use std::collections::HashMap;
use crate::{
error::AUTDInternalError,
fpga::FilterPhase,
geometry::{Device, Geometry, Transducer},
operation::{Operation, TypeTag},
};
use super::FilterType;
#[derive(Default)]
pub struct ConfigurePhaseFilterOp {
remains: HashMap<usize, usize>,
}
impl<T: Transducer> Operation<T> for ConfigurePhaseFilterOp {
fn pack(&mut self, device: &Device<T>, tx: &mut [u8]) -> Result<usize, AUTDInternalError> {
assert_eq!(self.remains[&device.idx()], 1);
assert!(tx.len() >= 2 + device.num_transducers() * std::mem::size_of::<FilterPhase>());
tx[0] = TypeTag::Filter as u8;
tx[1] = FilterType::AddPhase as u8;
unsafe {
let dst = std::slice::from_raw_parts_mut(
tx[2..].as_mut_ptr() as *mut FilterPhase,
device.num_transducers(),
);
dst.iter_mut()
.zip(device.iter())
.for_each(|(d, tr)| d.set(tr.phase_filter(), tr.cycle()));
}
Ok(2 + device.num_transducers() * std::mem::size_of::<FilterPhase>())
}
fn required_size(&self, device: &Device<T>) -> usize {
2 + device.num_transducers() * std::mem::size_of::<FilterPhase>()
}
fn init(&mut self, geometry: &Geometry<T>) -> Result<(), AUTDInternalError> {
self.remains = geometry.devices().map(|device| (device.idx(), 1)).collect();
Ok(())
}
fn remains(&self, device: &Device<T>) -> usize {
self.remains[&device.idx()]
}
fn commit(&mut self, device: &Device<T>) {
self.remains.insert(device.idx(), 0);
}
}
#[cfg(test)]
mod tests {
use rand::prelude::*;
use super::*;
use crate::{
defined::PI,
geometry::{tests::create_geometry, LegacyTransducer},
};
const NUM_TRANS_IN_UNIT: usize = 249;
const NUM_DEVICE: usize = 10;
#[test]
fn filter_phase_op() {
let mut geometry = create_geometry::<LegacyTransducer>(NUM_DEVICE, NUM_TRANS_IN_UNIT);
let mut tx =
vec![0x00u8; (2 + NUM_TRANS_IN_UNIT * std::mem::size_of::<u16>()) * NUM_DEVICE];
let mut rng = rand::thread_rng();
geometry.devices_mut().for_each(|dev| {
dev.iter_mut().for_each(|tr| {
tr.set_phase_filter(rng.gen_range(-2.0 * PI..2.0 * PI));
})
});
let mut op = ConfigurePhaseFilterOp::default();
assert!(op.init(&geometry).is_ok());
geometry.devices().for_each(|dev| {
assert_eq!(
op.required_size(dev),
2 + NUM_TRANS_IN_UNIT * std::mem::size_of::<u16>()
)
});
geometry
.devices()
.for_each(|dev| assert_eq!(op.remains(dev), 1));
geometry.devices().for_each(|dev| {
assert!(op
.pack(
dev,
&mut tx[dev.idx() * (2 + NUM_TRANS_IN_UNIT * std::mem::size_of::<u16>())..]
)
.is_ok());
op.commit(dev);
});
geometry
.devices()
.for_each(|dev| assert_eq!(op.remains(dev), 0));
geometry.devices().for_each(|dev| {
assert_eq!(
tx[dev.idx() * (2 + NUM_TRANS_IN_UNIT * std::mem::size_of::<u16>())],
TypeTag::Filter as u8
);
assert_eq!(
tx[dev.idx() * (2 + NUM_TRANS_IN_UNIT * std::mem::size_of::<u16>()) + 1],
FilterType::AddPhase as u8
);
tx.chunks(2)
.skip((1 + NUM_TRANS_IN_UNIT) * dev.idx())
.skip(1)
.zip(dev.iter())
.for_each(|(d, tr)| {
let phase = FilterPhase::to_phase(tr.phase_filter(), tr.cycle());
assert_eq!(d[0], (phase & 0xFF) as u8);
assert_eq!(d[1], (phase >> 8) as u8);
})
});
}
}