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//! Linear algebra operations for Matrix
//!
//! This module provides linear operations:
//! - `transpose()` - Matrix transpose
//! - `matvec()` - Matrix-vector multiplication
//! - `vecmat()` - Vector-matrix multiplication
use crate::{Backend, TruenoError, Vector};
#[cfg(feature = "tracing")]
use tracing::instrument;
/// Backend dispatch macro for dot product - centralizes platform-specific SIMD dispatch
macro_rules! dispatch_dot {
($backend:expr, $a:expr, $b:expr) => {{
#[cfg(target_arch = "x86_64")]
use crate::backends::{avx2::Avx2Backend, sse2::Sse2Backend};
use crate::backends::{scalar::ScalarBackend, VectorBackend};
// SAFETY: CPU features verified at runtime before backend selection
unsafe {
match $backend {
Backend::Scalar => ScalarBackend::dot($a, $b),
#[cfg(target_arch = "x86_64")]
Backend::SSE2 | Backend::AVX => Sse2Backend::dot($a, $b),
#[cfg(target_arch = "x86_64")]
Backend::AVX2 | Backend::AVX512 => Avx2Backend::dot($a, $b),
#[cfg(not(target_arch = "x86_64"))]
Backend::SSE2 | Backend::AVX | Backend::AVX2 | Backend::AVX512 => {
ScalarBackend::dot($a, $b)
}
#[cfg(any(target_arch = "aarch64", target_arch = "arm"))]
Backend::NEON => {
use crate::backends::neon::NeonBackend;
NeonBackend::dot($a, $b)
}
#[cfg(not(any(target_arch = "aarch64", target_arch = "arm")))]
Backend::NEON => ScalarBackend::dot($a, $b),
#[cfg(target_arch = "wasm32")]
Backend::WasmSIMD => {
use crate::backends::wasm::WasmBackend;
WasmBackend::dot($a, $b)
}
#[cfg(not(target_arch = "wasm32"))]
Backend::WasmSIMD => ScalarBackend::dot($a, $b),
Backend::GPU | Backend::Auto => ScalarBackend::dot($a, $b),
}
}
}};
}
use super::super::Matrix;
impl Matrix<f32> {
/// Transpose this matrix (swap rows and columns)
///
/// Returns a new matrix with dimensions swapped: `self.rows → result.cols`,
/// `self.cols → result.rows`.
///
/// # Performance
///
/// Uses cache-optimized block-wise transpose with 32x32 blocks.
/// Sequential writes for output ensure good cache behavior.
///
/// # Example
///
/// ```
/// use trueno::Matrix;
///
/// let m = Matrix::from_vec(2, 3, vec![1.0, 2.0, 3.0, 4.0, 5.0, 6.0]).unwrap();
/// let t = m.transpose();
///
/// // [[1, 2, 3], [[1, 4],
/// // [4, 5, 6]] → [2, 5],
/// // [3, 6]]
/// assert_eq!(t.rows(), 3);
/// assert_eq!(t.cols(), 2);
/// assert_eq!(t.get(0, 0), Some(&1.0));
/// assert_eq!(t.get(0, 1), Some(&4.0));
/// assert_eq!(t.get(1, 0), Some(&2.0));
/// ```
// KAIZEN-040: Delegate to crate::blis::transpose which has AVX2 8×8
// in-register micro-kernel with 64×64 L1-resident tiling and prefetch.
// Previous implementation used scalar 32×32 blocks.
#[cfg_attr(feature = "tracing", instrument(skip(self), fields(dims = %format!("{}x{}", self.rows, self.cols))))]
pub fn transpose(&self) -> Matrix<f32> {
// Uninit allocation: transpose writes every element (plus remainder edges).
// Skipping the zero-fill saves ~300µs at 2048×2048 (16MB).
let n = self.cols * self.rows;
let mut data: Vec<f32> = Vec::with_capacity(n);
// SAFETY: transpose() writes every element of result.data:
// - 8×8 AVX2 tiles cover rows/8 × cols/8 blocks
// - Scalar remainder writes cover the edge rows/cols
unsafe {
data.set_len(n);
}
let mut result = Matrix { rows: self.cols, cols: self.rows, data, backend: self.backend };
// BLIS transpose handles AVX2 dispatch, remainder edges, and shape-adaptive
// loop ordering internally. Dimensions are correct by construction so
// the only possible error (size mismatch) cannot occur.
if let Err(e) =
crate::blis::transpose::transpose(self.rows, self.cols, &self.data, &mut result.data)
{
// Unreachable: result is allocated as cols×rows which matches rows×cols elements.
// If somehow triggered, fall back to scalar element-wise transpose.
debug_assert!(false, "BLIS transpose dimension mismatch: {e}");
for i in 0..self.rows {
for j in 0..self.cols {
result.data[j * self.rows + i] = self.data[i * self.cols + j];
}
}
}
result
}
/// Matrix-vector multiplication (column vector): A × v
///
/// Multiplies this matrix by a column vector, computing `A × v` where the result
/// is a column vector with length equal to the number of rows in `A`.
///
/// # Mathematical Definition
///
/// For an m×n matrix A and an n-dimensional vector v:
/// ```text
/// result[i] = Σ(j=0 to n-1) A[i,j] × v[j]
/// ```
///
/// # Arguments
///
/// * `v` - Column vector with length equal to `self.cols()`
///
/// # Returns
///
/// A new vector with length `self.rows()`
///
/// # Errors
///
/// Returns `InvalidInput` if `v.len() != self.cols()`
///
/// # Example
///
/// ```
/// use trueno::{Matrix, Vector};
///
/// let m = Matrix::from_vec(2, 3, vec![1.0, 2.0, 3.0, 4.0, 5.0, 6.0]).unwrap();
/// let v = Vector::from_slice(&[1.0, 2.0, 3.0]);
/// let result = m.matvec(&v).unwrap();
///
/// // [[1, 2, 3] [1] [1×1 + 2×2 + 3×3] [14]
/// // [4, 5, 6]] × [2] = [4×1 + 5×2 + 6×3] = [32]
/// // [3]
/// assert_eq!(result.as_slice(), &[14.0, 32.0]);
/// ```
pub fn matvec(&self, v: &Vector<f32>) -> Result<Vector<f32>, TruenoError> {
if v.len() != self.cols {
return Err(TruenoError::InvalidInput(format!(
"Vector length {} does not match matrix columns {} for matrix-vector multiplication",
v.len(),
self.cols
)));
}
let v_slice = v.as_slice();
// Uninit allocation: every element is SET (not accumulated) by
// `*result = dispatch_dot!(...)` or parallel `*out = dispatch_dot!(...)`.
let n = self.rows;
let mut result_data: Vec<f32> = Vec::with_capacity(n);
// SAFETY: Both serial and parallel paths write every element via
// `*out = dispatch_dot!(...)` (SET, not accumulate). No reads before writes.
unsafe {
result_data.set_len(n);
}
// Parallel execution for large matrices (≥2048 rows)
// CGP-DBUF: lowered from 4096 to 2048. Previous regression at 2048 was
// from thread::scope (~40µs). Rayon par_chunks_mut is ~3µs overhead.
// 2048×2048 matvec: ~180µs compute → 3µs is 1.7% acceptable.
#[cfg(feature = "parallel")]
{
const PARALLEL_THRESHOLD: usize = 2048;
if self.rows >= PARALLEL_THRESHOLD {
use rayon::prelude::*;
// Chunk rows into slices per thread (amortizes task overhead).
// Previous per-row parallelism spawned rows-many tasks; chunked
// spawns num_threads tasks, each processing rows/num_threads rows.
let num_threads = rayon::current_num_threads().min(8);
let rows_per = (self.rows + num_threads - 1) / num_threads;
let cols = self.cols;
let data = &self.data;
result_data.par_chunks_mut(rows_per).enumerate().for_each(|(tid, out_chunk)| {
let row_start = tid * rows_per;
for (i, out) in out_chunk.iter_mut().enumerate() {
let r = row_start + i;
let row = &data[r * cols..(r + 1) * cols];
*out = dispatch_dot!(self.backend, row, v_slice);
}
});
// Move result_data — avoids redundant from_slice copy.
return Ok(Vector::from_vec(result_data));
}
}
// SIMD-optimized execution: each row-vector product is a dot product
for (i, result) in result_data.iter_mut().enumerate() {
let row_start = i * self.cols;
let row = &self.data[row_start..(row_start + self.cols)];
// Use SIMD dot product for each row
*result = dispatch_dot!(self.backend, row, v_slice);
}
// Move result_data — avoids redundant from_slice copy.
Ok(Vector::from_vec(result_data))
}
/// Vector-matrix multiplication (row vector): v^T × A
///
/// Multiplies a row vector by this matrix, computing `v^T × A` where the result
/// is a row vector with length equal to the number of columns in `A`.
///
/// # Mathematical Definition
///
/// For an m-dimensional vector v and an m×n matrix A:
/// ```text
/// result[j] = Σ(i=0 to m-1) v[i] × A[i,j]
/// ```
///
/// # Arguments
///
/// * `v` - Row vector with length equal to `m.rows()`
/// * `m` - Matrix to multiply
///
/// # Returns
///
/// A new vector with length `m.cols()`
///
/// # Errors
///
/// Returns `InvalidInput` if `v.len() != m.rows()`
///
/// # Example
///
/// ```
/// use trueno::{Matrix, Vector};
///
/// let m = Matrix::from_vec(2, 3, vec![1.0, 2.0, 3.0, 4.0, 5.0, 6.0]).unwrap();
/// let v = Vector::from_slice(&[1.0, 2.0]);
/// let result = Matrix::vecmat(&v, &m).unwrap();
///
/// // [1, 2] × [[1, 2, 3] = [1×1 + 2×4, 1×2 + 2×5, 1×3 + 2×6]
/// // [4, 5, 6]]
/// // = [9, 12, 15]
/// assert_eq!(result.as_slice(), &[9.0, 12.0, 15.0]);
/// ```
// KAIZEN-041: Uses crate::blis::gemv with AVX2 VFMADD,
// 4-way K-unrolling and N-tiled accumulators.
pub fn vecmat(v: &Vector<f32>, m: &Matrix<f32>) -> Result<Vector<f32>, TruenoError> {
if v.len() != m.rows {
return Err(TruenoError::InvalidInput(format!(
"Vector length {} does not match matrix rows {} for vector-matrix multiplication",
v.len(),
m.rows
)));
}
let mut result_data = vec![0.0f32; m.cols];
// Parallelize along K dimension for large matrices (DRAM-bound → multi-channel).
// Threshold: K * N >= 4M (e.g., 2048×2048). Below this, thread overhead dominates.
#[cfg(feature = "parallel")]
{
const PARALLEL_THRESHOLD: usize = 4_000_000;
if m.rows * m.cols >= PARALLEL_THRESHOLD {
use rayon::prelude::*;
let n = m.cols;
let k = m.rows;
let num_threads = rayon::current_num_threads().min(8); // cap at 8 for DRAM BW
let k_per = (k + num_threads - 1) / num_threads;
// Each thread computes partial c for its slice of K rows
let partials: Vec<Vec<f32>> = (0..num_threads)
.into_par_iter()
.map(|t| {
let k_start = t * k_per;
let k_end = (k_start + k_per).min(k);
if k_start >= k_end {
return vec![0.0f32; n];
}
let mut local = vec![0.0f32; n];
let v_slice = &v.as_slice()[k_start..k_end];
let b_slice = &m.data[k_start * n..k_end * n];
crate::blis::gemv::gemv(k_end - k_start, n, v_slice, b_slice, &mut local);
local
})
.collect();
// Reduce partials
for p in &partials {
for (i, &v) in p.iter().enumerate() {
result_data[i] += v;
}
}
return Ok(Vector::from_vec(result_data));
}
}
crate::blis::gemv::gemv(m.rows, m.cols, v.as_slice(), &m.data, &mut result_data);
Ok(Vector::from_vec(result_data))
}
}
#[cfg(test)]
mod tests;