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DistanceKernel.cu
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DistanceKernel.cu
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#include <ATen/ATen.h>
#include <ATen/cuda/Exceptions.h>
#include <ATen/cuda/DeviceUtils.cuh>
#include <ATen/cuda/CUDAContext.h>
#include <THC/THCTensorMathReduce.cuh>
#include <math.h>
#include <ATen/native/Distance.h>
#include <c10/macros/Macros.h>
namespace at { namespace native {
namespace {
static const int forward_threads = 256;
template <typename scalar_t>
static __forceinline__ __device__ scalar_t device_sqrt(scalar_t val);
template <>
__forceinline__ __device__ float device_sqrt(float val) {
return ::sqrtf(val);
}
template <>
__forceinline__ __device__ double device_sqrt(double val) {
return ::sqrt(val);
}
template <typename scalar_t>
struct dists {
static __forceinline__ __device__ scalar_t sign(scalar_t val) {
return (0 < val) - (val < 0);
}
// Zero norm
struct zero {
static __forceinline__ __device__ void inc(scalar_t& agg, const scalar_t diff, const scalar_t p) { agg += diff != 0.0; }
static __forceinline__ __device__ scalar_t finish(const scalar_t agg, const scalar_t p) { return agg; }
static __forceinline__ __device__ void agg(scalar_t& update, const scalar_t other) { update += other; }
};
// One norm
struct one {
static __forceinline__ __device__ void inc(scalar_t& agg, const scalar_t diff, const scalar_t p) { agg += diff; }
static __forceinline__ __device__ scalar_t finish(const scalar_t agg, const scalar_t p) { return agg; }
static __forceinline__ __device__ void agg(scalar_t& update, const scalar_t other) { update += other; }
static __forceinline__ __device__ scalar_t backward(const scalar_t diff, const scalar_t grad, const scalar_t dist, const scalar_t p) { return grad * sign(diff); }
};
// Special case backward when p is less than two
struct lt_two {
static __forceinline__ __device__ scalar_t backward(const scalar_t diff, const scalar_t grad, const scalar_t dist, const scalar_t p) {
return (dist == 0.0 || (diff == 0.0 && p < 1)) ? 0 : (sign(diff) * std::pow(std::abs(diff), p - 1) * grad / std::pow(dist, p - 1));
}
};
// Two norm
struct two {
static __forceinline__ __device__ void inc(scalar_t& agg, const scalar_t diff, const scalar_t p) { agg += diff * diff; }
static __forceinline__ __device__ scalar_t finish(const scalar_t agg, const scalar_t p) { return device_sqrt<scalar_t>(agg); }
static __forceinline__ __device__ void agg(scalar_t& update, const scalar_t other) { update += other; }
static __forceinline__ __device__ scalar_t backward(const scalar_t diff, const scalar_t grad, const scalar_t dist, const scalar_t p) { return dist == 0.0 ? 0 : grad * diff / dist; }
};
// General p norm
struct p {
static __forceinline__ __device__ void inc(scalar_t& agg, const scalar_t diff, const scalar_t p) { agg += std::pow(diff, p); }
static __forceinline__ __device__ scalar_t finish(const scalar_t agg, const scalar_t p) { return std::pow(agg, static_cast<scalar_t>(1) / p); }
static __forceinline__ __device__ void agg(scalar_t& update, const scalar_t other) { update += other; }
static __forceinline__ __device__ scalar_t backward(const scalar_t diff, const scalar_t grad, const scalar_t dist, const scalar_t p) { return dist == 0.0 ? 0 : diff * std::pow(std::abs(diff), p - 2) * grad / std::pow(dist, p - 1); }
};
// Inf norm
struct inf {
static __forceinline__ __device__ void inc(scalar_t& agg, const scalar_t diff, const scalar_t p) { if (diff > agg) { agg = diff; } }
static __forceinline__ __device__ scalar_t finish(const scalar_t agg, const scalar_t p) { return agg; }
static __forceinline__ __device__ void agg(scalar_t& update, const scalar_t other) { if (other > update) { update = other; } }
static __forceinline__ __device__ scalar_t backward(const scalar_t diff, const scalar_t grad, const scalar_t dist, const scalar_t p) { return grad * sign(diff) * (std::abs(diff) == dist); }
};
};
template <typename scalar_t, typename F>
__device__ static inline scalar_t reduce_agg(scalar_t agg) {
for (int offset = warpSize / 2; offset > 0; offset /= 2) {
F::agg(agg, WARP_SHFL_DOWN(agg, offset));
}
__shared__ scalar_t shared[forward_threads];
int lane = threadIdx.x % warpSize;
int warp_id = threadIdx.x / warpSize;
if (lane == 0) {
shared[warp_id] = agg;
}
__syncthreads();
agg = (threadIdx.x < blockDim.x / warpSize) ? shared[lane] : 0.0;
if (warp_id == 0) {
for (int offset = blockDim.x / warpSize / 2; offset > 0; offset /= 2) {
F::agg(agg, WARP_SHFL_DOWN(agg, offset));
}
}
return agg;
}
template <typename scalar_t, typename F>
__global__ static void pdist_kernel_cuda_impl(scalar_t * result, const scalar_t * self, const int64_t n, const int64_t m, const scalar_t p,
const double n2, const double n2_squared_minus_1) {
const int64_t k = blockIdx.x;
const int stride = blockDim.x;
// The -1 accounts for floating point truncation issues
int64_t i = static_cast<int64_t>((n2 - device_sqrt<double>(n2_squared_minus_1 - 2 * k)));
int64_t j = k - n * i + i * (i + 1) / 2 + i + 1;
const scalar_t * const start = self + i * m;
const scalar_t * const end = start + m;
const scalar_t * a = start + threadIdx.x;
const scalar_t * b = self + j * m + threadIdx.x;
scalar_t agg = 0.0;
for (; a < end; a += stride, b += stride) {
F::inc(agg, std::abs(*a - *b), p);
}
agg = reduce_agg<scalar_t, F>(agg);
if (threadIdx.x == 0) {
result[k] = F::finish(agg, p);
}
}
template <typename scalar_t, typename F>
__global__ static void cdist_backward_kernel_cuda_impl(scalar_t * buffer, const scalar_t * grad, const scalar_t * x1, const scalar_t * x2, const scalar_t * dist, int64_t gs,
const scalar_t p, const int64_t r1, const int64_t r2, const int64_t m, const int64_t count, const int64_t r_size, const int64_t l1_size, const int64_t l2_size) {
const int y = (blockIdx.y * gridDim.z + blockIdx.z) * blockDim.y + threadIdx.y;
const int init = blockIdx.x * blockDim.x + threadIdx.x;
if (y >= count || init >= m) {
return;
}
const int l = y / r_size;
const int k = y % r_size;
const int stride = blockDim.x * gridDim.x;
const int l_size = r_size * m;
int64_t i = k / r2;
int64_t j = k % r2;
const scalar_t grad_k = grad[y];
const scalar_t dist_k = dist[y];
const scalar_t * const start = x1 + l * l1_size + i * m;
const scalar_t * const end = start + m;
const scalar_t * self_i = start + init;
const scalar_t * self_j = x2 + l * l2_size + j * m + init;
scalar_t * buff_i = buffer + l * l_size + (r1 * j + i) * m + init;
for (; self_i < end; self_i += stride, self_j += stride, buff_i += stride) {
const scalar_t res = F::backward(*self_i - *self_j, grad_k, dist_k, p);
*buff_i = res;
}
}
template <typename scalar_t, typename F>
__global__ static void pdist_backward_kernel_cuda_impl(scalar_t * buffer, const scalar_t * grad, const scalar_t * self, const scalar_t * dist, int64_t gs, const int64_t n, const int64_t m, const int64_t combs, const scalar_t p,
const double n2, const double n2_squared_minus_1) {
const int64_t k = blockIdx.x * blockDim.x + threadIdx.x;
const int init = blockIdx.y * blockDim.y + threadIdx.y;
const int stride = blockDim.y * gridDim.y;
if (k >= combs) {
return;
}
// The -1 accounts for floating point truncation issues
int64_t i = static_cast<int64_t>((n2 - device_sqrt<double>(n2_squared_minus_1 - 2 * k)));
int64_t j = k - n * i + i * (i + 1) / 2 + i + 1;
int64_t ib = j - i - 1;
int64_t jb = n - 2 - i;
const scalar_t grad_k = grad[k * gs];
const scalar_t dist_k = dist[k];
const scalar_t * const start = self + i * m;
const scalar_t * const end = start + m;
const scalar_t * self_i = start + init;
const scalar_t * self_j = self + j * m + init;
scalar_t * buff_i = buffer + (ib * n + i) * m + init;
scalar_t * buff_j = buffer + (jb * n + j) * m + init;
for (; self_i < end; self_i += stride, self_j += stride, buff_i += stride, buff_j += stride) {
const scalar_t res = F::backward(*self_i - *self_j, grad_k, dist_k, p);
*buff_i = res;
*buff_j = -res;
}
}
template <typename scalar_t, typename F>
__global__ static void cdist_kernel_cuda_impl(scalar_t * result, const scalar_t * x1, const scalar_t * x2,
const scalar_t p, const int64_t r1, const int64_t r2, const int64_t m, const int64_t r_size, const int64_t l1_size, const int64_t l2_size) {
const int64_t l = blockIdx.x / r_size;
const int64_t k = blockIdx.x % r_size;
const int64_t i = k / r2;
const int64_t j = k % r2;
const int stride = blockDim.x;
const scalar_t * const start = x1 + l * l1_size + i * m;
const scalar_t * const end = start + m;
const scalar_t * a = start + threadIdx.x;
const scalar_t * b = x2 + l * l2_size + j * m + threadIdx.x;
scalar_t agg = 0.0;
for (; a < end; a += stride, b += stride) {
F::inc(agg, std::abs(*a - *b), p);
}
agg = reduce_agg<scalar_t, F>(agg);
if (threadIdx.x == 0) {
result[blockIdx.x] = F::finish(agg, p);
}
}
void cdist_kernel_impl(Tensor& result, const Tensor& x1, const Tensor& x2, double p) {
const int64_t r1 = x1.size(-2);
const int64_t r2 = x2.size(-2);
const int64_t m = x1.size(-1);
const int64_t r_size = r1 * r2;
const int64_t l1_size = r1 * m;
const int64_t l2_size = r2 * m;
const dim3 grid(result.numel());
const dim3 block(forward_threads);
AT_DISPATCH_FLOATING_TYPES(x1.scalar_type(), "cdist_cuda", [&] {
if (p == 0.0) {
cdist_kernel_cuda_impl<scalar_t, dists<scalar_t>::zero><<<grid, block, 0, at::cuda::getCurrentCUDAStream()>>>(result.data_ptr<scalar_t>(), x1.data_ptr<scalar_t>(), x2.data_ptr<scalar_t>(), p, r1, r2, m, r_size, l1_size, l2_size);
C10_CUDA_KERNEL_LAUNCH_CHECK();
} else if (p == 1.0) {
cdist_kernel_cuda_impl<scalar_t, dists<scalar_t>::one><<<grid, block, 0, at::cuda::getCurrentCUDAStream()>>>(result.data_ptr<scalar_t>(), x1.data_ptr<scalar_t>(), x2.data_ptr<scalar_t>(), p, r1, r2, m, r_size, l1_size, l2_size);
C10_CUDA_KERNEL_LAUNCH_CHECK();
} else if (p == 2.0) {
cdist_kernel_cuda_impl<scalar_t, dists<scalar_t>::two><<<grid, block, 0, at::cuda::getCurrentCUDAStream()>>>(result.data_ptr<scalar_t>(), x1.data_ptr<scalar_t>(), x2.data_ptr<scalar_t>(), p, r1, r2, m, r_size, l1_size, l2_size);
C10_CUDA_KERNEL_LAUNCH_CHECK();
} else if (std::isinf(p)) {
cdist_kernel_cuda_impl<scalar_t, dists<scalar_t>::inf><<<grid, block, 0, at::cuda::getCurrentCUDAStream()>>>(result.data_ptr<scalar_t>(), x1.data_ptr<scalar_t>(), x2.data_ptr<scalar_t>(), p, r1, r2, m, r_size, l1_size, l2_size);
C10_CUDA_KERNEL_LAUNCH_CHECK();
} else {
cdist_kernel_cuda_impl<scalar_t, dists<scalar_t>::p><<<grid, block, 0, at::cuda::getCurrentCUDAStream()>>>(result.data_ptr<scalar_t>(), x1.data_ptr<scalar_t>(), x2.data_ptr<scalar_t>(), p, r1, r2, m, r_size, l1_size, l2_size);
C10_CUDA_KERNEL_LAUNCH_CHECK();
}
});
}
void pdist_forward_kernel_impl(Tensor& result, const Tensor& self, double p) {
const dim3 grid(result.numel());
const dim3 block(forward_threads);
int64_t n = self.size(0);
int64_t m = self.size(1);
// https://github.com/pytorch/pytorch/issues/15511 demonstrated we need to do
// some math in fp64 -- this is just minimizing the amount of fp64 math we do on the device.
const double n2 = n - .5;
const double n2_squared_minus_1 = n2 * n2 - 1;
AT_DISPATCH_FLOATING_TYPES(self.scalar_type(), "pdist_cuda", [&] {
if (p == 0.0) {
pdist_kernel_cuda_impl<scalar_t, dists<scalar_t>::zero><<<grid, block, 0, at::cuda::getCurrentCUDAStream()>>>(result.data_ptr<scalar_t>(), self.data_ptr<scalar_t>(), n, m, p, n2, n2_squared_minus_1);
C10_CUDA_KERNEL_LAUNCH_CHECK();
} else if (p == 1.0) {
pdist_kernel_cuda_impl<scalar_t, dists<scalar_t>::one><<<grid, block, 0, at::cuda::getCurrentCUDAStream()>>>(result.data_ptr<scalar_t>(), self.data_ptr<scalar_t>(), n, m, p, n2, n2_squared_minus_1);
C10_CUDA_KERNEL_LAUNCH_CHECK();
} else if (p == 2.0) {
pdist_kernel_cuda_impl<scalar_t, dists<scalar_t>::two><<<grid, block, 0, at::cuda::getCurrentCUDAStream()>>>(result.data_ptr<scalar_t>(), self.data_ptr<scalar_t>(), n, m, p, n2, n2_squared_minus_1);
C10_CUDA_KERNEL_LAUNCH_CHECK();
} else if (std::isinf(p)) {
pdist_kernel_cuda_impl<scalar_t, dists<scalar_t>::inf><<<grid, block, 0, at::cuda::getCurrentCUDAStream()>>>(result.data_ptr<scalar_t>(), self.data_ptr<scalar_t>(), n, m, p, n2, n2_squared_minus_1);
C10_CUDA_KERNEL_LAUNCH_CHECK();
} else {
pdist_kernel_cuda_impl<scalar_t, dists<scalar_t>::p><<<grid, block, 0, at::cuda::getCurrentCUDAStream()>>>(result.data_ptr<scalar_t>(), self.data_ptr<scalar_t>(), n, m, p, n2, n2_squared_minus_1);
C10_CUDA_KERNEL_LAUNCH_CHECK();
}
});
}
void pdist_backward_kernel_impl(Tensor& result, const Tensor& grad, const Tensor& self, const double p, const Tensor& dist) {
if (p == 0.0 || grad.numel() == 0 || self.numel() == 0) {
result.fill_(0);
return;
}
const int64_t n = result.size(0);
int64_t m = self.size(1);
const int block_x = 16;
// NB: be careful with changing block_y; as it's currently written, grid_y is limited to be 2^16.
// block_y of 64 gives us max pdist dim1 of 2**24
const int block_y = 64;
const int grid_x = (dist.numel() + block_x - 1) / block_x;
const int grid_y = (m + block_y * 8 - 1) / (block_y * 8);
const dim3 grid(grid_x, grid_y);
const dim3 block(block_x, block_y);
// https://github.com/pytorch/pytorch/issues/15511 demonstrated we need to do
// some math in fp64 -- this is just minimizing the amount of fp64 math we do on the device.
const double n2 = n - .5;
const double n2_squared_minus_1 = n2 * n2 - 1;
Tensor buffer = at::empty({n - 1, result.size(0), result.size(1)}, result.options());
AT_DISPATCH_FLOATING_TYPES(self.scalar_type(), "pdist_cuda_backward", [&] {
if (p == 1.0) {
pdist_backward_kernel_cuda_impl<scalar_t, dists<scalar_t>::one><<<grid, block, 0, at::cuda::getCurrentCUDAStream()>>>(buffer.data_ptr<scalar_t>(), grad.data_ptr<scalar_t>(), self.data_ptr<scalar_t>(), dist.data_ptr<scalar_t>(), grad.stride(0), n, m, dist.numel(), p, n2, n2_squared_minus_1);
C10_CUDA_KERNEL_LAUNCH_CHECK();
} else if (p < 2.0) {
pdist_backward_kernel_cuda_impl<scalar_t, dists<scalar_t>::lt_two><<<grid, block, 0, at::cuda::getCurrentCUDAStream()>>>(buffer.data_ptr<scalar_t>(), grad.data_ptr<scalar_t>(), self.data_ptr<scalar_t>(), dist.data_ptr<scalar_t>(), grad.stride(0), n, m, dist.numel(), p, n2, n2_squared_minus_1);
C10_CUDA_KERNEL_LAUNCH_CHECK();
} else if (p == 2.0) {
pdist_backward_kernel_cuda_impl<scalar_t, dists<scalar_t>::two><<<grid, block, 0, at::cuda::getCurrentCUDAStream()>>>(buffer.data_ptr<scalar_t>(), grad.data_ptr<scalar_t>(), self.data_ptr<scalar_t>(), dist.data_ptr<scalar_t>(), grad.stride(0), n, m, dist.numel(), p, n2, n2_squared_minus_1);
C10_CUDA_KERNEL_LAUNCH_CHECK();
} else if (std::isinf(p)) {
pdist_backward_kernel_cuda_impl<scalar_t, dists<scalar_t>::inf><<<grid, block, 0, at::cuda::getCurrentCUDAStream()>>>(buffer.data_ptr<scalar_t>(), grad.data_ptr<scalar_t>(), self.data_ptr<scalar_t>(), dist.data_ptr<scalar_t>(), grad.stride(0), n, m, dist.numel(), p, n2, n2_squared_minus_1);
C10_CUDA_KERNEL_LAUNCH_CHECK();
} else {
pdist_backward_kernel_cuda_impl<scalar_t, dists<scalar_t>::p><<<grid, block, 0, at::cuda::getCurrentCUDAStream()>>>(buffer.data_ptr<scalar_t>(), grad.data_ptr<scalar_t>(), self.data_ptr<scalar_t>(), dist.data_ptr<scalar_t>(), grad.stride(0), n, m, dist.numel(), p, n2, n2_squared_minus_1);
C10_CUDA_KERNEL_LAUNCH_CHECK();
}
});
at::sum_out(result, buffer, 0);
}
void cdist_backward_kernel_impl(Tensor& result, const Tensor& grad, const Tensor& x1, const Tensor& x2, const double p, const Tensor& dist) {
if (p == 0.0 || grad.numel() == 0 || x1.numel() == 0 || x2.numel() == 0) {
result.fill_(0);
return;
}
const int64_t r1 = x1.size(-2);
const int64_t r2 = x2.size(-2);
const int64_t m = x1.size(-1);
// Just like we do in the CPU code, assume that result is always batched
int64_t batch = result.size(0);
const int block_x = 64;
const int block_y = 16;
const int grid_x = (m + block_x * 8 - 1) / (block_x * 8);
const int64_t count = dist.numel();
const int64_t grid_temp = (count + block_y - 1) / block_y;
const int grid_y = (grid_temp - 1) / 65535 + 1;
const int grid_z = (grid_temp - 1) / grid_y + 1;
const dim3 grid(grid_x, grid_y, grid_z);
const dim3 block(block_x, block_y);
const int64_t r_size = r1 * r2;
const int64_t l1_size = r1 * m;
const int64_t l2_size = r2 * m;
//current implementation supports only gradient that can be collapsed to 1D. However, to avoid checking this assumption,
//we call grad.contiguous() before backward, so stride is guaranteed to be 1
const int64_t gs = 1;
Tensor buffer = at::empty({batch, r2, r1, m}, result.options());
AT_DISPATCH_FLOATING_TYPES(result.scalar_type(), "cdist_cuda_backward", [&] {
if (p == 1.0) {
cdist_backward_kernel_cuda_impl<scalar_t, dists<scalar_t>::one><<<grid, block, 0, at::cuda::getCurrentCUDAStream()>>>(buffer.data_ptr<scalar_t>(),
grad.data_ptr<scalar_t>(), x1.data_ptr<scalar_t>(), x2.data_ptr<scalar_t>(), dist.data_ptr<scalar_t>(),
gs, p, r1, r2, m, count, r_size, l1_size, l2_size);
C10_CUDA_KERNEL_LAUNCH_CHECK();
} else if (p < 2.0) {
cdist_backward_kernel_cuda_impl<scalar_t, dists<scalar_t>::lt_two><<<grid, block, 0, at::cuda::getCurrentCUDAStream()>>>(buffer.data_ptr<scalar_t>(),
grad.data_ptr<scalar_t>(), x1.data_ptr<scalar_t>(), x2.data_ptr<scalar_t>(), dist.data_ptr<scalar_t>(),
gs, p, r1, r2, m, count, r_size, l1_size, l2_size);
C10_CUDA_KERNEL_LAUNCH_CHECK();
} else if (p == 2.0) {
cdist_backward_kernel_cuda_impl<scalar_t, dists<scalar_t>::two><<<grid, block, 0, at::cuda::getCurrentCUDAStream()>>>(buffer.data_ptr<scalar_t>(),
grad.data_ptr<scalar_t>(), x1.data_ptr<scalar_t>(), x2.data_ptr<scalar_t>(), dist.data_ptr<scalar_t>(),
gs, p, r1, r2, m, count, r_size, l1_size, l2_size);
C10_CUDA_KERNEL_LAUNCH_CHECK();
} else if (std::isinf(p)) {
cdist_backward_kernel_cuda_impl<scalar_t, dists<scalar_t>::inf><<<grid, block, 0, at::cuda::getCurrentCUDAStream()>>>(buffer.data_ptr<scalar_t>(),
grad.data_ptr<scalar_t>(), x1.data_ptr<scalar_t>(), x2.data_ptr<scalar_t>(), dist.data_ptr<scalar_t>(),
gs, p, r1, r2, m, count, r_size, l1_size, l2_size);
C10_CUDA_KERNEL_LAUNCH_CHECK();
} else {
cdist_backward_kernel_cuda_impl<scalar_t, dists<scalar_t>::p><<<grid, block, 0, at::cuda::getCurrentCUDAStream()>>>(buffer.data_ptr<scalar_t>(),
grad.data_ptr<scalar_t>(), x1.data_ptr<scalar_t>(), x2.data_ptr<scalar_t>(), dist.data_ptr<scalar_t>(),
gs, p, r1, r2, m, count, r_size, l1_size, l2_size);
C10_CUDA_KERNEL_LAUNCH_CHECK();
}
});
at::sum_out(result, buffer, 1);
}
} // anonymous namespace
REGISTER_DISPATCH(pdist_forward_stub, &pdist_forward_kernel_impl);
REGISTER_DISPATCH(pdist_backward_stub, &pdist_backward_kernel_impl);
REGISTER_DISPATCH(cdist_stub, &cdist_kernel_impl);
REGISTER_DISPATCH(cdist_backward_stub, &cdist_backward_kernel_impl);
}} // at::native