-index"
-checksum = "3ce15dd3ed8aa2f8eeac4716d6ef5ab58b6b9256db41d7e1a0224c2788e8fd87"
+checksum = "a1e8cdbefb79a9a5a65e0db8b47b723ee907b7c7f8496c76a1770b5c310bab82"
 dependencies = [
 "proc-macro2",
 "quote",
@ -842,6 +844,12 @@ version = "1.13.0"
 source = "registry+https://github.com/rust-lang/crates.io-index"
 checksum = "879f6906492a7cd215bfa4cf595b600146ccfac0c79bcbd1f3000162af5e8b06"
 [[package]]
 name = "ucd-trie"
 version = "0.1.3"
 source = "registry+https://github.com/rust-lang/crates.io-index"
 checksum = "56dee185309b50d1f11bfedef0fe6d036842e3fb77413abef29f8f8d1c5d4c1c"
 [[package]]
 name = "ufmt-write"
 version = "0.1.0"
@ -850,9 +858,9 @@ checksum = "e87a2ed6b42ec5e28cc3b94c09982969e9227600b2e3dcbc1db927a84c06bd69"
 [[package]]
 name = "unicode-xid"
-version = "0.2.1"
+version = "0.2.2"
 source = "registry+https://github.com/rust-lang/crates.io-index"
-checksum = "f7fe0bb3479651439c9112f72b6c505038574c9fbb575ed1bf3b797fa39dd564"
+checksum = "8ccb82d61f80a663efe1f787a51b16b5a51e3314d6ac365b08639f52387b33f3"
 [[package]]
 name = "vcell"
--- a/Cargo.toml
+++ b/Cargo.toml
@ -45,20 +45,19 @@ ad9959 = { path = "ad9959" }
 miniconf = "0.1.0"
 shared-bus = {version = "0.2.2", features = ["cortex-m"] }
 serde-json-core = "0.4"
 mcp23017 = "1.0"
 # rtt-target bump
 [dependencies.rtt-logger]
 git = "https://github.com/quartiq/rtt-logger.git"
 rev = "70b0eb5"
-# rewrite
+# fast double buffered DMA without poisoning and buffer swapping
 [dependencies.mcp23017]
 git = "https://github.com/lucazulian/mcp23017.git"
 rev = "523d71d"
 [dependencies.stm32h7xx-hal]
 features = ["stm32h743v", "rt", "unproven", "ethernet", "quadspi"]
-version = "0.9.0"
+# version = "0.9.0"
 git = "https://github.com/quartiq/stm32h7xx-hal.git"
 rev = "b0b8a93"
 # link.x section start/end
 [patch.crates-io.cortex-m-rt]
--- a/ad9959/src/lib.rs
+++ b/ad9959/src/lib.rs
@ -43,6 +43,7 @@ pub enum Mode {
 /// The configuration registers within the AD9959 DDS device. The values of each register are
 /// equivalent to the address.
 #[allow(clippy::upper_case_acronyms)]
 pub enum Register {
    CSR = 0x00,
    FR1 = 0x01,
@ -596,6 +597,22 @@ impl ProfileSerializer {
        self.index += value.len() + 1;
    }
    fn pad(&mut self) {
        // Pad the buffer to 32-bit (4 byte) alignment by adding dummy writes to CSR and LSRR.
        match self.index & 3 {
            3 => {
                // For a level of 3, we have to pad with 5 bytes to align things.
                self.add_write(Register::CSR, &[(self.mode as u8) << 1]);
                self.add_write(Register::LSRR, &[0, 0]);
            }
            2 => self.add_write(Register::CSR, &[(self.mode as u8) << 1]),
            1 => self.add_write(Register::LSRR, &[0, 0]),
            0 => {}
            _ => unreachable!(),
        }
    }
    /// Get the serialized profile as a slice of 32-bit words.
    ///
    /// # Note
@ -604,21 +621,8 @@ impl ProfileSerializer {
    ///
    /// # Returns
    /// A slice of `u32` words representing the serialized profile.
-    pub fn finalize<'a>(&'a mut self) -> &[u32] {
+    pub fn finalize<'a>(&'a mut self) -> &'a [u32] {
-        // Pad the buffer to 32-bit alignment by adding dummy writes to CSR and LSRR.
+        self.pad();
        let padding = 4 - (self.index % 4);
        match padding {
            1 => {
                // For a pad size of 1, we have to pad with 5 bytes to align things.
                self.add_write(Register::CSR, &[(self.mode as u8) << 1]);
                self.add_write(Register::LSRR, &[0, 0]);
            }
            2 => self.add_write(Register::CSR, &[(self.mode as u8) << 1]),
            3 => self.add_write(Register::LSRR, &[0, 0]),
            4 => {}
            _ => unreachable!(),
        }
        unsafe {
            core::slice::from_raw_parts::<'a, u32>(
                &self.data as *const _ as *const u32,
--- a/dsp/Cargo.toml
+++ b/dsp/Cargo.toml
@ -6,7 +6,7 @@ edition = "2018"
 [dependencies]
 serde = { version = "1.0", features = ["derive"], default-features = false }
-num = { version = "0.4.0", default-features = false }
+num-complex = { version = "0.4.0", features = ["serde"], default-features = false }
 miniconf = "0.1"
 [dev-dependencies]
--- a/dsp/benches/micro.rs
+++ b/dsp/benches/micro.rs
@ -44,11 +44,11 @@ fn pll_bench() {
    let mut dut = PLL::default();
    println!(
        "PLL::update(t, 12, 12): {}",
-        bench_env(0x241, |x| dut.update(*x, 12, 12))
+        bench_env(Some(0x241), |x| dut.update(*x, 12, 12))
    );
    println!(
        "PLL::update(t, sf, sp): {}",
-        bench_env((0x241, 21, 20), |(x, p, q)| dut.update(*x, *p, *q))
+        bench_env((Some(0x241), 21, 20), |(x, p, q)| dut.update(*x, *p, *q))
    );
 }
--- a/dsp/src/atan2.rs
+++ b/dsp/src/atan2.rs
@ -77,6 +77,8 @@ pub fn atan2(y: i32, x: i32) -> i32 {
    if sign.1 {
        angle = angle.wrapping_neg();
        // Negation ends up in slightly faster assembly
        // angle = !angle;
    }
    angle
--- a/dsp/src/complex.rs
+++ b/dsp/src/complex.rs
@ -1,4 +1,4 @@
-pub use num::Complex;
+pub use num_complex::Complex;
 use super::{atan2, cossin};
--- a/dsp/src/pll.rs
+++ b/dsp/src/pll.rs
@ -45,7 +45,7 @@ impl PLL {
    /// The signal's phase/frequency is reconstructed relative to the sampling period.
    ///
    /// Args:
-    /// * `x`: New input phase sample.
+    /// * `x`: New input phase sample or None if a sample has been missed.
    /// * `shift_frequency`: Frequency error scaling. The frequency gain per update is
    ///   `1/(1 << shift_frequency)`.
    /// * `shift_phase`: Phase error scaling. The phase gain is `1/(1 << shift_phase)`
@ -55,12 +55,13 @@ impl PLL {
    /// A tuple of instantaneous phase and frequency (the current phase increment).
    pub fn update(
        &mut self,
-        x: i32,
+        x: Option<i32>,
        shift_frequency: u8,
        shift_phase: u8,
    ) -> (i32, i32) {
        debug_assert!((1..=30).contains(&shift_frequency));
        debug_assert!((1..=30).contains(&shift_phase));
        let f = if let Some(x) = x {
            let e = x.wrapping_sub(self.f);
            self.f = self.f.wrapping_add(
                (1i32 << (shift_frequency - 1))
@ -69,12 +70,16 @@ impl PLL {
                    >> shift_frequency,
            );
            self.x = x;
-        let f = self.f.wrapping_add(
+            self.f.wrapping_add(
                (1i32 << (shift_phase - 1))
                    .wrapping_add(e)
                    .wrapping_sub(self.y)
                    >> shift_phase,
-        );
+            )
        } else {
            self.x = self.x.wrapping_add(self.f);
            self.f
        };
        self.y = self.y.wrapping_add(f);
        (self.y, f)
    }
@ -86,7 +91,7 @@ mod tests {
    #[test]
    fn mini() {
        let mut p = PLL::default();
-        let (y, f) = p.update(0x10000, 8, 4);
+        let (y, f) = p.update(Some(0x10000), 8, 4);
        assert_eq!(y, 0x1100);
        assert_eq!(f, y);
    }
@ -100,7 +105,7 @@ mod tests {
        let mut x = 0i32;
        for i in 0..n {
            x = x.wrapping_add(f0);
-            let (y, f) = p.update(x, shift.0, shift.1);
+            let (y, f) = p.update(Some(x), shift.0, shift.1);
            if i > n / 4 {
                assert_eq!(f.wrapping_sub(f0).abs() <= 1, true);
            }
--- a/dsp/src/tools.rs
+++ b/dsp/src/tools.rs
@ -87,20 +87,3 @@ pub fn macc_i32(y0: i32, x: &[i32], a: &[i32], shift: u32) -> i32 {
        .fold(y0, |y, xa| y + xa);
    (y >> shift) as i32
 }
 /// Combine high and low i32 into a single downscaled i32, saturating the type.
 pub fn saturating_scale(lo: i32, hi: i32, shift: u32) -> i32 {
    debug_assert!(shift & 31 == shift);
    let shift_hi = 31 - shift;
    debug_assert!(shift_hi & 31 == shift_hi);
    let over = hi >> shift;
    if over < -1 {
        i32::MIN
    } else if over > 0 {
        i32::MAX
    } else {
        (lo >> shift) + (hi << shift_hi)
    }
 }
--- a/dsp/src/unwrap.rs
+++ b/dsp/src/unwrap.rs
@ -16,6 +16,27 @@ pub fn overflowing_sub(y: i32, x: i32) -> (i32, i8) {
    (delta, wrap)
 }
 /// Combine high and low i32 into a single downscaled i32, saturating monotonically.
 ///
 /// Args:
 /// `lo`: LSB i32 to scale down by `shift` and range-extend with `hi`
 /// `hi`: MSB i32 to scale up and extend `lo` with. Output will be clipped if
 ///     `hi` exceeds the output i32 range.
 /// `shift`: Downscale `lo` by that many bits. Values from 1 to 32 inclusive
 ///     are valid.
 pub fn saturating_scale(lo: i32, hi: i32, shift: u32) -> i32 {
    debug_assert!(shift > 0);
    debug_assert!(shift <= 32);
    let hi_range = -1 << (shift - 1);
    if hi <= hi_range {
        i32::MIN - hi_range
    } else if -hi <= hi_range {
        hi_range - i32::MIN
    } else {
        (lo >> shift) + (hi << (32 - shift))
    }
 }
 /// Overflow unwrapper.
 ///
 /// This is unwrapping as in the phase and overflow unwrapping context, not
--- a/miniconf.py
+++ b/miniconf.py
@ -16,6 +16,7 @@ from gmqtt import Client as MqttClient
 LOGGER = logging.getLogger(__name__)
 class Miniconf:
    """An asynchronous API for controlling Miniconf devices using MQTT."""
@ -33,64 +34,64 @@ class Miniconf:
            client: A connected MQTT5 client.
            prefix: The MQTT toptic prefix of the device to control.
        """
        self.uuid = uuid.uuid1()
        self.request_id = 0
        self.client = client
        self.prefix = prefix
        self.inflight = {}
        self.client.on_message = self._handle_response
-        self.client.subscribe(f'{prefix}/response/{self.uuid.hex}')
+        self.response_topic = f'{prefix}/response/{uuid.uuid1().hex}'
        self.client.subscribe(self.response_topic)
-    def _handle_response(self, _client, _topic, payload, _qos, properties):
+    def _handle_response(self, _client, topic, payload, _qos, properties):
        """Callback function for when messages are received over MQTT.
        Args:
            _client: The MQTT client.
-            _topic: The topic that the message was received on.
+            topic: The topic that the message was received on.
            payload: The payload of the message.
            _qos: The quality-of-service level of the received packet
            properties: A dictionary of properties associated with the message.
        """
-        # Extract corrleation data from the properties
+        if topic == self.response_topic:
-        correlation_data = json.loads(properties['correlation_data'][0].decode('ascii'))
+            # Extract request_id corrleation data from the properties
-
+            request_id = int.from_bytes(
-        # Get the request ID from the correlation data
+                properties['correlation_data'][0], 'big')
        request_id = correlation_data['request_id']
            self.inflight[request_id].set_result(json.loads(payload))
            del self.inflight[request_id]
        else:
            LOGGER.warn('Unexpected message on "%s"', topic)
-
+    async def command(self, path, value, retain=True):
    async def command(self, path, value):
        """Write the provided data to the specified path.
        Args:
            path: The path to write the message to.
            value: The value to write to the path.
            retain: Retain the MQTT message changing the setting
                by the broker.
        Returns:
            The response to the command as a dictionary.
        """
-        setting_topic = f'{self.prefix}/settings/{path}'
+        topic = f'{self.prefix}/settings/{path}'
        response_topic = f'{self.prefix}/response/{self.uuid.hex}'
        # Assign a unique identifier to this update request.
        request_id = self.request_id
        self.request_id += 1
        assert request_id not in self.inflight, 'Invalid ID encountered'
        correlation_data = json.dumps({
            'request_id': request_id,
        }).encode('ascii')
        value = json.dumps(value)
        LOGGER.info('Sending %s to "%s"', value, setting_topic)
        fut = asyncio.get_running_loop().create_future()
-        self.inflight[request_id] = fut
+        # Assign unique correlation data for response dispatch
-        self.client.publish(setting_topic, payload=value, qos=0, retain=True,
+        assert self.request_id not in self.inflight
-                            response_topic=response_topic,
+        self.inflight[self.request_id] = fut
        correlation_data = self.request_id.to_bytes(4, 'big')
        self.request_id += 1
        payload = json.dumps(value)
        LOGGER.info('Sending "%s" to "%s"', value, topic)
        self.client.publish(
            topic, payload=payload, qos=0, retain=retain,
            response_topic=self.response_topic,
            correlation_data=correlation_data)
        return await fut
@ -100,16 +101,20 @@ def main():
        description='Miniconf command line interface.',
        formatter_class=argparse.RawDescriptionHelpFormatter,
        epilog='''Examples:
-%(prog)s dt/sinara/stabilizer afe/0='"G2"' iir_ch/0/0=\
+%(prog)s dt/sinara/dual-iir/00-11-22-33-aa-bb iir_ch/0/0=\
-'{"y_min": -32767, "y_max": 32767, "y_offset": 0, "ba": [1.0, 0, 0, 0, 0]}'
+'{"y_min":-32767,"y_max":32767,"y_offset":0,"ba":[1.0,0,0,0,0]}'
 %(prog)s dt/sinara/lockin/00-11-22-33-aa-bb afe/0='"G2"'\
 ''')
    parser.add_argument('-v', '--verbose', action='count', default=0,
                        help='Increase logging verbosity')
    parser.add_argument('--broker', '-b', default='mqtt', type=str,
                        help='The MQTT broker address')
    parser.add_argument('--no-retain', '-n', default=False,
                        action='store_true',
                        help='Do not retain the affected settings')
    parser.add_argument('prefix', type=str,
                        help='The MQTT topic prefix of the target')
-    parser.add_argument('settings', metavar="KEY=VALUE", nargs='+',
+    parser.add_argument('settings', metavar="PATH=VALUE", nargs='+',
                        help='JSON encoded values for settings path keys.')
    args = parser.parse_args()
@ -122,9 +127,10 @@ def main():
    async def configure_settings():
        interface = await Miniconf.create(args.prefix, args.broker)
-        for key_value in args.settings:
+        for setting in args.settings:
-            path, value = key_value.split("=", 1)
+            path, value = setting.split("=", 1)
-            response = await interface.command(path, json.loads(value))
+            response = await interface.command(path, json.loads(value),
                                               not args.no_retain)
            print(f'{path}: {response}')
            if response['code'] != 0:
                return response['code']
--- a/src/bin/dual-iir.rs
+++ b/src/bin/dual-iir.rs
@ -2,19 +2,28 @@
 #![no_std]
 #![no_main]
-use stabilizer::{hardware, net};
+use core::sync::atomic::{fence, Ordering};
 use miniconf::Miniconf;
 use serde::Deserialize;
 use dsp::iir;
-use hardware::{
+use stabilizer::{
-    Adc0Input, Adc1Input, AdcCode, AfeGain, Dac0Output, Dac1Output, DacCode,
+    flatten_closures,
-    DigitalInput0, DigitalInput1, InputPin, SystemTimer, AFE0, AFE1,
+    hardware::{
-};
+        self,
-
+        adc::{Adc0Input, Adc1Input, AdcCode},
-use net::{
+        afe::Gain,
-    BlockGenerator, NetworkUsers, Telemetry, TelemetryBuffer, NetworkState,
+        dac::{Dac0Output, Dac1Output, DacCode},
        embedded_hal::digital::v2::InputPin,
        hal,
        system_timer::SystemTimer,
        DigitalInput0, DigitalInput1, AFE0, AFE1,
    },
    net::{
        miniconf::Miniconf,
        serde::Deserialize,
        telemetry::{Telemetry, TelemetryBuffer},
        NetworkState, NetworkUsers,
        data_stream::BlockGenerator,
    },
 };
 const SCALE: f32 = i16::MAX as _;
@ -24,7 +33,7 @@ const IIR_CASCADE_LENGTH: usize = 1;
 #[derive(Clone, Copy, Debug, Deserialize, Miniconf)]
 pub struct Settings {
-    afe: [AfeGain; 2],
+    afe: [Gain; 2],
    iir_ch: [[iir::IIR; IIR_CASCADE_LENGTH]; 2],
    allow_hold: bool,
    force_hold: bool,
@ -35,7 +44,7 @@ impl Default for Settings {
    fn default() -> Self {
        Self {
            // Analog frontend programmable gain amplifier gains (G1, G2, G5, G10)
-            afe: [AfeGain::G1, AfeGain::G1],
+            afe: [Gain::G1, Gain::G1],
            // IIR filter tap gains are an array `[b0, b1, b2, a1, a2]` such that the
            // new output is computed as `y0 = a1*y1 + a2*y2 + b0*x0 + b1*x1 + b2*x2`.
            // The array is `iir_state[channel-index][cascade-index][coeff-index]`.
@ -52,7 +61,7 @@ impl Default for Settings {
    }
 }
-#[rtic::app(device = stm32h7xx_hal::stm32, peripherals = true, monotonic = stabilizer::hardware::SystemTimer)]
+#[rtic::app(device = stabilizer::hardware::hal::stm32, peripherals = true, monotonic = stabilizer::hardware::system_timer::SystemTimer)]
 const APP: () = {
    struct Resources {
        afes: (AFE0, AFE1),
@ -72,7 +81,8 @@ const APP: () = {
    #[init(spawn=[telemetry, settings_update, ethernet_link])]
    fn init(c: init::Context) -> init::LateResources {
        // Configure the microcontroller
-        let (mut stabilizer, _pounder) = hardware::setup(c.core, c.device);
+        let (mut stabilizer, _pounder) =
            hardware::setup::setup(c.core, c.device);
        let mut network = NetworkUsers::new(
            stabilizer.net.stack,
@ -110,7 +120,7 @@ const APP: () = {
            generator,
            network,
            digital_inputs: stabilizer.digital_inputs,
-            telemetry: net::TelemetryBuffer::default(),
+            telemetry: TelemetryBuffer::default(),
            settings: Settings::default(),
        }
    }
@ -134,54 +144,66 @@ const APP: () = {
    #[task(binds=DMA1_STR4, resources=[adcs, digital_inputs, dacs, iir_state, settings, telemetry, generator], priority=2)]
    #[inline(never)]
    #[link_section = ".itcm.process"]
-    fn process(c: process::Context) {
+    fn process(mut c: process::Context) {
-        let adc_samples = [
+        let process::Resources {
-            c.resources.adcs.0.acquire_buffer(),
+            adcs: (ref mut adc0, ref mut adc1),
-            c.resources.adcs.1.acquire_buffer(),
+            dacs: (ref mut dac0, ref mut dac1),
-        ];
+            ref digital_inputs,
-
+            ref settings,
-        let dac_samples = [
+            ref mut iir_state,
-            c.resources.dacs.0.acquire_buffer(),
+            ref mut telemetry,
-            c.resources.dacs.1.acquire_buffer(),
+        } = c.resources;
        ];
        let digital_inputs = [
-            c.resources.digital_inputs.0.is_high().unwrap(),
+            digital_inputs.0.is_high().unwrap(),
-            c.resources.digital_inputs.1.is_high().unwrap(),
+            digital_inputs.1.is_high().unwrap(),
        ];
        telemetry.digital_inputs = digital_inputs;
-        let hold = c.resources.settings.force_hold
+        let hold =
-            || (digital_inputs[1] && c.resources.settings.allow_hold);
+            settings.force_hold || (digital_inputs[1] && settings.allow_hold);
        flatten_closures!(with_buffer, adc0, adc1, dac0, dac1, {
            let adc_samples = [adc0, adc1];
            let dac_samples = [dac0, dac1];
            // Preserve instruction and data ordering w.r.t. DMA flag access.
            fence(Ordering::SeqCst);
            for channel in 0..adc_samples.len() {
-            for sample in 0..adc_samples[0].len() {
+                adc_samples[channel]
-                let mut y = f32::from(adc_samples[channel][sample] as i16);
+                    .iter()
-                for i in 0..c.resources.iir_state[channel].len() {
+                    .zip(dac_samples[channel].iter_mut())
-                    y = c.resources.settings.iir_ch[channel][i].update(
+                    .map(|(ai, di)| {
-                        &mut c.resources.iir_state[channel][i],
+                        let x = f32::from(*ai as i16);
-                        y,
+                        let y = settings.iir_ch[channel]
-                        hold,
+                            .iter()
-                    );
+                            .zip(iir_state[channel].iter_mut())
-                }
+                            .fold(x, |yi, (ch, state)| {
-                // Note(unsafe): The filter limits ensure that the value is in range.
+                                ch.update(state, yi, hold)
                            });
                        // Note(unsafe): The filter limits must ensure that the value is in range.
                        // The truncation introduces 1/2 LSB distortion.
-                let y = unsafe { y.to_int_unchecked::<i16>() };
+                        let y: i16 = unsafe { y.to_int_unchecked() };
                        // Convert to DAC code
-                dac_samples[channel][sample] = DacCode::from(y).0;
+                        *di = DacCode::from(y).0;
-            }
+                    })
                    .last();
            }
            // Stream the data.
            c.resources.generator.send(&adc_samples, &dac_samples);
            // Update telemetry measurements.
-        c.resources.telemetry.adcs =
+            telemetry.adcs =
                [AdcCode(adc_samples[0][0]), AdcCode(adc_samples[1][0])];
-        c.resources.telemetry.dacs =
+            telemetry.dacs =
                [DacCode(dac_samples[0][0]), DacCode(dac_samples[1][0])];
-        c.resources.telemetry.digital_inputs = digital_inputs;
+            // Preserve instruction and data ordering w.r.t. DMA flag access.
            fence(Ordering::SeqCst);
        });
    }
    #[idle(resources=[network], spawn=[settings_update])]
@ -238,27 +260,27 @@ const APP: () = {
    #[task(binds = ETH, priority = 1)]
    fn eth(_: eth::Context) {
-        unsafe { stm32h7xx_hal::ethernet::interrupt_handler() }
+        unsafe { hal::ethernet::interrupt_handler() }
    }
    #[task(binds = SPI2, priority = 3)]
    fn spi2(_: spi2::Context) {
-        panic!("ADC0 input overrun");
+        panic!("ADC0 SPI error");
    }
    #[task(binds = SPI3, priority = 3)]
    fn spi3(_: spi3::Context) {
-        panic!("ADC1 input overrun");
+        panic!("ADC1 SPI error");
    }
    #[task(binds = SPI4, priority = 3)]
    fn spi4(_: spi4::Context) {
-        panic!("DAC0 output error");
+        panic!("DAC0 SPI error");
    }
    #[task(binds = SPI5, priority = 3)]
    fn spi5(_: spi5::Context) {
-        panic!("DAC1 output error");
+        panic!("DAC1 SPI error");
    }
    extern "C" {
--- a/src/bin/lockin.rs
+++ b/src/bin/lockin.rs
@ -2,23 +2,31 @@
 #![no_std]
 #![no_main]
-use embedded_hal::digital::v2::InputPin;
+use core::sync::atomic::{fence, Ordering};
 use serde::Deserialize;
 use dsp::{Accu, Complex, ComplexExt, Lockin, RPLL};
-
+use stabilizer::{
-use stabilizer::net;
+    flatten_closures,
-
+    hardware::{
-use stabilizer::hardware::{
+        self,
-    design_parameters, setup, Adc0Input, Adc1Input, AdcCode, AfeGain,
+        adc::{Adc0Input, Adc1Input, AdcCode},
-    Dac0Output, Dac1Output, DacCode, DigitalInput0, DigitalInput1,
+        afe::Gain,
-    InputStamper, SystemTimer, AFE0, AFE1,
+        dac::{Dac0Output, Dac1Output, DacCode},
        design_parameters,
        embedded_hal::digital::v2::InputPin,
        hal,
        input_stamper::InputStamper,
        system_timer::SystemTimer,
        DigitalInput0, DigitalInput1, AFE0, AFE1,
    },
    net::{
        miniconf::Miniconf,
        serde::Deserialize,
        telemetry::{Telemetry, TelemetryBuffer},
        NetworkState, NetworkUsers,
    },
 };
 use miniconf::Miniconf;
 use net::{NetworkState, NetworkUsers, Telemetry, TelemetryBuffer};
 // A constant sinusoid to send on the DAC output.
 // Full-scale gives a +/- 10.24V amplitude waveform. Scale it down to give +/- 1V.
 const ONE: i16 = ((1.0 / 10.24) * i16::MAX as f32) as _;
@ -45,7 +53,7 @@ enum LockinMode {
 #[derive(Copy, Clone, Debug, Deserialize, Miniconf)]
 pub struct Settings {
-    afe: [AfeGain; 2],
+    afe: [Gain; 2],
    lockin_mode: LockinMode,
    pll_tc: [u8; 2],
@ -61,7 +69,7 @@ pub struct Settings {
 impl Default for Settings {
    fn default() -> Self {
        Self {
-            afe: [AfeGain::G1; 2],
+            afe: [Gain::G1; 2],
            lockin_mode: LockinMode::External,
@ -78,7 +86,7 @@ impl Default for Settings {
    }
 }
-#[rtic::app(device = stm32h7xx_hal::stm32, peripherals = true, monotonic = stabilizer::hardware::SystemTimer)]
+#[rtic::app(device = stabilizer::hardware::hal::stm32, peripherals = true, monotonic = stabilizer::hardware::system_timer::SystemTimer)]
 const APP: () = {
    struct Resources {
        afes: (AFE0, AFE1),
@ -97,7 +105,8 @@ const APP: () = {
    #[init(spawn=[settings_update, telemetry, ethernet_link])]
    fn init(c: init::Context) -> init::LateResources {
        // Configure the microcontroller
-        let (mut stabilizer, _pounder) = setup(c.core, c.device);
+        let (mut stabilizer, _pounder) =
            hardware::setup::setup(c.core, c.device);
        let network = NetworkUsers::new(
            stabilizer.net.stack,
@ -143,7 +152,7 @@ const APP: () = {
            network,
            digital_inputs: stabilizer.digital_inputs,
            timestamper: stabilizer.timestamper,
-            telemetry: net::TelemetryBuffer::default(),
+            telemetry: TelemetryBuffer::default(),
            settings,
@ -162,26 +171,22 @@ const APP: () = {
    #[task(binds=DMA1_STR4, resources=[adcs, dacs, lockin, timestamper, pll, settings, telemetry], priority=2)]
    #[inline(never)]
    #[link_section = ".itcm.process"]
-    fn process(c: process::Context) {
+    fn process(mut c: process::Context) {
-        let adc_samples = [
+        let process::Resources {
-            c.resources.adcs.0.acquire_buffer(),
+            adcs: (ref mut adc0, ref mut adc1),
-            c.resources.adcs.1.acquire_buffer(),
+            dacs: (ref mut dac0, ref mut dac1),
-        ];
+            ref settings,
-
+            ref mut telemetry,
-        let mut dac_samples = [
+            ref mut lockin,
-            c.resources.dacs.0.acquire_buffer(),
+            ref mut pll,
-            c.resources.dacs.1.acquire_buffer(),
+            ref mut timestamper,
-        ];
+        } = c.resources;
        let lockin = c.resources.lockin;
        let settings = c.resources.settings;
        let (reference_phase, reference_frequency) = match settings.lockin_mode
        {
            LockinMode::External => {
-                let timestamp =
+                let timestamp = timestamper.latest_timestamp().unwrap_or(None); // Ignore data from timer capture overflows.
-                    c.resources.timestamper.latest_timestamp().unwrap_or(None); // Ignore data from timer capture overflows.
+                let (pll_phase, pll_frequency) = pll.update(
                let (pll_phase, pll_frequency) = c.resources.pll.update(
                    timestamp.map(|t| t as i32),
                    settings.pll_tc[0],
                    settings.pll_tc[1],
@ -208,6 +213,13 @@ const APP: () = {
            reference_phase.wrapping_mul(settings.lockin_harmonic),
        );
        flatten_closures!(with_buffer, adc0, adc1, dac0, dac1, {
            let adc_samples = [adc0, adc1];
            let mut dac_samples = [dac0, dac1];
            // Preserve instruction and data ordering w.r.t. DMA flag access.
            fence(Ordering::SeqCst);
            let output: Complex<i32> = adc_samples[0]
                .iter()
                // Zip in the LO phase.
@ -240,13 +252,16 @@ const APP: () = {
                    *sample = DacCode::from(value as i16).0;
                }
            }
            // Update telemetry measurements.
-        c.resources.telemetry.adcs =
+            telemetry.adcs =
                [AdcCode(adc_samples[0][0]), AdcCode(adc_samples[1][0])];
-        c.resources.telemetry.dacs =
+            telemetry.dacs =
                [DacCode(dac_samples[0][0]), DacCode(dac_samples[1][0])];
            // Preserve instruction and data ordering w.r.t. DMA flag access.
            fence(Ordering::SeqCst);
        });
    }
    #[idle(resources=[network], spawn=[settings_update])]
@ -309,27 +324,7 @@ const APP: () = {
    #[task(binds = ETH, priority = 1)]
    fn eth(_: eth::Context) {
-        unsafe { stm32h7xx_hal::ethernet::interrupt_handler() }
+        unsafe { hal::ethernet::interrupt_handler() }
    }
    #[task(binds = SPI2, priority = 3)]
    fn spi2(_: spi2::Context) {
        panic!("ADC0 input overrun");
    }
    #[task(binds = SPI3, priority = 3)]
    fn spi3(_: spi3::Context) {
        panic!("ADC1 input overrun");
    }
    #[task(binds = SPI4, priority = 3)]
    fn spi4(_: spi4::Context) {
        panic!("DAC0 output error");
    }
    #[task(binds = SPI5, priority = 3)]
    fn spi5(_: spi5::Context) {
        panic!("DAC1 output error");
    }
    extern "C" {
--- a/src/hardware/adc.rs
+++ b/src/hardware/adc.rs
@ -29,15 +29,9 @@
 ///! available. When enough samples have been collected, a transfer-complete interrupt is generated
 ///! and the ADC samples are available for processing.
 ///!
-///! The SPI peripheral internally has an 8- or 16-byte TX and RX FIFO, which corresponds to a 4- or
+///! After a complete transfer of a batch of samples, the inactive buffer is available to the
-///! 8-sample buffer for incoming ADC samples. During the handling of the DMA transfer completion,
+///! user for processing. The processing must complete before the DMA transfer of the next batch
-///! there is a small window where buffers are swapped over where it's possible that a sample could
+///! completes.
 ///! be lost. In order to avoid this, the SPI RX FIFO is effectively used as a "sample overflow"
 ///! region and can buffer a number of samples until the next DMA transfer is configured. If a DMA
 ///! transfer is still not set in time, the SPI peripheral will generate an input-overrun interrupt.
 ///! This interrupt then serves as a means of detecting if samples have been lost, which will occur
 ///! whenever data processing takes longer than the collection period.
 ///!
 ///!
 ///! ## Starting Data Collection
 ///!
@ -68,26 +62,26 @@
 ///! sample DMA requests, which can be completed by setting e.g. ADC0's comparison to a counter
 ///! value of 0 and ADC1's comparison to a counter value of 1.
 ///!
-///! In this implementation, single buffer mode DMA transfers are used because the SPI RX FIFO can
+///! In this implementation, double buffer mode DMA transfers are used because the SPI RX FIFOs
-///! be used as a means to both detect and buffer ADC samples during the buffer swap-over. Because
+///! have finite depth, FIFO access is slower than AXISRAM access, and because the single
-///! of this, double-buffered mode does not offer any advantages over single-buffered mode (unless
+///! buffer mode DMA disable/enable and buffer update sequence is slow.
 ///! double-buffered mode offers less overhead due to the DMA disable/enable procedure).
 use stm32h7xx_hal as hal;
-use super::design_parameters::SAMPLE_BUFFER_SIZE;
+use super::design_parameters::{SampleBuffer, SAMPLE_BUFFER_SIZE};
 use super::timers;
 use hal::dma::{
    config::Priority,
    dma::{DMAReq, DmaConfig},
    traits::TargetAddress,
-    MemoryToPeripheral, PeripheralToMemory, Transfer,
+    DMAError, MemoryToPeripheral, PeripheralToMemory, Transfer,
 };
 /// A type representing an ADC sample.
 #[derive(Copy, Clone)]
 pub struct AdcCode(pub u16);
 #[allow(clippy::from_over_into)]
 impl Into<f32> for AdcCode {
    /// Convert raw ADC codes to/from voltage levels.
    ///
@ -119,8 +113,7 @@ static mut SPI_EOT_CLEAR: [u32; 1] = [0x00];
 // processed). Note that the contents of AXI SRAM is uninitialized, so the buffer contents on
 // startup are undefined. The dimensions are `ADC_BUF[adc_index][ping_pong_index][sample_index]`.
 #[link_section = ".axisram.buffers"]
-static mut ADC_BUF: [[[u16; SAMPLE_BUFFER_SIZE]; 2]; 2] =
+static mut ADC_BUF: [[SampleBuffer; 2]; 2] = [[[0; SAMPLE_BUFFER_SIZE]; 2]; 2];
    [[[0; SAMPLE_BUFFER_SIZE]; 2]; 2];
 macro_rules! adc_input {
    ($name:ident, $index:literal, $trigger_stream:ident, $data_stream:ident, $clear_stream:ident,
@ -192,12 +185,11 @@ macro_rules! adc_input {
            /// Represents data associated with ADC.
            pub struct $name {
                next_buffer: Option<&'static mut [u16; SAMPLE_BUFFER_SIZE]>,
                transfer: Transfer<
                    hal::dma::dma::$data_stream<hal::stm32::DMA1>,
                    hal::spi::Spi<hal::stm32::$spi, hal::spi::Disabled, u16>,
                    PeripheralToMemory,
-                    &'static mut [u16; SAMPLE_BUFFER_SIZE],
+                    &'static mut SampleBuffer,
                    hal::dma::DBTransfer,
                >,
                trigger_transfer: Transfer<
@ -316,6 +308,7 @@ macro_rules! adc_input {
                    // data stream is used to trigger a transfer completion interrupt.
                    let data_config = DmaConfig::default()
                        .memory_increment(true)
                        .double_buffer(true)
                        .transfer_complete_interrupt($index == 1)
                        .priority(Priority::VeryHigh);
@ -333,17 +326,14 @@ macro_rules! adc_input {
                        Transfer::init(
                            data_stream,
                            spi,
-                            // Note(unsafe): The ADC_BUF[$index][0] is "owned" by this peripheral.
+                            // Note(unsafe): The ADC_BUF[$index] is "owned" by this peripheral.
                            // It shall not be used anywhere else in the module.
                            unsafe { &mut ADC_BUF[$index][0] },
-                            None,
+                            unsafe { Some(&mut ADC_BUF[$index][1]) },
                            data_config,
                        );
                    Self {
                        // Note(unsafe): The ADC_BUF[$index][1] is "owned" by this peripheral. It
                        // shall not be used anywhere else in the module.
                        next_buffer: unsafe { Some(&mut ADC_BUF[$index][1]) },
                        transfer: data_transfer,
                        trigger_transfer,
                        clear_transfer,
@ -364,27 +354,17 @@ macro_rules! adc_input {
                }
-                /// Obtain a buffer filled with ADC samples.
+                /// Wait for the transfer of the currently active buffer to complete,
                /// then call a function on the now inactive buffer and acknowledge the
                /// transfer complete flag.
                ///
-                /// # Returns
+                /// NOTE(unsafe): Memory safety and access ordering is not guaranteed
-                /// A reference to the underlying buffer that has been filled with ADC samples.
+                /// (see the HAL DMA docs).
-                pub fn acquire_buffer(&mut self) -> &[u16; SAMPLE_BUFFER_SIZE] {
+                pub fn with_buffer<F, R>(&mut self, f: F) -> Result<R, DMAError>
-                    // Wait for the transfer to fully complete before continuing.  Note: If a device
+                    where
-                    // hangs up, check that this conditional is passing correctly, as there is no
+                F: FnOnce(&mut SampleBuffer) -> R,
-                    // time-out checks here in the interest of execution speed.
+                {
-                    while !self.transfer.get_transfer_complete_flag() {}
+                    unsafe { self.transfer.next_dbm_transfer_with(|buf, _current| f(buf)) }
                    let next_buffer = self.next_buffer.take().unwrap();
                    // Start the next transfer.
                    self.transfer.clear_interrupts();
                    let (prev_buffer, _, _) =
                        self.transfer.next_transfer(next_buffer).unwrap();
                     // .unwrap_none() https://github.com/rust-lang/rust/issues/62633
                    self.next_buffer.replace(prev_buffer);
                    self.next_buffer.as_ref().unwrap()
                }
            }
        }
--- a/src/hardware/dac.rs
+++ b/src/hardware/dac.rs
@ -52,13 +52,13 @@
 ///! served promptly after the transfer completes.
 use stm32h7xx_hal as hal;
-use super::design_parameters::SAMPLE_BUFFER_SIZE;
+use super::design_parameters::{SampleBuffer, SAMPLE_BUFFER_SIZE};
 use super::timers;
 use hal::dma::{
    dma::{DMAReq, DmaConfig},
    traits::TargetAddress,
-    MemoryToPeripheral, Transfer,
+    DMAError, MemoryToPeripheral, Transfer,
 };
 // The following global buffers are used for the DAC code DMA transfers. Two buffers are used for
@ -66,14 +66,14 @@ use hal::dma::{
 // processed). Note that the contents of AXI SRAM is uninitialized, so the buffer contents on
 // startup are undefined. The dimensions are `ADC_BUF[adc_index][ping_pong_index][sample_index]`.
 #[link_section = ".axisram.buffers"]
-static mut DAC_BUF: [[[u16; SAMPLE_BUFFER_SIZE]; 3]; 2] =
+static mut DAC_BUF: [[SampleBuffer; 2]; 2] = [[[0; SAMPLE_BUFFER_SIZE]; 2]; 2];
    [[[0; SAMPLE_BUFFER_SIZE]; 3]; 2];
 /// Custom type for referencing DAC output codes.
 /// The internal integer is the raw code written to the DAC output register.
 #[derive(Copy, Clone)]
 pub struct DacCode(pub u16);
 #[allow(clippy::from_over_into)]
 impl Into<f32> for DacCode {
    fn into(self) -> f32 {
        // The DAC output range in bipolar mode (including the external output op-amp) is +/- 4.096
@ -105,7 +105,7 @@ macro_rules! dac_output {
                _channel: timers::tim2::$trigger_channel,
                spi: hal::spi::Spi<hal::stm32::$spi, hal::spi::Disabled, u16>,
            ) -> Self {
-                Self { _channel, spi }
+                Self { spi, _channel }
            }
            /// Start the SPI and begin operating in a DMA-driven transfer mode.
@ -137,13 +137,12 @@ macro_rules! dac_output {
        /// Represents data associated with DAC.
        pub struct $name {
            next_buffer: Option<&'static mut [u16; SAMPLE_BUFFER_SIZE]>,
            // Note: SPI TX functionality may not be used from this structure to ensure safety with DMA.
            transfer: Transfer<
                hal::dma::dma::$data_stream<hal::stm32::DMA1>,
                $spi,
                MemoryToPeripheral,
-                &'static mut [u16; SAMPLE_BUFFER_SIZE],
+                &'static mut SampleBuffer,
                hal::dma::DBTransfer,
            >,
        }
@ -198,33 +197,26 @@ macro_rules! dac_output {
                        trigger_config,
                    );
-                Self {
+                Self { transfer }
                    transfer,
                    // Note(unsafe): This buffer is only used once and provided for the next DMA transfer.
                    next_buffer: unsafe { Some(&mut DAC_BUF[$index][2]) },
                }
            }
            pub fn start(&mut self) {
                self.transfer.start(|spi| spi.start_dma());
            }
-            /// Acquire the next output buffer to populate it with DAC codes.
+            /// Wait for the transfer of the currently active buffer to complete,
-            pub fn acquire_buffer(&mut self) -> &mut [u16; SAMPLE_BUFFER_SIZE] {
+            /// then call a function on the now inactive buffer and acknowledge the
-                // Note: If a device hangs up, check that this conditional is passing correctly, as
+            /// transfer complete flag.
-                // there is no time-out checks here in the interest of execution speed.
+            ///
-                while !self.transfer.get_transfer_complete_flag() {}
+            /// NOTE(unsafe): Memory safety and access ordering is not guaranteed
-
+            /// (see the HAL DMA docs).
-                let next_buffer = self.next_buffer.take().unwrap();
+            pub fn with_buffer<F, R>(&mut self, f: F) -> Result<R, DMAError>
-
+            where
-                // Start the next transfer.
+                F: FnOnce(&mut SampleBuffer) -> R,
-                let (prev_buffer, _, _) =
+            {
-                    self.transfer.next_transfer(next_buffer).unwrap();
+                unsafe {
-
+                    self.transfer.next_dbm_transfer_with(|buf, _current| f(buf))
-                // .unwrap_none() https://github.com/rust-lang/rust/issues/62633
+                }
                self.next_buffer.replace(prev_buffer);
                self.next_buffer.as_mut().unwrap()
            }
        }
    };
--- a/src/hardware/design_parameters.rs
+++ b/src/hardware/design_parameters.rs
@ -50,5 +50,7 @@ pub const ADC_SAMPLE_TICKS: u16 = 1 << ADC_SAMPLE_TICKS_LOG2;
 pub const SAMPLE_BUFFER_SIZE_LOG2: u8 = 3;
 pub const SAMPLE_BUFFER_SIZE: usize = 1 << SAMPLE_BUFFER_SIZE_LOG2;
 pub type SampleBuffer = [u16; SAMPLE_BUFFER_SIZE];
 // The MQTT broker IPv4 address
 pub const MQTT_BROKER: [u8; 4] = [10, 34, 16, 10];
--- a/src/hardware/digital_input_stamper.rs
+++ b/src/hardware/digital_input_stamper.rs
--- a/src/hardware/mod.rs
+++ b/src/hardware/mod.rs
@ -1,28 +1,19 @@
 pub use embedded_hal;
 ///! Module for all hardware-specific setup of Stabilizer
-use stm32h7xx_hal as hal;
+pub use stm32h7xx_hal as hal;
-// Re-export for the DigitalInputs below:
+pub mod adc;
-pub use embedded_hal::digital::v2::InputPin;
+pub mod afe;
-
+pub mod cycle_counter;
-mod adc;
+pub mod dac;
 mod afe;
 mod configuration;
 mod cycle_counter;
 mod dac;
 pub mod design_parameters;
-mod digital_input_stamper;
+pub mod input_stamper;
 mod eeprom;
 pub mod pounder;
-mod system_timer;
+pub mod setup;
-mod timers;
+pub mod system_timer;
-pub use adc::{Adc0Input, Adc1Input, AdcCode};
+mod eeprom;
-pub use afe::Gain as AfeGain;
+mod timers;
 pub use cycle_counter::CycleCounter;
 pub use dac::{Dac0Output, Dac1Output, DacCode};
 pub use digital_input_stamper::InputStamper;
 pub use pounder::DdsOutput;
 pub use system_timer::SystemTimer;
 // Type alias for the analog front-end (AFE) for ADC0.
 pub type AFE0 = afe::ProgrammableGainAmplifier<
@ -52,8 +43,6 @@ pub type NetworkStack = smoltcp_nal::NetworkStack<
 pub type EthernetPhy = hal::ethernet::phy::LAN8742A<hal::ethernet::EthernetMAC>;
 pub use configuration::{setup, PounderDevices, StabilizerDevices};
 #[inline(never)]
 #[panic_handler]
 fn panic(info: &core::panic::PanicInfo) -> ! {
--- a/src/hardware/pounder/attenuators.rs
+++ b/src/hardware/pounder/attenuators.rs
@ -30,16 +30,16 @@ pub trait AttenuatorInterface {
        // Read all the channels, modify the channel of interest, and write all the channels back.
        // This ensures the staging register and the output register are always in sync.
        let mut channels = [0_u8; 4];
-        self.read_all_attenuators(&mut channels)?;
+        self.transfer_attenuators(&mut channels)?;
        // The lowest 2 bits of the 8-bit shift register on the attenuator are ignored. Shift the
        // attenuator code into the upper 6 bits of the register value. Note that the attenuator
        // treats inputs as active-low, so the code is inverted before writing.
-        channels[channel as usize] = (!attenuation_code) << 2;
+        channels[channel as usize] = !(attenuation_code << 2);
-        self.write_all_attenuators(&channels)?;
+        self.transfer_attenuators(&mut channels)?;
        // Finally, latch the output of the updated channel to force it into an active state.
-        self.latch_attenuators(channel)?;
+        self.latch_attenuator(channel)?;
        Ok(attenuation_code as f32 / 2.0)
    }
@ -57,8 +57,8 @@ pub trait AttenuatorInterface {
        // Reading the data always shifts data out of the staging registers, so we perform a
        // duplicate write-back to ensure the staging register is always equal to the output
        // register.
-        self.read_all_attenuators(&mut channels)?;
+        self.transfer_attenuators(&mut channels)?;
-        self.write_all_attenuators(&channels)?;
+        self.transfer_attenuators(&mut channels)?;
        // The attenuation code is stored in the upper 6 bits of the register, where each LSB
        // represents 0.5 dB. The attenuator stores the code as active-low, so inverting the result
@ -74,13 +74,10 @@ pub trait AttenuatorInterface {
    fn reset_attenuators(&mut self) -> Result<(), Error>;
-    fn latch_attenuators(&mut self, channel: Channel) -> Result<(), Error>;
+    fn latch_attenuator(&mut self, channel: Channel) -> Result<(), Error>;
-    fn read_all_attenuators(
+
    fn transfer_attenuators(
        &mut self,
        channels: &mut [u8; 4],
    ) -> Result<(), Error>;
    fn write_all_attenuators(
        &mut self,
        channels: &[u8; 4],
    ) -> Result<(), Error>;
 }
--- a/src/hardware/pounder/dds_output.rs
+++ b/src/hardware/pounder/dds_output.rs
@ -52,9 +52,11 @@
 ///! compile-time-known register update sequence needed for the application, the serialization
 ///! process can be done once and then register values can be written into a pre-computed serialized
 ///! buffer to avoid the software overhead of much of the serialization process.
 use log::warn;
 use stm32h7xx_hal as hal;
 use super::{hrtimer::HighResTimerE, QspiInterface};
 use ad9959::{Channel, DdsConfig, ProfileSerializer};
 use stm32h7xx_hal as hal;
 /// The DDS profile update stream.
 pub struct DdsOutput {
--- a/src/hardware/pounder/mod.rs
+++ b/src/hardware/pounder/mod.rs
@ -1,30 +1,30 @@
 use super::hal;
 use embedded_hal::{adc::OneShot, blocking::spi::Transfer};
 use serde::{Deserialize, Serialize};
 pub mod attenuators;
-mod dds_output;
+pub mod dds_output;
 pub mod hrtimer;
-mod rf_power;
+pub mod rf_power;
 #[cfg(feature = "pounder_v1_1")]
 pub mod timestamp;
-pub use dds_output::DdsOutput;
+pub enum GpioPin {
-
+    Led4Green = 0,
-use super::hal;
+    Led5Red = 1,
-
+    Led6Green = 2,
-use attenuators::AttenuatorInterface;
+    Led7Red = 3,
-use rf_power::PowerMeasurementInterface;
+    Led8Green = 4,
-
+    Led9Red = 5,
-use embedded_hal::{adc::OneShot, blocking::spi::Transfer};
+    AttLe0 = 8,
-
+    AttLe1 = 8 + 1,
-const EXT_CLK_SEL_PIN: u8 = 8 + 7;
+    AttLe2 = 8 + 2,
-#[allow(dead_code)]
+    AttLe3 = 8 + 3,
-const OSC_EN_N_PIN: u8 = 8 + 6;
+    AttRstN = 8 + 5,
-const ATT_RST_N_PIN: u8 = 8 + 5;
+    OscEnN = 8 + 6,
-const ATT_LE3_PIN: u8 = 8 + 3;
+    ExtClkSel = 8 + 7,
-const ATT_LE2_PIN: u8 = 8 + 2;
+}
 const ATT_LE1_PIN: u8 = 8 + 1;
 const ATT_LE0_PIN: u8 = 8;
 #[derive(Debug, Copy, Clone)]
 pub enum Error {
@ -37,13 +37,15 @@ pub enum Error {
    Adc,
 }
 /// The numerical value (discriminant) of the Channel enum is the index in the attenuator shift
 /// register as well as the attenuator latch enable signal index on the GPIO extender.
 #[derive(Debug, Copy, Clone)]
 #[allow(dead_code)]
 pub enum Channel {
-    In0,
+    In0 = 0,
-    In1,
+    Out0 = 1,
-    Out0,
+    In1 = 2,
-    Out1,
+    Out1 = 3,
 }
 #[derive(Serialize, Deserialize, Copy, Clone, Debug)]
@ -80,14 +82,14 @@ pub struct DdsClockConfig {
    pub external_clock: bool,
 }
-impl Into<ad9959::Channel> for Channel {
+impl From<Channel> for ad9959::Channel {
    /// Translate pounder channels to DDS output channels.
-    fn into(self) -> ad9959::Channel {
+    fn from(other: Channel) -> Self {
-        match self {
+        match other {
-            Channel::In0 => ad9959::Channel::Two,
+            Channel::In0 => Self::Two,
-            Channel::In1 => ad9959::Channel::Four,
+            Channel::In1 => Self::Four,
-            Channel::Out0 => ad9959::Channel::One,
+            Channel::Out0 => Self::One,
-            Channel::Out1 => ad9959::Channel::Three,
+            Channel::Out1 => Self::Three,
        }
    }
 }
@ -300,41 +302,35 @@ impl PounderDevices {
            adc2_in_p,
        };
-        // Configure power-on-default state for pounder. All LEDs are on, on-board oscillator
+        // Configure power-on-default state for pounder. All LEDs are off, on-board oscillator
-        // selected, attenuators out of reset. Note that testing indicates the output state needs to
+        // selected and enabled, attenuators out of reset. Note that testing indicates the
-        // be set first to properly update the output registers.
+        // output state needs to be set first to properly update the output registers.
        devices
            .mcp23017
            .all_pin_mode(mcp23017::PinMode::OUTPUT)
            .map_err(|_| Error::I2c)?;
        devices
            .mcp23017
-            .write_gpio(mcp23017::Port::GPIOA, 0x3F)
+            .write_gpio(mcp23017::Port::GPIOA, 0x00)
            .map_err(|_| Error::I2c)?;
        devices
            .mcp23017
-            .write_gpio(mcp23017::Port::GPIOB, 1 << 5)
+            .write_gpio(mcp23017::Port::GPIOB, 0x2F)
            .map_err(|_| Error::I2c)?;
        devices
            .mcp23017
            .digital_write(EXT_CLK_SEL_PIN, false)
            .map_err(|_| Error::I2c)?;
        Ok(devices)
    }
 }
-impl AttenuatorInterface for PounderDevices {
+impl attenuators::AttenuatorInterface for PounderDevices {
    /// Reset all of the attenuators to a power-on default state.
    fn reset_attenuators(&mut self) -> Result<(), Error> {
        self.mcp23017
-            .digital_write(ATT_RST_N_PIN, false)
+            .write_gpio(mcp23017::Port::GPIOB, 0x0f)
            .map_err(|_| Error::I2c)?;
-        // TODO: Measure the I2C transaction speed to the RST pin to ensure that the delay is
+        // Duration of one I2C transaction is sufficiently long.
        // sufficient. Document the delay here.
        self.mcp23017
-            .digital_write(ATT_RST_N_PIN, true)
+            .write_gpio(mcp23017::Port::GPIOB, 0x2f)
            .map_err(|_| Error::I2c)?;
        Ok(())
@ -344,31 +340,24 @@ impl AttenuatorInterface for PounderDevices {
    ///
    /// Args:
    /// * `channel` - The attenuator channel to latch.
-    fn latch_attenuators(&mut self, channel: Channel) -> Result<(), Error> {
+    fn latch_attenuator(&mut self, channel: Channel) -> Result<(), Error> {
-        let pin = match channel {
+        let pin = channel as u8;
            Channel::In0 => ATT_LE0_PIN,
            Channel::In1 => ATT_LE2_PIN,
            Channel::Out0 => ATT_LE1_PIN,
            Channel::Out1 => ATT_LE3_PIN,
        };
        self.mcp23017
-            .digital_write(pin, true)
+            .write_gpio(mcp23017::Port::GPIOB, 0x2f & !(1 << pin))
            .map_err(|_| Error::I2c)?;
-        // TODO: Measure the I2C transaction speed to the RST pin to ensure that the delay is
+        // Duration of one I2C transaction is sufficiently long.
        // sufficient. Document the delay here.
        self.mcp23017
-            .digital_write(pin, false)
+            .write_gpio(mcp23017::Port::GPIOB, 0x2f)
            .map_err(|_| Error::I2c)?;
        Ok(())
    }
    /// Read the raw attenuation codes stored in the attenuator shift registers.
    ///
    /// Args:
-    /// * `channels` - A slice to store the channel readings into.
+    /// * `channels` - A 4 byte slice to be shifted into the
-    fn read_all_attenuators(
+    ///     attenuators and to contain the data shifted out.
    fn transfer_attenuators(
        &mut self,
        channels: &mut [u8; 4],
    ) -> Result<(), Error> {
@ -378,26 +367,9 @@ impl AttenuatorInterface for PounderDevices {
        Ok(())
    }
    /// Write the attenuator shift registers.
    ///
    /// Args:
    /// * `channels` - The data to write into the attenuators.
    fn write_all_attenuators(
        &mut self,
        channels: &[u8; 4],
    ) -> Result<(), Error> {
        let mut result = [0_u8; 4];
        result.clone_from_slice(channels);
        self.attenuator_spi
            .transfer(&mut result)
            .map_err(|_| Error::Spi)?;
        Ok(())
    }
 }
-impl PowerMeasurementInterface for PounderDevices {
+impl rf_power::PowerMeasurementInterface for PounderDevices {
    /// Sample an ADC channel.
    ///
    /// Args:
--- a/src/hardware/pounder/rf_power.rs
+++ b/src/hardware/pounder/rf_power.rs
@ -1,20 +1,22 @@
 use super::{Channel, Error};
-/// Provide an interface to measure RF input power in dB.
+/// Provide an interface to measure RF input power in dBm.
 pub trait PowerMeasurementInterface {
    fn sample_converter(&mut self, channel: Channel) -> Result<f32, Error>;
    /// Measure the power of an input channel in dBm.
    ///
    /// Note: This function assumes the input channel is connected to an AD8363 output.
    ///
    /// Args:
-    /// * `channel` - The pounder channel to measure the power of in dBm.
+    /// * `channel` - The pounder input channel to measure the power of.
    ///
    /// Returns:
    /// Power in dBm after the digitally controlled attenuator before the amplifier.
    fn measure_power(&mut self, channel: Channel) -> Result<f32, Error> {
        let analog_measurement = self.sample_converter(channel)?;
-        // The AD8363 with VSET connected to VOUT provides an output voltage of 51.7mV / dB at
+        // The AD8363 with VSET connected to VOUT provides an output voltage of 51.7 mV/dB at
-        // 100MHz. It also indicates  a y-intercept of -58dBm.
+        // 100MHz with an intercept of -58 dBm.
-        Ok(analog_measurement / 0.0517 - 58.0)
+        // It is placed behind a 20 dB tap.
        Ok(analog_measurement * (1. / 0.0517) + (-58. + 20.))
    }
 }
--- a/src/hardware/pounder/timestamp.rs
+++ b/src/hardware/pounder/timestamp.rs
@ -13,50 +13,24 @@
 ///! Once the timer is configured, an input capture is configured to record the timer count
 ///! register. The input capture is configured to utilize an internal trigger for the input capture.
 ///! The internal trigger is selected such that when a sample is generated on ADC0, the input
-///! capture is simultaneously triggered. This results in the input capture triggering identically
+///! capture is simultaneously triggered. That trigger is prescaled (its rate is divided) by the
-///! to when the ADC samples the input.
+///! batch size. This results in the input capture triggering identically to when the ADC samples
-///!
+///! the last sample of the batch. That sample is then available for processing by the user.
-///! Once the input capture is properly configured, a DMA transfer is configured to collect all of
+use crate::hardware::{design_parameters, timers};
-///! timestamps. The DMA transfer collects 1 timestamp for each ADC sample collected. In order to
+use core::convert::TryFrom;
 ///! avoid potentially losing a timestamp for a sample, the DMA transfer operates in double-buffer
 ///! mode. As soon as the DMA transfer completes, the hardware automatically swaps over to a second
 ///! buffer to continue capturing. This alleviates timing sensitivities of the DMA transfer
 ///! schedule.
 use stm32h7xx_hal as hal;
 use hal::dma::{dma::DmaConfig, PeripheralToMemory, Transfer};
 use crate::hardware::{design_parameters::SAMPLE_BUFFER_SIZE, timers};
 // Three buffers are required for double buffered mode - 2 are owned by the DMA stream and 1 is the
 // working data provided to the application. These buffers must exist in a DMA-accessible memory
 // region. Note that AXISRAM is not initialized on boot, so their initial contents are undefined.
 #[link_section = ".axisram.buffers"]
 static mut BUF: [[u16; SAMPLE_BUFFER_SIZE]; 3] = [[0; SAMPLE_BUFFER_SIZE]; 3];
 /// Software unit to timestamp stabilizer ADC samples using an external pounder reference clock.
 pub struct Timestamper {
    next_buffer: Option<&'static mut [u16; SAMPLE_BUFFER_SIZE]>,
    timer: timers::PounderTimestampTimer,
-    transfer: Transfer<
+    capture_channel: timers::tim8::Channel1InputCapture,
        hal::dma::dma::Stream0<hal::stm32::DMA2>,
        timers::tim8::Channel1InputCapture,
        PeripheralToMemory,
        &'static mut [u16; SAMPLE_BUFFER_SIZE],
        hal::dma::DBTransfer,
    >,
 }
 impl Timestamper {
    /// Construct the pounder sample timestamper.
    ///
    /// # Note
    /// The DMA is immediately configured after instantiation. It will not collect any samples
    /// until the sample timer begins to cause input capture triggers.
    ///
    /// # Args
    /// * `timestamp_timer` - The timer peripheral used for capturing timestamps from.
    /// * `stream` - The DMA stream to use for collecting timestamps.
    /// * `capture_channel` - The input capture channel for collecting timestamps.
    /// * `sampling_timer` - The stabilizer ADC sampling timer.
    /// * `_clock_input` - The input pin for the external clock from Pounder.
@ -65,18 +39,12 @@ impl Timestamper {
    /// The new pounder timestamper in an operational state.
    pub fn new(
        mut timestamp_timer: timers::PounderTimestampTimer,
        stream: hal::dma::dma::Stream0<hal::stm32::DMA2>,
        capture_channel: timers::tim8::Channel1,
        sampling_timer: &mut timers::SamplingTimer,
        _clock_input: hal::gpio::gpioa::PA0<
            hal::gpio::Alternate<hal::gpio::AF3>,
        >,
    ) -> Self {
        let config = DmaConfig::default()
            .memory_increment(true)
            .circular_buffer(true)
            .double_buffer(true);
        // The sampling timer should generate a trigger output when CH1 comparison occurs.
        sampling_timer.generate_trigger(timers::TriggerGenerator::ComparePulse);
@ -85,64 +53,39 @@ impl Timestamper {
        timestamp_timer.set_trigger_source(timers::TriggerSource::Trigger1);
        // The capture channel should capture whenever the trigger input occurs.
-        let input_capture = capture_channel
+        let mut input_capture = capture_channel
            .into_input_capture(timers::tim8::CaptureSource1::TRC);
        input_capture.listen_dma();
-        // The data transfer is always a transfer of data from the peripheral to a RAM buffer.
+        // Capture at the batch period.
-        let data_transfer: Transfer<_, _, PeripheralToMemory, _, _> =
+        input_capture.configure_prescaler(
-            Transfer::init(
+            timers::Prescaler::try_from(
-                stream,
+                design_parameters::SAMPLE_BUFFER_SIZE_LOG2,
-                input_capture,
+            )
-                // Note(unsafe): BUF[0] and BUF[1] are "owned" by this peripheral.
+            .unwrap(),
                // They shall not be used anywhere else in the module.
                unsafe { &mut BUF[0] },
                unsafe { Some(&mut BUF[1]) },
                config,
        );
        Self {
            timer: timestamp_timer,
-            transfer: data_transfer,
+            capture_channel: input_capture,
            // Note(unsafe): BUF[2] is "owned" by this peripheral. It shall not be used anywhere
            // else in the module.
            next_buffer: unsafe { Some(&mut BUF[2]) },
        }
    }
-    /// Start the DMA transfer for collecting timestamps.
+    /// Start collecting timestamps.
    #[allow(dead_code)]
    pub fn start(&mut self) {
-        self.transfer
+        self.capture_channel.enable();
            .start(|capture_channel| capture_channel.enable());
    }
    /// Update the period of the underlying timestamp timer.
    #[allow(dead_code)]
    pub fn update_period(&mut self, period: u16) {
        self.timer.set_period_ticks(period);
    }
-    /// Obtain a buffer filled with timestamps.
+    /// Obtain a timestamp.
    ///
    /// # Returns
-    /// A reference to the underlying buffer that has been filled with timestamps.
+    /// A `Result` potentially indicating capture overflow and containing a `Option` of a captured
-    #[allow(dead_code)]
+    /// timestamp.
-    pub fn acquire_buffer(&mut self) -> &[u16; SAMPLE_BUFFER_SIZE] {
+    pub fn latest_timestamp(&mut self) -> Result<Option<u16>, Option<u16>> {
-        // Wait for the transfer to fully complete before continuing.
+        self.capture_channel.latest_capture()
        // Note: If a device hangs up, check that this conditional is passing correctly, as there is
        // no time-out checks here in the interest of execution speed.
        while !self.transfer.get_transfer_complete_flag() {}
        let next_buffer = self.next_buffer.take().unwrap();
        // Start the next transfer.
        let (prev_buffer, _, _) =
            self.transfer.next_transfer(next_buffer).unwrap();
        self.next_buffer.replace(prev_buffer); // .unwrap_none() https://github.com/rust-lang/rust/issues/62633
        self.next_buffer.as_ref().unwrap()
    }
 }
--- a/src/hardware/configuration.rs
+++ b/src/hardware/configuration.rs
@ -12,9 +12,10 @@ use smoltcp_nal::smoltcp;
 use embedded_hal::digital::v2::{InputPin, OutputPin};
 use super::{
-    adc, afe, cycle_counter::CycleCounter, dac, design_parameters,
+    adc, afe, cycle_counter::CycleCounter, dac, design_parameters, eeprom,
-    digital_input_stamper, eeprom, pounder, system_timer, timers, DdsOutput,
+    input_stamper::InputStamper, pounder, pounder::dds_output::DdsOutput,
-    DigitalInput0, DigitalInput1, EthernetPhy, NetworkStack, AFE0, AFE1,
+    system_timer, timers, DigitalInput0, DigitalInput1, EthernetPhy,
    NetworkStack, AFE0, AFE1,
 };
 const NUM_TCP_SOCKETS: usize = 4;
@ -105,7 +106,7 @@ pub struct StabilizerDevices {
    pub afes: (AFE0, AFE1),
    pub adcs: (adc::Adc0Input, adc::Adc1Input),
    pub dacs: (dac::Dac0Output, dac::Dac1Output),
-    pub timestamper: digital_input_stamper::InputStamper,
+    pub timestamper: InputStamper,
    pub adc_dac_timer: timers::SamplingTimer,
    pub timestamp_timer: timers::TimestampTimer,
    pub net: NetworkDevices,
@ -256,11 +257,6 @@ pub fn setup(
    let dma_streams =
        hal::dma::dma::StreamsTuple::new(device.DMA1, ccdr.peripheral.DMA1);
    // Early, before the DMA1 peripherals (#272)
    #[cfg(feature = "pounder_v1_1")]
    let dma2_streams =
        hal::dma::dma::StreamsTuple::new(device.DMA2, ccdr.peripheral.DMA2);
    // Configure timer 2 to trigger conversions for the ADC
    let mut sampling_timer = {
        // The timer frequency is manually adjusted below, so the 1KHz setting here is a
@ -537,10 +533,7 @@ pub fn setup(
    let input_stamper = {
        let trigger = gpioa.pa3.into_alternate_af2();
-        digital_input_stamper::InputStamper::new(
+        InputStamper::new(trigger, timestamp_timer_channels.ch4)
            trigger,
            timestamp_timer_channels.ch4,
        )
    };
    let digital_inputs = {
@ -836,7 +829,7 @@ pub fn setup(
            let scl = gpiob.pb8.into_alternate_af4().set_open_drain();
            let i2c1 = device.I2C1.i2c(
                (scl, sda),
-                100.khz(),
+                400.khz(),
                ccdr.peripheral.I2C1,
                &ccdr.clocks,
            );
@ -980,7 +973,6 @@ pub fn setup(
            pounder::timestamp::Timestamper::new(
                timestamp_timer,
                dma2_streams.0,
                tim8_channels.ch1,
                &mut sampling_timer,
                etr_pin,
--- a/src/hardware/timers.rs
+++ b/src/hardware/timers.rs
@ -1,5 +1,6 @@
 ///! The sampling timer is used for managing ADC sampling and external reference timestamping.
 use super::hal;
 use num_enum::TryFromPrimitive;
 use hal::stm32::{
    // TIM1 and TIM8 have identical registers.
@ -34,6 +35,8 @@ pub enum TriggerSource {
 /// Prescalers for externally-supplied reference clocks.
 #[allow(dead_code)]
 #[derive(TryFromPrimitive)]
 #[repr(u8)]
 pub enum Prescaler {
    Div1 = 0b00,
    Div2 = 0b01,
@ -353,6 +356,21 @@ macro_rules! timer_channels {
                    let regs = unsafe { &*<$TY>::ptr() };
                    regs.[< $ccmrx _input >]().modify(|_, w| w.[< ic $index f >]().bits(filter as u8));
                }
                /// Configure the input capture prescaler.
                ///
                /// # Args
                /// * `psc` - Prescaler exponent.
                #[allow(dead_code)]
                pub fn configure_prescaler(&mut self, prescaler: super::Prescaler) {
                    // Note(unsafe): This channel owns all access to the specific timer channel.
                    // Only atomic operations on completed on the timer registers.
                    let regs = unsafe { &*<$TY>::ptr() };
                    // Note(unsafe): Enum values are all valid.
                    #[allow(unused_unsafe)]
                    regs.[< $ccmrx _input >]().modify(|_, w| unsafe {
                        w.[< ic $index psc >]().bits(prescaler as u8)});
                }
            }
            // Note(unsafe): This manually implements DMA support for input-capture channels. This
--- a/src/lib.rs
+++ b/src/lib.rs
@ -1,8 +1,18 @@
 #![no_std]
 #![cfg_attr(feature = "nightly", feature(core_intrinsics))]
 #[macro_use]
 extern crate log;
 pub mod hardware;
 pub mod net;
 /// Macro to reduce rightward drift when calling the same closure-based API
 /// on multiple structs simultaneously, e.g. when accessing DMA buffers.
 /// This could be improved a bit using the tuple-based style from `mutex-trait`.
 #[macro_export]
 macro_rules! flatten_closures {
    ($fn:ident, $e:ident, $fun:block) => {
        $e.$fn(|$e| $fun ).unwrap()
    };
    ($fn:ident, $e:ident, $($es:ident),+, $fun:block) => {
        $e.$fn(|$e| flatten_closures!($fn, $($es),*, $fun)).unwrap()
    };
 }
--- a/src/net/miniconf_client.rs
+++ b/src/net/miniconf_client.rs
@ -11,6 +11,7 @@
 ///! Respones to settings updates are sent without quality-of-service guarantees, so there's no
 ///! guarantee that the requestee will be informed that settings have been applied.
 use heapless::String;
 use log::info;
 use super::{MqttMessage, NetworkReference, SettingsResponse, UpdateState};
 use crate::hardware::design_parameters::MQTT_BROKER;
@ -102,7 +103,7 @@ where
            let path = match topic.strip_prefix(prefix) {
                // For paths, we do not want to include the leading slash.
                Some(path) => {
-                    if path.len() > 0 {
+                    if !path.is_empty() {
                        &path[1..]
                    } else {
                        path
@ -116,9 +117,8 @@ where
            let message: SettingsResponse = settings
                .string_set(path.split('/').peekable(), message)
-                .and_then(|_| {
+                .map(|_| {
                    update = true;
                    Ok(())
                })
                .into();
--- a/src/net/mod.rs
+++ b/src/net/mod.rs
@ -5,31 +5,29 @@
 ///! telemetry (via MQTT), configuration of run-time settings (via MQTT + Miniconf), and live data
 ///! streaming over raw UDP/TCP sockets. This module encompasses the main processing routines
 ///! related to Stabilizer networking operations.
 pub use heapless;
 pub use miniconf;
 pub use serde;
 pub mod messages;
 pub mod miniconf_client;
 pub mod network_processor;
 pub mod shared;
 pub mod telemetry;
 pub mod data_stream;
 use crate::hardware::{cycle_counter::CycleCounter, EthernetPhy, NetworkStack};
 use messages::{MqttMessage, SettingsResponse};
 use miniconf_client::MiniconfClient;
 use network_processor::NetworkProcessor;
 use shared::NetworkManager;
 use telemetry::TelemetryClient;
 use core::fmt::Write;
 use heapless::String;
 use miniconf::Miniconf;
 use serde::Serialize;
 use core::fmt::Write;
 mod data_stream;
 mod messages;
 mod miniconf_client;
 mod network_processor;
 mod shared;
 mod telemetry;
 pub use data_stream::BlockGenerator;
 use crate::hardware::{CycleCounter, EthernetPhy, NetworkStack};
 use data_stream::DataStream;
 use messages::{MqttMessage, SettingsResponse};
 pub use miniconf_client::MiniconfClient;
 pub use network_processor::NetworkProcessor;
 pub use shared::NetworkManager;
 use smoltcp_nal::embedded_nal::SocketAddr;
 pub use telemetry::{Telemetry, TelemetryBuffer, TelemetryClient};
 pub type NetworkReference = shared::NetworkStackProxy<'static, NetworkStack>;
 #[derive(Copy, Clone, PartialEq)]
--- a/src/net/network_processor.rs
+++ b/src/net/network_processor.rs
@ -4,7 +4,7 @@
 ///! The network processir is a small taks to regularly process incoming data over ethernet, handle
 ///! the ethernet PHY state, and reset the network as appropriate.
 use super::{NetworkReference, UpdateState};
-use crate::hardware::{CycleCounter, EthernetPhy};
+use crate::hardware::{cycle_counter::CycleCounter, EthernetPhy};
 /// Processor for managing network hardware.
 pub struct NetworkProcessor {
--- a/src/net/telemetry.rs
+++ b/src/net/telemetry.rs
@ -16,7 +16,7 @@ use serde::Serialize;
 use super::NetworkReference;
 use crate::hardware::{
-    design_parameters::MQTT_BROKER, AdcCode, AfeGain, DacCode,
+    adc::AdcCode, afe::Gain, dac::DacCode, design_parameters::MQTT_BROKER,
 };
 /// The telemetry client for reporting telemetry data over MQTT.
@ -73,7 +73,7 @@ impl TelemetryBuffer {
    ///
    /// # Returns
    /// The finalized telemetry structure that can be serialized and reported.
-    pub fn finalize(self, afe0: AfeGain, afe1: AfeGain) -> Telemetry {
+    pub fn finalize(self, afe0: Gain, afe1: Gain) -> Telemetry {
        let in0_volts = Into::<f32>::into(self.adcs[0]) / afe0.as_multiplier();
        let in1_volts = Into::<f32>::into(self.adcs[1]) / afe1.as_multiplier();
`@ -1,4 +1,4 @@`
	`pub use num::Complex;`	`pub use num_complex::Complex;`

	`use super::{atan2, cossin};`	`use super::{atan2, cossin};`