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// Copyright (c) 2021, NVIDIA CORPORATION & AFFILIATES. All rights reserved.
//
// NVIDIA CORPORATION and its licensors retain all intellectual property
// and proprietary rights in and to this software, related documentation
// and any modifications thereto. Any use, reproduction, disclosure or
// distribution of this software and related documentation without an express
// license agreement from NVIDIA CORPORATION is strictly prohibited.
#include <c10/util/Half.h>
#include "filtered_lrelu.h"
#include <cstdint>
//------------------------------------------------------------------------
// Helpers.
enum // Filter modes.
{
MODE_SUSD = 0, // Separable upsampling, separable downsampling.
MODE_FUSD = 1, // Full upsampling, separable downsampling.
MODE_SUFD = 2, // Separable upsampling, full downsampling.
MODE_FUFD = 3, // Full upsampling, full downsampling.
};
template <class T> struct InternalType;
template <> struct InternalType<double>
{
typedef double scalar_t; typedef double2 vec2_t; typedef double4 vec4_t;
__device__ __forceinline__ static vec2_t zero_vec2(void) { return make_double2(0, 0); }
__device__ __forceinline__ static vec4_t zero_vec4(void) { return make_double4(0, 0, 0, 0); }
__device__ __forceinline__ static double clamp(double x, double c) { return fmin(fmax(x, -c), c); }
};
template <> struct InternalType<float>
{
typedef float scalar_t; typedef float2 vec2_t; typedef float4 vec4_t;
__device__ __forceinline__ static vec2_t zero_vec2(void) { return make_float2(0, 0); }
__device__ __forceinline__ static vec4_t zero_vec4(void) { return make_float4(0, 0, 0, 0); }
__device__ __forceinline__ static float clamp(float x, float c) { return fminf(fmaxf(x, -c), c); }
};
template <> struct InternalType<c10::Half>
{
typedef float scalar_t; typedef float2 vec2_t; typedef float4 vec4_t;
__device__ __forceinline__ static vec2_t zero_vec2(void) { return make_float2(0, 0); }
__device__ __forceinline__ static vec4_t zero_vec4(void) { return make_float4(0, 0, 0, 0); }
__device__ __forceinline__ static float clamp(float x, float c) { return fminf(fmaxf(x, -c), c); }
};
#define MIN(A, B) ((A) < (B) ? (A) : (B))
#define MAX(A, B) ((A) > (B) ? (A) : (B))
#define CEIL_DIV(A, B) (((B)==1) ? (A) : \
((B)==2) ? ((int)((A)+1) >> 1) : \
((B)==4) ? ((int)((A)+3) >> 2) : \
(((A) + ((A) > 0 ? (B) - 1 : 0)) / (B)))
// This works only up to blocks of size 256 x 256 and for all N that are powers of two.
template <int N> __device__ __forceinline__ void fast_div_mod(int& x, int& y, unsigned int i)
{
if ((N & (N-1)) && N <= 256)
y = (i * ((1<<24)/N + 1)) >> 24; // Assumes N <= 256, i < N*256.
else
y = i/N;
x = i - y*N;
}
// Type cast stride before reading it.
template <class T> __device__ __forceinline__ T get_stride(const int64_t& x)
{
return *reinterpret_cast<const T*>(&x);
}
//------------------------------------------------------------------------
// Filters, setup kernel, copying function.
#define MAX_FILTER_SIZE 32
// Combined up/down filter buffers so that transfer can be done with one copy.
__device__ float g_fbuf[2 * MAX_FILTER_SIZE * MAX_FILTER_SIZE]; // Filters in global memory, written by setup kernel.
__device__ __constant__ float c_fbuf[2 * MAX_FILTER_SIZE * MAX_FILTER_SIZE]; // Filters in constant memory, read by main kernel.
// Accessors to combined buffers to index up/down filters individually.
#define c_fu (c_fbuf)
#define c_fd (c_fbuf + MAX_FILTER_SIZE * MAX_FILTER_SIZE)
#define g_fu (g_fbuf)
#define g_fd (g_fbuf + MAX_FILTER_SIZE * MAX_FILTER_SIZE)
// Set up filters into global memory buffer.
static __global__ void setup_filters_kernel(filtered_lrelu_kernel_params p)
{
for (int idx = threadIdx.x; idx < MAX_FILTER_SIZE * MAX_FILTER_SIZE; idx += blockDim.x)
{
int x, y;
fast_div_mod<MAX_FILTER_SIZE>(x, y, idx);
int fu_x = p.flip ? x : (p.fuShape.x - 1 - x);
int fu_y = p.flip ? y : (p.fuShape.y - 1 - y);
if (p.fuShape.y > 0)
g_fu[idx] = (x >= p.fuShape.x || y >= p.fuShape.y) ? 0.0f : p.fu[fu_x * p.fuStride.x + fu_y * p.fuStride.y];
else
g_fu[idx] = (x >= p.fuShape.x || y > 0) ? 0.0f : p.fu[fu_x * p.fuStride.x];
int fd_x = p.flip ? x : (p.fdShape.x - 1 - x);
int fd_y = p.flip ? y : (p.fdShape.y - 1 - y);
if (p.fdShape.y > 0)
g_fd[idx] = (x >= p.fdShape.x || y >= p.fdShape.y) ? 0.0f : p.fd[fd_x * p.fdStride.x + fd_y * p.fdStride.y];
else
g_fd[idx] = (x >= p.fdShape.x || y > 0) ? 0.0f : p.fd[fd_x * p.fdStride.x];
}
}
// Host function to copy filters written by setup kernel into constant buffer for main kernel.
template <bool, bool> static cudaError_t copy_filters(cudaStream_t stream)
{
void* src = 0;
cudaError_t err = cudaGetSymbolAddress(&src, g_fbuf);
if (err) return err;
return cudaMemcpyToSymbolAsync(c_fbuf, src, 2 * MAX_FILTER_SIZE * MAX_FILTER_SIZE * sizeof(float), 0, cudaMemcpyDeviceToDevice, stream);
}
//------------------------------------------------------------------------
// Coordinate spaces:
// - Relative to input tensor: inX, inY, tileInX, tileInY
// - Relative to input tile: relInX, relInY, tileInW, tileInH
// - Relative to upsampled tile: relUpX, relUpY, tileUpW, tileUpH
// - Relative to output tile: relOutX, relOutY, tileOutW, tileOutH
// - Relative to output tensor: outX, outY, tileOutX, tileOutY
//
// Relationships between coordinate spaces:
// - inX = tileInX + relInX
// - inY = tileInY + relInY
// - relUpX = relInX * up + phaseInX
// - relUpY = relInY * up + phaseInY
// - relUpX = relOutX * down
// - relUpY = relOutY * down
// - outX = tileOutX + relOutX
// - outY = tileOutY + relOutY
extern __shared__ char s_buf_raw[]; // When sharedKB <= 48, allocate shared memory statically inside the kernel, otherwise use the externally allocated shared memory buffer.
template <class T, class index_t, int sharedKB, bool signWrite, bool signRead, int filterMode, int up, int fuSize, int down, int fdSize, int tileOutW, int tileOutH, int threadsPerBlock, bool enableXrep, bool enableWriteSkip>
static __global__ void filtered_lrelu_kernel(filtered_lrelu_kernel_params p)
{
// Check that we don't try to support non-existing filter modes.
static_assert(up == 1 || up == 2 || up == 4, "only up=1, up=2, up=4 scales supported");
static_assert(down == 1 || down == 2 || down == 4, "only down=1, down=2, down=4 scales supported");
static_assert(fuSize >= up, "upsampling filter size must be at least upsampling factor");
static_assert(fdSize >= down, "downsampling filter size must be at least downsampling factor");
static_assert(fuSize % up == 0, "upsampling filter size must be divisible with upsampling factor");
static_assert(fdSize % down == 0, "downsampling filter size must be divisible with downsampling factor");
static_assert(fuSize <= MAX_FILTER_SIZE && fdSize <= MAX_FILTER_SIZE, "filter size greater than MAX_FILTER_SIZE");
static_assert(up != 1 || (fuSize == 1 && (filterMode == MODE_FUFD || filterMode == MODE_FUSD)), "up=1 supported only for 1x1 full filters");
static_assert(down != 1 || (fdSize == 1 && (filterMode == MODE_FUFD || filterMode == MODE_SUFD)), "down=1 supported only for 1x1 full filters");
static_assert(!(up == 4 && (filterMode == MODE_FUFD || filterMode == MODE_FUSD)), "full filters not supported for up=4");
static_assert(!(down == 4 && (filterMode == MODE_FUFD || filterMode == MODE_SUFD)), "full filters not supported for down=4");
// Static definitions.
typedef typename InternalType<T>::scalar_t scalar_t;
typedef typename InternalType<T>::vec2_t vec2_t;
typedef typename InternalType<T>::vec4_t vec4_t;
const int tileUpW = (tileOutW * down + (fdSize - 1) - (down - 1) + 3) & ~3; // Upsampled tile width, rounded up to multiple of 4.
const int tileUpH = tileOutH * down + (fdSize - 1) - (down - 1); // Upsampled tile height.
const int tileInW = CEIL_DIV(tileUpW + (fuSize - 1), up); // Input tile width.
const int tileInH = CEIL_DIV(tileUpH + (fuSize - 1), up); // Input tile height.
const int tileUpH_up = CEIL_DIV(tileUpH, up) * up; // Upsampled tile height rounded up to a multiple of up.
const int tileInH_up = CEIL_DIV(tileUpH_up + (fuSize - 1), up); // For allocations only, to avoid shared memory read overruns with up=2 and up=4.
// Merge 1x1 downsampling into last upsampling step for upf1 and ups2.
const bool downInline = (down == 1) && ((up == 1 && filterMode == MODE_FUFD) || (up == 2 && filterMode == MODE_SUFD));
// Sizes of logical buffers.
const int szIn = tileInH_up * tileInW;
const int szUpX = tileInH_up * tileUpW;
const int szUpXY = downInline ? 0 : (tileUpH * tileUpW);
const int szDownX = tileUpH * tileOutW;
// Sizes for shared memory arrays.
const int s_buf0_size_base =
(filterMode == MODE_SUSD) ? MAX(szIn, szUpXY) :
(filterMode == MODE_FUSD) ? MAX(szIn, szDownX) :
(filterMode == MODE_SUFD) ? MAX(szIn, szUpXY) :
(filterMode == MODE_FUFD) ? szIn :
-1;
const int s_buf1_size_base =
(filterMode == MODE_SUSD) ? MAX(szUpX, szDownX) :
(filterMode == MODE_FUSD) ? szUpXY :
(filterMode == MODE_SUFD) ? szUpX :
(filterMode == MODE_FUFD) ? szUpXY :
-1;
// Ensure U128 alignment.
const int s_buf0_size = (s_buf0_size_base + 3) & ~3;
const int s_buf1_size = (s_buf1_size_base + 3) & ~3;
// Check at compile time that we don't use too much shared memory.
static_assert((s_buf0_size + s_buf1_size) * sizeof(scalar_t) <= (sharedKB << 10), "shared memory overflow");
// Declare shared memory arrays.
scalar_t* s_buf0;
scalar_t* s_buf1;
if (sharedKB <= 48)
{
// Allocate shared memory arrays here.
__shared__ scalar_t s_buf0_st[(sharedKB > 48) ? (1<<24) : (s_buf0_size + s_buf1_size)]; // Prevent launching if this isn't optimized away when unused.
s_buf0 = s_buf0_st;
s_buf1 = s_buf0 + s_buf0_size;
}
else
{
// Use the dynamically allocated shared memory array.
s_buf0 = (scalar_t*)s_buf_raw;
s_buf1 = s_buf0 + s_buf0_size;
}
// Pointers to the buffers.
scalar_t* s_tileIn; // Input tile: [relInX * tileInH + relInY]
scalar_t* s_tileUpX; // After horizontal upsampling: [relInY * tileUpW + relUpX]
scalar_t* s_tileUpXY; // After upsampling: [relUpY * tileUpW + relUpX]
scalar_t* s_tileDownX; // After horizontal downsampling: [relUpY * tileOutW + relOutX]
if (filterMode == MODE_SUSD)
{
s_tileIn = s_buf0;
s_tileUpX = s_buf1;
s_tileUpXY = s_buf0;
s_tileDownX = s_buf1;
}
else if (filterMode == MODE_FUSD)
{
s_tileIn = s_buf0;
s_tileUpXY = s_buf1;
s_tileDownX = s_buf0;
}
else if (filterMode == MODE_SUFD)
{
s_tileIn = s_buf0;
s_tileUpX = s_buf1;
s_tileUpXY = s_buf0;
}
else if (filterMode == MODE_FUFD)
{
s_tileIn = s_buf0;
s_tileUpXY = s_buf1;
}
// Allow large grids in z direction via per-launch offset.
int channelIdx = blockIdx.z + p.blockZofs;
int batchIdx = channelIdx / p.yShape.z;
channelIdx -= batchIdx * p.yShape.z;
// Offset to output feature map. In bytes.
index_t mapOfsOut = channelIdx * get_stride<index_t>(p.yStride.z) + batchIdx * get_stride<index_t>(p.yStride.w);
// Sign shift amount.
uint32_t signXo = ((threadIdx.x + p.sOfs.x) << 1) & 6;
// Inner tile loop.
#pragma unroll 1
for (int tileIdx = 0; !enableXrep || (tileIdx < MIN(p.tilesXrep, p.tilesXdim - p.tilesXrep * blockIdx.y)); tileIdx++)
{
// Locate output tile.
int tileX = enableXrep ? blockIdx.y * p.tilesXrep + tileIdx : blockIdx.x;
int tileOutX = tileX * tileOutW;
int tileOutY = (enableXrep ? blockIdx.x : blockIdx.y) * tileOutH;
// Locate input tile.
int tmpX = tileOutX * down - p.pad0.x;
int tmpY = tileOutY * down - p.pad0.y;
int tileInX = CEIL_DIV(tmpX, up);
int tileInY = CEIL_DIV(tmpY, up);
const int phaseInX = tileInX * up - tmpX;
const int phaseInY = tileInY * up - tmpY;
// Extra sync if input and output buffers are the same and we are not on first tile.
if (enableXrep && tileIdx > 0 && (filterMode == MODE_FUSD || (filterMode == MODE_SUFD && !downInline) || (filterMode == MODE_FUFD && downInline)))
__syncthreads();
// Load input tile & apply bias. Unrolled.
scalar_t b = (scalar_t)*(const T*)((const char*)p.b + (channelIdx * get_stride<index_t>(p.bStride)));
index_t mapOfsIn = channelIdx * get_stride<index_t>(p.xStride.z) + batchIdx * get_stride<index_t>(p.xStride.w);
int idx = threadIdx.x;
const int loopCountIN = CEIL_DIV(tileInW * tileInH, threadsPerBlock);
#pragma unroll
for (int loop = 0; loop < loopCountIN; loop++)
{
int relInX, relInY;
fast_div_mod<tileInW>(relInX, relInY, idx);
int inX = tileInX + relInX;
int inY = tileInY + relInY;
scalar_t v = 0;
if ((uint32_t)inX < p.xShape.x && (uint32_t)inY < p.xShape.y)
v = (scalar_t)*((const T*)((const char*)p.x + (inX * get_stride<index_t>(p.xStride.x) + inY * get_stride<index_t>(p.xStride.y) + mapOfsIn))) + b;
bool skip = (loop == loopCountIN-1) && (idx >= tileInW * tileInH);
if (!skip)
s_tileIn[idx] = v;
idx += threadsPerBlock;
}
if (filterMode == MODE_SUSD || filterMode == MODE_SUFD) // Separable upsampling filter.
{
// Horizontal upsampling.
__syncthreads();
if (up == 4)
{
for (int idx = threadIdx.x*up; idx < tileUpW * tileInH; idx += blockDim.x*up)
{
int relUpX0, relInY;
fast_div_mod<tileUpW>(relUpX0, relInY, idx);
int relInX0 = relUpX0 / up;
int src0 = relInX0 + tileInW * relInY;
int dst = relInY * tileUpW + relUpX0;
vec4_t v = InternalType<T>::zero_vec4();
scalar_t a = s_tileIn[src0];
if (phaseInX == 0)
{
#pragma unroll
for (int step = 0; step < fuSize / up; step++)
{
v.x += a * (scalar_t)c_fu[step * up + 0];
a = s_tileIn[src0 + step + 1];
v.y += a * (scalar_t)c_fu[step * up + 3];
v.z += a * (scalar_t)c_fu[step * up + 2];
v.w += a * (scalar_t)c_fu[step * up + 1];
}
}
else if (phaseInX == 1)
{
#pragma unroll
for (int step = 0; step < fuSize / up; step++)
{
v.x += a * (scalar_t)c_fu[step * up + 1];
v.y += a * (scalar_t)c_fu[step * up + 0];
a = s_tileIn[src0 + step + 1];
v.z += a * (scalar_t)c_fu[step * up + 3];
v.w += a * (scalar_t)c_fu[step * up + 2];
}
}
else if (phaseInX == 2)
{
#pragma unroll
for (int step = 0; step < fuSize / up; step++)
{
v.x += a * (scalar_t)c_fu[step * up + 2];
v.y += a * (scalar_t)c_fu[step * up + 1];
v.z += a * (scalar_t)c_fu[step * up + 0];
a = s_tileIn[src0 + step + 1];
v.w += a * (scalar_t)c_fu[step * up + 3];
}
}
else // (phaseInX == 3)
{
#pragma unroll
for (int step = 0; step < fuSize / up; step++)
{
v.x += a * (scalar_t)c_fu[step * up + 3];
v.y += a * (scalar_t)c_fu[step * up + 2];
v.z += a * (scalar_t)c_fu[step * up + 1];
v.w += a * (scalar_t)c_fu[step * up + 0];
a = s_tileIn[src0 + step + 1];
}
}
s_tileUpX[dst+0] = v.x;
s_tileUpX[dst+1] = v.y;
s_tileUpX[dst+2] = v.z;
s_tileUpX[dst+3] = v.w;
}
}
else if (up == 2)
{
bool p0 = (phaseInX == 0);
for (int idx = threadIdx.x*up; idx < tileUpW * tileInH; idx += blockDim.x*up)
{
int relUpX0, relInY;
fast_div_mod<tileUpW>(relUpX0, relInY, idx);
int relInX0 = relUpX0 / up;
int src0 = relInX0 + tileInW * relInY;
int dst = relInY * tileUpW + relUpX0;
vec2_t v = InternalType<T>::zero_vec2();
scalar_t a = s_tileIn[src0];
if (p0) // (phaseInX == 0)
{
#pragma unroll
for (int step = 0; step < fuSize / up; step++)
{
v.x += a * (scalar_t)c_fu[step * up + 0];
a = s_tileIn[src0 + step + 1];
v.y += a * (scalar_t)c_fu[step * up + 1];
}
}
else // (phaseInX == 1)
{
#pragma unroll
for (int step = 0; step < fuSize / up; step++)
{
v.x += a * (scalar_t)c_fu[step * up + 1];
v.y += a * (scalar_t)c_fu[step * up + 0];
a = s_tileIn[src0 + step + 1];
}
}
s_tileUpX[dst+0] = v.x;
s_tileUpX[dst+1] = v.y;
}
}
// Vertical upsampling & nonlinearity.
__syncthreads();
int groupMask = 15 << ((threadIdx.x & 31) & ~3);
int minY = tileOutY ? (tileOutY - tileOutH) * down + tileUpH : 0; // Skip already written signs.
int sShapeMaxY = MIN(p.sShape.y, tileOutY * down + tileUpH); // Avoid out-of-tile sign writes.
if (up == 4)
{
minY -= 3; // Adjust according to block height.
for (int idx = threadIdx.x; idx < tileUpW * tileUpH_up / up; idx += blockDim.x)
{
int relUpX, relInY0;
fast_div_mod<tileUpW>(relUpX, relInY0, idx);
int relUpY0 = relInY0 * up;
int src0 = relInY0 * tileUpW + relUpX;
int dst = relUpY0 * tileUpW + relUpX;
vec4_t v = InternalType<T>::zero_vec4();
scalar_t a = s_tileUpX[src0];
if (phaseInY == 0)
{
#pragma unroll
for (int step = 0; step < fuSize / up; step++)
{
v.x += a * (scalar_t)c_fu[step * up + 0];
a = s_tileUpX[src0 + (step + 1) * tileUpW];
v.y += a * (scalar_t)c_fu[step * up + 3];
v.z += a * (scalar_t)c_fu[step * up + 2];
v.w += a * (scalar_t)c_fu[step * up + 1];
}
}
else if (phaseInY == 1)
{
#pragma unroll
for (int step = 0; step < fuSize / up; step++)
{
v.x += a * (scalar_t)c_fu[step * up + 1];
v.y += a * (scalar_t)c_fu[step * up + 0];
a = s_tileUpX[src0 + (step + 1) * tileUpW];
v.z += a * (scalar_t)c_fu[step * up + 3];
v.w += a * (scalar_t)c_fu[step * up + 2];
}
}
else if (phaseInY == 2)
{
#pragma unroll
for (int step = 0; step < fuSize / up; step++)
{
v.x += a * (scalar_t)c_fu[step * up + 2];
v.y += a * (scalar_t)c_fu[step * up + 1];
v.z += a * (scalar_t)c_fu[step * up + 0];
a = s_tileUpX[src0 + (step + 1) * tileUpW];
v.w += a * (scalar_t)c_fu[step * up + 3];
}
}
else // (phaseInY == 3)
{
#pragma unroll
for (int step = 0; step < fuSize / up; step++)
{
v.x += a * (scalar_t)c_fu[step * up + 3];
v.y += a * (scalar_t)c_fu[step * up + 2];
v.z += a * (scalar_t)c_fu[step * up + 1];
v.w += a * (scalar_t)c_fu[step * up + 0];
a = s_tileUpX[src0 + (step + 1) * tileUpW];
}
}
int x = tileOutX * down + relUpX;
int y = tileOutY * down + relUpY0;
int signX = x + p.sOfs.x;
int signY = y + p.sOfs.y;
int signZ = blockIdx.z + p.blockZofs;
int signXb = signX >> 2;
index_t si0 = signXb + p.sShape.x * (signY + (index_t)p.sShape.y * signZ);
index_t si1 = si0 + p.sShape.x;
index_t si2 = si0 + p.sShape.x * 2;
index_t si3 = si0 + p.sShape.x * 3;
v.x *= (scalar_t)((float)up * (float)up * p.gain);
v.y *= (scalar_t)((float)up * (float)up * p.gain);
v.z *= (scalar_t)((float)up * (float)up * p.gain);
v.w *= (scalar_t)((float)up * (float)up * p.gain);
if (signWrite)
{
if (!enableWriteSkip)
{
// Determine and write signs.
int sx = __float_as_uint(v.x) >> 31 << 0;
int sy = __float_as_uint(v.y) >> 31 << 8;
int sz = __float_as_uint(v.z) >> 31 << 16;
int sw = __float_as_uint(v.w) >> 31 << 24;
if (sx) v.x *= p.slope;
if (sy) v.y *= p.slope;
if (sz) v.z *= p.slope;
if (sw) v.w *= p.slope;
if (fabsf(v.x) > p.clamp) { sx = 2 << 0; v.x = InternalType<T>::clamp(v.x, p.clamp); }
if (fabsf(v.y) > p.clamp) { sy = 2 << 8; v.y = InternalType<T>::clamp(v.y, p.clamp); }
if (fabsf(v.z) > p.clamp) { sz = 2 << 16; v.z = InternalType<T>::clamp(v.z, p.clamp); }
if (fabsf(v.w) > p.clamp) { sw = 2 << 24; v.w = InternalType<T>::clamp(v.w, p.clamp); }
if ((uint32_t)signXb < p.swLimit && signY >= minY)
{
// Combine signs.
uint32_t s = sx + sy + sw + sz;
s <<= (signX & 3) << 1;
s |= __shfl_xor_sync(groupMask, s, 1);
s |= __shfl_xor_sync(groupMask, s, 2);
// Write signs.
if ((uint32_t)(signY + 0) < sShapeMaxY) { p.s[si0] = (unsigned char)(s >> 0); }
if ((uint32_t)(signY + 1) < sShapeMaxY) { p.s[si1] = (unsigned char)(s >> 8); }
if ((uint32_t)(signY + 2) < sShapeMaxY) { p.s[si2] = (unsigned char)(s >> 16); }
if ((uint32_t)(signY + 3) < sShapeMaxY) { p.s[si3] = (unsigned char)(s >> 24); }
}
}
else
{
// Determine and write signs.
if ((uint32_t)signXb < p.swLimit && signY >= minY)
{
int sx = __float_as_uint(v.x) >> 31 << 0;
int sy = __float_as_uint(v.y) >> 31 << 8;
int sz = __float_as_uint(v.z) >> 31 << 16;
int sw = __float_as_uint(v.w) >> 31 << 24;
if (sx) v.x *= p.slope;
if (sy) v.y *= p.slope;
if (sz) v.z *= p.slope;
if (sw) v.w *= p.slope;
if (fabsf(v.x) > p.clamp) { sx = 2 << 0; v.x = InternalType<T>::clamp(v.x, p.clamp); }
if (fabsf(v.y) > p.clamp) { sy = 2 << 8; v.y = InternalType<T>::clamp(v.y, p.clamp); }
if (fabsf(v.z) > p.clamp) { sz = 2 << 16; v.z = InternalType<T>::clamp(v.z, p.clamp); }
if (fabsf(v.w) > p.clamp) { sw = 2 << 24; v.w = InternalType<T>::clamp(v.w, p.clamp); }
// Combine signs.
uint32_t s = sx + sy + sw + sz;
s <<= (signX & 3) << 1;
s |= __shfl_xor_sync(groupMask, s, 1);
s |= __shfl_xor_sync(groupMask, s, 2);
// Write signs.
if ((uint32_t)(signY + 0) < sShapeMaxY) { p.s[si0] = (unsigned char)(s >> 0); }
if ((uint32_t)(signY + 1) < sShapeMaxY) { p.s[si1] = (unsigned char)(s >> 8); }
if ((uint32_t)(signY + 2) < sShapeMaxY) { p.s[si2] = (unsigned char)(s >> 16); }
if ((uint32_t)(signY + 3) < sShapeMaxY) { p.s[si3] = (unsigned char)(s >> 24); }
}
else
{
// Just compute the values.
if (v.x < 0.f) v.x *= p.slope; v.x = InternalType<T>::clamp(v.x, p.clamp);
if (v.y < 0.f) v.y *= p.slope; v.y = InternalType<T>::clamp(v.y, p.clamp);
if (v.z < 0.f) v.z *= p.slope; v.z = InternalType<T>::clamp(v.z, p.clamp);
if (v.w < 0.f) v.w *= p.slope; v.w = InternalType<T>::clamp(v.w, p.clamp);
}
}
}
else if (signRead) // Read signs and apply.
{
if ((uint32_t)signXb < p.swLimit)
{
int ss = (signX & 3) << 1;
if ((uint32_t)(signY + 0) < p.sShape.y) { int s = p.s[si0] >> ss; if (s & 1) v.x *= p.slope; if (s & 2) v.x = 0.f; }
if ((uint32_t)(signY + 1) < p.sShape.y) { int s = p.s[si1] >> ss; if (s & 1) v.y *= p.slope; if (s & 2) v.y = 0.f; }
if ((uint32_t)(signY + 2) < p.sShape.y) { int s = p.s[si2] >> ss; if (s & 1) v.z *= p.slope; if (s & 2) v.z = 0.f; }
if ((uint32_t)(signY + 3) < p.sShape.y) { int s = p.s[si3] >> ss; if (s & 1) v.w *= p.slope; if (s & 2) v.w = 0.f; }
}
}
else // Forward pass with no sign write.
{
if (v.x < 0.f) v.x *= p.slope; v.x = InternalType<T>::clamp(v.x, p.clamp);
if (v.y < 0.f) v.y *= p.slope; v.y = InternalType<T>::clamp(v.y, p.clamp);
if (v.z < 0.f) v.z *= p.slope; v.z = InternalType<T>::clamp(v.z, p.clamp);
if (v.w < 0.f) v.w *= p.slope; v.w = InternalType<T>::clamp(v.w, p.clamp);
}
s_tileUpXY[dst + 0 * tileUpW] = v.x;
if (relUpY0 + 1 < tileUpH) s_tileUpXY[dst + 1 * tileUpW] = v.y;
if (relUpY0 + 2 < tileUpH) s_tileUpXY[dst + 2 * tileUpW] = v.z;
if (relUpY0 + 3 < tileUpH) s_tileUpXY[dst + 3 * tileUpW] = v.w;
}
}
else if (up == 2)
{
minY -= 1; // Adjust according to block height.
for (int idx = threadIdx.x; idx < tileUpW * tileUpH_up / up; idx += blockDim.x)
{
int relUpX, relInY0;
fast_div_mod<tileUpW>(relUpX, relInY0, idx);
int relUpY0 = relInY0 * up;
int src0 = relInY0 * tileUpW + relUpX;
int dst = relUpY0 * tileUpW + relUpX;
vec2_t v = InternalType<T>::zero_vec2();
scalar_t a = s_tileUpX[src0];
if (phaseInY == 0)
{
#pragma unroll
for (int step = 0; step < fuSize / up; step++)
{
v.x += a * (scalar_t)c_fu[step * up + 0];
a = s_tileUpX[src0 + (step + 1) * tileUpW];
v.y += a * (scalar_t)c_fu[step * up + 1];
}
}
else // (phaseInY == 1)
{
#pragma unroll
for (int step = 0; step < fuSize / up; step++)
{
v.x += a * (scalar_t)c_fu[step * up + 1];
v.y += a * (scalar_t)c_fu[step * up + 0];
a = s_tileUpX[src0 + (step + 1) * tileUpW];
}
}
int x = tileOutX * down + relUpX;
int y = tileOutY * down + relUpY0;
int signX = x + p.sOfs.x;
int signY = y + p.sOfs.y;
int signZ = blockIdx.z + p.blockZofs;
int signXb = signX >> 2;
index_t si0 = signXb + p.sShape.x * (signY + (index_t)p.sShape.y * signZ);
index_t si1 = si0 + p.sShape.x;
v.x *= (scalar_t)((float)up * (float)up * p.gain);
v.y *= (scalar_t)((float)up * (float)up * p.gain);
if (signWrite)
{
if (!enableWriteSkip)
{
// Determine and write signs.
int sx = __float_as_uint(v.x) >> 31 << 0;
int sy = __float_as_uint(v.y) >> 31 << 8;
if (sx) v.x *= p.slope;
if (sy) v.y *= p.slope;
if (fabsf(v.x) > p.clamp) { sx = 2 << 0; v.x = InternalType<T>::clamp(v.x, p.clamp); }
if (fabsf(v.y) > p.clamp) { sy = 2 << 8; v.y = InternalType<T>::clamp(v.y, p.clamp); }
if ((uint32_t)signXb < p.swLimit && signY >= minY)
{
// Combine signs.
int s = sx + sy;
s <<= signXo;
s |= __shfl_xor_sync(groupMask, s, 1);
s |= __shfl_xor_sync(groupMask, s, 2);
// Write signs.
if ((uint32_t)(signY + 0) < sShapeMaxY) { p.s[si0] = (unsigned char)(s >> 0); }
if ((uint32_t)(signY + 1) < sShapeMaxY) { p.s[si1] = (unsigned char)(s >> 8); }
}
}
else
{
// Determine and write signs.
if ((uint32_t)signXb < p.swLimit && signY >= minY)
{
int sx = __float_as_uint(v.x) >> 31 << 0;
int sy = __float_as_uint(v.y) >> 31 << 8;
if (sx) v.x *= p.slope;
if (sy) v.y *= p.slope;
if (fabsf(v.x) > p.clamp) { sx = 2 << 0; v.x = InternalType<T>::clamp(v.x, p.clamp); }
if (fabsf(v.y) > p.clamp) { sy = 2 << 8; v.y = InternalType<T>::clamp(v.y, p.clamp); }
// Combine signs.
int s = sx + sy;
s <<= signXo;
s |= __shfl_xor_sync(groupMask, s, 1);
s |= __shfl_xor_sync(groupMask, s, 2);
// Write signs.
if ((uint32_t)(signY + 0) < sShapeMaxY) { p.s[si0] = (unsigned char)(s >> 0); }
if ((uint32_t)(signY + 1) < sShapeMaxY) { p.s[si1] = (unsigned char)(s >> 8); }
}
else
{
// Just compute the values.
if (v.x < 0.f) v.x *= p.slope; v.x = InternalType<T>::clamp(v.x, p.clamp);
if (v.y < 0.f) v.y *= p.slope; v.y = InternalType<T>::clamp(v.y, p.clamp);
}
}
}
else if (signRead) // Read signs and apply.
{
if ((uint32_t)signXb < p.swLimit)
{
if ((uint32_t)(signY + 0) < p.sShape.y) { int s = p.s[si0] >> signXo; if (s & 1) v.x *= p.slope; if (s & 2) v.x = 0.f; }
if ((uint32_t)(signY + 1) < p.sShape.y) { int s = p.s[si1] >> signXo; if (s & 1) v.y *= p.slope; if (s & 2) v.y = 0.f; }
}
}
else // Forward pass with no sign write.
{
if (v.x < 0.f) v.x *= p.slope; v.x = InternalType<T>::clamp(v.x, p.clamp);
if (v.y < 0.f) v.y *= p.slope; v.y = InternalType<T>::clamp(v.y, p.clamp);
}
if (!downInline)
{
// Write into temporary buffer.
s_tileUpXY[dst] = v.x;
if (relUpY0 < tileUpH - 1)
s_tileUpXY[dst + tileUpW] = v.y;
}
else
{
// Write directly into output buffer.
if ((uint32_t)x < p.yShape.x)
{
int ymax = MIN(p.yShape.y, tileUpH + tileOutY * down);
index_t ofs = x * get_stride<index_t>(p.yStride.x) + y * get_stride<index_t>(p.yStride.y) + mapOfsOut;
if ((uint32_t)y + 0 < p.yShape.y) *((T*)((char*)p.y + ofs)) = (T)(v.x * (scalar_t)c_fd[0]);
if ((uint32_t)y + 1 < ymax) *((T*)((char*)p.y + ofs + get_stride<index_t>(p.yStride.y))) = (T)(v.y * (scalar_t)c_fd[0]);
}
}
}
}
}
else if (filterMode == MODE_FUSD || filterMode == MODE_FUFD)
{
// Full upsampling filter.
if (up == 2)
{
// 2 x 2-wide.
__syncthreads();
int minY = tileOutY ? (tileOutY - tileOutH) * down + tileUpH + p.sOfs.y : 0; // Skip already written signs.
for (int idx = threadIdx.x * 4; idx < tileUpW * tileUpH; idx += blockDim.x * 4)
{
int relUpX0, relUpY0;
fast_div_mod<tileUpW>(relUpX0, relUpY0, idx);
int relInX0 = CEIL_DIV(relUpX0 - phaseInX, up);
int relInY0 = CEIL_DIV(relUpY0 - phaseInY, up);
int src0 = relInX0 + tileInW * relInY0;
int tap0y = (relInY0 * up + phaseInY - relUpY0);
#define X_LOOP(TAPY, PX) \
for (int sx = 0; sx < fuSize / up; sx++) \
{ \
v.x += a * (scalar_t)c_fu[(sx * up + (((PX) - 0) & (up - 1))) + (sy * up + (TAPY)) * MAX_FILTER_SIZE]; \
v.z += b * (scalar_t)c_fu[(sx * up + (((PX) - 0) & (up - 1))) + (sy * up + (TAPY)) * MAX_FILTER_SIZE]; if ((PX) == 0) { a = b; b = s_tileIn[src0 + 2 + sx + sy * tileInW]; } \
v.y += a * (scalar_t)c_fu[(sx * up + (((PX) - 1) & (up - 1))) + (sy * up + (TAPY)) * MAX_FILTER_SIZE]; \
v.w += b * (scalar_t)c_fu[(sx * up + (((PX) - 1) & (up - 1))) + (sy * up + (TAPY)) * MAX_FILTER_SIZE]; if ((PX) == 1) { a = b; b = s_tileIn[src0 + 2 + sx + sy * tileInW]; } \
}
vec4_t v = InternalType<T>::zero_vec4();
if (tap0y == 0 && phaseInX == 0)
#pragma unroll
for (int sy = 0; sy < fuSize / up; sy++) { scalar_t a = s_tileIn[src0 + sy * tileInW]; scalar_t b = s_tileIn[src0 + sy * tileInW + 1];
#pragma unroll
X_LOOP(0, 0) }
if (tap0y == 0 && phaseInX == 1)
#pragma unroll
for (int sy = 0; sy < fuSize / up; sy++) { scalar_t a = s_tileIn[src0 + sy * tileInW]; scalar_t b = s_tileIn[src0 + sy * tileInW + 1];
#pragma unroll
X_LOOP(0, 1) }
if (tap0y == 1 && phaseInX == 0)
#pragma unroll
for (int sy = 0; sy < fuSize / up; sy++) { scalar_t a = s_tileIn[src0 + sy * tileInW]; scalar_t b = s_tileIn[src0 + sy * tileInW + 1];
#pragma unroll
X_LOOP(1, 0) }
if (tap0y == 1 && phaseInX == 1)
#pragma unroll
for (int sy = 0; sy < fuSize / up; sy++) { scalar_t a = s_tileIn[src0 + sy * tileInW]; scalar_t b = s_tileIn[src0 + sy * tileInW + 1];
#pragma unroll
X_LOOP(1, 1) }
#undef X_LOOP
int x = tileOutX * down + relUpX0;
int y = tileOutY * down + relUpY0;
int signX = x + p.sOfs.x;
int signY = y + p.sOfs.y;
int signZ = blockIdx.z + p.blockZofs;
int signXb = signX >> 2;
index_t si = signXb + p.sShape.x * (signY + (index_t)p.sShape.y * signZ);
v.x *= (scalar_t)((float)up * (float)up * p.gain);
v.y *= (scalar_t)((float)up * (float)up * p.gain);
v.z *= (scalar_t)((float)up * (float)up * p.gain);
v.w *= (scalar_t)((float)up * (float)up * p.gain);
if (signWrite)
{
if (!enableWriteSkip)
{
// Determine and write signs.
int sx = __float_as_uint(v.x) >> 31;
int sy = __float_as_uint(v.y) >> 31;
int sz = __float_as_uint(v.z) >> 31;
int sw = __float_as_uint(v.w) >> 31;
if (sx) v.x *= p.slope; if (fabsf(v.x) > p.clamp) { sx = 2; v.x = InternalType<T>::clamp(v.x, p.clamp); }
if (sy) v.y *= p.slope; if (fabsf(v.y) > p.clamp) { sy = 2; v.y = InternalType<T>::clamp(v.y, p.clamp); }
if (sz) v.z *= p.slope; if (fabsf(v.z) > p.clamp) { sz = 2; v.z = InternalType<T>::clamp(v.z, p.clamp); }
if (sw) v.w *= p.slope; if (fabsf(v.w) > p.clamp) { sw = 2; v.w = InternalType<T>::clamp(v.w, p.clamp); }
if ((uint32_t)signXb < p.swLimit && (uint32_t)signY < p.sShape.y && signY >= minY)
{
p.s[si] = sx + (sy << 2) + (sz << 4) + (sw << 6);
}
}
else
{
// Determine and write signs.
if ((uint32_t)signXb < p.swLimit && (uint32_t)signY < p.sShape.y && signY >= minY)
{
int sx = __float_as_uint(v.x) >> 31;
int sy = __float_as_uint(v.y) >> 31;
int sz = __float_as_uint(v.z) >> 31;
int sw = __float_as_uint(v.w) >> 31;
if (sx) v.x *= p.slope; if (fabsf(v.x) > p.clamp) { sx = 2; v.x = InternalType<T>::clamp(v.x, p.clamp); }
if (sy) v.y *= p.slope; if (fabsf(v.y) > p.clamp) { sy = 2; v.y = InternalType<T>::clamp(v.y, p.clamp); }
if (sz) v.z *= p.slope; if (fabsf(v.z) > p.clamp) { sz = 2; v.z = InternalType<T>::clamp(v.z, p.clamp); }
if (sw) v.w *= p.slope; if (fabsf(v.w) > p.clamp) { sw = 2; v.w = InternalType<T>::clamp(v.w, p.clamp); }
p.s[si] = sx + (sy << 2) + (sz << 4) + (sw << 6);
}
else
{
// Just compute the values.
if (v.x < 0.f) v.x *= p.slope; v.x = InternalType<T>::clamp(v.x, p.clamp);
if (v.y < 0.f) v.y *= p.slope; v.y = InternalType<T>::clamp(v.y, p.clamp);
if (v.z < 0.f) v.z *= p.slope; v.z = InternalType<T>::clamp(v.z, p.clamp);
if (v.w < 0.f) v.w *= p.slope; v.w = InternalType<T>::clamp(v.w, p.clamp);
}
}
}
else if (signRead) // Read sign and apply.
{
if ((uint32_t)signY < p.sShape.y)
{
int s = 0;
if ((uint32_t)signXb < p.swLimit) s = p.s[si];
if ((uint32_t)signXb + 1 < p.swLimit) s |= p.s[si + 1] << 8;
s >>= (signX & 3) << 1;
if (s & 0x01) v.x *= p.slope; if (s & 0x02) v.x = 0.f;
if (s & 0x04) v.y *= p.slope; if (s & 0x08) v.y = 0.f;
if (s & 0x10) v.z *= p.slope; if (s & 0x20) v.z = 0.f;
if (s & 0x40) v.w *= p.slope; if (s & 0x80) v.w = 0.f;
}
}
else // Forward pass with no sign write.
{
if (v.x < 0.f) v.x *= p.slope; v.x = InternalType<T>::clamp(v.x, p.clamp);
if (v.y < 0.f) v.y *= p.slope; v.y = InternalType<T>::clamp(v.y, p.clamp);
if (v.z < 0.f) v.z *= p.slope; v.z = InternalType<T>::clamp(v.z, p.clamp);
if (v.w < 0.f) v.w *= p.slope; v.w = InternalType<T>::clamp(v.w, p.clamp);
}
s_tileUpXY[idx + 0] = v.x;
s_tileUpXY[idx + 1] = v.y;
s_tileUpXY[idx + 2] = v.z;
s_tileUpXY[idx + 3] = v.w;
}
}
else if (up == 1)
{
__syncthreads();
uint32_t groupMask = 15 << ((threadIdx.x & 31) & ~3);
int minY = tileOutY ? (tileOutY - tileOutH) * down + tileUpH : 0; // Skip already written signs.
for (int idx = threadIdx.x; idx < tileUpW * tileUpH; idx += blockDim.x)
{
int relUpX0, relUpY0;
fast_div_mod<tileUpW>(relUpX0, relUpY0, idx);
scalar_t v = s_tileIn[idx] * (scalar_t)c_fu[0]; // 1x1 filter.
int x = tileOutX * down + relUpX0;
int y = tileOutY * down + relUpY0;
int signX = x + p.sOfs.x;
int signY = y + p.sOfs.y;
int signZ = blockIdx.z + p.blockZofs;
int signXb = signX >> 2;
index_t si = signXb + p.sShape.x * (signY + (index_t)p.sShape.y * signZ);
v *= (scalar_t)((float)up * (float)up * p.gain);
if (signWrite)
{
if (!enableWriteSkip)
{
// Determine and write sign.
uint32_t s = 0;
uint32_t signXbit = (1u << signXo);
if (v < 0.f)
{
s = signXbit;
v *= p.slope;
}
if (fabsf(v) > p.clamp)
{
s = signXbit * 2;
v = InternalType<T>::clamp(v, p.clamp);
}
if ((uint32_t)signXb < p.swLimit && (uint32_t)signY < p.sShape.y && signY >= minY)
{
s += __shfl_xor_sync(groupMask, s, 1); // Coalesce.
s += __shfl_xor_sync(groupMask, s, 2); // Coalesce.
p.s[si] = s; // Write.
}
}
else
{
// Determine and write sign.
if ((uint32_t)signXb < p.swLimit && (uint32_t)signY < p.sShape.y && signY >= minY)
{
uint32_t s = 0;
uint32_t signXbit = (1u << signXo);
if (v < 0.f)
{
s = signXbit;
v *= p.slope;
}
if (fabsf(v) > p.clamp)
{
s = signXbit * 2;
v = InternalType<T>::clamp(v, p.clamp);
}
s += __shfl_xor_sync(groupMask, s, 1); // Coalesce.
s += __shfl_xor_sync(groupMask, s, 2); // Coalesce.
p.s[si] = s; // Write.
}
else
{
// Just compute the value.
if (v < 0.f) v *= p.slope;
v = InternalType<T>::clamp(v, p.clamp);
}
}
}
else if (signRead)
{
// Read sign and apply if within sign tensor bounds.
if ((uint32_t)signXb < p.swLimit && (uint32_t)signY < p.sShape.y)
{
int s = p.s[si];
s >>= signXo;
if (s & 1) v *= p.slope;
if (s & 2) v = 0.f;
}
}
else // Forward pass with no sign write.
{
if (v < 0.f) v *= p.slope;
v = InternalType<T>::clamp(v, p.clamp);
}
if (!downInline) // Write into temporary buffer.
s_tileUpXY[idx] = v;
else if ((uint32_t)x < p.yShape.x && (uint32_t)y < p.yShape.y) // Write directly into output buffer
*((T*)((char*)p.y + (x * get_stride<index_t>(p.yStride.x) + y * get_stride<index_t>(p.yStride.y) + mapOfsOut))) = (T)(v * (scalar_t)c_fd[0]);
}
}
}
// Downsampling.
if (filterMode == MODE_SUSD || filterMode == MODE_FUSD)
{
// Horizontal downsampling.
__syncthreads();
if (down == 4 && tileOutW % 4 == 0)
{
// Calculate 4 pixels at a time.
for (int idx = threadIdx.x * 4; idx < tileOutW * tileUpH; idx += blockDim.x * 4)
{
int relOutX0, relUpY;
fast_div_mod<tileOutW>(relOutX0, relUpY, idx);
int relUpX0 = relOutX0 * down;
int src0 = relUpY * tileUpW + relUpX0;
vec4_t v = InternalType<T>::zero_vec4();
#pragma unroll
for (int step = 0; step < fdSize; step++)
{
v.x += s_tileUpXY[src0 + 0 + step] * (scalar_t)c_fd[step];
v.y += s_tileUpXY[src0 + 4 + step] * (scalar_t)c_fd[step];
v.z += s_tileUpXY[src0 + 8 + step] * (scalar_t)c_fd[step];
v.w += s_tileUpXY[src0 + 12 + step] * (scalar_t)c_fd[step];
}
s_tileDownX[idx+0] = v.x;
s_tileDownX[idx+1] = v.y;
s_tileDownX[idx+2] = v.z;
s_tileDownX[idx+3] = v.w;
}
}
else if ((down == 2 || down == 4) && (tileOutW % 2 == 0))
{
// Calculate 2 pixels at a time.
for (int idx = threadIdx.x * 2; idx < tileOutW * tileUpH; idx += blockDim.x * 2)
{
int relOutX0, relUpY;
fast_div_mod<tileOutW>(relOutX0, relUpY, idx);
int relUpX0 = relOutX0 * down;
int src0 = relUpY * tileUpW + relUpX0;
vec2_t v = InternalType<T>::zero_vec2();
#pragma unroll
for (int step = 0; step < fdSize; step++)
{
v.x += s_tileUpXY[src0 + 0 + step] * (scalar_t)c_fd[step];
v.y += s_tileUpXY[src0 + down + step] * (scalar_t)c_fd[step];
}
s_tileDownX[idx+0] = v.x;
s_tileDownX[idx+1] = v.y;
}
}
else
{
// Calculate 1 pixel at a time.
for (int idx = threadIdx.x; idx < tileOutW * tileUpH; idx += blockDim.x)
{
int relOutX0, relUpY;
fast_div_mod<tileOutW>(relOutX0, relUpY, idx);
int relUpX0 = relOutX0 * down;
int src = relUpY * tileUpW + relUpX0;
scalar_t v = 0.f;
#pragma unroll
for (int step = 0; step < fdSize; step++)
v += s_tileUpXY[src + step] * (scalar_t)c_fd[step];
s_tileDownX[idx] = v;
}
}
// Vertical downsampling & store output tile.
__syncthreads();
for (int idx = threadIdx.x; idx < tileOutW * tileOutH; idx += blockDim.x)
{
int relOutX, relOutY0;
fast_div_mod<tileOutW>(relOutX, relOutY0, idx);
int relUpY0 = relOutY0 * down;
int src0 = relUpY0 * tileOutW + relOutX;
scalar_t v = 0;
#pragma unroll
for (int step = 0; step < fdSize; step++)
v += s_tileDownX[src0 + step * tileOutW] * (scalar_t)c_fd[step];
int outX = tileOutX + relOutX;
int outY = tileOutY + relOutY0;
if (outX < p.yShape.x & outY < p.yShape.y)
*((T*)((char*)p.y + (outX * get_stride<index_t>(p.yStride.x) + outY * get_stride<index_t>(p.yStride.y) + mapOfsOut))) = (T)v;
}
}
else if (filterMode == MODE_SUFD || filterMode == MODE_FUFD)
{
// Full downsampling filter.
if (down == 2)
{
// 2-wide.
__syncthreads();
for (int idx = threadIdx.x * 2; idx < tileOutW * tileOutH; idx += blockDim.x * 2)
{
int relOutX0, relOutY0;
fast_div_mod<tileOutW>(relOutX0, relOutY0, idx);
int relUpX0 = relOutX0 * down;
int relUpY0 = relOutY0 * down;
int src0 = relUpY0 * tileUpW + relUpX0;
vec2_t v = InternalType<T>::zero_vec2();
#pragma unroll
for (int sy = 0; sy < fdSize; sy++)
#pragma unroll
for (int sx = 0; sx < fdSize; sx++)
{
v.x += s_tileUpXY[src0 + 0 + sx + sy * tileUpW] * (scalar_t)c_fd[sx + sy * MAX_FILTER_SIZE];
v.y += s_tileUpXY[src0 + 2 + sx + sy * tileUpW] * (scalar_t)c_fd[sx + sy * MAX_FILTER_SIZE];
}
int outX = tileOutX + relOutX0;
int outY = tileOutY + relOutY0;
if ((uint32_t)outY < p.yShape.y)
{
index_t ofs = outX * get_stride<index_t>(p.yStride.x) + outY * get_stride<index_t>(p.yStride.y) + mapOfsOut;
if (outX + 0 < p.yShape.x) *((T*)((char*)p.y + ofs)) = (T)v.x;
if (outX + 1 < p.yShape.x) *((T*)((char*)p.y + ofs + get_stride<index_t>(p.yStride.x))) = (T)v.y;
}
}
}
else if (down == 1 && !downInline)
{
// Thread per pixel.
__syncthreads();
for (int idx = threadIdx.x; idx < tileOutW * tileOutH; idx += blockDim.x)
{
int relOutX0, relOutY0;
fast_div_mod<tileOutW>(relOutX0, relOutY0, idx);
scalar_t v = s_tileUpXY[idx] * (scalar_t)c_fd[0]; // 1x1 filter.
int outX = tileOutX + relOutX0;
int outY = tileOutY + relOutY0;
if ((uint32_t)outX < p.yShape.x && (uint32_t)outY < p.yShape.y)
*((T*)((char*)p.y + (outX * get_stride<index_t>(p.yStride.x) + outY * get_stride<index_t>(p.yStride.y) + mapOfsOut))) = (T)v;
}
}
}
if (!enableXrep)
break;
}
}
//------------------------------------------------------------------------
// Compute activation function and signs for upsampled data tensor, modifying data tensor in-place. Used for accelerating the generic variant.
// Sign tensor is known to be contiguous, and p.x and p.s have the same z, w dimensions. 64-bit indexing is always used.
template <class T, bool signWrite, bool signRead>
static __global__ void filtered_lrelu_act_kernel(filtered_lrelu_act_kernel_params p)
{
typedef typename InternalType<T>::scalar_t scalar_t;
// Indexing.
int32_t x = threadIdx.x + blockIdx.x * blockDim.x;
int32_t ymax = signWrite ? p.sShape.y : p.xShape.y;
int32_t qmax = p.xShape.z * p.xShape.w; // Combined minibatch*channel maximum index.
// Loop to accommodate oversized tensors.
for (int32_t q = blockIdx.z; q < qmax; q += gridDim.z)
for (int32_t y = blockIdx.y; y < ymax; y += gridDim.y)
{
// Extract z and w (channel, minibatch index).
int32_t w = q / p.xShape.z;
int32_t z = q - w * p.xShape.z;
// Choose behavior based on sign read/write mode.
if (signWrite)
{
// Process value if in p.x.
uint32_t s = 0;
if (x < p.xShape.x && y < p.xShape.y)
{
int64_t ix = x * p.xStride.x + y * p.xStride.y + z * p.xStride.z + w * p.xStride.w;
T* pv = ((T*)p.x) + ix;
scalar_t v = (scalar_t)(*pv);
// Gain, LReLU, clamp.
v *= p.gain;
if (v < 0.f)
{
v *= p.slope;
s = 1; // Sign.
}
if (fabsf(v) > p.clamp)
{
v = InternalType<T>::clamp(v, p.clamp);
s = 2; // Clamp.
}
*pv = (T)v; // Write value.
}
// Coalesce into threads 0 and 16 of warp.
uint32_t m = (threadIdx.x & 16) ? 0xffff0000u : 0x0000ffffu;
s <<= ((threadIdx.x & 15) << 1); // Shift into place.
s |= __shfl_xor_sync(m, s, 1); // Distribute.
s |= __shfl_xor_sync(m, s, 2);
s |= __shfl_xor_sync(m, s, 4);
s |= __shfl_xor_sync(m, s, 8);
// Write signs if leader and in p.s.
if (!(threadIdx.x & 15) && x < p.sShape.x) // y is always in.
{
uint64_t is = x + p.sShape.x * (y + (int64_t)p.sShape.y * q); // Contiguous.
((uint32_t*)p.s)[is >> 4] = s;
}
}
else if (signRead)
{
// Process value if in p.x.
if (x < p.xShape.x) // y is always in.
{
int64_t ix = x * p.xStride.x + y * p.xStride.y + z * p.xStride.z + w * p.xStride.w;
T* pv = ((T*)p.x) + ix;
scalar_t v = (scalar_t)(*pv);
v *= p.gain;
// Apply sign buffer offset.
uint32_t sx = x + p.sOfs.x;
uint32_t sy = y + p.sOfs.y;
// Read and apply signs if we land inside valid region of sign buffer.
if (sx < p.sShape.x && sy < p.sShape.y)
{
uint64_t is = (sx >> 2) + (p.sShape.x >> 2) * (sy + (uint64_t)p.sShape.y * q); // Contiguous.
unsigned char s = p.s[is];
s >>= (sx & 3) << 1; // Shift into place.
if (s & 1) // Sign?
v *= p.slope;
if (s & 2) // Clamp?
v = 0.f;
}
*pv = (T)v; // Write value.
}
}
else
{
// Forward pass with no sign write. Process value if in p.x.
if (x < p.xShape.x) // y is always in.
{
int64_t ix = x * p.xStride.x + y * p.xStride.y + z * p.xStride.z + w * p.xStride.w;
T* pv = ((T*)p.x) + ix;
scalar_t v = (scalar_t)(*pv);
v *= p.gain;
if (v < 0.f)
v *= p.slope;
if (fabsf(v) > p.clamp)
v = InternalType<T>::clamp(v, p.clamp);
*pv = (T)v; // Write value.
}
}
}
}
template <class T, bool signWrite, bool signRead> void* choose_filtered_lrelu_act_kernel(void)
{
return (void*)filtered_lrelu_act_kernel<T, signWrite, signRead>;
}
//------------------------------------------------------------------------
// CUDA kernel selection.
template <class T, class index_t, bool signWrite, bool signRead> filtered_lrelu_kernel_spec choose_filtered_lrelu_kernel(const filtered_lrelu_kernel_params& p, int sharedKB)
{
filtered_lrelu_kernel_spec s = { 0 };
// Return the first matching kernel.
#define CASE(SH, U, FU, D, FD, MODE, TW, TH, W, XR, WS) \
if (sharedKB >= SH) \
if ((p.fuShape.y == 0 && (MODE == MODE_SUSD || MODE == MODE_SUFD)) || (p.fuShape.y > 0 && (MODE == MODE_FUSD || MODE == MODE_FUFD))) \
if ((p.fdShape.y == 0 && (MODE == MODE_SUSD || MODE == MODE_FUSD)) || (p.fdShape.y > 0 && (MODE == MODE_SUFD || MODE == MODE_FUFD))) \
if (p.up == U && p.fuShape.x <= FU && p.fuShape.y <= FU && p.down == D && p.fdShape.x <= FD && p.fdShape.y <= FD) \
{ \
static_assert((D*TW % 4) == 0, "down * tileWidth must be divisible by 4"); \
static_assert(FU % U == 0, "upscaling filter size must be multiple of upscaling factor"); \
static_assert(FD % D == 0, "downscaling filter size must be multiple of downscaling factor"); \
s.setup = (void*)setup_filters_kernel; \
s.exec = (void*)filtered_lrelu_kernel<T, index_t, SH, signWrite, signRead, MODE, U, FU, D, FD, TW, TH, W*32, !!XR, !!WS>; \
s.tileOut = make_int2(TW, TH); \
s.numWarps = W; \
s.xrep = XR; \
s.dynamicSharedKB = (SH == 48) ? 0 : SH; \
return s; \
}
// Launch parameters for various kernel specializations.
// Small filters must be listed before large filters, otherwise the kernel for larger filter will always match first.
// Kernels that use more shared memory must be listed before those that use less, for the same reason.
CASE(/*sharedKB*/48, /*up,fu*/1,1, /*down,fd*/1,1, /*mode*/MODE_FUFD, /*tw,th,warps,xrep,wskip*/64, 178, 32, 0, 0) // 1t-upf1-downf1
CASE(/*sharedKB*/48, /*up,fu*/2,8, /*down,fd*/1,1, /*mode*/MODE_SUFD, /*tw,th,warps,xrep,wskip*/152, 95, 16, 0, 0) // 4t-ups2-downf1
CASE(/*sharedKB*/48, /*up,fu*/1,1, /*down,fd*/2,8, /*mode*/MODE_FUSD, /*tw,th,warps,xrep,wskip*/56, 22, 16, 0, 0) // 4t-upf1-downs2
CASE(/*sharedKB*/48, /*up,fu*/2,8, /*down,fd*/2,8, /*mode*/MODE_SUSD, /*tw,th,warps,xrep,wskip*/56, 29, 16, 11, 0) // 4t-ups2-downs2
CASE(/*sharedKB*/48, /*up,fu*/2,8, /*down,fd*/2,8, /*mode*/MODE_FUSD, /*tw,th,warps,xrep,wskip*/60, 28, 16, 0, 0) // 4t-upf2-downs2
CASE(/*sharedKB*/48, /*up,fu*/2,8, /*down,fd*/2,8, /*mode*/MODE_SUFD, /*tw,th,warps,xrep,wskip*/56, 28, 16, 0, 0) // 4t-ups2-downf2
CASE(/*sharedKB*/48, /*up,fu*/4,16, /*down,fd*/2,8, /*mode*/MODE_SUSD, /*tw,th,warps,xrep,wskip*/56, 31, 16, 11, 0) // 4t-ups4-downs2
CASE(/*sharedKB*/48, /*up,fu*/4,16, /*down,fd*/2,8, /*mode*/MODE_SUFD, /*tw,th,warps,xrep,wskip*/56, 36, 16, 0, 0) // 4t-ups4-downf2
CASE(/*sharedKB*/48, /*up,fu*/2,8, /*down,fd*/4,16, /*mode*/MODE_SUSD, /*tw,th,warps,xrep,wskip*/16, 22, 16, 12, 0) // 4t-ups2-downs4
CASE(/*sharedKB*/48, /*up,fu*/2,8, /*down,fd*/4,16, /*mode*/MODE_FUSD, /*tw,th,warps,xrep,wskip*/29, 15, 16, 0, 0) // 4t-upf2-downs4
CASE(/*sharedKB*/48, /*up,fu*/2,12, /*down,fd*/1,1, /*mode*/MODE_SUFD, /*tw,th,warps,xrep,wskip*/96, 150, 28, 0, 0) // 6t-ups2-downf1
CASE(/*sharedKB*/48, /*up,fu*/1,1, /*down,fd*/2,12, /*mode*/MODE_FUSD, /*tw,th,warps,xrep,wskip*/32, 35, 24, 0, 0) // 6t-upf1-downs2
CASE(/*sharedKB*/48, /*up,fu*/2,12, /*down,fd*/2,12, /*mode*/MODE_SUSD, /*tw,th,warps,xrep,wskip*/32, 46, 16, 10, 0) // 6t-ups2-downs2
CASE(/*sharedKB*/48, /*up,fu*/2,12, /*down,fd*/2,12, /*mode*/MODE_FUSD, /*tw,th,warps,xrep,wskip*/58, 28, 24, 8, 0) // 6t-upf2-downs2
CASE(/*sharedKB*/48, /*up,fu*/2,12, /*down,fd*/2,12, /*mode*/MODE_SUFD, /*tw,th,warps,xrep,wskip*/52, 28, 16, 0, 0) // 6t-ups2-downf2
CASE(/*sharedKB*/48, /*up,fu*/4,24, /*down,fd*/2,12, /*mode*/MODE_SUSD, /*tw,th,warps,xrep,wskip*/32, 51, 16, 5, 0) // 6t-ups4-downs2
CASE(/*sharedKB*/48, /*up,fu*/4,24, /*down,fd*/2,12, /*mode*/MODE_SUFD, /*tw,th,warps,xrep,wskip*/32, 56, 16, 6, 0) // 6t-ups4-downf2
CASE(/*sharedKB*/48, /*up,fu*/2,12, /*down,fd*/4,24, /*mode*/MODE_SUSD, /*tw,th,warps,xrep,wskip*/16, 18, 16, 12, 0) // 6t-ups2-downs4
CASE(/*sharedKB*/96, /*up,fu*/2,12, /*down,fd*/4,24, /*mode*/MODE_FUSD, /*tw,th,warps,xrep,wskip*/27, 31, 32, 6, 0) // 6t-upf2-downs4 96kB
CASE(/*sharedKB*/48, /*up,fu*/2,12, /*down,fd*/4,24, /*mode*/MODE_FUSD, /*tw,th,warps,xrep,wskip*/27, 13, 24, 0, 0) // 6t-upf2-downs4
CASE(/*sharedKB*/48, /*up,fu*/2,16, /*down,fd*/1,1, /*mode*/MODE_SUFD, /*tw,th,warps,xrep,wskip*/148, 89, 24, 0, 0) // 8t-ups2-downf1
CASE(/*sharedKB*/48, /*up,fu*/1,1, /*down,fd*/2,16, /*mode*/MODE_FUSD, /*tw,th,warps,xrep,wskip*/32, 31, 16, 5, 0) // 8t-upf1-downs2
CASE(/*sharedKB*/48, /*up,fu*/2,16, /*down,fd*/2,16, /*mode*/MODE_SUSD, /*tw,th,warps,xrep,wskip*/32, 41, 16, 9, 0) // 8t-ups2-downs2
CASE(/*sharedKB*/48, /*up,fu*/2,16, /*down,fd*/2,16, /*mode*/MODE_FUSD, /*tw,th,warps,xrep,wskip*/56, 26, 24, 0, 0) // 8t-upf2-downs2
CASE(/*sharedKB*/48, /*up,fu*/2,16, /*down,fd*/2,16, /*mode*/MODE_SUFD, /*tw,th,warps,xrep,wskip*/32, 40, 16, 0, 0) // 8t-ups2-downf2
CASE(/*sharedKB*/48, /*up,fu*/4,32, /*down,fd*/2,16, /*mode*/MODE_SUSD, /*tw,th,warps,xrep,wskip*/32, 46, 24, 5, 0) // 8t-ups4-downs2
CASE(/*sharedKB*/48, /*up,fu*/4,32, /*down,fd*/2,16, /*mode*/MODE_SUFD, /*tw,th,warps,xrep,wskip*/32, 50, 16, 0, 0) // 8t-ups4-downf2
CASE(/*sharedKB*/96, /*up,fu*/2,16, /*down,fd*/4,32, /*mode*/MODE_SUSD, /*tw,th,warps,xrep,wskip*/24, 24, 32, 12, 1) // 8t-ups2-downs4 96kB
CASE(/*sharedKB*/48, /*up,fu*/2,16, /*down,fd*/4,32, /*mode*/MODE_SUSD, /*tw,th,warps,xrep,wskip*/16, 13, 16, 10, 1) // 8t-ups2-downs4
CASE(/*sharedKB*/96, /*up,fu*/2,16, /*down,fd*/4,32, /*mode*/MODE_FUSD, /*tw,th,warps,xrep,wskip*/25, 28, 28, 4, 0) // 8t-upf2-downs4 96kB
CASE(/*sharedKB*/48, /*up,fu*/2,16, /*down,fd*/4,32, /*mode*/MODE_FUSD, /*tw,th,warps,xrep,wskip*/25, 10, 24, 0, 0) // 8t-upf2-downs4
#undef CASE
return s; // No kernel found.
}
//------------------------------------------------------------------------
|