Fused Softmax

In this tutorial, you will write a fused softmax operation that is significantly faster than PyTorch’s native op for a particular class of matrices: those whose rows can fit in the GPU’s SRAM.

In doing so, you will learn about:

• The benefits of kernel fusion for bandwidth-bound operations.

• Reduction operators in Triton.

Motivations

Custom GPU kernels for elementwise additions are educationally valuable but won’t get you very far in practice. Let us consider instead the case of a simple (numerically stabilized) softmax operation:

import torch

import triton
import triton.language as tl
from triton.runtime import driver


def is_hip():
    return triton.runtime.driver.active.get_current_target().backend == "hip"


def is_cdna():
    return is_hip() and triton.runtime.driver.active.get_current_target().arch in ('gfx940', 'gfx941', 'gfx942',
                                                                                   'gfx90a', 'gfx908')


def naive_softmax(x):
    """Compute row-wise softmax of X using native pytorch

    We subtract the maximum element in order to avoid overflows. Softmax is invariant to
    this shift.
    """
    # read  MN elements ; write M  elements
    x_max = x.max(dim=1)[0]
    # read MN + M elements ; write MN elements
    z = x - x_max[:, None]
    # read  MN elements ; write MN elements
    numerator = torch.exp(z)
    # read  MN elements ; write M  elements
    denominator = numerator.sum(dim=1)
    # read MN + M elements ; write MN elements
    ret = numerator / denominator[:, None]
    # in total: read 5MN + 2M elements ; wrote 3MN + 2M elements
    return ret

When implemented naively in PyTorch, computing y = naive_softmax(x) for \(x \in R^{M \times N}\) requires reading \(5MN + 2M\) elements from DRAM and writing back \(3MN + 2M\) elements. This is obviously wasteful; we’d prefer to have a custom “fused” kernel that only reads X once and does all the necessary computations on-chip. Doing so would require reading and writing back only \(MN\) bytes, so we could expect a theoretical speed-up of ~4x (i.e., \((8MN + 4M) / 2MN\)). The torch.jit.script flags aims to perform this kind of “kernel fusion” automatically but, as we will see later, it is still far from ideal.

Compute Kernel

Our softmax kernel works as follows: each program loads a set of rows of the input matrix X strided by number of programs, normalizes it and writes back the result to the output Y.

Note that one important limitation of Triton is that each block must have a power-of-two number of elements, so we need to internally “pad” each row and guard the memory operations properly if we want to handle any possible input shapes:

@triton.jit
def softmax_kernel(output_ptr, input_ptr, input_row_stride, output_row_stride, n_rows, n_cols, BLOCK_SIZE: tl.constexpr,
                   num_stages: tl.constexpr):
    # starting row of the program
    row_start = tl.program_id(0)
    row_step = tl.num_programs(0)
    for row_idx in tl.range(row_start, n_rows, row_step, num_stages=num_stages):
        # The stride represents how much we need to increase the pointer to advance 1 row
        row_start_ptr = input_ptr + row_idx * input_row_stride
        # The block size is the next power of two greater than n_cols, so we can fit each
        # row in a single block
        col_offsets = tl.arange(0, BLOCK_SIZE)
        input_ptrs = row_start_ptr + col_offsets
        # Load the row into SRAM, using a mask since BLOCK_SIZE may be > than n_cols
        mask = col_offsets < n_cols
        row = tl.load(input_ptrs, mask=mask, other=-float('inf'))
        # Subtract maximum for numerical stability
        row_minus_max = row - tl.max(row, axis=0)
        # Note that exponentiation in Triton is fast but approximate (i.e., think __expf in CUDA)
        numerator = tl.exp(row_minus_max)
        denominator = tl.sum(numerator, axis=0)
        softmax_output = numerator / denominator
        # Write back output to DRAM
        output_row_start_ptr = output_ptr + row_idx * output_row_stride
        output_ptrs = output_row_start_ptr + col_offsets
        tl.store(output_ptrs, softmax_output, mask=mask)

We can create a helper function that enqueues the kernel and its (meta-)arguments for any given input tensor.

device = torch.cuda.current_device()
properties = driver.active.utils.get_device_properties(device)
NUM_SM = properties["multiprocessor_count"]
NUM_REGS = properties["max_num_regs"]
SIZE_SMEM = properties["max_shared_mem"]
WARP_SIZE = properties["warpSize"]
target = triton.runtime.driver.active.get_current_target()
kernels = {}


def softmax(x):
    n_rows, n_cols = x.shape

    # The block size of each loop iteration is the smallest power of two greater than the number of columns in `x`
    BLOCK_SIZE = triton.next_power_of_2(n_cols)

    # Another trick we can use is to ask the compiler to use more threads per row by
    # increasing the number of warps (`num_warps`) over which each row is distributed.
    # You will see in the next tutorial how to auto-tune this value in a more natural
    # way so you don't have to come up with manual heuristics yourself.
    num_warps = 8

    # Number of software piepling stages.
    num_stages = 4 if SIZE_SMEM > 200000 else 2

    # Allocate output
    y = torch.empty_like(x)

    # pre-compile kernel to get register usage and compute thread occupancy.
    kernel, num_programs = kernels.get(BLOCK_SIZE, (None, 0))
    if kernel is None:
        kernel = softmax_kernel.warmup(y, x, x.stride(0), y.stride(0), n_rows, n_cols, BLOCK_SIZE=BLOCK_SIZE,
                                       num_stages=num_stages, num_warps=num_warps, grid=(1, ))
        kernel._init_handles()
        n_regs = kernel.n_regs
        size_smem = kernel.metadata.shared
        if is_hip():
            # NUM_REGS represents the number of regular purpose registers. On CDNA architectures this is half of all registers available.
            # However, this is not always the case. In most cases all registers can be used as regular purpose registers.
            # ISA SECTION (3.6.4 for CDNA3)
            # VGPRs are allocated out of two pools: regular VGPRs and accumulation VGPRs. Accumulation VGPRs are used
            # with matrix VALU instructions, and can also be loaded directly from memory. A wave may have up to 512 total
            # VGPRs, 256 of each type. When a wave has fewer than 512 total VGPRs, the number of each type is flexible - it is
            # not required to be equal numbers of both types.
            if is_cdna():
                NUM_GPRS = NUM_REGS * 2

            # MAX_NUM_THREADS represents maximum number of resident threads per multi-processor.
            # When we divide this number with WARP_SIZE we get maximum number of waves that can
            # execute on a CU (multi-processor)  in parallel.
            MAX_NUM_THREADS = properties["max_threads_per_sm"]
            max_num_waves = MAX_NUM_THREADS // WARP_SIZE
            occupancy = min(NUM_GPRS // WARP_SIZE // n_regs, max_num_waves) // num_warps
        else:
            occupancy = NUM_REGS // (n_regs * WARP_SIZE * num_warps)
        occupancy = min(occupancy, SIZE_SMEM // size_smem)
        num_programs = NUM_SM * occupancy
        kernels[BLOCK_SIZE] = (kernel, num_programs)

    num_programs = min(num_programs, n_rows)

    # Create a number of persistent programs.
    kernel[(num_programs, 1, 1)](
        y,
        x,
        x.stride(0),
        y.stride(0),
        n_rows,
        n_cols,
    )
    return y

Unit Test

We make sure that we test our kernel on a matrix with an irregular number of rows and columns. This will allow us to verify that our padding mechanism works.

torch.manual_seed(0)
x = torch.randn(1823, 781, device='cuda')
y_triton = softmax(x)
y_torch = torch.softmax(x, axis=1)
assert torch.allclose(y_triton, y_torch), (y_triton, y_torch)

As expected, the results are identical.

Benchmark

Here we will benchmark our operation as a function of the number of columns in the input matrix – assuming 4096 rows. We will then compare its performance against (1) torch.softmax and (2) the naive_softmax defined above.

@triton.testing.perf_report(
    triton.testing.Benchmark(
        x_names=['N'],  # argument names to use as an x-axis for the plot
        x_vals=[128 * i for i in range(2, 100)],  # different possible values for `x_name`
        line_arg='provider',  # argument name whose value corresponds to a different line in the plot
        line_vals=['triton', 'torch'],  # possible values for `line_arg``
        line_names=[
            "Triton",
            "Torch",
        ],  # label name for the lines
        styles=[('blue', '-'), ('green', '-')],  # line styles
        ylabel="GB/s",  # label name for the y-axis
        plot_name="softmax-performance",  # name for the plot. Used also as a file name for saving the plot.
        args={'M': 4096},  # values for function arguments not in `x_names` and `y_name`
    ))
def benchmark(M, N, provider):
    x = torch.randn(M, N, device='cuda', dtype=torch.float32)
    stream = torch.cuda.Stream()
    torch.cuda.set_stream(stream)
    if provider == 'torch':
        ms = triton.testing.do_bench(lambda: torch.softmax(x, axis=-1))
    if provider == 'triton':
        ms = triton.testing.do_bench(lambda: softmax(x))
    gbps = lambda ms: 2 * x.nelement() * x.element_size() * 1e-9 / (ms * 1e-3)
    return gbps(ms)


benchmark.run(show_plots=True, print_data=True)

softmax-performance:
          N       Triton        Torch
0     256.0   479.971415   702.139663
1     384.0   613.489806   804.742475
2     512.0   757.308365   923.473008
3     640.0   792.051811   961.830972
4     768.0   872.367065  1033.113093
5     896.0   932.895877  1067.405188
6    1024.0   989.438959  1129.162127
7    1152.0  1112.417652   614.940583
8    1280.0  1156.447348   669.547786
9    1408.0  1156.167100   725.404231
10   1536.0  1187.712733   782.654510
11   1664.0  1218.862046   815.667263
12   1792.0  1233.590604   854.532308
13   1920.0  1255.456581   908.113861
14   2048.0  1270.281625   958.344204
15   2176.0  1257.045464   976.763217
16   2304.0  1266.731133  1011.394436
17   2432.0  1290.127580  1053.298897
18   2560.0  1296.583449  1082.990627
19   2688.0  1314.693382  1104.309499
20   2816.0  1332.546636  1133.581467
21   2944.0  1327.624345  1169.870031
22   3072.0  1353.640841  1187.736957
23   3200.0  1353.220618  1192.174610
24   3328.0  1363.641333  1227.636505
25   3456.0  1373.281889  1247.479233
26   3584.0  1375.770007  1258.537236
27   3712.0  1378.913165  1270.766004
28   3840.0  1389.251747  1298.249544
29   3968.0  1390.697837  1313.064552
30   4096.0  1402.824581  1325.247436
31   4224.0  1330.811484  1160.612852
32   4352.0  1334.043866  1173.129910
33   4480.0  1349.110557  1184.574665
34   4608.0  1359.838974  1191.423570
35   4736.0  1363.032668  1197.348060
36   4864.0  1379.382583  1218.583994
37   4992.0  1375.980047  1237.385693
38   5120.0  1371.203812  1250.252107
39   5248.0  1375.119936  1257.147176
40   5376.0  1376.502713  1287.848724
41   5504.0  1381.458560  1298.379544
42   5632.0  1390.390942  1315.963848
43   5760.0  1391.360785  1321.663121
44   5888.0  1386.578913  1342.204717
45   6016.0  1399.833504  1354.020567
46   6144.0  1411.381737  1374.478180
47   6272.0  1417.616876  1376.650571
48   6400.0  1415.051396  1385.060043
49   6528.0  1412.316190  1392.812077
50   6656.0  1423.865574  1403.358983
51   6784.0  1412.134443  1417.108951
52   6912.0  1431.047456  1426.964999
53   7040.0  1424.970812  1430.834852
54   7168.0  1428.934183  1436.517200
55   7296.0  1435.660930  1442.566029
56   7424.0  1433.571928  1446.973560
57   7552.0  1428.555765  1456.004828
58   7680.0  1435.309231  1461.972743
59   7808.0  1434.510651  1466.803134
60   7936.0  1437.678716  1465.534748
61   8064.0  1436.084725  1473.054894
62   8192.0  1434.386853  1482.412155
63   8320.0  1391.891694  1399.981688
64   8448.0  1380.358548  1406.076925
65   8576.0  1394.888859  1396.690410
66   8704.0  1390.768797  1396.130286
67   8832.0  1382.413603  1404.592061
68   8960.0  1395.243342  1412.769341
69   9088.0  1411.527259  1417.466346
70   9216.0  1400.909976  1426.596086
71   9344.0  1402.486354  1426.510050
72   9472.0  1398.834902  1430.743271
73   9600.0  1393.100801  1433.705458
74   9728.0  1399.536009  1444.842892
75   9856.0  1415.974631  1442.096158
76   9984.0  1400.929888  1451.247395
77  10112.0  1410.581457  1452.466523
78  10240.0  1416.177667  1469.316875
79  10368.0  1417.322739  1460.591910
80  10496.0  1412.850281  1468.017150
81  10624.0  1412.680008  1468.076393
82  10752.0  1404.906930  1471.349144
83  10880.0  1398.881206  1481.058594
84  11008.0  1421.418331  1476.153870
85  11136.0  1422.667248  1483.317770
86  11264.0  1429.545510  1489.454579
87  11392.0  1414.557658  1488.380936
88  11520.0  1420.718429  1497.344137
89  11648.0  1428.797265  1500.208617
90  11776.0  1433.342691  1500.593549
91  11904.0  1444.444772  1507.989222
92  12032.0  1422.775520  1505.912506
93  12160.0  1416.091598  1512.305483
94  12288.0  1433.751886  1389.649613
95  12416.0  1449.014173  1390.461567
96  12544.0  1438.416199  1393.102407
97  12672.0  1446.080469  1391.976252

In the above plot, we can see that:

• Triton is 4x faster than the Torch JIT. This confirms our suspicions that the Torch JIT does not do any fusion here.

• Triton is noticeably faster than torch.softmax – in addition to being easier to read, understand and maintain. Note however that the PyTorch softmax operation is more general and will work on tensors of any shape.