Crate rustacuda[][src]

Expand description

This crate provides a safe, user-friendly wrapper around the CUDA Driver API.

CUDA Terminology:

Devices and Hosts:

This crate and its documentation uses the terms “device” and “host” frequently, so it’s worth explaining them in more detail. A device refers to a CUDA-capable GPU or similar device and its associated external memory space. The host is the CPU and its associated memory space. Data must be transferred from host memory to device memory before the device can use it for computations, and the results must then be transferred back to host memory.

Contexts, Modules, Streams and Functions:

A CUDA context is akin to a process on the host - it contains all of the state for working with a device, all memory allocations, etc. Each context is associated with a single device.

A Module is similar to a shared-object library - it is a piece of compiled code which exports functions and global values. Functions can be loaded from modules and launched on a device as one might load a function from a shared-object file and call it. Functions are also known as kernels and the two terms will be used interchangeably.

A Stream is akin to a thread - asynchronous work such as kernel execution can be queued into a stream. Work within a single stream will execute sequentially in the order that it was submitted, and may interleave with work from other streams.

Grids, Blocks and Threads:

CUDA devices typically execute kernel functions on many threads in parallel. These threads can be grouped into thread blocks, which share an area of fast hardware memory known as shared memory. Thread blocks can be one-, two-, or three-dimensional, which is helpful when working with multi-dimensional data such as images. Thread blocks are then grouped into grids, which can also be one-, two-, or three-dimensional.

CUDA devices often contain multiple separate processors. Each processor is capable of excuting many threads simultaneously, but they must be from the same thread block. Thus, it is important to ensure that the grid size is large enough to provide work for all processors. On the other hand, if the thread blocks are too small each processor will be under-utilized and the code will be unable to make effective use of shared memory.

Usage:

Before using RustaCUDA, you must install the CUDA development libraries for your system. Version 8.0 or newer is required. You must also have a CUDA-capable GPU installed with the appropriate drivers.

Add the following to your Cargo.toml:

[dependencies]
rustacuda = "0.1"
rustacuda_derive = "0.1"
rustacuda_core = "0.1"

And this to your crate root:

#[macro_use]
extern crate rustacuda;

#[macro_use]
extern crate rustacuda_derive;

extern crate rustacuda_core;

Finally, set the CUDA_LIBRARY_PATH environment variable to the location of your CUDA libraries. For example, on Windows (MINGW):

export CUDA_LIBRARY_PATH="C:\Program Files\NVIDIA GPU Computing Toolkit\CUDA\v9.1\lib\x64"

Examples

Adding two numbers on the device:

First, download the resources/add.ptx file from the RustaCUDA repository and place it in the resources directory for your application.

#[macro_use]
extern crate rustacuda;
extern crate rustacuda_core;

use rustacuda::prelude::*;
use rustacuda::memory::DeviceBox;
use std::error::Error;
use std::ffi::CString;

fn main() -> Result<(), Box<dyn Error>> {
    // Initialize the CUDA API
    rustacuda::init(CudaFlags::empty())?;
     
    // Get the first device
    let device = Device::get_device(0)?;

    // Create a context associated to this device
    let context = Context::create_and_push(
        ContextFlags::MAP_HOST | ContextFlags::SCHED_AUTO, device)?;

    // Load the module containing the function we want to call
    let module_data = CString::new(include_str!("../resources/add.ptx"))?;
    let module = Module::load_from_string(&module_data)?;

    // Create a stream to submit work to
    let stream = Stream::new(StreamFlags::NON_BLOCKING, None)?;

    // Allocate space on the device and copy numbers to it.
    let mut x = DeviceBox::new(&10.0f32)?;
    let mut y = DeviceBox::new(&20.0f32)?;
    let mut result = DeviceBox::new(&0.0f32)?;

    // Launching kernels is unsafe since Rust can't enforce safety - think of kernel launches
    // as a foreign-function call. In this case, it is - this kernel is written in CUDA C.
    unsafe {
        // Launch the `sum` function with one block containing one thread on the given stream.
        launch!(module.sum<<<1, 1, 0, stream>>>(
            x.as_device_ptr(),
            y.as_device_ptr(),
            result.as_device_ptr(),
            1 // Length
        ))?;
    }

    // The kernel launch is asynchronous, so we wait for the kernel to finish executing
    stream.synchronize()?;

    // Copy the result back to the host
    let mut result_host = 0.0f32;
    result.copy_to(&mut result_host)?;
     
    println!("Sum is {}", result_host);

    Ok(())
}

Modules

CUDA context management

Functions and types for enumerating CUDA devices and retrieving information about them.

Types for error handling

Events can be used to track status and dependencies, as well as to measure the duration of work submitted to a CUDA stream.

Functions and types for working with CUDA kernels.

Access to CUDA’s memory allocation and transfer functions.

Functions and types for working with CUDA modules.

This module re-exports a number of commonly-used types for working with RustaCUDA.

Streams of work for the device to perform.

Macros

Launch a kernel function asynchronously.

Structs

Struct representing the CUDA API version number.

Bit flags for initializing the CUDA driver. Currently, no flags are defined, so CudaFlags::empty() is the only valid value.

Functions

Initialize the CUDA Driver API.

Shortcut for initializing the CUDA Driver API and creating a CUDA context with default settings for the first device.