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CUDA
Hardware
NVIDIA maintains a list of supported hardware. For actual hardware, you'll need the "nvidia.ko" kernel module. Download the nvidia-kernel-source and nvidia-kernel-common packages, unpack /usr/src/nvidia-kernel.tar.bz2, and run make-kpkg modules_image. Install the resulting .deb, and modprobe nvidia. You'll see something like this in dmesg output:
nvidia: module license 'NVIDIA' taints kernel. Disabling lock debugging due to kernel taint nvidia 0000:07:00.0: enabling device (0000 -> 0003) nvidia 0000:07:00.0: PCI INT A -> GSI 21 (level, low) -> IRQ 21 nvidia 0000:07:00.0: setting latency timer to 64 NVRM: loading NVIDIA UNIX x86_64 Kernel Module 190.53 Wed Dec 9 15:29:46 PST 2009
Once the module is loaded, CUDA should be able to find the device. See below for sample outputs. Each device has a compute capability, though this does not encompass all differentiated capabilities (see also deviceOverlap and canMapHostMemory...). Note that "emulation mode" has been removed as of CUDA Toolkit Version 3.1.
CUDA model
Host
- A host contains zero or more CUDA-capable devices (emulation must be used if zero devices are available).
- It can run multiple CUDA processes, each composed of one or more host threads.
- A given host thread can execute code on only one device at once.
- Multiple host threads can execute code on the same device.
Device
- A device packages a streaming processor array (SPA), a memory interface, and possibly memory (global memory. device memory).
- In CUDA terminology, an integrated (vs discrete) device does not have its own global memory.
- Specially-prepared global memory is designated constant memory, and can be cached.
- Pinned (locked) host memory avoids a bounce buffer, accelerating transfers.
- Larger one-time setup cost due to device register programming for DMA transfers.
- This memory will be unswappable -- allocate only as much as is needed.
- Pinned memory can be mapped directly into CUDAspace on integrated devices or in the presence of some IOMMUs.
- "Zero (explicit)-copy" interface (can never hide all bus delays)
- Write-combining memory (configured via MTRRs or PATs) avoids PCI snoop requirements and maximizes linear throughput
- Subtle side-effects; not to be used glibly or carelessly!
- Distributes work at block granularity to Texture Processing Clusters (TPCs).
Texture Processing Cluster
Streaming Multiprocessors (SMs) are grouped into TPCs. Each TPC contains some number of SMs and a single texture processing unit, including a few filters and a cache for texture memory. The details of these texture caches have not generally been publicized, but NVIDIA optimization guides confirm 1- and 2-dimensional spatial caching to be in effect.
Streaming Multiprocessor
- Each SM has a register file, fast local (shared) memory, a cache for constant memory, an instruction cache (ROP), a multithreaded instruction dispatcher, and some number of Stream Processors (SPs).
- 8192 registers for compute capability <= 1.1, otherwise
- 16384 for compute capability <= 1.3
- A group of threads which share a memory and can "synchronize their execution to coördinate accesses to memory" (use a barrier) form a block. Each thread has a threadId within its (three-dimensional) block.
- For a block of dimensions <Dx, Dy, Dz>, the threadId of the thread having index <x, y, z> is (x + y * Dx + z * Dy * Dx).
- Register allocation is performed per-block, and rounded up to the nearest
- 256 registers per block for compute capability <= 1.1, otherwise
- 512 registers per block for compute capability <= 1.3.
- A group of blocks which share a kernel form a grid. Each block (and each thread within that block) has a blockId within its (two-dimensional) grid.
- For a grid of dimensions <Dx, Dy>, the blockId of the block having index <x, y> is (x + y * Dx).
- Thus, a given thread's <blockId X threadId> dyad is unique across the grid. All the threads of a block share a blockId, and corresponding threads of various blocks share a threadId.
- Each time the kernel is instantiated, new grid and block dimensions may be provided.
- A block's threads, starting from threadId 0, are broken up into contiguous warps having some warp size number of threads.
- Distributes out-of-order work at warp granularity across SPs.
- One program counter per warp -- divergence within warp leads to serialization.
- Divergence is trivially supported with a per-warp stack; warps reconverge at immediate post-dominators of branches
- Supports some maximum number of blocks and threads (~8 and ~768 on G80).
Block sizing
FIXME: review/verify this!
How tightly can we bound the optimal block size T, given a warp size w? The number of threads per block ought almost always be a multiple of w, both to:
- facilitate coalescing (coalescing requirements are related to w/2), and
- maximize utilization of SPs within warp-granular scheduling.
A SM has r registers and s words of shared memory, allocated per-block (see above). Assuming that w threads can be supported (i.e., that none requires more than r/w registers or s/w words of shared memory), the most obvious lower bound is w itself. The most obvious upper bound, assuming arbitrary available work, is the greatest multiple of w supported by hardware (and, obviously, the SDK). A block must be scheduled to an SM, which requires:
- registers sufficient to support the block,
- shared memory sufficient to support the block,
- that the total number of threads not exceed some limit t (likely bounding the divergence-tracking stacks), and
- that the total number of blocks not exceed some limit b (likely bounding the warp-scheduling complexity).
A given SM, then, supports T values through the minimum of {r/Thrreg, s/Blkshmem, and t}; as the block requires fewer registers and less shared memory, the upper bound converges to t.
Motivations for larger blocks include:
- freedom in the b dimension exposes parallelism until t <= b * T
- larger maximum possible kernels (an absolute limit exists on grid dimensions)
- better if data can be reused among threads (e.g. in tiled matrix multiply)
Motivations for smaller blocks include:
- freedom in the t dimension exposes parallelism until t >= b * T
- freedom in the r and s dimensions exposes parallelism until r >= b * T * Thrreg or s >= b * Blkshmem.
- cheaper per-block operations(?) (__syncthreads(), voting, etc)
- support for older hardware and SDKs
- fairer distribution among SMs and thus possibly better utilization, lower latency
- relative speedup tends to 0 as work grows arbitrarily on finite SMs
- relative speedup tends to 1/Fracpar on infinitely many SMs
We can now optimize occupancy for a specific {t, b, r and s}, assuming t to be a multiple of both w and b:
- Let T = t / b. T is thus guaranteed to be the smallest multiple of w such that t == b * T.
- Check the r and w conditions. FIXME: handle reduction
- FIXME: handle very large (external) kernels
Optimizing for ranges of hardware values is left as an exercise for the reader. Occupancy is only worth optimizing if the number of warps are insufficient to hide latencies. It might be possible to eliminate latencies altogether by reusing data throughout a block via shared memory; if the algorithm permits, this is almost certainly a net win. In that case, we likely want to maximize Blkshmem. A more advanced theory would incorporate the arithmetic intensity of a kernel...FIXME
Stream Processor
- In-order, multithreaded processor: memory latencies can be hidden only by TLP, not ILP.
- UPDATE Vasily Volkov's awesome GTC 2010 paper, "Better Performance at Lower Occupancy", destroys this notion.
- Really. Go read Vasily's paper. It's better than anything you'll find here.
- Arithmetic intensity and parallelism are paramount!
- Memory-bound kernels require sufficiently high occupancy (the ratio of concurrently-running warps to maximum possible concurrent warps (as applied, usually, to SMs)) to hide latency.
- UPDATE Vasily Volkov's awesome GTC 2010 paper, "Better Performance at Lower Occupancy", destroys this notion.
- No branch prediction or speculation (and thus also no pipeline flushes on mispredicted branches).
Memory type | PTX name | Sharing | Kernel access | Host access | Cache location | Adddressable |
---|---|---|---|---|---|---|
Registers | .reg | Per-thread | Read-write | None | None | No |
Special registers | .sreg | varies | Read-only | None | None | No |
Local memory | .local | Per-thread | Read-write | None | None | Yes |
Shared memory | .shared | Per-block | Read-write | None | None | Yes |
Global memory | .global | Global | Read-write | Read-write | 1.x: None
2.0+: L1 on SM, L2 on TPC(?) |
Yes |
Constant memory | .const | Per-grid | Read | Read-write | Stream multiprocessor | Yes |
Texture memory | .tex | Global | Read | Read-write | Texture processing cluster | texture API |
Parameters (to grids or functions) | .param | Per-grid (or per-thread) | Read-only (or read-write) | None | None | Yes (or restricted) |
Compute Capabilities
The original public CUDA revision was 1.0, implemented on the NV50 chipset corresponding to the GeForce 8 series. Compute capability, formed of a non-negative major and minor revision number, can be queried on CUDA-capable cards. All revisions thus far have been backwards-compatible.
Revision | Changes |
---|---|
1.1 |
|
1.2 |
|
1.3 |
|
2.0 |
|
2.1 | ? |
Building CUDA Apps
nvcc flags
- -ptax-options=-v displays per-thread register usage
SDK's common.mk
This assumes use of the SDK's common.mk, as recommended by the documentation.
- Add the library path to LD_LIBRARY_PATH, assuming CUDA's been installed to a non-standard directory.
- Set the CUDA_INSTALL_PATH and ROOTDIR (yeargh!) if outside the SDK.
- I keep the following in bin/cudasetup of my home directory. Source it, using sh's . cudasetup syntax:
CUDA="$HOME/local/cuda/" export CUDA_INSTALL_PATH="$CUDA" export ROOTDIR="$CUDA/C/common/" if [ -n "$LD_LIBRARY_PATH" ] ; then export "LD_LIBRARY_PATH=$LD_LIBRARY_PATH:$CUDA/lib64" else export "LD_LIBRARY_PATH=$CUDA/lib64" fi unset CUDA
- Set EXECUTABLE in your Makefile, and include $CUDA_INSTALL_PATH/C/common/common.mk
Unit testing
The DEFAULT_GOAL special variable of GNU Make can be used:
.PHONY: test .DEFAULT_GOAL:=test include $(CUDA_INSTALL_PATH)/C/common/common.mk test: $(TARGET) $(TARGET)
Libraries
Two mutually exclusive means of driving CUDA are available: the "Driver API" and "C for CUDA" with its accompanying nvcc compiler and runtime. The latter (libcudart) is built atop the former, and requires its libcuda library.
Undocumented Functions
The following unlisted functions were extracted from 3.0's libcudart.so using objdump -T:
00000000000097d0 g DF .text 000000000000020e Base __cudaRegisterShared 0000000000005410 g DF .text 0000000000000003 Base __cudaSynchronizeThreads 0000000000009e60 g DF .text 0000000000000246 Base __cudaRegisterVar 000000000000a0b0 g DF .text 0000000000000455 Base __cudaRegisterFatBinary 00000000000095c0 g DF .text 000000000000020e Base __cudaRegisterSharedVar 0000000000005420 g DF .text 0000000000000002 Base __cudaTextureFetch 000000000000a510 g DF .text 00000000000009dd Base __cudaUnregisterFatBinary 00000000000099e0 g DF .text 000000000000024e Base __cudaRegisterFunction 0000000000005820 g DF .text 000000000000001c Base __cudaMutexOperation 0000000000009c30 g DF .text 000000000000022e Base __cudaRegisterTexture
deviceQuery info
- Memory shown is that amount which is free; I've substituted total VRAM.
- Most CUDA devices can switch between multiple frequencies; the "Clock rate" output ought be considered accurate only at a given moment, and the outputs listed here are merely illustrative.
- Three device modes are currently supported:
- 0: Default (multiple applications can use the device)
- 1: Exclusive (only one application may use the device; other calls to cuCtxCreate will fail)
- 2: Disabled (no applications may use the device; all calls to cuCtxCreate will fail
- The mode can be set using nvidia-smi's -c option, specifying the device number via -g.
- A run time limit is activated by default if the device is being used to drive a display.
- Please feel free to send me output!
Device name | Memory | MP's | Cores | Const mem | Shmem/block | Reg/block | Warp size | Thr/block | Max pitch | Texalign | Clock | C+E? | Integrated? | Shared maps? |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Compute capability 2.1 | ||||||||||||||
GeForce GTX 460 | 1GB | 7 | 224 | 64k | 48k | 32k | 32 | 1024 | 2G | 512b | 1.35GHz | 2x | No | Yes |
Compute capability 2.0 | ||||||||||||||
Tesla C2050 (*CB) | 3GB | 14 | 448 | 64k | 48k | 32k | 32 | 1024 | 2G | 512b | 1.15GHz | 2x | No | Yes |
Tesla C2070 (*CB) | 6GB | 14 | 448 | 64k | 48k | 32k | 32 | 1024 | 2G | 512b | 1.15GHz | 2x | No | Yes |
GeForce GTX 480 | 1536MB | 15 | 480 | |||||||||||
GeForce GTX 470 | 1280MB | 14 | 448 | |||||||||||
Compute capability 1.3 | ||||||||||||||
Tesla C1060 | 4GB | 30 | 240 | 65536b | 16384b | 16384 | 32 | 512 | 262144b | 256b | 1.30GHz | Yes | No | Yes |
GeForce GTX 295 | 1GB | 30 | 240 | 65536b | 16384b | 16384 | 32 | 512 | 262144b | 256b | 1.24GHz | Yes | No | Yes |
GeForce GTX 285 | 1GB | 30 | 240 | 65536b | 16384b | 16384 | 32 | 512 | 262144b | 256b | 1.48GHz | Yes | Yes | Yes |
GeForce GTX 280 | 1GB | 30 | 240 | 65536b | 16384b | 16384 | 32 | 512 | 262144b | 256b | 1.30GHz | Yes | No | Yes |
GeForce GTX 260 | 1GB | 27 | 216 | 65536b | 16384b | 16384 | 32 | 512 | 262144b | 256b | 1.47GHz | Yes | No | Yes |
Compute capability 1.2 | ||||||||||||||
GeForce GT 360M | 1GB | 12 | 96 | 65536b | 16384b | 16384 | 32 | 512 | 262144b | 256b | 1.32GHz | Yes | No | Yes |
GeForce 310 | 512MB | 2 | 16 | 65536b | 16384b | 16384 | 32 | 512 | 262144b | 256b | 1.40GHz | Yes | No | Yes |
GeForce 240 GT | 1GB | 12 | 96 | 65536b | 16384b | 16384 | 32 | 512 | 262144b | 256b | 1.424GHz | Yes | No | Yes |
Compute capability 1.1 | ||||||||||||||
ION | 256MB | 2 | 16 | 65536b | 16384b | 8192 | 32 | 512 | 262144b | 256b | 1.1GHz | No | Yes | Yes |
Quadro FX 570 | 256MB | 2 | 16 | 65536b | 16384b | 8192 | 32 | 512 | 262144b | 256b | 0.92GHz | Yes | No | No |
GeForce GTS 250 (*JR) | 1G | 16 | 128 | 65536b | 16384b | 8192 | 32 | 512 | 2147483647b (!) | 256b | 1.84GHz | Yes | No | No |
GeForce 9800 GTX | 512MB | 16 | 128 | 65536b | 16384b | 8192 | 32 | 512 | 262144b | 256b | 1.67GHz | Yes | Yes | Yes |
GeForce 9600 GT | 512MB | 8 | 64 | 65536b | 16384b | 8192 | 32 | 512 | 262144b | 256b | 1.62GHz,
1.50GHz |
Yes | No | No |
GeForce 9400M | 256MB | 2 | 16 | 65536b | 16384b | 8192 | 32 | 512 | 262144b | 256b | 0.88GHz | No | No | No |
GeForce 8800 GTS 512 | 512MB | 16 | 128 | 65536b | 16384b | 8192 | 32 | 512 | 262144b | 256b | 1.62GHz | Yes | No | No |
GeForce 8600 GT | 256MB | 4 | 32 | 65536b | 16384b | 8192 | 32 | 512 | 262144b | 256b | 0.95GHz | Yes | No | No |
GeForce 9400M | 512MB | 1 | 8 | 65536b | 16384b | 8192 | 32 | 512 | 262144b | 256b | 1.40GHz | No | No | No |
(*CB) Thanks to Cameron Black for this submission! (*JR) Thanks to Javier Ruiz for this submission!
See Also
- The nouveau Wiki's CUDA page
- Honza Havlicek's guide to NVIDIA architecture
- Context switching and the PSWITCH instruction
- The gpuocelot project, hosted on Google Code.
- The NVIDIA GPU Developer Zone
- My CUBAR tools and reverse-engineered libcudest