benchmarks/GPU/bench_gpu_chaining.cpp

// GPU chaining benchmarks: measure async pipeline efficiency.
//
// Compares:
//   1. Host round-trip per solve (baseline)
//   2. DeviceMatrix chaining (no host round-trip between solves)
//   3. Varying chain lengths (1, 2, 4, 8 consecutive solves)
//
// For Nsight Systems: look for gaps between kernel launches in the timeline.
// Host round-trip creates visible idle gaps; chaining should show back-to-back kernels.
//
//   nsys profile --trace=cuda,nvtx ./bench_gpu_chaining

#include <benchmark/benchmark.h>

#include <Eigen/Cholesky>
#include <Eigen/GPU>

using namespace Eigen;

#ifndef SCALAR
#define SCALAR double
#endif

using Scalar = SCALAR;
using Mat = Matrix<Scalar, Dynamic, Dynamic>;

static Mat make_spd(Index n) {
  Mat M = Mat::Random(n, n);
  return M.adjoint() * M + Mat::Identity(n, n) * static_cast<Scalar>(n);
}

static void cuda_warmup() {
  static bool done = false;
  if (!done) {
    void* p;
    cudaMalloc(&p, 1);
    cudaFree(p);
    done = true;
  }
}

// --------------------------------------------------------------------------
// Baseline: host round-trip between every solve
// --------------------------------------------------------------------------

static void BM_Chain_HostRoundtrip(benchmark::State& state) {
  cuda_warmup();
  const Index n = state.range(0);
  const int chain_len = static_cast<int>(state.range(1));

  Mat A = make_spd(n);
  Mat B = Mat::Random(n, 1);
  GpuLLT<Scalar> llt(A);

  for (auto _ : state) {
    Mat X = B;
    for (int i = 0; i < chain_len; ++i) {
      X = llt.solve(X);  // host → device → host each time
    }
    benchmark::DoNotOptimize(X.data());
  }

  state.counters["n"] = n;
  state.counters["chain"] = chain_len;
  state.counters["solves/iter"] = chain_len;
}

// --------------------------------------------------------------------------
// DeviceMatrix chaining: no host round-trip between solves
// --------------------------------------------------------------------------

static void BM_Chain_Device(benchmark::State& state) {
  cuda_warmup();
  const Index n = state.range(0);
  const int chain_len = static_cast<int>(state.range(1));

  Mat A = make_spd(n);
  Mat B = Mat::Random(n, 1);
  GpuLLT<Scalar> llt(A);
  auto d_B = DeviceMatrix<Scalar>::fromHost(B);

  for (auto _ : state) {
    DeviceMatrix<Scalar> d_X = llt.solve(d_B);
    for (int i = 1; i < chain_len; ++i) {
      d_X = llt.solve(d_X);  // device → device, fully async
    }
    Mat X = d_X.toHost();  // single sync at end
    benchmark::DoNotOptimize(X.data());
  }

  state.counters["n"] = n;
  state.counters["chain"] = chain_len;
  state.counters["solves/iter"] = chain_len;
}

// --------------------------------------------------------------------------
// DeviceMatrix chaining with async download (overlap D2H with next iteration)
// --------------------------------------------------------------------------

static void BM_Chain_DeviceAsync(benchmark::State& state) {
  cuda_warmup();
  const Index n = state.range(0);
  const int chain_len = static_cast<int>(state.range(1));

  Mat A = make_spd(n);
  Mat B = Mat::Random(n, 1);
  GpuLLT<Scalar> llt(A);
  auto d_B = DeviceMatrix<Scalar>::fromHost(B);

  for (auto _ : state) {
    DeviceMatrix<Scalar> d_X = llt.solve(d_B);
    for (int i = 1; i < chain_len; ++i) {
      d_X = llt.solve(d_X);
    }
    auto transfer = d_X.toHostAsync();
    Mat X = transfer.get();
    benchmark::DoNotOptimize(X.data());
  }

  state.counters["n"] = n;
  state.counters["chain"] = chain_len;
  state.counters["solves/iter"] = chain_len;
}

// --------------------------------------------------------------------------
// Pure GPU chain (no download — measures kernel-only throughput)
// --------------------------------------------------------------------------

static void BM_Chain_DeviceNoDownload(benchmark::State& state) {
  cuda_warmup();
  const Index n = state.range(0);
  const int chain_len = static_cast<int>(state.range(1));

  Mat A = make_spd(n);
  Mat B = Mat::Random(n, 1);
  GpuLLT<Scalar> llt(A);
  auto d_B = DeviceMatrix<Scalar>::fromHost(B);

  for (auto _ : state) {
    DeviceMatrix<Scalar> d_X = llt.solve(d_B);
    for (int i = 1; i < chain_len; ++i) {
      d_X = llt.solve(d_X);
    }
    cudaStreamSynchronize(llt.stream());
    benchmark::DoNotOptimize(d_X.data());
  }

  state.counters["n"] = n;
  state.counters["chain"] = chain_len;
  state.counters["solves/iter"] = chain_len;
}

// --------------------------------------------------------------------------
// Compute + solve chain (full pipeline: factorize, then chain solves)
// --------------------------------------------------------------------------

static void BM_FullPipeline_Host(benchmark::State& state) {
  cuda_warmup();
  const Index n = state.range(0);
  const int chain_len = static_cast<int>(state.range(1));

  Mat A = make_spd(n);
  Mat B = Mat::Random(n, 1);

  for (auto _ : state) {
    GpuLLT<Scalar> llt(A);
    Mat X = B;
    for (int i = 0; i < chain_len; ++i) {
      X = llt.solve(X);
    }
    benchmark::DoNotOptimize(X.data());
  }

  state.counters["n"] = n;
  state.counters["chain"] = chain_len;
}

static void BM_FullPipeline_Device(benchmark::State& state) {
  cuda_warmup();
  const Index n = state.range(0);
  const int chain_len = static_cast<int>(state.range(1));

  Mat A = make_spd(n);
  Mat B = Mat::Random(n, 1);

  for (auto _ : state) {
    auto d_A = DeviceMatrix<Scalar>::fromHost(A);
    auto d_B = DeviceMatrix<Scalar>::fromHost(B);
    GpuLLT<Scalar> llt;
    llt.compute(d_A);
    DeviceMatrix<Scalar> d_X = llt.solve(d_B);
    for (int i = 1; i < chain_len; ++i) {
      d_X = llt.solve(d_X);
    }
    Mat X = d_X.toHost();
    benchmark::DoNotOptimize(X.data());
  }

  state.counters["n"] = n;
  state.counters["chain"] = chain_len;
}

// --------------------------------------------------------------------------
// Registration
// --------------------------------------------------------------------------

// clang-format off
// Args: {matrix_size, chain_length}
BENCHMARK(BM_Chain_HostRoundtrip)->ArgsProduct({{64, 256, 1024, 4096}, {1, 2, 4, 8}})->Unit(benchmark::kMicrosecond);
BENCHMARK(BM_Chain_Device)->ArgsProduct({{64, 256, 1024, 4096}, {1, 2, 4, 8}})->Unit(benchmark::kMicrosecond);
BENCHMARK(BM_Chain_DeviceAsync)->ArgsProduct({{64, 256, 1024, 4096}, {1, 2, 4, 8}})->Unit(benchmark::kMicrosecond);
BENCHMARK(BM_Chain_DeviceNoDownload)->ArgsProduct({{64, 256, 1024, 4096}, {1, 2, 4, 8}})->Unit(benchmark::kMicrosecond);

BENCHMARK(BM_FullPipeline_Host)->ArgsProduct({{256, 1024, 4096}, {1, 4}})->Unit(benchmark::kMicrosecond);
BENCHMARK(BM_FullPipeline_Device)->ArgsProduct({{256, 1024, 4096}, {1, 4}})->Unit(benchmark::kMicrosecond);
// clang-format on
GPU: Add library dispatch module (DeviceMatrix, cuBLAS, cuSOLVER) Add Eigen/GPU module: A standalone GPU library dispatch layer where DeviceMatrix<Scalar> operations map 1:1 to cuBLAS/cuSOLVER calls. CPU and GPU solvers coexist in the same binary with compatible syntax. Core infrastructure: - DeviceMatrix<Scalar>: RAII dense column-major GPU memory wrapper with async host transfer (fromHost/toHost) and CUDA event-based cross-stream synchronization. - GpuContext: Unified execution context owning a CUDA stream + cuBLAS handle + cuSOLVER handle. Thread-local default with explicit override via setThreadLocal(). Stream-borrowing constructor for integration. - DeviceBuffer: Typed RAII device allocation with move semantics. cuBLAS dispatch (expression syntax): - GEMM: d_C = d_A.adjoint() * d_B (cublasXgemm) - TRSM: d_X = d_A.triangularView<Lower>().solve(d_B) (cublasXtrsm) - SYMM/HEMM: d_C = d_A.selfadjointView<Lower>() * d_B (cublasXsymm) - SYRK/HERK: d_C = d_A * d_A.adjoint() (cublasXsyrk) cuSOLVER dispatch: - GpuLLT: Cached Cholesky factorization (cusolverDnXpotrf + Xpotrs) - GpuLU: Cached LU factorization (cusolverDnXgetrf + Xgetrs) - Solver chaining: auto x = d_A.llt().solve(d_B) - Solver expressions with .device(ctx) for explicit stream control. CI: Bump CUDA container to Ubuntu 22.04 (CMake 3.22), GCC 10->11, Clang 12->14. Bump cmake_minimum_required to 3.17 for FindCUDAToolkit. Tests: gpu_cublas.cpp, gpu_cusolver_llt.cpp, gpu_cusolver_lu.cpp, gpu_device_matrix.cpp, gpu_library_example.cu Benchmarks: bench_gpu_solvers.cpp, bench_gpu_chaining.cpp, bench_gpu_batching.cpp 2026-04-09 16:15:39 -07:00			`// GPU chaining benchmarks: measure async pipeline efficiency.`
			`//`
			`// Compares:`
			`// 1. Host round-trip per solve (baseline)`
			`// 2. DeviceMatrix chaining (no host round-trip between solves)`
			`// 3. Varying chain lengths (1, 2, 4, 8 consecutive solves)`
			`//`
			`// For Nsight Systems: look for gaps between kernel launches in the timeline.`
			`// Host round-trip creates visible idle gaps; chaining should show back-to-back kernels.`
			`//`
			`// nsys profile --trace=cuda,nvtx ./bench_gpu_chaining`

			`#include <benchmark/benchmark.h>`

			`#include <Eigen/Cholesky>`
			`#include <Eigen/GPU>`

			`using namespace Eigen;`

			`#ifndef SCALAR`
			`#define SCALAR double`
			`#endif`

			`using Scalar = SCALAR;`
			`using Mat = Matrix<Scalar, Dynamic, Dynamic>;`

			`static Mat make_spd(Index n) {`
			`Mat M = Mat::Random(n, n);`
			`return M.adjoint() * M + Mat::Identity(n, n) * static_cast<Scalar>(n);`
			`}`

			`static void cuda_warmup() {`
			`static bool done = false;`
			`if (!done) {`
			`void* p;`
			`cudaMalloc(&p, 1);`
			`cudaFree(p);`
			`done = true;`
			`}`
			`}`

			`// --------------------------------------------------------------------------`
			`// Baseline: host round-trip between every solve`
			`// --------------------------------------------------------------------------`

			`static void BM_Chain_HostRoundtrip(benchmark::State& state) {`
			`cuda_warmup();`
			`const Index n = state.range(0);`
			`const int chain_len = static_cast<int>(state.range(1));`

			`Mat A = make_spd(n);`
			`Mat B = Mat::Random(n, 1);`
			`GpuLLT<Scalar> llt(A);`

			`for (auto _ : state) {`
			`Mat X = B;`
			`for (int i = 0; i < chain_len; ++i) {`
			`X = llt.solve(X); // host → device → host each time`
			`}`
			`benchmark::DoNotOptimize(X.data());`
			`}`

			`state.counters["n"] = n;`
			`state.counters["chain"] = chain_len;`
			`state.counters["solves/iter"] = chain_len;`
			`}`

			`// --------------------------------------------------------------------------`
			`// DeviceMatrix chaining: no host round-trip between solves`
			`// --------------------------------------------------------------------------`

			`static void BM_Chain_Device(benchmark::State& state) {`
			`cuda_warmup();`
			`const Index n = state.range(0);`
			`const int chain_len = static_cast<int>(state.range(1));`

			`Mat A = make_spd(n);`
			`Mat B = Mat::Random(n, 1);`
			`GpuLLT<Scalar> llt(A);`
			`auto d_B = DeviceMatrix<Scalar>::fromHost(B);`

			`for (auto _ : state) {`
			`DeviceMatrix<Scalar> d_X = llt.solve(d_B);`
			`for (int i = 1; i < chain_len; ++i) {`
			`d_X = llt.solve(d_X); // device → device, fully async`
			`}`
			`Mat X = d_X.toHost(); // single sync at end`
			`benchmark::DoNotOptimize(X.data());`
			`}`

			`state.counters["n"] = n;`
			`state.counters["chain"] = chain_len;`
			`state.counters["solves/iter"] = chain_len;`
			`}`

			`// --------------------------------------------------------------------------`
			`// DeviceMatrix chaining with async download (overlap D2H with next iteration)`
			`// --------------------------------------------------------------------------`

			`static void BM_Chain_DeviceAsync(benchmark::State& state) {`
			`cuda_warmup();`
			`const Index n = state.range(0);`
			`const int chain_len = static_cast<int>(state.range(1));`

			`Mat A = make_spd(n);`
			`Mat B = Mat::Random(n, 1);`
			`GpuLLT<Scalar> llt(A);`
			`auto d_B = DeviceMatrix<Scalar>::fromHost(B);`

			`for (auto _ : state) {`
			`DeviceMatrix<Scalar> d_X = llt.solve(d_B);`
			`for (int i = 1; i < chain_len; ++i) {`
			`d_X = llt.solve(d_X);`
			`}`
			`auto transfer = d_X.toHostAsync();`
			`Mat X = transfer.get();`
			`benchmark::DoNotOptimize(X.data());`
			`}`

			`state.counters["n"] = n;`
			`state.counters["chain"] = chain_len;`
			`state.counters["solves/iter"] = chain_len;`
			`}`

			`// --------------------------------------------------------------------------`
			`// Pure GPU chain (no download — measures kernel-only throughput)`
			`// --------------------------------------------------------------------------`

			`static void BM_Chain_DeviceNoDownload(benchmark::State& state) {`
			`cuda_warmup();`
			`const Index n = state.range(0);`
			`const int chain_len = static_cast<int>(state.range(1));`

			`Mat A = make_spd(n);`
			`Mat B = Mat::Random(n, 1);`
			`GpuLLT<Scalar> llt(A);`
			`auto d_B = DeviceMatrix<Scalar>::fromHost(B);`

			`for (auto _ : state) {`
			`DeviceMatrix<Scalar> d_X = llt.solve(d_B);`
			`for (int i = 1; i < chain_len; ++i) {`
			`d_X = llt.solve(d_X);`
			`}`
			`cudaStreamSynchronize(llt.stream());`
			`benchmark::DoNotOptimize(d_X.data());`
			`}`

			`state.counters["n"] = n;`
			`state.counters["chain"] = chain_len;`
			`state.counters["solves/iter"] = chain_len;`
			`}`

			`// --------------------------------------------------------------------------`
			`// Compute + solve chain (full pipeline: factorize, then chain solves)`
			`// --------------------------------------------------------------------------`

			`static void BM_FullPipeline_Host(benchmark::State& state) {`
			`cuda_warmup();`
			`const Index n = state.range(0);`
			`const int chain_len = static_cast<int>(state.range(1));`

			`Mat A = make_spd(n);`
			`Mat B = Mat::Random(n, 1);`

			`for (auto _ : state) {`
			`GpuLLT<Scalar> llt(A);`
			`Mat X = B;`
			`for (int i = 0; i < chain_len; ++i) {`
			`X = llt.solve(X);`
			`}`
			`benchmark::DoNotOptimize(X.data());`
			`}`

			`state.counters["n"] = n;`
			`state.counters["chain"] = chain_len;`
			`}`

			`static void BM_FullPipeline_Device(benchmark::State& state) {`
			`cuda_warmup();`
			`const Index n = state.range(0);`
			`const int chain_len = static_cast<int>(state.range(1));`

			`Mat A = make_spd(n);`
			`Mat B = Mat::Random(n, 1);`

			`for (auto _ : state) {`
			`auto d_A = DeviceMatrix<Scalar>::fromHost(A);`
			`auto d_B = DeviceMatrix<Scalar>::fromHost(B);`
			`GpuLLT<Scalar> llt;`
			`llt.compute(d_A);`
			`DeviceMatrix<Scalar> d_X = llt.solve(d_B);`
			`for (int i = 1; i < chain_len; ++i) {`
			`d_X = llt.solve(d_X);`
			`}`
			`Mat X = d_X.toHost();`
			`benchmark::DoNotOptimize(X.data());`
			`}`

			`state.counters["n"] = n;`
			`state.counters["chain"] = chain_len;`
			`}`

			`// --------------------------------------------------------------------------`
			`// Registration`
			`// --------------------------------------------------------------------------`

			`// clang-format off`
			`// Args: {matrix_size, chain_length}`
			`BENCHMARK(BM_Chain_HostRoundtrip)->ArgsProduct({{64, 256, 1024, 4096}, {1, 2, 4, 8}})->Unit(benchmark::kMicrosecond);`
			`BENCHMARK(BM_Chain_Device)->ArgsProduct({{64, 256, 1024, 4096}, {1, 2, 4, 8}})->Unit(benchmark::kMicrosecond);`
			`BENCHMARK(BM_Chain_DeviceAsync)->ArgsProduct({{64, 256, 1024, 4096}, {1, 2, 4, 8}})->Unit(benchmark::kMicrosecond);`
			`BENCHMARK(BM_Chain_DeviceNoDownload)->ArgsProduct({{64, 256, 1024, 4096}, {1, 2, 4, 8}})->Unit(benchmark::kMicrosecond);`

			`BENCHMARK(BM_FullPipeline_Host)->ArgsProduct({{256, 1024, 4096}, {1, 4}})->Unit(benchmark::kMicrosecond);`
			`BENCHMARK(BM_FullPipeline_Device)->ArgsProduct({{256, 1024, 4096}, {1, 4}})->Unit(benchmark::kMicrosecond);`
			`// clang-format on`