385 lines
23 KiB
Plaintext
385 lines
23 KiB
Plaintext
// Copyright (c) 2021, NVIDIA CORPORATION & AFFILIATES. All rights reserved.
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//
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// NVIDIA CORPORATION and its licensors retain all intellectual property
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// and proprietary rights in and to this software, related documentation
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// and any modifications thereto. Any use, reproduction, disclosure or
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// distribution of this software and related documentation without an express
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// license agreement from NVIDIA CORPORATION is strictly prohibited.
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#include <c10/util/Half.h>
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#include "upfirdn2d.h"
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//------------------------------------------------------------------------
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// Helpers.
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template <class T> struct InternalType;
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template <> struct InternalType<double> { typedef double scalar_t; };
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template <> struct InternalType<float> { typedef float scalar_t; };
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template <> struct InternalType<c10::Half> { typedef float scalar_t; };
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static __device__ __forceinline__ int floor_div(int a, int b)
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{
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int t = 1 - a / b;
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return (a + t * b) / b - t;
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}
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//------------------------------------------------------------------------
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// Generic CUDA implementation for large filters.
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template <class T> static __global__ void upfirdn2d_kernel_large(upfirdn2d_kernel_params p)
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{
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typedef typename InternalType<T>::scalar_t scalar_t;
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// Calculate thread index.
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int minorBase = blockIdx.x * blockDim.x + threadIdx.x;
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int outY = minorBase / p.launchMinor;
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minorBase -= outY * p.launchMinor;
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int outXBase = blockIdx.y * p.loopX * blockDim.y + threadIdx.y;
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int majorBase = blockIdx.z * p.loopMajor;
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if (outXBase >= p.outSize.x | outY >= p.outSize.y | majorBase >= p.sizeMajor)
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return;
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// Setup Y receptive field.
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int midY = outY * p.down.y + p.up.y - 1 - p.pad0.y;
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int inY = min(max(floor_div(midY, p.up.y), 0), p.inSize.y);
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int h = min(max(floor_div(midY + p.filterSize.y, p.up.y), 0), p.inSize.y) - inY;
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int filterY = midY + p.filterSize.y - (inY + 1) * p.up.y;
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if (p.flip)
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filterY = p.filterSize.y - 1 - filterY;
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// Loop over major, minor, and X.
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for (int majorIdx = 0, major = majorBase; majorIdx < p.loopMajor & major < p.sizeMajor; majorIdx++, major++)
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for (int minorIdx = 0, minor = minorBase; minorIdx < p.loopMinor & minor < p.sizeMinor; minorIdx++, minor += p.launchMinor)
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{
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int nc = major * p.sizeMinor + minor;
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int n = nc / p.inSize.z;
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int c = nc - n * p.inSize.z;
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for (int loopX = 0, outX = outXBase; loopX < p.loopX & outX < p.outSize.x; loopX++, outX += blockDim.y)
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{
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// Setup X receptive field.
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int midX = outX * p.down.x + p.up.x - 1 - p.pad0.x;
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int inX = min(max(floor_div(midX, p.up.x), 0), p.inSize.x);
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int w = min(max(floor_div(midX + p.filterSize.x, p.up.x), 0), p.inSize.x) - inX;
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int filterX = midX + p.filterSize.x - (inX + 1) * p.up.x;
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if (p.flip)
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filterX = p.filterSize.x - 1 - filterX;
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// Initialize pointers.
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const T* xp = &((const T*)p.x)[inX * p.inStride.x + inY * p.inStride.y + c * p.inStride.z + n * p.inStride.w];
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const float* fp = &p.f[filterX * p.filterStride.x + filterY * p.filterStride.y];
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int filterStepX = ((p.flip) ? p.up.x : -p.up.x) * p.filterStride.x;
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int filterStepY = ((p.flip) ? p.up.y : -p.up.y) * p.filterStride.y;
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// Inner loop.
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scalar_t v = 0;
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for (int y = 0; y < h; y++)
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{
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for (int x = 0; x < w; x++)
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{
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v += (scalar_t)(*xp) * (scalar_t)(*fp);
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xp += p.inStride.x;
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fp += filterStepX;
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}
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xp += p.inStride.y - w * p.inStride.x;
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fp += filterStepY - w * filterStepX;
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}
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// Store result.
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v *= p.gain;
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((T*)p.y)[outX * p.outStride.x + outY * p.outStride.y + c * p.outStride.z + n * p.outStride.w] = (T)v;
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}
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}
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}
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//------------------------------------------------------------------------
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// Specialized CUDA implementation for small filters.
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template <class T, int upx, int upy, int downx, int downy, int filterW, int filterH, int tileOutW, int tileOutH, int loopMinor>
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static __global__ void upfirdn2d_kernel_small(upfirdn2d_kernel_params p)
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{
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typedef typename InternalType<T>::scalar_t scalar_t;
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const int tileInW = ((tileOutW - 1) * downx + filterW - 1) / upx + 1;
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const int tileInH = ((tileOutH - 1) * downy + filterH - 1) / upy + 1;
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__shared__ volatile scalar_t sf[filterH][filterW];
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__shared__ volatile scalar_t sx[tileInH][tileInW][loopMinor];
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// Calculate tile index.
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int minorBase = blockIdx.x;
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int tileOutY = minorBase / p.launchMinor;
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minorBase -= tileOutY * p.launchMinor;
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minorBase *= loopMinor;
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tileOutY *= tileOutH;
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int tileOutXBase = blockIdx.y * p.loopX * tileOutW;
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int majorBase = blockIdx.z * p.loopMajor;
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if (tileOutXBase >= p.outSize.x | tileOutY >= p.outSize.y | majorBase >= p.sizeMajor)
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return;
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// Load filter (flipped).
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for (int tapIdx = threadIdx.x; tapIdx < filterH * filterW; tapIdx += blockDim.x)
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{
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int fy = tapIdx / filterW;
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int fx = tapIdx - fy * filterW;
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scalar_t v = 0;
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if (fx < p.filterSize.x & fy < p.filterSize.y)
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{
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int ffx = (p.flip) ? fx : p.filterSize.x - 1 - fx;
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int ffy = (p.flip) ? fy : p.filterSize.y - 1 - fy;
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v = (scalar_t)p.f[ffx * p.filterStride.x + ffy * p.filterStride.y];
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}
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sf[fy][fx] = v;
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}
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// Loop over major and X.
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for (int majorIdx = 0, major = majorBase; majorIdx < p.loopMajor & major < p.sizeMajor; majorIdx++, major++)
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{
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int baseNC = major * p.sizeMinor + minorBase;
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int n = baseNC / p.inSize.z;
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int baseC = baseNC - n * p.inSize.z;
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for (int loopX = 0, tileOutX = tileOutXBase; loopX < p.loopX & tileOutX < p.outSize.x; loopX++, tileOutX += tileOutW)
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{
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// Load input pixels.
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int tileMidX = tileOutX * downx + upx - 1 - p.pad0.x;
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int tileMidY = tileOutY * downy + upy - 1 - p.pad0.y;
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int tileInX = floor_div(tileMidX, upx);
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int tileInY = floor_div(tileMidY, upy);
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__syncthreads();
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for (int inIdx = threadIdx.x; inIdx < tileInH * tileInW * loopMinor; inIdx += blockDim.x)
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{
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int relC = inIdx;
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int relInX = relC / loopMinor;
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int relInY = relInX / tileInW;
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relC -= relInX * loopMinor;
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relInX -= relInY * tileInW;
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int c = baseC + relC;
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int inX = tileInX + relInX;
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int inY = tileInY + relInY;
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scalar_t v = 0;
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if (inX >= 0 & inY >= 0 & inX < p.inSize.x & inY < p.inSize.y & c < p.inSize.z)
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v = (scalar_t)((const T*)p.x)[inX * p.inStride.x + inY * p.inStride.y + c * p.inStride.z + n * p.inStride.w];
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sx[relInY][relInX][relC] = v;
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}
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// Loop over output pixels.
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__syncthreads();
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for (int outIdx = threadIdx.x; outIdx < tileOutH * tileOutW * loopMinor; outIdx += blockDim.x)
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{
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int relC = outIdx;
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int relOutX = relC / loopMinor;
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int relOutY = relOutX / tileOutW;
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relC -= relOutX * loopMinor;
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relOutX -= relOutY * tileOutW;
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int c = baseC + relC;
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int outX = tileOutX + relOutX;
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int outY = tileOutY + relOutY;
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// Setup receptive field.
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int midX = tileMidX + relOutX * downx;
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int midY = tileMidY + relOutY * downy;
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int inX = floor_div(midX, upx);
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int inY = floor_div(midY, upy);
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int relInX = inX - tileInX;
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int relInY = inY - tileInY;
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int filterX = (inX + 1) * upx - midX - 1; // flipped
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int filterY = (inY + 1) * upy - midY - 1; // flipped
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// Inner loop.
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if (outX < p.outSize.x & outY < p.outSize.y & c < p.outSize.z)
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{
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scalar_t v = 0;
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#pragma unroll
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for (int y = 0; y < filterH / upy; y++)
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#pragma unroll
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for (int x = 0; x < filterW / upx; x++)
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v += sx[relInY + y][relInX + x][relC] * sf[filterY + y * upy][filterX + x * upx];
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v *= p.gain;
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((T*)p.y)[outX * p.outStride.x + outY * p.outStride.y + c * p.outStride.z + n * p.outStride.w] = (T)v;
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}
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}
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}
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}
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}
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//------------------------------------------------------------------------
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// CUDA kernel selection.
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template <class T> upfirdn2d_kernel_spec choose_upfirdn2d_kernel(const upfirdn2d_kernel_params& p)
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{
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int s = p.inStride.z, fx = p.filterSize.x, fy = p.filterSize.y;
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upfirdn2d_kernel_spec spec = {(void*)upfirdn2d_kernel_large<T>, -1,-1,1, 4}; // contiguous
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if (s == 1) spec = {(void*)upfirdn2d_kernel_large<T>, -1,-1,4, 1}; // channels_last
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// No up/downsampling.
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if (p.up.x == 1 && p.up.y == 1 && p.down.x == 1 && p.down.y == 1)
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{
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// contiguous
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if (s != 1 && fx <= 24 && fy <= 24) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 24,24, 64,32,1>, 64,32,1, 1};
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if (s != 1 && fx <= 16 && fy <= 16) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 16,16, 64,32,1>, 64,32,1, 1};
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if (s != 1 && fx <= 7 && fy <= 7 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 7,7, 64,16,1>, 64,16,1, 1};
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if (s != 1 && fx <= 6 && fy <= 6 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 6,6, 64,16,1>, 64,16,1, 1};
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if (s != 1 && fx <= 5 && fy <= 5 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 5,5, 64,16,1>, 64,16,1, 1};
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if (s != 1 && fx <= 4 && fy <= 4 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 4,4, 64,16,1>, 64,16,1, 1};
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if (s != 1 && fx <= 3 && fy <= 3 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 3,3, 64,16,1>, 64,16,1, 1};
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if (s != 1 && fx <= 24 && fy <= 1 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 24,1, 128,8,1>, 128,8,1, 1};
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if (s != 1 && fx <= 16 && fy <= 1 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 16,1, 128,8,1>, 128,8,1, 1};
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if (s != 1 && fx <= 8 && fy <= 1 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 8,1, 128,8,1>, 128,8,1, 1};
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if (s != 1 && fx <= 1 && fy <= 24) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 1,24, 32,32,1>, 32,32,1, 1};
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if (s != 1 && fx <= 1 && fy <= 16) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 1,16, 32,32,1>, 32,32,1, 1};
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if (s != 1 && fx <= 1 && fy <= 8 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 1,8, 32,32,1>, 32,32,1, 1};
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// channels_last
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if (s == 1 && fx <= 24 && fy <= 24) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 24,24, 32,32,1>, 32,32,1, 1};
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if (s == 1 && fx <= 16 && fy <= 16) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 16,16, 32,32,1>, 32,32,1, 1};
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if (s == 1 && fx <= 7 && fy <= 7 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 7,7, 16,16,8>, 16,16,8, 1};
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if (s == 1 && fx <= 6 && fy <= 6 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 6,6, 16,16,8>, 16,16,8, 1};
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if (s == 1 && fx <= 5 && fy <= 5 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 5,5, 16,16,8>, 16,16,8, 1};
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if (s == 1 && fx <= 4 && fy <= 4 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 4,4, 16,16,8>, 16,16,8, 1};
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if (s == 1 && fx <= 3 && fy <= 3 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 3,3, 16,16,8>, 16,16,8, 1};
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if (s == 1 && fx <= 24 && fy <= 1 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 24,1, 128,1,16>, 128,1,16, 1};
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if (s == 1 && fx <= 16 && fy <= 1 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 16,1, 128,1,16>, 128,1,16, 1};
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if (s == 1 && fx <= 8 && fy <= 1 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 8,1, 128,1,16>, 128,1,16, 1};
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if (s == 1 && fx <= 1 && fy <= 24) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 1,24, 1,128,16>, 1,128,16, 1};
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if (s == 1 && fx <= 1 && fy <= 16) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 1,16, 1,128,16>, 1,128,16, 1};
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if (s == 1 && fx <= 1 && fy <= 8 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,1, 1,8, 1,128,16>, 1,128,16, 1};
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}
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// 2x upsampling.
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if (p.up.x == 2 && p.up.y == 2 && p.down.x == 1 && p.down.y == 1)
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{
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// contiguous
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if (s != 1 && fx <= 24 && fy <= 24) spec = {(void*)upfirdn2d_kernel_small<T, 2,2, 1,1, 24,24, 64,32,1>, 64,32,1, 1};
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if (s != 1 && fx <= 16 && fy <= 16) spec = {(void*)upfirdn2d_kernel_small<T, 2,2, 1,1, 16,16, 64,32,1>, 64,32,1, 1};
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if (s != 1 && fx <= 8 && fy <= 8 ) spec = {(void*)upfirdn2d_kernel_small<T, 2,2, 1,1, 8,8, 64,16,1>, 64,16,1, 1};
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if (s != 1 && fx <= 6 && fy <= 6 ) spec = {(void*)upfirdn2d_kernel_small<T, 2,2, 1,1, 6,6, 64,16,1>, 64,16,1, 1};
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if (s != 1 && fx <= 4 && fy <= 4 ) spec = {(void*)upfirdn2d_kernel_small<T, 2,2, 1,1, 4,4, 64,16,1>, 64,16,1, 1};
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if (s != 1 && fx <= 2 && fy <= 2 ) spec = {(void*)upfirdn2d_kernel_small<T, 2,2, 1,1, 2,2, 64,16,1>, 64,16,1, 1};
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// channels_last
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if (s == 1 && fx <= 24 && fy <= 24) spec = {(void*)upfirdn2d_kernel_small<T, 2,2, 1,1, 24,24, 32,32,1>, 32,32,1, 1};
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if (s == 1 && fx <= 16 && fy <= 16) spec = {(void*)upfirdn2d_kernel_small<T, 2,2, 1,1, 16,16, 32,32,1>, 32,32,1, 1};
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if (s == 1 && fx <= 8 && fy <= 8 ) spec = {(void*)upfirdn2d_kernel_small<T, 2,2, 1,1, 8,8, 16,16,8>, 16,16,8, 1};
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if (s == 1 && fx <= 6 && fy <= 6 ) spec = {(void*)upfirdn2d_kernel_small<T, 2,2, 1,1, 6,6, 16,16,8>, 16,16,8, 1};
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if (s == 1 && fx <= 4 && fy <= 4 ) spec = {(void*)upfirdn2d_kernel_small<T, 2,2, 1,1, 4,4, 16,16,8>, 16,16,8, 1};
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if (s == 1 && fx <= 2 && fy <= 2 ) spec = {(void*)upfirdn2d_kernel_small<T, 2,2, 1,1, 2,2, 16,16,8>, 16,16,8, 1};
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}
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if (p.up.x == 2 && p.up.y == 1 && p.down.x == 1 && p.down.y == 1)
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{
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// contiguous
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if (s != 1 && fx <= 24 && fy <= 1) spec = {(void*)upfirdn2d_kernel_small<T, 2,1, 1,1, 24,1, 128,8,1>, 128,8,1, 1};
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if (s != 1 && fx <= 16 && fy <= 1) spec = {(void*)upfirdn2d_kernel_small<T, 2,1, 1,1, 16,1, 128,8,1>, 128,8,1, 1};
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if (s != 1 && fx <= 8 && fy <= 1) spec = {(void*)upfirdn2d_kernel_small<T, 2,1, 1,1, 8,1, 128,8,1>, 128,8,1, 1};
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// channels_last
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if (s == 1 && fx <= 24 && fy <= 1) spec = {(void*)upfirdn2d_kernel_small<T, 2,1, 1,1, 24,1, 128,1,16>, 128,1,16, 1};
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if (s == 1 && fx <= 16 && fy <= 1) spec = {(void*)upfirdn2d_kernel_small<T, 2,1, 1,1, 16,1, 128,1,16>, 128,1,16, 1};
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if (s == 1 && fx <= 8 && fy <= 1) spec = {(void*)upfirdn2d_kernel_small<T, 2,1, 1,1, 8,1, 128,1,16>, 128,1,16, 1};
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}
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if (p.up.x == 1 && p.up.y == 2 && p.down.x == 1 && p.down.y == 1)
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{
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// contiguous
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if (s != 1 && fx <= 1 && fy <= 24) spec = {(void*)upfirdn2d_kernel_small<T, 1,2, 1,1, 1,24, 32,32,1>, 32,32,1, 1};
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if (s != 1 && fx <= 1 && fy <= 16) spec = {(void*)upfirdn2d_kernel_small<T, 1,2, 1,1, 1,16, 32,32,1>, 32,32,1, 1};
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if (s != 1 && fx <= 1 && fy <= 8 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,2, 1,1, 1,8, 32,32,1>, 32,32,1, 1};
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// channels_last
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if (s == 1 && fx <= 1 && fy <= 24) spec = {(void*)upfirdn2d_kernel_small<T, 1,2, 1,1, 1,24, 1,128,16>, 1,128,16, 1};
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if (s == 1 && fx <= 1 && fy <= 16) spec = {(void*)upfirdn2d_kernel_small<T, 1,2, 1,1, 1,16, 1,128,16>, 1,128,16, 1};
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if (s == 1 && fx <= 1 && fy <= 8 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,2, 1,1, 1,8, 1,128,16>, 1,128,16, 1};
|
|
}
|
|
|
|
// 2x downsampling.
|
|
if (p.up.x == 1 && p.up.y == 1 && p.down.x == 2 && p.down.y == 2)
|
|
{
|
|
// contiguous
|
|
if (s != 1 && fx <= 24 && fy <= 24) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 2,2, 24,24, 32,16,1>, 32,16,1, 1};
|
|
if (s != 1 && fx <= 16 && fy <= 16) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 2,2, 16,16, 32,16,1>, 32,16,1, 1};
|
|
if (s != 1 && fx <= 8 && fy <= 8 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 2,2, 8,8, 32,8,1>, 32,8,1, 1};
|
|
if (s != 1 && fx <= 6 && fy <= 6 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 2,2, 6,6, 32,8,1>, 32,8,1, 1};
|
|
if (s != 1 && fx <= 4 && fy <= 4 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 2,2, 4,4, 32,8,1>, 32,8,1, 1};
|
|
if (s != 1 && fx <= 2 && fy <= 2 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 2,2, 2,2, 32,8,1>, 32,8,1, 1};
|
|
// channels_last
|
|
if (s == 1 && fx <= 24 && fy <= 24) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 2,2, 24,24, 16,16,1>, 16,16,1, 1};
|
|
if (s == 1 && fx <= 16 && fy <= 16) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 2,2, 16,16, 16,16,1>, 16,16,1, 1};
|
|
if (s == 1 && fx <= 8 && fy <= 8 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 2,2, 8,8, 8,8,8>, 8,8,8, 1};
|
|
if (s == 1 && fx <= 6 && fy <= 6 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 2,2, 6,6, 8,8,8>, 8,8,8, 1};
|
|
if (s == 1 && fx <= 4 && fy <= 4 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 2,2, 4,4, 8,8,8>, 8,8,8, 1};
|
|
if (s == 1 && fx <= 2 && fy <= 2 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 2,2, 2,2, 8,8,8>, 8,8,8, 1};
|
|
}
|
|
if (p.up.x == 1 && p.up.y == 1 && p.down.x == 2 && p.down.y == 1)
|
|
{
|
|
// contiguous
|
|
if (s != 1 && fx <= 24 && fy <= 1) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 2,1, 24,1, 64,8,1>, 64,8,1, 1};
|
|
if (s != 1 && fx <= 16 && fy <= 1) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 2,1, 16,1, 64,8,1>, 64,8,1, 1};
|
|
if (s != 1 && fx <= 8 && fy <= 1) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 2,1, 8,1, 64,8,1>, 64,8,1, 1};
|
|
// channels_last
|
|
if (s == 1 && fx <= 24 && fy <= 1) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 2,1, 24,1, 64,1,8>, 64,1,8, 1};
|
|
if (s == 1 && fx <= 16 && fy <= 1) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 2,1, 16,1, 64,1,8>, 64,1,8, 1};
|
|
if (s == 1 && fx <= 8 && fy <= 1) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 2,1, 8,1, 64,1,8>, 64,1,8, 1};
|
|
}
|
|
if (p.up.x == 1 && p.up.y == 1 && p.down.x == 1 && p.down.y == 2)
|
|
{
|
|
// contiguous
|
|
if (s != 1 && fx <= 1 && fy <= 24) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,2, 1,24, 32,16,1>, 32,16,1, 1};
|
|
if (s != 1 && fx <= 1 && fy <= 16) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,2, 1,16, 32,16,1>, 32,16,1, 1};
|
|
if (s != 1 && fx <= 1 && fy <= 8 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,2, 1,8, 32,16,1>, 32,16,1, 1};
|
|
// channels_last
|
|
if (s == 1 && fx <= 1 && fy <= 24) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,2, 1,24, 1,64,8>, 1,64,8, 1};
|
|
if (s == 1 && fx <= 1 && fy <= 16) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,2, 1,16, 1,64,8>, 1,64,8, 1};
|
|
if (s == 1 && fx <= 1 && fy <= 8 ) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,2, 1,8, 1,64,8>, 1,64,8, 1};
|
|
}
|
|
|
|
// 4x upsampling.
|
|
if (p.up.x == 4 && p.up.y == 4 && p.down.x == 1 && p.down.y == 1)
|
|
{
|
|
// contiguous
|
|
if (s != 1 && fx <= 48 && fy <= 48) spec = {(void*)upfirdn2d_kernel_small<T, 4,4, 1,1, 48,48, 64,32,1>, 64,32,1, 1};
|
|
if (s != 1 && fx <= 32 && fy <= 32) spec = {(void*)upfirdn2d_kernel_small<T, 4,4, 1,1, 32,32, 64,32,1>, 64,32,1, 1};
|
|
// channels_last
|
|
if (s == 1 && fx <= 48 && fy <= 48) spec = {(void*)upfirdn2d_kernel_small<T, 4,4, 1,1, 48,48, 32,32,1>, 32,32,1, 1};
|
|
if (s == 1 && fx <= 32 && fy <= 32) spec = {(void*)upfirdn2d_kernel_small<T, 4,4, 1,1, 32,32, 32,32,1>, 32,32,1, 1};
|
|
}
|
|
if (p.up.x == 4 && p.up.y == 1 && p.down.x == 1 && p.down.y == 1)
|
|
{
|
|
// contiguous
|
|
if (s != 1 && fx <= 48 && fy <= 1) spec = {(void*)upfirdn2d_kernel_small<T, 4,1, 1,1, 48,1, 128,8,1>, 128,8,1, 1};
|
|
if (s != 1 && fx <= 32 && fy <= 1) spec = {(void*)upfirdn2d_kernel_small<T, 4,1, 1,1, 32,1, 128,8,1>, 128,8,1, 1};
|
|
// channels_last
|
|
if (s == 1 && fx <= 48 && fy <= 1) spec = {(void*)upfirdn2d_kernel_small<T, 4,1, 1,1, 48,1, 128,1,16>, 128,1,16, 1};
|
|
if (s == 1 && fx <= 32 && fy <= 1) spec = {(void*)upfirdn2d_kernel_small<T, 4,1, 1,1, 32,1, 128,1,16>, 128,1,16, 1};
|
|
}
|
|
if (p.up.x == 1 && p.up.y == 4 && p.down.x == 1 && p.down.y == 1)
|
|
{
|
|
// contiguous
|
|
if (s != 1 && fx <= 1 && fy <= 48) spec = {(void*)upfirdn2d_kernel_small<T, 1,4, 1,1, 1,48, 32,32,1>, 32,32,1, 1};
|
|
if (s != 1 && fx <= 1 && fy <= 32) spec = {(void*)upfirdn2d_kernel_small<T, 1,4, 1,1, 1,32, 32,32,1>, 32,32,1, 1};
|
|
// channels_last
|
|
if (s == 1 && fx <= 1 && fy <= 48) spec = {(void*)upfirdn2d_kernel_small<T, 1,4, 1,1, 1,48, 1,128,16>, 1,128,16, 1};
|
|
if (s == 1 && fx <= 1 && fy <= 32) spec = {(void*)upfirdn2d_kernel_small<T, 1,4, 1,1, 1,32, 1,128,16>, 1,128,16, 1};
|
|
}
|
|
|
|
// 4x downsampling (inefficient).
|
|
if (p.up.x == 1 && p.up.y == 1 && p.down.x == 4 && p.down.y == 1)
|
|
{
|
|
// contiguous
|
|
if (s != 1 && fx <= 48 && fy <= 1) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 4,1, 48,1, 32,8,1>, 32,8,1, 1};
|
|
if (s != 1 && fx <= 32 && fy <= 1) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 4,1, 32,1, 32,8,1>, 32,8,1, 1};
|
|
// channels_last
|
|
if (s == 1 && fx <= 48 && fy <= 1) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 4,1, 48,1, 32,1,8>, 32,1,8, 1};
|
|
if (s == 1 && fx <= 32 && fy <= 1) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 4,1, 32,1, 32,1,8>, 32,1,8, 1};
|
|
}
|
|
if (p.up.x == 1 && p.up.y == 1 && p.down.x == 1 && p.down.y == 4)
|
|
{
|
|
// contiguous
|
|
if (s != 1 && fx <= 1 && fy <= 48) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,4, 1,48, 32,8,1>, 32,8,1, 1};
|
|
if (s != 1 && fx <= 1 && fy <= 32) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,4, 1,32, 32,8,1>, 32,8,1, 1};
|
|
// channels_last
|
|
if (s == 1 && fx <= 1 && fy <= 48) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,4, 1,48, 1,32,8>, 1,32,8, 1};
|
|
if (s == 1 && fx <= 1 && fy <= 32) spec = {(void*)upfirdn2d_kernel_small<T, 1,1, 1,4, 1,32, 1,32,8>, 1,32,8, 1};
|
|
}
|
|
return spec;
|
|
}
|
|
|
|
//------------------------------------------------------------------------
|
|
// Template specializations.
|
|
|
|
template upfirdn2d_kernel_spec choose_upfirdn2d_kernel<double> (const upfirdn2d_kernel_params& p);
|
|
template upfirdn2d_kernel_spec choose_upfirdn2d_kernel<float> (const upfirdn2d_kernel_params& p);
|
|
template upfirdn2d_kernel_spec choose_upfirdn2d_kernel<c10::Half>(const upfirdn2d_kernel_params& p);
|
|
|
|
//------------------------------------------------------------------------
|