Trying to debug segfault if cudaMemcpy is limited to neighbour list update

src/force.cu

@@ -99,7 +99,9 @@ __global__ void calc_force(
 extern "C" {
 
 bool initialized = false;
-Atom c_atom;
+static Atom c_atom;
+int *c_neighs;
+int *c_neigh_numneigh;
 
 double computeForce(
         bool reneighbourHappenend,
@@ -117,9 +119,12 @@ double computeForce(
     MD_FLOAT sigma6 = param->sigma6;
     MD_FLOAT epsilon = param->epsilon;
 #endif
+    printf("-1\r\n");
 
     cudaProfilerStart();
 
+    printf("0\r\n");
+
     for(int i = 0; i < Nlocal; i++) {
         fx[i] = 0.0;
         fy[i] = 0.0;
@@ -140,6 +145,8 @@ double computeForce(
     c_atom.Nmax = atom->Nmax;
     c_atom.ntypes = atom->ntypes;
 
+    printf("0.1\r\n");
+
     /*
     int nDevices;
     cudaGetDeviceCount(&nDevices);
@@ -160,6 +167,8 @@ double computeForce(
     // HINT: Run with cuda-memcheck ./MDBench-NVCC in case of error
     // HINT: Only works for data layout = AOS!!!
 
+    printf("1\r\n");
+
     if(!initialized) {
         checkCUDAError( "c_atom.x malloc", cudaMalloc((void**)&(c_atom.x), sizeof(MD_FLOAT) * atom->Nmax * 3) );
         checkCUDAError( "c_atom.fx malloc", cudaMalloc((void**)&(c_atom.fx), sizeof(MD_FLOAT) * Nlocal) );
@@ -170,25 +179,31 @@ double computeForce(
         checkCUDAError( "c_atom.sigma6 malloc", cudaMalloc((void**)&(c_atom.sigma6), sizeof(MD_FLOAT) * atom->ntypes * atom->ntypes) );
         checkCUDAError( "c_atom.cutforcesq malloc", cudaMalloc((void**)&(c_atom.cutforcesq), sizeof(MD_FLOAT) * atom->ntypes * atom->ntypes) );
 
-        initialized = true;
+        checkCUDAError( "c_neighs malloc", cudaMalloc((void**)&c_neighs, sizeof(int) * Nlocal * neighbor->maxneighs) );
+        checkCUDAError( "c_neigh_numneigh malloc", cudaMalloc((void**)&c_neigh_numneigh, sizeof(int) * Nlocal) );
     }
 
-    checkCUDAError( "c_atom.x memcpy", cudaMemcpy(c_atom.x, atom->x, sizeof(MD_FLOAT) * atom->Nmax * 3, cudaMemcpyHostToDevice) );
-    checkCUDAError( "c_atom.fx memcpy", cudaMemcpy(c_atom.fx, fx, sizeof(MD_FLOAT) * Nlocal, cudaMemcpyHostToDevice) );
-    checkCUDAError( "c_atom.fy memcpy", cudaMemcpy(c_atom.fy, fy, sizeof(MD_FLOAT) * Nlocal, cudaMemcpyHostToDevice) );
-    checkCUDAError( "c_atom.fz memcpy", cudaMemcpy(c_atom.fz, fz, sizeof(MD_FLOAT) * Nlocal, cudaMemcpyHostToDevice) );
-    checkCUDAError( "c_atom.type memcpy", cudaMemcpy(c_atom.type, atom->type, sizeof(int) * atom->Nmax, cudaMemcpyHostToDevice) );
-    checkCUDAError( "c_atom.epsilon memcpy", cudaMemcpy(c_atom.epsilon, atom->epsilon, sizeof(MD_FLOAT) * atom->ntypes * atom->ntypes, cudaMemcpyHostToDevice) );
-    checkCUDAError( "c_atom.sigma6 memcpy", cudaMemcpy(c_atom.sigma6, atom->sigma6, sizeof(MD_FLOAT) * atom->ntypes * atom->ntypes, cudaMemcpyHostToDevice) );
-    checkCUDAError( "c_atom.cutforcesq memcpy", cudaMemcpy(c_atom.cutforcesq, atom->cutforcesq, sizeof(MD_FLOAT) * atom->ntypes * atom->ntypes, cudaMemcpyHostToDevice) );
+    printf("2\r\n");
 
-    int *c_neighs;
-    checkCUDAError( "c_neighs malloc", cudaMalloc((void**)&c_neighs, sizeof(int) * Nlocal * neighbor->maxneighs) );
-    checkCUDAError( "c_neighs memcpy", cudaMemcpy(c_neighs, neighbor->neighbors, sizeof(int) * Nlocal * neighbor->maxneighs, cudaMemcpyHostToDevice) );
+    if(reneighbourHappenend || !initialized) {
+        checkCUDAError( "c_atom.x memcpy", cudaMemcpy(c_atom.x, atom->x, sizeof(MD_FLOAT) * atom->Nmax * 3, cudaMemcpyHostToDevice) );
+        checkCUDAError( "c_atom.fx memcpy", cudaMemcpy(c_atom.fx, fx, sizeof(MD_FLOAT) * Nlocal, cudaMemcpyHostToDevice) );
+        checkCUDAError( "c_atom.fy memcpy", cudaMemcpy(c_atom.fy, fy, sizeof(MD_FLOAT) * Nlocal, cudaMemcpyHostToDevice) );
+        checkCUDAError( "c_atom.fz memcpy", cudaMemcpy(c_atom.fz, fz, sizeof(MD_FLOAT) * Nlocal, cudaMemcpyHostToDevice) );
+        checkCUDAError( "c_atom.type memcpy", cudaMemcpy(c_atom.type, atom->type, sizeof(int) * atom->Nmax, cudaMemcpyHostToDevice) );
+        checkCUDAError( "c_atom.epsilon memcpy", cudaMemcpy(c_atom.epsilon, atom->epsilon, sizeof(MD_FLOAT) * atom->ntypes * atom->ntypes, cudaMemcpyHostToDevice) );
+        checkCUDAError( "c_atom.sigma6 memcpy", cudaMemcpy(c_atom.sigma6, atom->sigma6, sizeof(MD_FLOAT) * atom->ntypes * atom->ntypes, cudaMemcpyHostToDevice) );
+        checkCUDAError( "c_atom.cutforcesq memcpy", cudaMemcpy(c_atom.cutforcesq, atom->cutforcesq, sizeof(MD_FLOAT) * atom->ntypes * atom->ntypes, cudaMemcpyHostToDevice) );
 
-    int *c_neigh_numneigh;
-    checkCUDAError( "c_neigh_numneigh malloc", cudaMalloc((void**)&c_neigh_numneigh, sizeof(int) * Nlocal) );
-    checkCUDAError( "c_neigh_numneigh memcpy", cudaMemcpy(c_neigh_numneigh, neighbor->numneigh, sizeof(int) * Nlocal, cudaMemcpyHostToDevice) );
+        checkCUDAError( "c_neigh_numneigh memcpy", cudaMemcpy(c_neigh_numneigh, neighbor->numneigh, sizeof(int) * Nlocal, cudaMemcpyHostToDevice) );
+        checkCUDAError( "c_neighs memcpy", cudaMemcpy(c_neighs, neighbor->neighbors, sizeof(int) * Nlocal * neighbor->maxneighs, cudaMemcpyHostToDevice) );
+    }
+
+    printf("3\r\n");
+
+    printf("4\r\n");
+
+    printf("5\r\n");
 
     const int num_threads_per_block = num_threads; // this should be multiple of 32 as operations are performed at the level of warps
     const int num_blocks = ceil((float)Nlocal / (float)num_threads_per_block);
@@ -201,10 +216,16 @@ double computeForce(
     checkCUDAError( "PeekAtLastError", cudaPeekAtLastError() );
     checkCUDAError( "DeviceSync", cudaDeviceSynchronize() );
 
+    printf("6\r\n");
+
     // copy results in c_atom.fx/fy/fz to atom->fx/fy/fz
-    cudaMemcpy(atom->fx, c_atom.fx, sizeof(MD_FLOAT) * Nlocal, cudaMemcpyDeviceToHost);
-    cudaMemcpy(atom->fy, c_atom.fy, sizeof(MD_FLOAT) * Nlocal, cudaMemcpyDeviceToHost);
-    cudaMemcpy(atom->fz, c_atom.fz, sizeof(MD_FLOAT) * Nlocal, cudaMemcpyDeviceToHost);
+    if(reneighbourHappenend) {
+        cudaMemcpy(atom->fx, c_atom.fx, sizeof(MD_FLOAT) * Nlocal, cudaMemcpyDeviceToHost);
+        cudaMemcpy(atom->fy, c_atom.fy, sizeof(MD_FLOAT) * Nlocal, cudaMemcpyDeviceToHost);
+        cudaMemcpy(atom->fz, c_atom.fz, sizeof(MD_FLOAT) * Nlocal, cudaMemcpyDeviceToHost);
+    }
+
+    printf("7\r\n");
 
     /*
     cudaFree(c_atom.x);
@@ -215,13 +236,15 @@ double computeForce(
     cudaFree(c_atom.cutforcesq);
     */
 
-    cudaFree(c_neighs); cudaFree(c_neigh_numneigh);
+    // cudaFree(c_neighs); cudaFree(c_neigh_numneigh);
 
     cudaProfilerStop();
 
     LIKWID_MARKER_STOP("force");
     double E = getTimeStamp();
 
+    initialized = true;
+
     return E-S;
 }
 }

src/main.c

@@ -111,13 +111,20 @@ double reneighbour(
 {
     double S, E;
 
+    printf("10.1\r\n");
+
     S = getTimeStamp();
     LIKWID_MARKER_START("reneighbour");
+    printf("10.2\r\n");
     updateAtomsPbc(atom, param);
+    printf("10.3\r\n");
     setupPbc(atom, param);
+    printf("10.4\r\n");
     updatePbc(atom, param);
+    printf("10.5\r\n");
     //sortAtom(atom);
     buildNeighbor(atom, neighbor);
+    printf("10.6\r\n");
     LIKWID_MARKER_STOP("reneighbour");
     E = getTimeStamp();
 
@@ -279,6 +286,11 @@ int main(int argc, char** argv)
         initialIntegrate(&param, &atom);
 
         const bool doReneighbour = (n + 1) % param.every == 0;
+        const bool doesReneighbourNextRound = (n + 2) % param.every == 0;
+
+        printf("Run %d does reneighbour: %d\r\n", n, doReneighbour);
+
+        printf("10\r\n");
 
         if(doReneighbour) {
             timer[NEIGH] += reneighbour(&param, &atom, &neighbor);
@@ -286,6 +298,8 @@ int main(int argc, char** argv)
             updatePbc(&atom, &param);
         }
 
+        printf("11\r\n");
+
         if(param.force_field == FF_EAM) {
             timer[FORCE] += computeForceEam(&eam, &param, &atom, &neighbor, &stats, 0, n + 1);
         } else {

src/neighbor.c

@@ -172,6 +172,8 @@ void buildNeighbor(Atom *atom, Neighbor *neighbor)
 {
     int nall = atom->Nlocal + atom->Nghost;
 
+    printf("nall: %d, nmax: %d\r\n", nall, nmax);
+
     /* extend atom arrays if necessary */
     if(nall > nmax) {
         nmax = nall;
@@ -183,10 +185,14 @@ void buildNeighbor(Atom *atom, Neighbor *neighbor)
         // neighbor->neighbors = (int*) malloc(nmax * neighbor->maxneighs * sizeof(int*));
     }
 
+    printf("10.5.1\r\n");
+
     /* bin local & ghost atoms */
     binatoms(atom);
     int resize = 1;
 
+    printf("10.5.2\r\n");
+
     /* loop over each atom, storing neighbors */
     while(resize) {
         int new_maxneighs = neighbor->maxneighs;
@@ -224,6 +230,7 @@ void buildNeighbor(Atom *atom, Neighbor *neighbor)
                     #else
                     const MD_FLOAT cutoff = cutneighsq;
                     #endif
+
                     if( rsq <= cutoff ) {
                         neighptr[n++] = j;
                     }
@@ -315,9 +322,14 @@ int coord2bin(MD_FLOAT xin, MD_FLOAT yin, MD_FLOAT zin)
 
 void binatoms(Atom *atom)
 {
+    printf("10.5.1.1\r\n");
     int nall = atom->Nlocal + atom->Nghost;
     int resize = 1;
 
+    printf("10.5.1.2\r\n");
+
+    printf("nall: %d, atom->Nmax: %d\r\n", nall, atom->Nmax);
+
     while(resize > 0) {
         resize = 0;
 
@@ -325,8 +337,13 @@ void binatoms(Atom *atom)
             bincount[i] = 0;
         }
 
+        printf("10.5.1.3\r\n");
+
         for(int i = 0; i < nall; i++) {
-            int ibin = coord2bin(atom_x(i), atom_y(i), atom_z(i));
+            MD_FLOAT x = atom_x(i);
+            MD_FLOAT y = atom_y(i);
+            MD_FLOAT z = atom_z(i);
+            int ibin = coord2bin(x, y, z);
 
             if(bincount[ibin] < atoms_per_bin) {
                 int ac = bincount[ibin]++;
@@ -336,11 +353,15 @@ void binatoms(Atom *atom)
             }
         }
 
+        printf("10.5.1.4\r\n");
+
         if(resize) {
             free(bins);
             atoms_per_bin *= 2;
             bins = (int*) malloc(mbins * atoms_per_bin * sizeof(int));
         }
+
+        printf("10.5.1.5\r\n");
     }
 }