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//use crate::common::validate_inputs;
use crate::indicators::max::{
min_data, output_length, IndicatorState, State, INPUTS_WIDTH, OPTIONS_WIDTH,
};
use crate::indicators::simd_indicators::max_simd::{assets::Calc, SimdState};
use crate::indicators::simd_indicators::road_train::{Asset, Driver, PrimeMover};
use crate::types::IndicatorError;
use crate::{common::validate_options, common_simd::assets::validate_inputs};
/// SIMD driver that advances the Maximum Value (max) across `N` asset lanes per scheduling
/// epoch.
struct MaxDriver {
periods: (usize, usize),
}
impl Driver<State> for MaxDriver {
/// Processes one epoch of bars for `N` assets simultaneously using SIMD.
///
/// Reads from `inputs[asset][0]` (real), writes the rolling maximum to
/// `outputs[asset][0]`, and updates `states[asset]` in place.
fn next_run<const N: usize>(
&mut self,
inputs: Vec<Vec<&[f64]>>,
mut outputs: Vec<Vec<&mut [f64]>>,
mut states: Vec<&mut State>,
_options: Vec<Option<&()>>,
) {
let len = inputs[0][0].len();
//collect outputs
let max_line_ptr = crate::extract_output_ptrs!(outputs, N, max_line_ptr);
let real_ptrs = crate::extract_input_ptrs!(inputs, N, real_ptrs);
let mut state = SimdState::new(&states);
let (period, look_back) = self.periods;
//let current: Vec<Simd<f64, N>> = crate::create_simd_vec_from_inputs!(real_ptrs, N, len);
match period {
1..=14 => {
for (j, i) in (self.periods.1..len).enumerate() {
let (max, _) =
unsafe { state.calc_unchecked_simd::<1>(real_ptrs, i, look_back) };
// Store results using pre-computed pointers
crate::write_simd_at_indices!(N, j,
max_line_ptr => max
);
}
}
/*15..=24 => {
for (j, i) in (self.periods.1..len).enumerate() {
let (max, _) =
unsafe { state.calc_unchecked_simd::<4>(real_ptrs, i, self.periods) };
// Store results using pre-computed pointers
crate::write_simd_at_indices!(N, j,
max_line_ptr => max
);
}
}*/
_ => {
for (j, i) in (self.periods.1..len).enumerate() {
let (max, _) =
unsafe { state.calc_unchecked_simd::<8>(real_ptrs, i, look_back) };
// Store results using pre-computed pointers
crate::write_simd_at_indices!(N, j,
max_line_ptr => max
);
}
}
}
// Update states efficiently
state.write_states(&mut states);
}
}
/// Calculates the Maximum Value (max) for `N` assets simultaneously using SIMD parallelism.
///
/// Uses the [`PrimeMover`] scheduler to batch assets into SIMD-width groups.
///
/// # Arguments
/// * `inputs` - An array of `N` asset input sets; `inputs[i]` is `[&[f64]; INPUTS_WIDTH]`
/// containing `[real]` for asset `i`.
/// * `options` - Shared options slice; `options[0]` is the period.
/// * `_optional_outputs` - Unused; max has no optional outputs.
///
/// # Returns
/// `Ok((outputs, states))` where `outputs[i][0]` is the rolling maximum for asset `i`
/// and `states[i]` is the final [`IndicatorState`] for asset `i`.
/// Returns `Err(IndicatorError)` if any input slice is too short or options are invalid.
pub fn indicator_by_assets<const N: usize>(
inputs: &[&[&[f64]; INPUTS_WIDTH]; N], //stock[ fields [ field [f64] ] ]
options: &[f64; OPTIONS_WIDTH],
_optional_outputs: Option<&[bool]>,
) -> Result<(Vec<Vec<Vec<f64>>>, Vec<IndicatorState>), IndicatorError> {
validate_inputs::<INPUTS_WIDTH>(inputs, min_data(options))?;
validate_options(options)?;
let periods = (options[0] as usize, options[0] as usize - 1);
let mut road_train = PrimeMover::<N, State>::new();
let mut output_buffers = Vec::with_capacity(N);
for i in 0..N {
let asset_inputs = vec![
inputs[i][0], // real
];
let max_line = {
let len = inputs[i][0].len();
let capacity = output_length(len, options);
crate::uninit_vec!(f64, capacity)
};
let state = State::new(
inputs[i][0][0], // real
periods.1,
);
let mut output_buffer = vec![max_line];
//let adosc_len = output_buffer[0].len();
let mut asset_outputs = Vec::with_capacity(output_buffer.len());
for j in 0..output_buffer.len() {
unsafe {
//let slice_len = output_buffer.len() - starts[j];
// Get a mutable reference to the output buffer for this asset
let output_buffer = &mut output_buffer[j];
asset_outputs.push(std::slice::from_raw_parts_mut(
output_buffer.as_mut_ptr(), //slice from
output_buffer.len(), // slice to
));
}
}
road_train.add_asset(Asset::new(
asset_inputs,
asset_outputs,
i,
periods.1,
periods.1,
state,
None,
));
output_buffers.push(output_buffer);
}
let mut driver = MaxDriver { periods };
let states_vec = road_train.drive(&mut driver);
let mut states = Vec::with_capacity(N);
for (i, state) in states_vec.into_iter().enumerate() {
states.push(IndicatorState::new(inputs[i][0], state, periods));
}
Ok((output_buffers, states))
}