triton/v1.1.2/_sources/getting-started/tutorials/05-layer-norm.rst.txt

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    .. note::
        :class: sphx-glr-download-link-note

        Click :ref:`here <sphx_glr_download_getting-started_tutorials_05-layer-norm.py>`
        to download the full example code

.. rst-class:: sphx-glr-example-title

.. _sphx_glr_getting-started_tutorials_05-layer-norm.py:


Layer Normalization
====================

.. GENERATED FROM PYTHON SOURCE LINES 5-252



.. image:: /getting-started/tutorials/images/sphx_glr_05-layer-norm_001.png
    :alt: 05 layer norm
    :class: sphx-glr-single-img


.. rst-class:: sphx-glr-script-out

 Out:

 .. code-block:: none

    layer-norm-backward:
              N      Triton       Torch        Apex
    0    1024.0  307.200008   98.303995  303.407414
    1    1536.0  351.085717  134.540150  341.333333
    2    2048.0  420.102553  161.684218  325.509933
    3    2560.0  465.454542  181.238943  326.808501
    4    3072.0  511.999982  192.501302  316.429186
    5    3584.0  551.384634  208.271186  309.410081
    6    4096.0  568.231237  220.412561  298.796351
    7    4608.0  500.416301  232.825259  289.507855
    8    5120.0  525.128191  242.366855  287.102804
    9    5632.0  542.843364  243.545956  288.820505
    10   6144.0  544.118087  248.242431  286.322318
    11   6656.0  532.479975  256.000009  285.767438
    12   7168.0  505.976473  260.654538  286.242939
    13   7680.0  481.253256  262.564106  279.272719
    14   8192.0  463.698115  267.130429  284.526763
    15   8704.0  417.791980  267.815384  284.987724
    16   9216.0  429.483477  272.729961  288.751954
    17   9728.0  438.857162  280.278512  289.667485
    18  10240.0  447.650282  286.433562  290.496460
    19  10752.0  428.651173  246.935876  290.594591
    20  11264.0  429.104745  245.536784  286.676558
    21  11776.0  423.089806  249.667843  288.981596
    22  12288.0  420.102570  254.673582  294.323369
    23  12800.0  414.574901  253.674644  289.811310
    24  13312.0  412.242569  252.959629  289.916513
    25  13824.0  406.090579  257.190689  291.799461
    26  14336.0  395.930964  254.297107  286.719986
    27  14848.0  386.498925  257.665934  289.481735
    28  15360.0  373.306347  257.970599  288.000007
    29  15872.0  369.832994  261.806182  290.120338






|

.. code-block:: default


    import torch
    import triton.language as tl
    import triton

    # Forward Pass
    @triton.jit
    def _layer_norm_fwd_fused(X, Y, W, B, M, V, stride, N, eps, **META):
        BLOCK_SIZE = META['BLOCK_SIZE']
        # position of elements processed by this program
        row =  tl.program_id(0)
        cols = tl.arange(0, BLOCK_SIZE)
        mask = cols < N
        # offset data pointers to start at the row of interest
        X += row * stride
        Y += row * stride
        # load data and cast to float32
        x = tl.load(X + cols, mask=mask, other=0).to(tl.float32)
        # compute mean
        mean = tl.sum(x, axis=0) / N
        # compute std
        xmean = tl.where(mask, x - mean, 0.)
        var   = tl.sum(xmean * xmean, axis=0) / N
        rstd  = 1 / tl.sqrt(var + eps)
        xhat  = xmean*rstd
        # write-back mean/rstd
        tl.store(M + row, mean)
        tl.store(V + row, rstd)
        # multiply by weight and add bias
        w = tl.load(W + cols, mask=mask)
        b = tl.load(B + cols, mask=mask)
        y = xhat * w + b
        # write-back
        tl.store(Y + cols, y, mask=mask)


    # Backward pass (DX + partial DW + partial DB)
    @triton.jit
    def _layer_norm_bwd_dx_fused(DX, DY, DW, DB, X, W, B, M, V, Lock,
                           stride, N, eps, 
                           **META):
        GROUP_SIZE_M = META['GROUP_SIZE_M']
        BLOCK_SIZE_N = META['BLOCK_SIZE_N']
        # position of elements processed by this program
        row =  tl.program_id(0)
        cols = tl.arange(0, BLOCK_SIZE_N)
        mask = cols < N
        # offset data pointers to start at the row of interest
        X  += row * stride
        DY += row * stride
        DX += row * stride
        # offset locks and weight/bias gradient pointer
        # each kernel instance accumulates partial sums for
        # DW and DB into one of GROUP_SIZE_M independent buffers
        # these buffers stay in the L2, which allow this kernel
        # to be fast
        lock_id = row % GROUP_SIZE_M
        Lock   += lock_id
        Count   = Lock + GROUP_SIZE_M
        DW      = DW + lock_id*N + cols
        DB      = DB + lock_id*N + cols
        # load data to SRAM
        x     = tl.load(X  + cols, mask=mask, other=0).to(tl.float32)
        dy    = tl.load(DY + cols, mask=mask, other=0).to(tl.float32)
        w     = tl.load(W  + cols, mask=mask).to(tl.float32)
        mean  = tl.load(M + row)
        rstd  = tl.load(V + row)
        # compute dx
        xhat  = (x - mean)*rstd
        wdy   = w * dy
        xhat  = tl.where(mask, xhat, 0.)
        wdy   = tl.where(mask, wdy , 0.)
        mean1 = tl.sum(xhat * wdy, axis=0) / N
        mean2 = tl.sum(wdy, axis=0) / N
        dx    = (wdy - (xhat*mean1 + mean2))*rstd
        # write-back dx
        tl.store(DX + cols, dx, mask=mask)
        # accumulate partial sums for dw/db
        partial_dw = (dy*xhat).to(w.dtype)
        partial_db = (dy).to(w.dtype)
        while tl.atomic_cas(Lock, 0, 1) == 1:
            pass
        count = tl.load(Count)
        # first store doesn't accumulate
        if count == 0:
            tl.atomic_xchg(Count, 1)
        else:
            partial_dw += tl.load(DW, mask=mask)
            partial_db += tl.load(DB, mask=mask)
        tl.store(DW, partial_dw, mask=mask)
        tl.store(DB, partial_db, mask=mask)
        # release lock
        tl.atomic_xchg(Lock, 0)

    # Backward pass (total DW + total DB)
    @triton.jit
    def _layer_norm_bwd_dwdb(DW, DB, FINAL_DW, FINAL_DB, M, N, **meta):
        pid = tl.program_id(0)
        BLOCK_SIZE_M = meta['BLOCK_SIZE_M']
        BLOCK_SIZE_N = meta['BLOCK_SIZE_N']
        cols = pid*BLOCK_SIZE_N + tl.arange(0, BLOCK_SIZE_N)
        dw   = tl.zeros((BLOCK_SIZE_M, BLOCK_SIZE_N), dtype=tl.float32)
        db   = tl.zeros((BLOCK_SIZE_M, BLOCK_SIZE_N), dtype=tl.float32)
        for i in range(0, M, BLOCK_SIZE_M):
            rows = i + tl.arange(0, meta['BLOCK_SIZE_M'])
            mask = (rows[:, None] < M) & (cols[None, :] < N)
            offs = rows[:, None]*N + cols[None, :]
            dw += tl.load(DW + offs, mask=mask, other=0.)
            db += tl.load(DB + offs, mask=mask, other=0.)
        sum_dw = tl.sum(dw, axis=0)
        sum_db = tl.sum(db, axis=0)
        tl.store(FINAL_DW + cols, sum_dw, mask=cols<N)
        tl.store(FINAL_DB + cols, sum_db, mask=cols<N)

    class LayerNorm(torch.autograd.Function):

        @staticmethod
        def forward(ctx, x, normalized_shape, weight, bias, eps):
            # allocate output
            y = torch.empty_like(x)
            # reshape input data into 2D tensor
            x_arg = x.reshape(-1, x.shape[-1])
            M, N = x_arg.shape
            mean = torch.empty((M, ), dtype=torch.float32, device='cuda')
            rstd = torch.empty((M, ), dtype=torch.float32, device='cuda')
            # Less than 64KB per feature: enqueue fused kernel
            MAX_FUSED_SIZE = 65536 // x.element_size()
            BLOCK_SIZE     = min(MAX_FUSED_SIZE, triton.next_power_of_2(N))
            if N > BLOCK_SIZE:
                raise RuntimeError("This layer norm doesn't support feature dim >= 64KB.")
            # heuristics for number of warps
            num_warps = min(max(BLOCK_SIZE // 256, 1), 8)
            # enqueue kernel
            _layer_norm_fwd_fused[(M,)](x_arg, y, weight, bias, mean, rstd, 
                                        x_arg.stride(0), N, eps, 
                                        BLOCK_SIZE=BLOCK_SIZE, num_warps=num_warps)
            ctx.save_for_backward(x, weight, bias, mean, rstd)
            ctx.BLOCK_SIZE = BLOCK_SIZE
            ctx.num_warps  = num_warps
            ctx.eps        = eps
            return y

        @staticmethod
        def backward(ctx, dy):
            x, w, b, m, v = ctx.saved_tensors
            # heuristics for amount of parallel reduction stream for DG/DB
            N = w.shape[0]
            GROUP_SIZE_M = 64
            if N <= 8192: GROUP_SIZE_M = 96
            if N <= 4096: GROUP_SIZE_M = 128
            if N <= 1024: GROUP_SIZE_M = 256
            # allocate output
            locks = torch.zeros(2*GROUP_SIZE_M, dtype=torch.int32, device='cuda')
            _dw = torch.empty((GROUP_SIZE_M, w.shape[0]), dtype=x.dtype, device=w.device)
            _db = torch.empty((GROUP_SIZE_M, w.shape[0]), dtype=x.dtype, device=w.device)
            dw  = torch.empty((w.shape[0],), dtype=w.dtype, device=w.device)
            db  = torch.empty((w.shape[0],), dtype=w.dtype, device=w.device)
            dx = torch.empty_like(dy)
            # enqueue kernel using forward pass heuristics
            # also compute partial sums for DW and DB
            x_arg = x.reshape(-1, x.shape[-1])
            M, N = x_arg.shape
            _layer_norm_bwd_dx_fused[(M,)](dx, dy, _dw, _db, x, w, b, m, v, locks,
                                           x_arg.stride(0), N, ctx.eps,
                                           BLOCK_SIZE_N=ctx.BLOCK_SIZE, 
                                           GROUP_SIZE_M=GROUP_SIZE_M,
                                           num_warps=ctx.num_warps)
            grid = lambda meta: [triton.cdiv(N, meta['BLOCK_SIZE_N'])]
            # accumulate partial sums in separate kernel
            _layer_norm_bwd_dwdb[grid](_dw, _db, dw, db, GROUP_SIZE_M, N, 
                                       BLOCK_SIZE_M = 32, 
                                       BLOCK_SIZE_N = 128)
            return dx, None, dw, db, None


    layer_norm = LayerNorm.apply


    def test_layer_norm(M, N, dtype, eps=1e-5, device='cuda'):
        # create data
        x_shape = (M, N)
        w_shape = (x_shape[-1], )
        weight  = torch.rand(w_shape, dtype=dtype, device='cuda', requires_grad=True)
        bias    = torch.rand(w_shape, dtype=dtype, device='cuda', requires_grad=True)
        x       = -2.3 + 0.5*torch.randn(x_shape, dtype=dtype, device='cuda')
        dy      = .1*torch.randn_like(x)
        x.requires_grad_(True)
        # forward pass
        y_tri = layer_norm(x, w_shape, weight, bias, eps)
        y_ref = torch.nn.functional.layer_norm(x, w_shape, weight, bias, eps).to(dtype)
        # backward pass (triton)
        y_tri.backward(dy, retain_graph=True)
        dx_tri, dw_tri, db_tri = [_.grad.clone() for _ in [x, weight, bias]]
        x.grad, weight.grad, bias.grad = None, None, None
        # backward pass (torch)
        y_ref.backward(dy, retain_graph=True)
        dx_ref, dw_ref, db_ref = [_.grad.clone() for _ in [x, weight, bias]]
        # compare
        triton.testing.assert_almost_equal(y_tri, y_ref)
        triton.testing.assert_almost_equal(dx_tri, dx_ref)
        triton.testing.assert_almost_equal(db_tri, db_ref, decimal=1)
        triton.testing.assert_almost_equal(dw_tri, dw_ref, decimal=1)

    @triton.testing.perf_report(
        triton.testing.Benchmark(
            x_names=['N'],
            x_vals=[512 * i for i in range(2, 32)],
            line_arg='provider',
            line_vals=['triton', 'torch', 'apex'],
            line_names=['Triton', 'Torch', 'Apex'],
            styles=[('blue', '-'), ('green', '-'), ('orange', '-')],
            ylabel='GB/s',
            plot_name='layer-norm-backward',
            args={'M': 4096, 'dtype': torch.float16, 'mode': 'backward'}
        )
    )
    def bench_layer_norm(M, N, dtype, provider, mode='backward',eps=1e-5, device='cuda'):
        # create data
        x_shape = (M, N)
        w_shape = (x_shape[-1], )
        weight  = torch.rand(w_shape, dtype=dtype, device='cuda', requires_grad=True)
        bias    = torch.rand(w_shape, dtype=dtype, device='cuda', requires_grad=True)
        x       = -2.3 + 0.5*torch.randn(x_shape, dtype=dtype, device='cuda')
        dy      = .1*torch.randn_like(x)
        x.requires_grad_(True)
        # utility functions
        if provider == 'triton':
            y_fwd = lambda: layer_norm(x, w_shape, weight, bias, eps)
        if provider == 'torch':
            y_fwd = lambda: torch.nn.functional.layer_norm(x, w_shape, weight, bias, eps)
        if provider == 'apex':
            import apex
            apex_layer_norm = apex.normalization.FusedLayerNorm(w_shape).to(x.device).to(x.dtype)
            y_fwd = lambda: apex_layer_norm(x)
        # forward pass
        if mode == 'forward':
            gbps = lambda ms: 2*x.numel()*x.element_size()/ms*1e-6
            ms, min_ms, max_ms = triton.testing.do_bench(y_fwd, rep=500)
        # backward pass
        if mode == 'backward':
            gbps = lambda ms: 3*x.numel()*x.element_size()/ms*1e-6
            y = y_fwd()
            ms, min_ms, max_ms = triton.testing.do_bench(lambda: y.backward(dy, retain_graph=True), 
                                                         grad_to_none=[x], rep=500)
        return gbps(ms), gbps(max_ms), gbps(min_ms)

    bench_layer_norm.run(save_path='.', print_data=True)


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