density not crashing, but broken

2024-03-02 21:51:47 -05:00 · 2024-03-02 21:51:47 -05:00 · 62373d266c
commit 62373d266c
parent e955c1f479
9 changed files with 296 additions and 81 deletions
--- a/src/main/c/compile.sh
+++ b/src/main/c/compile.sh
@ -61,12 +61,17 @@ INPUT_FILES="./src/threadpool.c"
 OUTPUT_FILE="./threadpool.o"
 gcc $COMPILE_FLAGS -I"$BASE_INCLUDE_DIR" -I"$OS_INCLUDE_DIR" $INPUT_FILES -o $OUTPUT_FILE
 COMPILE_FLAGS="-c -fPIC -m64 -mavx -mavx2 -O1"
 INPUT_FILES="./src/libfluidsim.c"
 OUTPUT_FILE="./libfluidsim.o"
 gcc $COMPILE_FLAGS -I"$BASE_INCLUDE_DIR" -I"$OS_INCLUDE_DIR" $INPUT_FILES -o $OUTPUT_FILE
 #compile shared object file
 OUTPUT_FILE="libfluidsim$LIB_ENDING"
 COMPILE_FLAGS="-shared"
-INPUT_FILES="densitystep.o velocitystep.o chunkmask.o threadpool.o"
+INPUT_FILES="densitystep.o velocitystep.o chunkmask.o threadpool.o libfluidsim.o"
 gcc $COMPILE_FLAGS $INPUT_FILES -o $OUTPUT_FILE
 #move to resources
--- a/src/main/c/includes/electrosphere_FluidSim.h
+++ b/src/main/c/includes/electrosphere_FluidSim.h
@ -16,7 +16,7 @@ extern "C" {
 #undef electrosphere_FluidSim_LINEARSOLVERTIMES
 #define electrosphere_FluidSim_LINEARSOLVERTIMES 20L
 #undef electrosphere_FluidSim_GRAVITY
-#define electrosphere_FluidSim_GRAVITY -100.0f
+#define electrosphere_FluidSim_GRAVITY 0.0f
 /*
 * Class:     electrosphere_FluidSim
 * Method:    createThreadpool
--- a/src/main/c/includes/libfluidsim.h
+++ b/src/main/c/includes/libfluidsim.h
@ -2,5 +2,15 @@
 #ifndef LIB_FLUID_SIM
 #define LIB_FLUID_SIM
 #include "./threadpool.h"
 void simulate(LibraryContext * context, int threadIndex);
 void addDensity(int N, int chunk_mask, float * jrx, float * x0, float dt);
 void diffuseDensity(int N, int chunk_mask, float * jrx, float * jrx0, float DIFFUSION_CONST, float VISCOSITY_CONST, float dt);
 void advectDensity(uint32_t chunk_mask, int N, float * jrd, float * jrd0, float * u, float * v, float * w, float dt);
 //close include guard
 #endif
--- a/src/main/c/includes/threadpool.h
+++ b/src/main/c/includes/threadpool.h
@ -1,6 +1,8 @@
 #ifndef THREADPOOL
 #define THREADPOOL
 #include <pthread.h>
 /**
 * A threadpool used to distribute work
@ -18,6 +20,7 @@ typedef struct {
 */
 typedef struct {
    int chunkMask;
    float timestep;
    float * d;
    float * u;
    float * v;
@ -26,6 +29,8 @@ typedef struct {
    float * u0;
    float * v0;
    float * w0;
    float diffuseConst;
    float viscosityConst;
 } Chunk;
--- a/src/main/c/src/densitystep.c
+++ b/src/main/c/src/densitystep.c
@ -1,4 +1,3 @@
 #include <jni.h>
 #include <stdio.h>
 #include <immintrin.h>
 #include <stdint.h>
@ -7,53 +6,35 @@
 #include "../includes/utilities.h"
 #include "../includes/chunkmask.h"
 void advectDensity(JNIEnv * env, uint32_t chunk_mask, int N, int b, jobjectArray jrd, jobjectArray d0, float * u, float * v, float * w, float dt);
-/*
+void addDensity(
- * Class:     electrosphere_FluidSim
+  int N,
- * Method:    addDensity
+  int chunk_mask,
- * Signature: (II[Ljava/nio/ByteBuffer;Ljava/nio/ByteBuffer;F)V
+  float * x,
- */
+  float * s,
-JNIEXPORT void JNICALL Java_electrosphere_FluidSim_addDensity
+  float dt){
  (JNIEnv * env,
  jobject this,
  jint N,
  jint chunk_mask,
  jobjectArray jrx,
  jobjectArray x0,
  jfloat dt){
    int i;
    int size=N*N*N;
    float * x = GET_ARR(env,jrx,CENTER_LOC);
    float * s = GET_ARR(env,x0,CENTER_LOC);
    for(i=0; i<size; i++){
        x[i] += dt*s[i];
    }
 }
-/*
+
- * Class:     electrosphere_FluidSim
+void diffuseDensity(
- * Method:    solveDiffuseDensity
+  int N,
- * Signature: (II[Ljava/nio/ByteBuffer;Ljava/nio/ByteBuffer;[Ljava/nio/ByteBuffer;[Ljava/nio/ByteBuffer;[Ljava/nio/ByteBuffer;FFF)V
+  int chunk_mask,
- */
+  float * jrx,
-JNIEXPORT void JNICALL Java_electrosphere_FluidSim_solveDiffuseDensity
+  float * jrx0,
-  (JNIEnv * env,
+  float DIFFUSION_CONST,
-  jobject this,
+  float VISCOSITY_CONST,
-  jint N,
+  float dt){
  jint chunk_mask,
  jobjectArray jrx,
  jobjectArray jrx0,
  jobjectArray jru,
  jobjectArray jrv,
  jobjectArray jrw,
  jfloat DIFFUSION_CONST,
  jfloat VISCOSITY_CONST,
  jfloat dt){
    float a=dt*DIFFUSION_CONST*N*N*N;
    float c=1+6*a;
    int i, j, k, l, m;
-    float * x = GET_ARR(env,jrx,CENTER_LOC);
+    float * x = jrx;
-    float * x0 = GET_ARR(env,jrx0,CENTER_LOC);
+    float * x0 = jrx0;
    __m256 aScalar = _mm256_set1_ps(a);
    __m256 cScalar = _mm256_set1_ps(c);
@ -85,42 +66,21 @@ JNIEXPORT void JNICALL Java_electrosphere_FluidSim_solveDiffuseDensity
    }
 }
-/*
+void advectDensity(uint32_t chunk_mask, int N, float * jrd, float * jrd0, float * u, float * v, float * w, float dt){
 * Class:     electrosphere_FluidSim
 * Method:    advectDensity
 * Signature: (II[Ljava/nio/ByteBuffer;Ljava/nio/ByteBuffer;[Ljava/nio/ByteBuffer;[Ljava/nio/ByteBuffer;[Ljava/nio/ByteBuffer;FFF)V
 */
 JNIEXPORT void JNICALL Java_electrosphere_FluidSim_advectDensity
  (JNIEnv * env,
  jobject this,
  jint N,
  jint chunk_mask,
  jobjectArray jrx,
  jobjectArray jrx0,
  jobjectArray jru,
  jobjectArray jrv,
  jobjectArray jrw,
  jfloat DIFFUSION_CONST,
  jfloat VISCOSITY_CONST,
  jfloat dt){
    advectDensity(env,chunk_mask,N,3,jrx,jrx0,GET_ARR(env,jru,CENTER_LOC),GET_ARR(env,jrv,CENTER_LOC),GET_ARR(env,jrw,CENTER_LOC),dt);
 }
 void advectDensity(JNIEnv * env, uint32_t chunk_mask, int N, int b, jobjectArray jrd, jobjectArray jrd0, float * u, float * v, float * w, float dt){
    int i, j, k, i0, j0, k0, i1, j1, k1;
    int m,n,o;
    float x, y, z, s0, t0, s1, t1, u1, u0, dtx,dty,dtz;
    dtx=dty=dtz=dt*N;
-    float * d = GET_ARR(env,jrd,CENTER_LOC);
+    float * d = jrd;
-    float * d0 = GET_ARR(env,jrd0,CENTER_LOC);
+    float * d0 = jrd0;
    for(k=1; k<N-1; k++){
        for(j=1; j<N-1; j++){
            for(i=1; i<N-1; i++){
-                d0 = GET_ARR(env,jrd0,CENTER_LOC);
+                d0 = jrd0;
                //calculate location to pull from
                x = i-dtx*u[IX(i,j,k)];
                y = j-dty*v[IX(i,j,k)];
--- a/src/main/c/src/libfluidsim.c
+++ b/src/main/c/src/libfluidsim.c
@ -0,0 +1,77 @@
 #include <jni.h>
 #include <stdio.h>
 #include <immintrin.h>
 #include <stdint.h>
 #include <unistd.h>
 #include <pthread.h>
 #include <semaphore.h>
 //git libs
 #include "../lib/stb/stb_ds.h"
 //all other headers
 #include "../includes/libfluidsim.h"
 #include "../includes/threadpool.h"
 #include "../includes/chunkmask.h"
 #include "../includes/utilities.h"
 #define DIM 18
 #define LINEARSOLVERTIMES 20
 //call this if the child threads need to wait on one another
 void sync(LibraryContext * context){
    pthread_barrier_wait(context->threadpool->barrierMain);
 }
 /**
 * Main simulation function
 */
 void simulate(LibraryContext * context, int threadIndex){
    int numThreads = context->threadpool->numThreads;
    int numChunks = context->numChunks;
    //add densities to chunks
    for(int i = threadIndex; i < numChunks; i = i + numThreads){
        Chunk chunk = context->chunks[i];
        addDensity(DIM,chunk.chunkMask,chunk.d,chunk.d0,chunk.timestep);
    }
    sync(context);
    //diffuse density
    for(int l = 0; l < LINEARSOLVERTIMES; l++){
        for(int i = threadIndex; i < numChunks; i = i + numThreads){
            Chunk chunk = context->chunks[i];
            SWAP(chunk.d,chunk.d0);
            diffuseDensity(
                DIM,
                chunk.chunkMask,
                chunk.d,
                chunk.d0,
                chunk.diffuseConst,
                chunk.viscosityConst,
                chunk.timestep
            );
            SWAP(chunk.d,chunk.d0);
        }
        sync(context);
    }
    //advect density
    for(int i = threadIndex; i < numChunks; i = i + numThreads){
        Chunk chunk = context->chunks[i];
        advectDensity(
            chunk.chunkMask,
            DIM,
            chunk.d,
            chunk.d0,
            chunk.u,
            chunk.v,
            chunk.w,
            chunk.timestep
        );
    }
    //call this if the child threads need to wait on one another
    sync(context);
 }
--- a/src/main/c/src/threadpool.c
+++ b/src/main/c/src/threadpool.c
@ -17,7 +17,7 @@
 #include "../includes/utilities.h"
 typedef struct {
-  ThreadPool * threadPool;
+  LibraryContext * libraryContext;
  int threadIndex; //the index for this thread in all threadpool objects
 } ThreadData;
@ -39,6 +39,7 @@ JNIEXPORT jlong JNICALL Java_electrosphere_FluidSim_createThreadpool
  LibraryContext * libraryContext = (LibraryContext *)malloc(sizeof(LibraryContext));
  libraryContext->numChunks = 0;
  libraryContext->chunks = NULL; //must be tied to NULL at the start
  //init threadpool
  libraryContext->threadpool = (ThreadPool *)malloc(sizeof(ThreadPool));
@ -71,7 +72,7 @@ JNIEXPORT jlong JNICALL Java_electrosphere_FluidSim_createThreadpool
    //create data to be sent to thread
    ThreadData * threadData = (ThreadData *)malloc(sizeof(ThreadData));
-    threadData->threadPool = pool;
+    threadData->libraryContext = libraryContext;
    threadData->threadIndex = i;
    //create thread
@ -124,7 +125,6 @@ JNIEXPORT void JNICALL Java_electrosphere_FluidSim_queueChunk(
  //if the array is full, malloc a new chunk, otherwise overwrite an existing one
  int arrayCapacity = stbds_arrlen(libraryContext->chunks);
  if(libraryContext->numChunks >= arrayCapacity){
    printf("%d > %d\n",libraryContext->numChunks,arrayCapacity);
    Chunk * newChunk = (Chunk *)malloc(sizeof(Chunk));
    newChunk->chunkMask = chunkMask;
    newChunk->u = GET_ARR(env,ur,CENTER_LOC);
@ -134,8 +134,11 @@ JNIEXPORT void JNICALL Java_electrosphere_FluidSim_queueChunk(
    newChunk->v0 = GET_ARR(env,v0r,CENTER_LOC);
    newChunk->w0 = GET_ARR(env,w0r,CENTER_LOC);
    newChunk->d = GET_ARR(env,dr,CENTER_LOC);
    stbds_arrput(libraryContext->chunks,newChunk[0]);
    newChunk->d0 = GET_ARR(env,d0r,CENTER_LOC);
    newChunk->timestep = timestep;
    newChunk->diffuseConst = DIFFUSION_CONSTANT;
    newChunk->viscosityConst = VISCOSITY_CONSTANT;
    stbds_arrput(libraryContext->chunks,newChunk[0]);
  } else {
    Chunk * currentChunk = &libraryContext->chunks[libraryContext->numChunks];
    currentChunk->chunkMask = chunkMask;
@ -147,10 +150,12 @@ JNIEXPORT void JNICALL Java_electrosphere_FluidSim_queueChunk(
    currentChunk->w0 = GET_ARR(env,w0r,CENTER_LOC);
    currentChunk->d = GET_ARR(env,dr,CENTER_LOC);
    currentChunk->d0 = GET_ARR(env,d0r,CENTER_LOC);
    currentChunk->timestep = timestep;
    currentChunk->diffuseConst = DIFFUSION_CONSTANT;
    currentChunk->viscosityConst = VISCOSITY_CONSTANT;
  }
  libraryContext->numChunks++;
  // arrput(libraryContext->chunks,newChunk);
 }
 /*
@ -191,30 +196,26 @@ JNIEXPORT void JNICALL Java_electrosphere_FluidSim_fetchWork(
 */
 void * mainThreadLoop(void * dataRaw){
  ThreadData * threadData = (ThreadData *)dataRaw;
-  ThreadPool * threadPool = threadData->threadPool;
+  LibraryContext * libraryContext = threadData->libraryContext;
  int threadIndex = threadData->threadIndex;
  printf("thread work\n");
  //main thread loop
  int running = 1;
-  while(running){
+  while(running==1){
    //begin work
    //wait to begin work until parent signals its ready
-    pthread_barrier_wait(threadPool->barrierWithParentThread);
+    pthread_barrier_wait(libraryContext->threadpool->barrierWithParentThread);
    //do main work
-
+    simulate(libraryContext,threadData->threadIndex);
    //call this if the child threads need to wait on one another
    pthread_barrier_wait(threadPool->barrierMain);
    //finalize work
    //the parent thread needs to call the barrier as well with whatever method it uses to grab data from the sim back to java
-    pthread_barrier_wait(threadPool->barrierWithParentThread);
+    pthread_barrier_wait(libraryContext->threadpool->barrierWithParentThread);
  }
--- a/src/main/java/electrosphere/FluidSim.java
+++ b/src/main/java/electrosphere/FluidSim.java
@ -79,7 +79,8 @@ public class FluidSim {
    static final int LINEARSOLVERTIMES = 20;
-    static final float GRAVITY = -100f;
+    static final float GRAVITY = 0.0f;
    // static final float GRAVITY = -100f; //<-- original value
    public void setup(Vector3i offset){
        //allocate buffers for this chunk
@ -713,6 +714,162 @@ public class FluidSim {
    /**
     *  OLD NATIVE DECLARATIONS
     */
    // /**
    //  * The native function call to simulate a frame of fluid
    //  * @param DIM_X
    //  * @param DIM_Y
    //  * @param DIM_Z
    //  * @param x
    //  * @param x0
    //  * @param u
    //  * @param v
    //  * @param w
    //  * @param u0
    //  * @param v0
    //  * @param w0
    //  * @param DIFFUSION_CONSTANT
    //  * @param VISCOSITY_CONSTANT
    //  * @param timestep
    //  */
    // private native void simulate(
    //     int DIM_X,
    //     int chunkMask,
    //     ByteBuffer[] x,
    //     ByteBuffer x0,
    //     ByteBuffer[] u,
    //     ByteBuffer[] v,
    //     ByteBuffer[] w,
    //     ByteBuffer[] u0,
    //     ByteBuffer[] v0,
    //     ByteBuffer[] w0,
    //     float DIFFUSION_CONSTANT,
    //     float VISCOSITY_CONSTANT,
    //     float timestep
    // );
    // private void calculateChunkMaskWrapper(){
    //     this.chunkMask = this.calculateChunkMask(density);
    // }
    // /**
    //  * Calculates the mask of chunk neighbors
    //  * @param densityBuffers The neighbor array
    //  * @return The mask
    //  */
    // private native int calculateChunkMask(ByteBuffer[] densityBuffers);
    // /**
    //  * Add vector values to u, v, and w all at once
    //  */
    // private void addSourceToVectorsWrapper(float timestep){
    //     addSourceToVectors(DIM, chunkMask, uVector, vVector, wVector, uAdditionVector, vAdditionVector, wAdditionVector, DIFFUSION_CONSTANT, VISCOSITY_CONSTANT, timestep);
    // }
    // private native void addSourceToVectors(int DIM_X, int chunkMask, ByteBuffer[] u, ByteBuffer v[], ByteBuffer w[], ByteBuffer u0[], ByteBuffer v0[], ByteBuffer w0[], float DIFFUSION_CONSTANT, float VISCOSITY_CONSTANT, float timestep);
    // /**
    //  * Solves u, v, and w diffusion systems of equations
    //  */
    // private void solveVectorDiffuseWrapper(float timestep){
    //     solveVectorDiffuse(DIM, chunkMask, uVector, vVector, wVector, uAdditionVector, vAdditionVector, wAdditionVector, DIFFUSION_CONSTANT, VISCOSITY_CONSTANT, timestep);
    // }
    // private native void solveVectorDiffuse(int DIM_X, int chunkMask, ByteBuffer[] u, ByteBuffer v[], ByteBuffer w[], ByteBuffer u0[], ByteBuffer v0[], ByteBuffer w0[], float DIFFUSION_CONSTANT, float VISCOSITY_CONSTANT, float timestep);
    // /**
    //  * Setup projection system
    //  */
    // private void setupProjectionWrapper(float timestep){
    //     setupProjection(DIM, chunkMask, uVector, vVector, wVector, uAdditionVector, vAdditionVector, wAdditionVector, DIFFUSION_CONSTANT, VISCOSITY_CONSTANT, timestep);
    // }
    // private native void setupProjection(int DIM_X, int chunkMask, ByteBuffer[] u, ByteBuffer v[], ByteBuffer w[], ByteBuffer u0[], ByteBuffer v0[], ByteBuffer w0[], float DIFFUSION_CONSTANT, float VISCOSITY_CONSTANT, float timestep);
    // /**
    //  * Solve projection system
    //  */
    // private void solveProjectionWrapper(float timestep){
    //     solveProjection(DIM, chunkMask, uVector, vVector, wVector, uAdditionVector, vAdditionVector, wAdditionVector, DIFFUSION_CONSTANT, VISCOSITY_CONSTANT, timestep);
    // }
    // private native void solveProjection(int DIM_X, int chunkMask, ByteBuffer[] u, ByteBuffer v[], ByteBuffer w[], ByteBuffer u0[], ByteBuffer v0[], ByteBuffer w0[], float DIFFUSION_CONSTANT, float VISCOSITY_CONSTANT, float timestep);
    // /**
    //  * Does work like subtracting curl from vector field, setting boundaries, etc
    //  */
    // private void finalizeProjectionWrapper(float timestep){
    //     finalizeProjection(DIM, chunkMask, uVector, vVector, wVector, uAdditionVector, vAdditionVector, wAdditionVector, DIFFUSION_CONSTANT, VISCOSITY_CONSTANT, timestep);
    // }
    // private native void finalizeProjection(int DIM_X, int chunkMask, ByteBuffer[] u, ByteBuffer v[], ByteBuffer w[], ByteBuffer u0[], ByteBuffer v0[], ByteBuffer w0[], float DIFFUSION_CONSTANT, float VISCOSITY_CONSTANT, float timestep);
    // /**
    //  * Advects vectors
    //  */
    // private void advectVectorsWrapper(float timestep){
    //     advectVectors(DIM, chunkMask, uVector, vVector, wVector, uAdditionVector, vAdditionVector, wAdditionVector, DIFFUSION_CONSTANT, VISCOSITY_CONSTANT, timestep);
    // }
    // private native void advectVectors(int DIM_X, int chunkMask, ByteBuffer[] u, ByteBuffer v[], ByteBuffer w[], ByteBuffer u0[], ByteBuffer v0[], ByteBuffer w0[], float DIFFUSION_CONSTANT, float VISCOSITY_CONSTANT, float timestep);
    // /**
    //  * Adds density to the simulation
    //  */
    // private void addDensityWrapper(float timestep){
    //     addDensity(DIM, chunkMask, density, densityAddition, timestep);
    // }
    // private native void addDensity(int DIM_X, int chunkMask, ByteBuffer[] x, ByteBuffer[] x0, float timestep);
    // /**
    //  * Solve density diffusion
    //  */
    // private void solveDiffuseDensityWrapper(float timestep){
    //     solveDiffuseDensity(DIM, chunkMask, density, densityAddition, uVector, vVector, wVector, DIFFUSION_CONSTANT, VISCOSITY_CONSTANT, timestep);
    // }
    // private native void solveDiffuseDensity(int DIM_X, int chunkMask, ByteBuffer[] x, ByteBuffer[] x0, ByteBuffer[] u, ByteBuffer v[], ByteBuffer w[], float DIFFUSION_CONSTANT, float VISCOSITY_CONSTANT, float timestep);
    // /**
    //  * Solve density diffusion
    //  */
    // private void advectDensityWrapper(float timestep){
    //     advectDensity(DIM, chunkMask, density, densityAddition, uVector, vVector, wVector, DIFFUSION_CONSTANT, VISCOSITY_CONSTANT, timestep);
    // }
    // private native void advectDensity(int DIM_X, int chunkMask, ByteBuffer[] x, ByteBuffer[] x0, ByteBuffer[] u, ByteBuffer v[], ByteBuffer w[], float DIFFUSION_CONSTANT, float VISCOSITY_CONSTANT, float timestep);
    // /**
    //  * Sets the bounds of the neighbormap to neighbor values if available
    //  */
    // private void setBoundsToNeighborsWrapper(int vectorDir, ByteBuffer[] neighborMap){
    //     setBoundsToNeighbors(DIM, chunkMask, vectorDir, neighborMap);
    // }
    // private native void setBoundsToNeighbors(int DIM_X, int chunkMask, int vectorDir, ByteBuffer[] neighborMap);
    // /**
    //  * Sets the bounds of the neighbormap to neighbor values if available, otherwise doesn't mess with them.
    //  * This is to make sure zeroing out doesn't mess up the sim
    //  */
    // private void copyNeighborsWrapper(int vectorDir, int x, ByteBuffer[] neighborMap){
    //     copyNeighbors(DIM, chunkMask, x, vectorDir, neighborMap);
    // }
    // private native void copyNeighbors(int DIM_X, int chunkMask, int x, int vectorDir, ByteBuffer[] neighborMap);
@ -957,7 +1114,7 @@ public class FluidSim {
                for(int k = 0; k < DIM; k++){
                    index = ((i)+(DIM)*(j) + (DIM)*(DIM)*(k));
                    u0ArrayView[index] = 0;
-                    v0ArrayView[index] = densityArrayView[index] * GRAVITY;
+                    v0ArrayView[index] = 0;
                    w0ArrayView[index] = 0;
                }
            }
--- a/src/main/java/electrosphere/Main.java
+++ b/src/main/java/electrosphere/Main.java
@ -56,7 +56,7 @@ public class Main {
                //Simulate
                //
                FluidSim.unlockThreadsWrapper();
-                FluidSim.simChunks(simArray,i,0.01f);
+                FluidSim.simChunks(simArray,i,0.0001f);
                FluidSim.unlockThreadsWrapper();
                time = time + (System.currentTimeMillis() - lastTime);
                //