baseline_null / pc_util /src /ball_query_gpu.cu
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#include <math.h>
#include <stdio.h>
#include <stdlib.h>
#include "ball_query_gpu.h"
#include "cuda_utils.h"
__global__ void ball_query_kernel_fast(int b, int n, int m, float radius, int nsample,
const float *__restrict__ new_xyz, const float *__restrict__ xyz, int *__restrict__ idx) {
// new_xyz: (B, M, 3)
// xyz: (B, N, 3)
// output:
// idx: (B, M, nsample)
int bs_idx = blockIdx.y;
int pt_idx = blockIdx.x * blockDim.x + threadIdx.x;
if (bs_idx >= b || pt_idx >= m) return;
new_xyz += bs_idx * m * 3 + pt_idx * 3;
xyz += bs_idx * n * 3;
idx += bs_idx * m * nsample + pt_idx * nsample;
float radius2 = radius * radius;
float new_x = new_xyz[0];
float new_y = new_xyz[1];
float new_z = new_xyz[2];
int cnt = 0;
for (int k = 0; k < n; ++k) {
float x = xyz[k * 3 + 0];
float y = xyz[k * 3 + 1];
float z = xyz[k * 3 + 2];
float d2 = (new_x - x) * (new_x - x) + (new_y - y) * (new_y - y) + (new_z - z) * (new_z - z);
if (d2 < radius2){
if (cnt == 0){
for (int l = 0; l < nsample; ++l) {
idx[l] = k;
}
}
idx[cnt] = k;
++cnt;
if (cnt >= nsample) break;
}
}
}
void ball_query_kernel_launcher_fast(int b, int n, int m, float radius, int nsample, \
const float *new_xyz, const float *xyz, int *idx) {
// new_xyz: (B, M, 3)
// xyz: (B, N, 3)
// output:
// idx: (B, M, nsample)
cudaError_t err;
dim3 blocks(DIVUP(m, THREADS_PER_BLOCK), b); // blockIdx.x(col), blockIdx.y(row)
dim3 threads(THREADS_PER_BLOCK);
ball_query_kernel_fast<<<blocks, threads>>>(b, n, m, radius, nsample, new_xyz, xyz, idx);
// cudaDeviceSynchronize(); // for using printf in kernel function
err = cudaGetLastError();
if (cudaSuccess != err) {
fprintf(stderr, "CUDA kernel failed : %s\n", cudaGetErrorString(err));
exit(-1);
}
}
__global__ void ball_center_query_kernel_fast(int b, int n, int m, float radius, \
const float *__restrict__ point, const float *__restrict__ key_point, int *__restrict__ idx) {
// key_point: (B, M, 3)
// point: (B, N, 3)
// output:
// idx: (B, N)
int bs_idx = blockIdx.y;
int pt_idx = blockIdx.x * blockDim.x + threadIdx.x;
if (bs_idx >= b || pt_idx >= n) return;
point += bs_idx * n * 3 + pt_idx * 3;
key_point += bs_idx * m * 3;
idx += bs_idx * n + pt_idx;
float radius2 = radius * radius;
float point_x = point[0];
float point_y = point[1];
float point_z = point[2];
float bestd = 1e8;
for (int k = 0; k < m; ++k) {
float x = key_point[k * 3 + 0];
float y = key_point[k * 3 + 1];
float z = key_point[k * 3 + 2];
if (((x + 1) * (x + 1) + (y + 1) * (y + 1) + (z + 1) * (z + 1)) < 1e-4) break;
float d2 = (point_x - x) * (point_x - x) + (point_y - y) * (point_y - y) + (point_z - z) * (point_z - z);
if (d2 < radius2 && d2 < bestd){
idx[0] = k;
bestd = d2;
}
}
}
void ball_center_query_kernel_launcher_fast(int b, int n, int m, float radius, \
const float *point, const float *key_point, int *idx) {
// point: (B, n, 3)
// key_point: (B, m, 3)
// output:
// idx: (B, n)
cudaError_t err;
dim3 blocks(DIVUP(n, THREADS_PER_BLOCK), b); // blockIdx.x(col), blockIdx.y(row)
dim3 threads(THREADS_PER_BLOCK);
ball_center_query_kernel_fast<<<blocks, threads>>>(b, n, m, radius, point, key_point, idx);
// cudaDeviceSynchronize(); // for using printf in kernel function
err = cudaGetLastError();
if (cudaSuccess != err) {
fprintf(stderr, "CUDA kernel failed : %s\n", cudaGetErrorString(err));
exit(-1);
}
}
__global__ void knn_query_kernel_fast(int b, int n, int m, int nsample, const float *__restrict__ new_xyz,
const float *__restrict__ xyz, float *__restrict__ dist2, int *__restrict__ idx) {
// new_xyz: (B, M, 3)
// xyz: (B, N, 3)
// output:
// dist2: (B, M, nsample)
// idx: (B, M, nsample)
int bs_idx = blockIdx.y;
int pt_idx = blockIdx.x * blockDim.x + threadIdx.x;
if (bs_idx >= b || pt_idx >= m) return;
new_xyz += bs_idx * m * 3 + pt_idx * 3;
xyz += bs_idx * n * 3;
dist2 += bs_idx * m * nsample + pt_idx * nsample;
idx += bs_idx * m * nsample + pt_idx * nsample;
float nx = new_xyz[0];
float ny = new_xyz[1];
float nz = new_xyz[2];
for (int i = 0; i < n; ++i) {
float x = xyz[i * 3 + 0];
float y = xyz[i * 3 + 1];
float z = xyz[i * 3 + 2];
float d2 = (nx - x) * (nx - x) + (ny - y) * (ny - y) + (nz - z) * (nz - z);
if (d2 < dist2[nsample - 1]) {
dist2[nsample - 1] = d2;
idx[nsample - 1] = i;
for (int j = nsample - 2; j >= 0; j--) {
if (d2 < dist2[j]){
dist2[j + 1] = dist2[j];
dist2[j] = d2;
idx[j + 1] = idx[j];
idx[j] = i;
}
}
}
}
}
void knn_query_kernel_launcher_fast(int b, int n, int m, int nsample, \
const float *new_xyz, const float *xyz, float *dist2, int *idx) {
cudaError_t err;
dim3 blocks(DIVUP(m, THREADS_PER_BLOCK), b); // blockIdx.x(col), blockIdx.y(row)
dim3 threads(THREADS_PER_BLOCK);
knn_query_kernel_fast<<<blocks, threads>>>(b, n, m, nsample, new_xyz, xyz, dist2, idx);
// cudaDeviceSynchronize(); // for using printf in kernel function
err = cudaGetLastError();
if (cudaSuccess != err) {
fprintf(stderr, "CUDA kernel failed : %s\n", cudaGetErrorString(err));
exit(-1);
}
}
__global__ void ball_query_kernel_stack(int B, int M, float radius, int nsample, \
const float *new_xyz, const int *new_xyz_batch_cnt, const float *xyz, const int *xyz_batch_cnt, int *idx) {
// :param xyz: (N1 + N2 ..., 3) xyz coordinates of the features
// :param xyz_batch_cnt: (batch_size), [N1, N2, ...]
// :param new_xyz: (M1 + M2 ..., 3) centers of the ball query
// :param new_xyz_batch_cnt: (batch_size), [M1, M2, ...]
// output:
// idx: (M, nsample)
int pt_idx = blockIdx.x * blockDim.x + threadIdx.x;
if (pt_idx >= M) return;
int bs_idx = 0, pt_cnt = new_xyz_batch_cnt[0];
for (int k = 1; k < B; k++){
if (pt_idx < pt_cnt) break;
pt_cnt += new_xyz_batch_cnt[k];
bs_idx = k;
}
int xyz_batch_start_idx = 0;
for (int k = 0; k < bs_idx; k++) xyz_batch_start_idx += xyz_batch_cnt[k];
// for (int k = 0; k < bs_idx; k++) new_xyz_batch_start_idx += new_xyz_batch_cnt[k];
new_xyz += pt_idx * 3;
xyz += xyz_batch_start_idx * 3;
idx += pt_idx * nsample;
float radius2 = radius * radius;
float new_x = new_xyz[0];
float new_y = new_xyz[1];
float new_z = new_xyz[2];
int n = xyz_batch_cnt[bs_idx];
int cnt = 0;
for (int k = 0; k < n; ++k) {
float x = xyz[k * 3 + 0];
float y = xyz[k * 3 + 1];
float z = xyz[k * 3 + 2];
float d2 = (new_x - x) * (new_x - x) + (new_y - y) * (new_y - y) + (new_z - z) * (new_z - z);
if (d2 < radius2){
if (cnt == 0){
for (int l = 0; l < nsample; ++l) {
idx[l] = k;
}
}
idx[cnt] = k;
++cnt;
if (cnt >= nsample) break;
}
}
if (cnt == 0) idx[0] = -1;
}
void ball_query_kernel_launcher_stack(int B, int M, float radius, int nsample,
const float *new_xyz, const int *new_xyz_batch_cnt, const float *xyz, const int *xyz_batch_cnt, int *idx){
// :param xyz: (N1 + N2 ..., 3) xyz coordinates of the features
// :param xyz_batch_cnt: (batch_size), [N1, N2, ...]
// :param new_xyz: (M1 + M2 ..., 3) centers of the ball query
// :param new_xyz_batch_cnt: (batch_size), [M1, M2, ...]
// output:
// idx: (M, nsample)
cudaError_t err;
dim3 blocks(DIVUP(M, THREADS_PER_BLOCK)); // blockIdx.x(col), blockIdx.y(row)
dim3 threads(THREADS_PER_BLOCK);
ball_query_kernel_stack<<<blocks, threads>>>(B, M, radius, nsample, new_xyz, new_xyz_batch_cnt, xyz, xyz_batch_cnt, idx);
// cudaDeviceSynchronize(); // for using printf in kernel function
err = cudaGetLastError();
if (cudaSuccess != err) {
fprintf(stderr, "CUDA kernel failed : %s\n", cudaGetErrorString(err));
exit(-1);
}
}