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/*
* diffraction-gpu.c
*
* Calculate diffraction patterns by Fourier methods (GPU version)
*
* Copyright © 2012-2015 Deutsches Elektronen-Synchrotron DESY,
* a research centre of the Helmholtz Association.
*
* Authors:
* 2009-2015 Thomas White <taw@physics.org>
* 2013 Alexandra Tolstikova
* 2013-2014 Chun Hong Yoon <chun.hong.yoon@desy.de>
*
* This file is part of CrystFEL.
*
* CrystFEL is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* CrystFEL is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with CrystFEL. If not, see <http://www.gnu.org/licenses/>.
*
*/
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif
#include <stdlib.h>
#include <math.h>
#include <stdio.h>
#include <string.h>
#include <complex.h>
#ifdef HAVE_CL_CL_H
#include <CL/cl.h>
#else
#include <cl.h>
#endif
#include "image.h"
#include "utils.h"
#include "cell.h"
#include "diffraction.h"
#include "cl-utils.h"
#include "pattern_sim.h"
#define SINC_LUT_ELEMENTS (4096)
struct gpu_context
{
cl_context ctx;
cl_command_queue cq;
cl_program prog;
cl_kernel kern;
cl_mem intensities;
cl_mem flags;
/* Array of sinc LUTs */
cl_mem *sinc_luts;
cl_float **sinc_lut_ptrs;
int max_sinc_lut; /* Number of LUTs, i.e. one greater than the maximum
* index. This equals the highest allowable "n". */
};
static void check_sinc_lut(struct gpu_context *gctx, int n, int no_fringes)
{
cl_int err;
cl_image_format fmt;
int i;
if ( n > gctx->max_sinc_lut ) {
gctx->sinc_luts = realloc(gctx->sinc_luts,
n*sizeof(*gctx->sinc_luts));
gctx->sinc_lut_ptrs = realloc(gctx->sinc_lut_ptrs,
n*sizeof(*gctx->sinc_lut_ptrs));
for ( i=gctx->max_sinc_lut; i<n; i++ ) {
gctx->sinc_lut_ptrs[i] = NULL;
}
gctx->max_sinc_lut = n;
}
if ( gctx->sinc_lut_ptrs[n-1] != NULL ) return;
/* Create a new sinc LUT */
gctx->sinc_lut_ptrs[n-1] = malloc(SINC_LUT_ELEMENTS*sizeof(cl_float));
gctx->sinc_lut_ptrs[n-1][0] = n;
if ( n == 1 ) {
for ( i=1; i<SINC_LUT_ELEMENTS; i++ ) {
gctx->sinc_lut_ptrs[n-1][i] = 1.0;
}
} else {
for ( i=1; i<SINC_LUT_ELEMENTS; i++ ) {
double x, val;
x = (double)i/SINC_LUT_ELEMENTS;
if ( no_fringes && (x > 1.0/n) && (1.0-x > 1.0/n) ) {
val = 0.0;
} else {
val = fabs(sin(M_PI*n*x)/sin(M_PI*x));
}
gctx->sinc_lut_ptrs[n-1][i] = val;
}
}
fmt.image_channel_order = CL_INTENSITY;
fmt.image_channel_data_type = CL_FLOAT;
gctx->sinc_luts[n-1] = clCreateImage2D(gctx->ctx,
CL_MEM_READ_ONLY | CL_MEM_COPY_HOST_PTR,
&fmt, SINC_LUT_ELEMENTS, 1, 0,
gctx->sinc_lut_ptrs[n-1], &err);
if ( err != CL_SUCCESS ) {
ERROR("Couldn't create LUT for %i\n", n);
return;
}
}
static int set_arg_float(struct gpu_context *gctx, int idx, float val)
{
cl_int err;
err = clSetKernelArg(gctx->kern, idx, sizeof(cl_float), &val);
if ( err != CL_SUCCESS ) {
ERROR("Couldn't set kernel argument %i: %s\n",
idx, clError(err));
return 1;
}
return 0;
}
static int set_arg_int(struct gpu_context *gctx, int idx, int val)
{
cl_int err;
err = clSetKernelArg(gctx->kern, idx, sizeof(cl_int), &val);
if ( err != CL_SUCCESS ) {
ERROR("Couldn't set kernel argument %i: %s\n",
idx, clError(err));
return 1;
}
return 0;
}
static int set_arg_mem(struct gpu_context *gctx, int idx, cl_mem val)
{
cl_int err;
err = clSetKernelArg(gctx->kern, idx, sizeof(cl_mem), &val);
if ( err != CL_SUCCESS ) {
ERROR("Couldn't set kernel argument %i: %s\n",
idx, clError(err));
return 1;
}
return 0;
}
static int do_panels(struct gpu_context *gctx, struct image *image,
double k, double weight,
int *n_inf, int *n_neg, int *n_nan)
{
int i;
const int sampling = 4; /* This, squared, number of samples / pixel */
if ( set_arg_float(gctx, 1, k) ) return 1;
if ( set_arg_float(gctx, 2, weight) ) return 1;
/* Iterate over panels */
for ( i=0; i<image->det->n_panels; i++ ) {
size_t dims[2];
size_t ldims[2];
struct panel *p;
cl_mem diff;
size_t diff_size;
float *diff_ptr;
int fs, ss;
cl_int err;
p = &image->det->panels[i];
/* Buffer for the results of this panel */
diff_size = p->w * p->h * sizeof(cl_float);
diff = clCreateBuffer(gctx->ctx, CL_MEM_WRITE_ONLY,
diff_size, NULL, &err);
if ( err != CL_SUCCESS ) {
ERROR("Couldn't allocate diffraction memory\n");
return 1;
}
if ( set_arg_mem(gctx, 0, diff) ) return 1;
if ( set_arg_int(gctx, 3, p->w) ) return 1;
if ( set_arg_float(gctx, 4, p->cnx) ) return 1;
if ( set_arg_float(gctx, 5, p->cny) ) return 1;
if ( set_arg_float(gctx, 6, p->fsx) ) return 1;
if ( set_arg_float(gctx, 7, p->fsy) ) return 1;
if ( set_arg_float(gctx, 8, p->fsz) ) return 1;
if ( set_arg_float(gctx, 9, p->ssx) ) return 1;
if ( set_arg_float(gctx, 10, p->ssy) ) return 1;
if ( set_arg_float(gctx, 11, p->ssz) ) return 1;
if ( set_arg_float(gctx, 12, p->res) ) return 1;
if ( set_arg_float(gctx, 13, p->clen) ) return 1;
dims[0] = p->w * sampling;
dims[1] = p->h * sampling;
ldims[0] = sampling;
ldims[1] = sampling;
err = clSetKernelArg(gctx->kern, 20,
sampling*sampling*sizeof(cl_float), NULL);
if ( err != CL_SUCCESS ) {
ERROR("Couldn't set local memory: %s\n", clError(err));
return 1;
}
err = clEnqueueNDRangeKernel(gctx->cq, gctx->kern, 2, NULL,
dims, ldims, 0, NULL, NULL);
if ( err != CL_SUCCESS ) {
ERROR("Couldn't enqueue diffraction kernel: %s\n",
clError(err));
return 1;
}
clFinish(gctx->cq);
diff_ptr = clEnqueueMapBuffer(gctx->cq, diff, CL_TRUE,
CL_MAP_READ, 0, diff_size,
0, NULL, NULL, &err);
if ( err != CL_SUCCESS ) {
ERROR("Couldn't map diffraction buffer: %s\n",
clError(err));
return 1;
}
for ( ss=0; ss<p->h; ss++ ) {
for ( fs=0; fs<p->w; fs++ ) {
float val;
val = diff_ptr[fs + p->w*ss];
if ( isinf(val) ) (*n_inf)++;
if ( val < 0.0 ) (*n_neg)++;
if ( isnan(val) ) (*n_nan)++;
image->dp[i][fs + p->w*ss] += val;
}
}
clEnqueueUnmapMemObject(gctx->cq, diff, diff_ptr,
0, NULL, NULL);
clReleaseMemObject(diff);
}
return 0;
}
int get_diffraction_gpu(struct gpu_context *gctx, struct image *image,
int na, int nb, int nc, UnitCell *ucell,
int no_fringes)
{
double ax, ay, az;
double bx, by, bz;
double cx, cy, cz;
cl_float16 cell;
cl_int err;
int n_inf = 0;
int n_neg = 0;
int n_nan = 0;
int i;
if ( gctx == NULL ) {
ERROR("GPU setup failed.\n");
return 1;
}
/* Ensure all required LUTs are available */
check_sinc_lut(gctx, na, no_fringes);
check_sinc_lut(gctx, nb, no_fringes);
check_sinc_lut(gctx, nc, no_fringes);
/* Unit cell */
cell_get_cartesian(ucell, &ax, &ay, &az, &bx, &by, &bz, &cx, &cy, &cz);
cell.s[0] = ax; cell.s[1] = ay; cell.s[2] = az;
cell.s[3] = bx; cell.s[4] = by; cell.s[5] = bz;
cell.s[6] = cx; cell.s[7] = cy; cell.s[8] = cz;
err = clSetKernelArg(gctx->kern, 14, sizeof(cl_float16), &cell);
if ( err != CL_SUCCESS ) {
ERROR("Couldn't set unit cell: %s\n", clError(err));
return 1;
}
if ( set_arg_mem(gctx, 15, gctx->intensities) ) return 1;
if ( set_arg_mem(gctx, 16, gctx->flags) ) return 1;
if ( set_arg_mem(gctx, 17, gctx->sinc_luts[na-1]) ) return 1;
if ( set_arg_mem(gctx, 18, gctx->sinc_luts[nb-1]) ) return 1;
if ( set_arg_mem(gctx, 19, gctx->sinc_luts[nc-1]) ) return 1;
/* Allocate memory for the result */
image->dp = malloc(image->det->n_panels * sizeof(float *));
if ( image->dp == NULL ) {
ERROR("Couldn't allocate memory for result.\n");
return 1;
}
for ( i=0; i<image->det->n_panels; i++ ) {
struct panel *p = &image->det->panels[i];
image->dp[i] = calloc(p->w * p->h, sizeof(float));
if ( image->dp[i] == NULL ) {
ERROR("Couldn't allocate memory for panel %i\n", i);
return 1;
}
}
double tot = 0.0;
for ( i=0; i<image->nsamples; i++ ) {
printf("%.3f eV, weight = %.5f\n",
ph_lambda_to_eV(1.0/image->spectrum[i].k),
image->spectrum[i].weight);
err = do_panels(gctx, image, image->spectrum[i].k,
image->spectrum[i].weight,
&n_inf, &n_neg, &n_nan);
if ( err ) return 1;
tot += image->spectrum[i].weight;
}
printf("total weight = %f\n", tot);
if ( n_neg + n_inf + n_nan ) {
ERROR("WARNING: The GPU calculation produced %i negative"
" values, %i infinities and %i NaNs.\n",
n_neg, n_inf, n_nan);
}
return 0;
}
/* Setup the OpenCL stuff, create buffers, load the structure factor table */
struct gpu_context *setup_gpu(int no_sfac,
const double *intensities, unsigned char *flags,
const char *sym, int dev_num)
{
struct gpu_context *gctx;
cl_uint nplat;
cl_platform_id platforms[8];
cl_context_properties prop[3];
cl_int err;
cl_device_id dev;
size_t intensities_size;
float *intensities_ptr;
size_t flags_size;
float *flags_ptr;
size_t maxwgsize;
int i;
char cflags[512] = "";
char *insert_stuff = NULL;
STATUS("Setting up GPU...\n");
err = clGetPlatformIDs(8, platforms, &nplat);
if ( err != CL_SUCCESS ) {
ERROR("Couldn't get platform IDs: %i\n", err);
return NULL;
}
if ( nplat == 0 ) {
ERROR("Couldn't find at least one platform!\n");
return NULL;
}
prop[0] = CL_CONTEXT_PLATFORM;
prop[1] = (cl_context_properties)platforms[0];
prop[2] = 0;
gctx = malloc(sizeof(*gctx));
gctx->ctx = clCreateContextFromType(prop, CL_DEVICE_TYPE_GPU,
NULL, NULL, &err);
if ( err != CL_SUCCESS ) {
ERROR("Couldn't create OpenCL context: %i\n", err);
free(gctx);
return NULL;
}
dev = get_cl_dev(gctx->ctx, dev_num);
gctx->cq = clCreateCommandQueue(gctx->ctx, dev, 0, &err);
if ( err != CL_SUCCESS ) {
ERROR("Couldn't create OpenCL command queue\n");
free(gctx);
return NULL;
}
/* Create a single-precision version of the scattering factors */
intensities_size = IDIM*IDIM*IDIM*sizeof(cl_float);
intensities_ptr = malloc(intensities_size);
if ( intensities != NULL ) {
for ( i=0; i<IDIM*IDIM*IDIM; i++ ) {
intensities_ptr[i] = intensities[i];
}
} else {
for ( i=0; i<IDIM*IDIM*IDIM; i++ ) {
intensities_ptr[i] = 100.0; /* Does nothing */
}
strncat(cflags, "-DFLAT_INTENSITIES ", 511-strlen(cflags));
}
gctx->intensities = clCreateBuffer(gctx->ctx,
CL_MEM_READ_ONLY | CL_MEM_COPY_HOST_PTR,
intensities_size, intensities_ptr, &err);
if ( err != CL_SUCCESS ) {
ERROR("Couldn't allocate intensities memory\n");
free(gctx);
return NULL;
}
free(intensities_ptr);
if ( sym != NULL ) {
int i, n;
SymOpList *pg;
size_t islen = 0;
insert_stuff = malloc(16384);
if ( insert_stuff == NULL ) return NULL;
insert_stuff[0] = '\0';
pg = get_pointgroup(sym);
n = num_equivs(pg, NULL);
for ( i=0; i<n; i++ ) {
IntegerMatrix *op = get_symop(pg, NULL, i);
char line[1024];
snprintf(line, 1023,
"val += lookup_flagged_intensity(intensities, "
"flags, %s, %s, %s);\n\t",
get_matrix_name(op, 0),
get_matrix_name(op, 1),
get_matrix_name(op, 2));
islen += strlen(line);
if ( islen > 16383 ) {
ERROR("Too many symmetry operators.\n");
return NULL;
}
strcat(insert_stuff, line);
}
free_symoplist(pg);
printf("Inserting --->%s<---\n", insert_stuff);
} else {
if ( intensities != NULL ) {
ERROR("You gave me an intensities file but no point"
" group. I'm assuming '1'.\n");
strncat(cflags, "-DPG1 ", 511-strlen(cflags));
}
}
/* Create a flag array */
flags_size = IDIM*IDIM*IDIM*sizeof(cl_float);
flags_ptr = malloc(flags_size);
if ( flags != NULL ) {
for ( i=0; i<IDIM*IDIM*IDIM; i++ ) {
flags_ptr[i] = flags[i];
}
} else {
for ( i=0; i<IDIM*IDIM*IDIM; i++ ) {
flags_ptr[i] = 1.0;
}
}
gctx->flags = clCreateBuffer(gctx->ctx,
CL_MEM_READ_ONLY | CL_MEM_COPY_HOST_PTR,
flags_size, flags_ptr, &err);
if ( err != CL_SUCCESS ) {
ERROR("Couldn't allocate flag buffer\n");
free(gctx);
return NULL;
}
free(flags_ptr);
gctx->prog = load_program(DATADIR"/crystfel/diffraction.cl", gctx->ctx,
dev, &err, cflags, insert_stuff);
if ( err != CL_SUCCESS ) {
free(gctx);
return NULL;
}
gctx->kern = clCreateKernel(gctx->prog, "diffraction", &err);
if ( err != CL_SUCCESS ) {
ERROR("Couldn't create kernel\n");
free(gctx);
return NULL;
}
gctx->max_sinc_lut = 0;
gctx->sinc_lut_ptrs = NULL;
gctx->sinc_luts = NULL;
clGetDeviceInfo(dev, CL_DEVICE_MAX_WORK_GROUP_SIZE,
sizeof(size_t), &maxwgsize, NULL);
STATUS("Maximum work group size = %lli\n", (long long int)maxwgsize);
return gctx;
}
void cleanup_gpu(struct gpu_context *gctx)
{
int i;
clReleaseProgram(gctx->prog);
clReleaseMemObject(gctx->intensities);
/* Release LUTs */
for ( i=1; i<=gctx->max_sinc_lut; i++ ) {
if ( gctx->sinc_lut_ptrs[i-1] != NULL ) {
clReleaseMemObject(gctx->sinc_luts[i-1]);
free(gctx->sinc_lut_ptrs[i-1]);
}
}
free(gctx->sinc_luts);
free(gctx->sinc_lut_ptrs);
clReleaseCommandQueue(gctx->cq);
clReleaseContext(gctx->ctx);
free(gctx);
}
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