use cubecl::prelude::*;
use cubecl_core as cubecl;
use crate::{ReinterpretSlice, ReinterpretSliceMut};
use half::f16;
#[cube(launch_unchecked)]
fn kernel_read_global(input: &Array<Line<i8>>, output: &mut Array<f16>) {
let line_size = input.line_size();
let list = ReinterpretSlice::<i8, f16>::new(input.to_slice(), line_size);
output[UNIT_POS] = list.read(UNIT_POS);
}
pub fn run_test_read_global<R: Runtime>(client: ComputeClient<R::Server>, line_size: usize) {
if !client.properties().features.dynamic_line_size {
return; }
let target = [f16::from_f32(1.0), f16::from_f32(-8.5)];
let casted: [i8; 4] = unsafe { core::mem::transmute(target) };
let input = client.create(i8::as_bytes(&casted));
let output = client.empty(4);
unsafe {
kernel_read_global::launch_unchecked::<R>(
&client,
CubeCount::new_single(),
CubeDim::new_1d(2),
ArrayArg::from_raw_parts::<i8>(&input, 4 / line_size, line_size as u8),
ArrayArg::from_raw_parts::<f16>(&output, 2, 1),
);
}
let actual = client.read_one(output);
let actual = f16::from_bytes(&actual);
assert_eq!(actual, target);
}
#[cube(launch_unchecked)]
fn kernel_write_global(output: &mut Array<Line<i8>>, input: &Array<f16>) {
let line_size = output.line_size();
let mut list = ReinterpretSliceMut::<i8, f16>::new(output.to_slice_mut(), line_size);
list.write(UNIT_POS, input[UNIT_POS]);
}
pub fn run_test_write_global<R: Runtime>(client: ComputeClient<R::Server>, line_size: usize) {
if !client.properties().features.dynamic_line_size {
return; }
let source = [f16::from_f32(1.0), f16::from_f32(-8.5)];
let casted: [i8; 4] = unsafe { core::mem::transmute(source) };
let output = client.empty(4);
let input = client.create(f16::as_bytes(&source));
unsafe {
kernel_write_global::launch_unchecked::<R>(
&client,
CubeCount::new_single(),
CubeDim::new_1d(2),
ArrayArg::from_raw_parts::<i8>(&output, 4 / line_size, line_size as u8),
ArrayArg::from_raw_parts::<f16>(&input, 2, 1),
);
}
let actual = client.read_one(output);
let actual = i8::from_bytes(&actual);
assert_eq!(actual, casted);
}
#[cube(launch_unchecked)]
fn kernel_read_shared_memory(output: &mut Array<f16>) {
let mut mem = SharedMemory::<i8>::new_lined(1_u32, 4_u32);
if UNIT_POS == 0 {
let mut line = Line::empty(4_u32);
line[0] = 0_i8;
line[1] = 60_i8;
line[2] = 64_i8;
line[3] = -56_i8;
mem[0] = line;
}
sync_cube();
let list = ReinterpretSlice::<i8, f16>::new(mem.to_slice(), 4_u32);
output[UNIT_POS] = list.read(UNIT_POS);
}
pub fn run_test_read_shared_memory<R: Runtime>(client: ComputeClient<R::Server>) {
if !client.properties().features.dynamic_line_size {
return; }
let target = [f16::from_f32(1.0), f16::from_f32(-8.5)];
let output = client.empty(4);
unsafe {
kernel_read_shared_memory::launch_unchecked::<R>(
&client,
CubeCount::new_single(),
CubeDim::new_1d(2),
ArrayArg::from_raw_parts::<f16>(&output, 2, 1),
);
}
let actual = client.read_one(output);
let actual = f16::from_bytes(&actual);
assert_eq!(actual, target);
}
#[cube(launch_unchecked)]
fn kernel_write_shared_memory(output: &mut Array<Line<i8>>, input: &Array<f16>) {
let mut mem = SharedMemory::<i8>::new_lined(1_u32, 4_u32);
let mut list = ReinterpretSliceMut::<i8, f16>::new(mem.to_slice_mut(), 4_u32);
list.write(UNIT_POS, input[UNIT_POS]);
output[2 * UNIT_POS] = mem[2 * UNIT_POS];
output[2 * UNIT_POS + 1] = mem[2 * UNIT_POS + 1];
}
pub fn run_test_write_shared_memory<R: Runtime>(client: ComputeClient<R::Server>) {
if !client.properties().features.dynamic_line_size {
return; }
let source = [f16::from_f32(1.0), f16::from_f32(-8.5)];
let casted: [i8; 4] = unsafe { core::mem::transmute(source) };
let output = client.empty(4);
let input = client.create(f16::as_bytes(&source));
unsafe {
kernel_write_shared_memory::launch_unchecked::<R>(
&client,
CubeCount::new_single(),
CubeDim::new_1d(2),
ArrayArg::from_raw_parts::<i8>(&output, 1, 4),
ArrayArg::from_raw_parts::<f16>(&input, 2, 1),
);
}
let actual = client.read_one(output);
let actual = i8::from_bytes(&actual);
assert_eq!(actual, casted);
}
#[macro_export]
macro_rules! testgen_reinterpret_slice {
() => {
mod reinterpret_slice_f16 {
use super::*;
mod global {
use super::*;
#[test]
fn read_from_i8x1() {
let client = TestRuntime::client(&Default::default());
cubecl_std::tests::reinterpret_slice::run_test_read_global::<TestRuntime>(client, 1);
}
#[test]
fn read_from_i8x2() {
let client = TestRuntime::client(&Default::default());
cubecl_std::tests::reinterpret_slice::run_test_read_global::<TestRuntime>(client, 2);
}
#[test]
fn read_from_i8x4() {
let client = TestRuntime::client(&Default::default());
cubecl_std::tests::reinterpret_slice::run_test_read_global::<TestRuntime>(client, 4);
}
#[test]
fn write_into_i8x1() {
let client = TestRuntime::client(&Default::default());
cubecl_std::tests::reinterpret_slice::run_test_write_global::<TestRuntime>(client, 1);
}
#[test]
fn write_into_i8x2() {
let client = TestRuntime::client(&Default::default());
cubecl_std::tests::reinterpret_slice::run_test_write_global::<TestRuntime>(client, 2);
}
#[test]
fn write_into_i8x4() {
let client = TestRuntime::client(&Default::default());
cubecl_std::tests::reinterpret_slice::run_test_write_global::<TestRuntime>(client, 4);
}
}
mod shared_memory {
use super::*;
#[test]
fn read_from_i8x4() {
let client = TestRuntime::client(&Default::default());
cubecl_std::tests::reinterpret_slice::run_test_read_shared_memory::<TestRuntime>(client);
}
#[test]
fn write_from_i8x4() {
let client = TestRuntime::client(&Default::default());
cubecl_std::tests::reinterpret_slice::run_test_write_shared_memory::<TestRuntime>(client);
}
}
}
};
}