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clamr_quo.cpp
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clamr_quo.cpp
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/*
* Copyright (c) 2011-2019, Triad National Security, LLC.
* All rights Reserved.
*
* CLAMR -- LA-CC-11-094
*
* Copyright 2011-2019. Triad National Security, LLC. This software was produced
* under U.S. Government contract 89233218CNA000001 for Los Alamos National
* Laboratory (LANL), which is operated by Triad National Security, LLC
* for the U.S. Department of Energy. The U.S. Government has rights to use,
* reproduce, and distribute this software. NEITHER THE GOVERNMENT NOR
* TRIAD NATIONAL SECURITY, LLC MAKES ANY WARRANTY, EXPRESS OR IMPLIED, OR
* ASSUMES ANY LIABILITY FOR THE USE OF THIS SOFTWARE. If software is modified
* to produce derivative works, such modified software should be clearly marked,
* so as not to confuse it with the version available from LANL.
*
* Additionally, redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of the Triad National Security, LLC, Los Alamos
* National Laboratory, LANL, the U.S. Government, nor the names of its
* contributors may be used to endorse or promote products derived from
* this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE TRIAD NATIONAL SECURITY, LLC AND
* CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT
* NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL TRIAD NATIONAL
* SECURITY, LLC OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS;
* OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
* WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
* CLAMR -- LA-CC-11-094
* This research code is being developed as part of the
* 2011 X Division Summer Workshop for the express purpose
* of a collaborative code for development of ideas in
* the implementation of AMR codes for Exascale platforms
*
* AMR implementation of the Wave code previously developed
* as a demonstration code for regular grids on Exascale platforms
* as part of the Supercomputing Challenge and Los Alamos
* National Laboratory
*
* Authors: Bob Robey XCP-2 [email protected]
* Neal Davis [email protected], [email protected]
* David Nicholaeff [email protected], [email protected]
* Dennis Trujillo [email protected], [email protected]
*
*/
#include <algorithm>
#include <math.h>
#include <stdio.h>
#include <stdlib.h>
#include <sys/time.h>
#include <unistd.h>
#include <signal.h>
#include <vector>
#include "input.h"
#include "mesh/mesh.h"
#include "mesh/partition.h"
#include "state.h"
#include "l7/l7.h"
#include "timer/timer.h"
#include "memstats/memstats.h"
#ifdef HAVE_MPI
#include <mpi.h>
#endif
#include <omp.h>
#include "display.h"
#ifndef DEBUG
#define DEBUG 0
#endif
static int do_cpu_calc = 1;
static int do_gpu_calc = 0;
typedef unsigned int uint;
#ifdef HAVE_GRAPHICS
static double circle_radius=-1.0;
static int view_mode = 0;
#ifdef FULL_PRECISION
void (*set_cell_coordinates)(double *, double *, double *, double *) = &set_cell_coordinates_double;
void (*set_cell_data)(double *) = &set_cell_data_double;
#else
void (*set_cell_coordinates)(float *, float *, float *, float *) = &set_cell_coordinates_float;
void (*set_cell_data)(float *) = &set_cell_data_float;
#endif
#endif
bool verbose, // Flag for verbose command-line output; init in input.cpp::parseInput().
localStencil, // Flag for use of local stencil; init in input.cpp::parseInput().
face_based, // Flag for face-based finite difference;
outline, // Flag for drawing outlines of cells; init in input.cpp::parseInput().
output_cuts; // Flag for outputting file of slice along y-axis; init in input.cpp::parseInput().
int outputInterval, // Periodicity of output; init in input.cpp::parseInput().
enhanced_precision_sum,// Flag for enhanced precision sum (default true); init in input.cpp::parseInput().
lttrace_on, // Flag to turn on logical time trace package;
do_quo_setup, // Flag to turn on quo dynamic scheduling policies package;
levmx, // Maximum number of refinement levels; init in input.cpp::parseInput().
nx, // x-resolution of coarse grid; init in input.cpp::parseInput().
ny, // y-resolution of coarse grid; init in input.cpp::parseInput().
niter, // Maximum time step; init in input.cpp::parseInput().
ndim = 2, // Dimensionality of problem (2 or 3).
ndigits,
nbits;
enum partition_method initial_order, // Initial order of mesh.
cycle_reorder; // Order of mesh every cycle.
static Mesh *mesh; // Object containing mesh information; init in grid.cpp::main().
static State *state; // Object containing state information corresponding to mesh; init in grid.cpp::main().
// Set up timing information.
static struct timespec tstart;
static double H_sum_initial = 0.0;
static double cpu_time_graphics = 0.0;
double cpu_time_main_setup = 0.0;
vector<state_t> H_global;
vector<spatial_t> x_global;
vector<spatial_t> dx_global;
vector<spatial_t> y_global;
vector<spatial_t> dy_global;
vector<int> proc_global;
int main(int argc, char **argv) {
// Process command-line arguments, if any.
int mype=0;
int numpe=0;
parseInput(argc, argv);
L7_Init(&mype, &numpe, &argc, argv);
#if 1 // SKG make things sane for debugging
signal(SIGSEGV, SIG_DFL);
#endif
struct timespec tstart_setup;
cpu_timer_start(&tstart_setup);
real_t circ_radius = 6.0;
// Scale the circle appropriately for the mesh size.
circ_radius = circ_radius * (real_t) nx / 128.0;
int boundary = 1;
int parallel_in = 1;
// figure out the max number of threads that can be spawned
if (0 == mype) {
int nt = omp_get_max_threads();
printf("--- num openmp threads: %d\n", nt);
fflush(stdout);
}
mesh = new Mesh(nx, ny, levmx, ndim, boundary, parallel_in, do_gpu_calc);
if (DEBUG) {
//if (mype == 0) mesh->print();
char filename[10];
sprintf(filename,"out%1d",mype);
mesh->fp=fopen(filename,"w");
//mesh->print_local();
}
mesh->init(nx, ny, circ_radius, initial_order, do_gpu_calc);
size_t &ncells = mesh->ncells;
size_t &ncells_global = mesh->ncells_global;
int &noffset = mesh->noffset;
state = new State(mesh);
state->init(do_gpu_calc);
vector<int> &nsizes = mesh->nsizes;
vector<int> &ndispl = mesh->ndispl;
vector<spatial_t> &x = mesh->x;
vector<spatial_t> &dx = mesh->dx;
vector<spatial_t> &y = mesh->y;
vector<spatial_t> &dy = mesh->dy;
nsizes.resize(numpe);
ndispl.resize(numpe);
int ncells_int = ncells;
MPI_Allgather(&ncells_int, 1, MPI_INT, &nsizes[0], 1, MPI_INT, MPI_COMM_WORLD);
ndispl[0]=0;
for (int ip=1; ip<numpe; ip++){
ndispl[ip] = ndispl[ip-1] + nsizes[ip-1];
}
noffset = ndispl[mype];
state->resize(ncells);
state->fill_circle(circ_radius, 80.0, 10.0);
x.clear();
dx.clear();
y.clear();
dy.clear();
// Kahan-type enhanced precision sum implementation.
double H_sum = state->mass_sum(enhanced_precision_sum);
if (mype == 0) printf ("Mass of initialized cells equal to %14.12lg\n", H_sum);
H_sum_initial = H_sum;
double cpu_time_main_setup = cpu_timer_stop(tstart_setup);
mesh->parallel_timer_output("CPU: setup time time was",cpu_time_main_setup, 0);
long long mem_used = memstats_memused();
if (mem_used > 0) {
mesh->parallel_memory_output("Memory used in startup ",mem_used, 0);
mesh->parallel_memory_output("Memory peak in startup ",memstats_mempeak(), 0);
mesh->parallel_memory_output("Memory free at startup ",memstats_memfree(), 0);
mesh->parallel_memory_output("Memory available at startup ",memstats_memtotal(), 0);
}
if (mype == 0) {
printf("Iteration 0 timestep n/a Sim Time 0.0 cells %ld Mass Sum %14.12lg\n", ncells_global, H_sum);
}
for (int i = 0; i < MESH_COUNTER_SIZE; i++){
mesh->cpu_counters[i]=0;
}
for (int i = 0; i < MESH_TIMER_SIZE; i++){
mesh->cpu_timers[i]=0.0;
}
#ifdef HAVE_GRAPHICS
#ifdef HAVE_OPENGL
set_mysize(ncells_global);
//vector<state_t> H_global;
//vector<spatial_t> x_global;
//vector<spatial_t> dx_global;
//vector<spatial_t> y_global;
//vector<spatial_t> dy_global;
//vector<int> proc_global;
if (mype == 0){
H_global.resize(ncells_global);
x_global.resize(ncells_global);
dx_global.resize(ncells_global);
y_global.resize(ncells_global);
dy_global.resize(ncells_global);
proc_global.resize(ncells_global);
}
MPI_Gatherv(&x[0], nsizes[mype], MPI_SPATIAL_T, &x_global[0], &nsizes[0], &ndispl[0], MPI_SPATIAL_T, 0, MPI_COMM_WORLD);
MPI_Gatherv(&dx[0], nsizes[mype], MPI_SPATIAL_T, &dx_global[0], &nsizes[0], &ndispl[0], MPI_SPATIAL_T, 0, MPI_COMM_WORLD);
MPI_Gatherv(&y[0], nsizes[mype], MPI_SPATIAL_T, &y_global[0], &nsizes[0], &ndispl[0], MPI_SPATIAL_T, 0, MPI_COMM_WORLD);
MPI_Gatherv(&dy[0], nsizes[mype], MPI_SPATIAL_T, &dy_global[0], &nsizes[0], &ndispl[0], MPI_SPATIAL_T, 0, MPI_COMM_WORLD);
MPI_Gatherv(&state->H[0], nsizes[mype], MPI_STATE_T, &H_global[0], &nsizes[0], &ndispl[0], MPI_STATE_T, 0, MPI_COMM_WORLD);
set_cell_data(&H_global[0]);
set_cell_coordinates(&x_global[0], &dx_global[0], &y_global[0], &dy_global[0]);
if (view_mode == 0) {
mesh->proc.resize(ncells);
for (size_t ii = 0; ii<ncells; ii++){
mesh->proc[ii] = mesh->mype;
}
MPI_Gatherv(&mesh->proc[0], nsizes[mype], MPI_INT, &proc_global[0], &nsizes[0], &ndispl[0], MPI_C_REAL, 0, MPI_COMM_WORLD);
}
set_cell_proc(&proc_global[0]);
#endif
#ifdef HAVE_MPE
set_mysize(ncells);
set_cell_data(&state->H[0]);
set_cell_coordinates(&mesh->x[0], &mesh->dx[0], &mesh->y[0], &mesh->dy[0]);
set_cell_proc(&mesh->proc[0]);
#endif
set_window((float)mesh->xmin, (float)mesh->xmax, (float)mesh->ymin, (float)mesh->ymax);
set_viewmode(view_mode);
set_outline((int)outline);
init_display(&argc, argv, "Shallow Water");
set_circle_radius(circle_radius);
draw_scene();
if (verbose) sleep(5);
sleep(2);
// Set flag to show mesh results rather than domain decomposition.
view_mode = 1;
// Clear superposition of circle on grid output.
circle_radius = -1.0;
MPI_Barrier(MPI_COMM_WORLD);
cpu_timer_start(&tstart);
set_idle_function(&do_calc);
start_main_loop();
#else
MPI_Barrier(MPI_COMM_WORLD);
cpu_timer_start(&tstart);
for (int it = 0; it < 10000000; it++) {
do_calc();
}
#endif
return 0;
}
static int ncycle = 0;
static double simTime = 0.0;
extern "C" void do_calc(void)
{ double g = 9.80;
double sigma = 0.95;
int icount, jcount;
struct timespec tstart_cpu;
// Initialize state variables for GPU calculation.
int &mype = mesh->mype;
int &numpe = mesh->numpe;
//int levmx = mesh->levmx;
size_t &ncells_global = mesh->ncells_global;
size_t &ncells = mesh->ncells;
size_t &ncells_ghost = mesh->ncells_ghost;
vector<char_t> mpot;
vector<char_t> mpot_global;
size_t old_ncells = ncells;
size_t old_ncells_global = ncells_global;
size_t new_ncells = 0;
double deltaT = 0.0;
// Main loop.
for (int nburst = 0; nburst < outputInterval && ncycle < niter; nburst++, ncycle++) {
// Define basic domain decomposition parameters for GPU.
old_ncells = ncells;
old_ncells_global = ncells_global;
MPI_Barrier(MPI_COMM_WORLD);
cpu_timer_start(&tstart_cpu);
// Calculate the real time step for the current discrete time step.
deltaT = state->set_timestep(g, sigma);
simTime += deltaT;
cpu_timer_start(&tstart_cpu);
mesh->calc_neighbors_local();
mesh->partition_measure();
// Currently not working -- may need to be earlier?
//if (mesh->have_boundary) {
// state->add_boundary_cells();
//}
// Apply BCs is currently done as first part of gpu_finite_difference and so comparison won't work here
// Execute main kernel
cpu_timer_start(&tstart_cpu);
state->calc_finite_difference(deltaT);
// Size of arrays gets reduced to just the real cells in this call for have_boundary = 0
state->remove_boundary_cells();
cpu_timer_start(&tstart_cpu);
mpot.resize(ncells_ghost);
new_ncells = state->calc_refine_potential(mpot, icount, jcount);
cpu_timer_start(&tstart_cpu);
//int add_ncells = new_ncells - old_ncells;
state->rezone_all(icount, jcount, mpot);
// Clear does not delete mpot, so have to swap with an empty vector to get
// it to delete the mpot memory. This is all to avoid valgrind from showing
// it as a reachable memory leak
//mpot.clear();
vector<char_t>().swap(mpot);
ncells = new_ncells;
mesh->ncells = new_ncells;
cpu_timer_start(&tstart_cpu);
state->do_load_balance_local(new_ncells);
// XXX
// mesh->proc.resize(ncells);
// if (icount) {
// vector<int> index(ncells);
// mesh->partition_cells(numpe, index, cycle_reorder);
// }
} // End burst loop
double H_sum = state->mass_sum(enhanced_precision_sum);
#ifdef __APPLE__
if (isnan(H_sum)) {
#else
if (std::isnan(H_sum)) {
#endif
printf("Got a NAN on cycle %d\n",ncycle);
exit(-1);
}
if (mype == 0){
printf("Iteration %3d timestep %lf Sim Time %lf cells %ld Mass Sum %14.12lg Mass Change %12.6lg\n",
ncycle, deltaT, simTime, ncells_global, H_sum, H_sum - H_sum_initial);
}
#ifdef HAVE_GRAPHICS
mesh->x.resize(ncells);
mesh->dx.resize(ncells);
mesh->y.resize(ncells);
mesh->dy.resize(ncells);
mesh->calc_spatial_coordinates(0);
cpu_timer_start(&tstart_cpu);
#ifdef HAVE_MPE
set_mysize(ncells);
set_cell_coordinates(&mesh->x[0], &mesh->dx[0], &mesh->y[0], &mesh->dy[0]);
set_cell_data(&state->H[0]);
set_cell_proc(&mesh->proc[0]);
#endif
#ifdef HAVE_OPENGL
vector<int> &nsizes = mesh->nsizes;
vector<int> &ndispl = mesh->ndispl;
set_mysize(ncells_global);
//vector<spatial_t> x_global;
//vector<spatial_t> dx_global;
//vector<spatial_t> y_global;
//vector<spatial_t> dy_global;
//vector<state_t> H_global;
//vector<int> proc_global;
if (mype == 0) {
x_global.resize(ncells_global);
dx_global.resize(ncells_global);
y_global.resize(ncells_global);
dy_global.resize(ncells_global);
H_global.resize(ncells_global);
proc_global.resize(ncells_global);
}
MPI_Gatherv(&mesh->x[0], nsizes[mype], MPI_SPATIAL_T, &x_global[0], &nsizes[0], &ndispl[0], MPI_SPATIAL_T, 0, MPI_COMM_WORLD);
MPI_Gatherv(&mesh->dx[0], nsizes[mype], MPI_SPATIAL_T, &dx_global[0], &nsizes[0], &ndispl[0], MPI_SPATIAL_T, 0, MPI_COMM_WORLD);
MPI_Gatherv(&mesh->y[0], nsizes[mype], MPI_SPATIAL_T, &y_global[0], &nsizes[0], &ndispl[0], MPI_SPATIAL_T, 0, MPI_COMM_WORLD);
MPI_Gatherv(&mesh->dy[0], nsizes[mype], MPI_SPATIAL_T, &dy_global[0], &nsizes[0], &ndispl[0], MPI_SPATIAL_T, 0, MPI_COMM_WORLD);
MPI_Gatherv(&state->H[0], nsizes[mype], MPI_STATE_T, &H_global[0], &nsizes[0], &ndispl[0], MPI_STATE_T, 0, MPI_COMM_WORLD);
if (view_mode == 0) {
mesh->proc.resize(ncells);
for (size_t ii = 0; ii<ncells; ii++){
mesh->proc[ii] = mesh->mype;
}
MPI_Gatherv(&mesh->proc[0], nsizes[mype], MPI_INT, &proc_global[0], &nsizes[0], &ndispl[0], MPI_INT, 0, MPI_COMM_WORLD);
}
set_cell_coordinates(&x_global[0], &dx_global[0], &y_global[0], &dy_global[0]);
set_cell_data(&H_global[0]);
set_cell_proc(&proc_global[0]);
#endif
set_viewmode(view_mode);
set_circle_radius(circle_radius);
draw_scene();
MPI_Barrier(MPI_COMM_WORLD);
cpu_time_graphics += cpu_timer_stop(tstart_cpu);
#endif
// Output final results and timing information.
if (ncycle >= niter) {
//free_display();
// Get overall program timing.
double elapsed_time = cpu_timer_stop(tstart);
long long mem_used = memstats_memused();
if (mem_used > 0) {
mesh->parallel_memory_output("Memory used ",mem_used, 0);
mesh->parallel_memory_output("Memory peak ",memstats_mempeak(), 0);
mesh->parallel_memory_output("Memory free ",memstats_memfree(), 0);
mesh->parallel_memory_output("Memory available ",memstats_memtotal(), 0);
}
state->output_timing_info(do_cpu_calc, do_gpu_calc, elapsed_time);
mesh->parallel_timer_output("CPU: graphics time was",cpu_time_graphics, 0);
mesh->print_partition_measure();
mesh->print_calc_neighbor_type();
mesh->print_partition_type();
if (mype ==0) {
printf("CPU: rezone frequency \t %8.4f\tpercent\n", (double)mesh->get_cpu_rezone_count()/(double)ncycle*100.0 );
printf("CPU: calc neigh frequency \t %8.4f\tpercent\n", (double)mesh->get_cpu_calc_neigh_count()/(double)ncycle*100.0 );
printf("CPU: load balance frequency \t %8.4f\tpercent\n", (double)mesh->get_cpu_load_balance_count()/(double)ncycle*100.0 );
printf("CPU: refine_smooth_iter per rezone \t %8.4f\t\n", (double)mesh->get_cpu_refine_smooth_count()/(double)mesh->get_cpu_rezone_count() );
}
mesh->terminate();
state->terminate();
delete mesh;
delete state;
L7_Terminate();
exit(0);
} // Complete final output.
}