/* WaveGRU: > Embed > GRU > O1 > O2 > Sampling > ... */ #include #include #include #include #include #include #include "sparse_matmul/sparse_matmul.h" namespace py = pybind11; using namespace std; using fvec = std::vector; using ivec = std::vector; using fndarray = py::array_t; using indarray = py::array_t; using mat = csrblocksparse::CsrBlockSparseMatrix; using vec = csrblocksparse::CacheAlignedVector; using masked_mat = csrblocksparse::MaskedSparseMatrix; mat create_mat(int h, int w) { auto m = masked_mat(w, h, 0.90, 4, 4, 0.0, true); auto a = mat(m); return a; } struct WaveGRU { int hidden_dim; int repeat_factor; mat m; vec b; vec z, r, hh, zrh; vec fco1, fco2; vec o1b, o2b; vec t; vec h; vec logits; mat o1, o2; std::vector embed; WaveGRU(int hidden_dim, int repeat_factor) : hidden_dim(hidden_dim), repeat_factor(repeat_factor), b(3*hidden_dim), t(3*hidden_dim), zrh(3*hidden_dim), z(hidden_dim), r(hidden_dim), hh(hidden_dim), fco1(hidden_dim), fco2(256), h(hidden_dim), o1b(hidden_dim), o2b(256), logits(256) { m = create_mat(hidden_dim, 3*hidden_dim); o1 = create_mat(hidden_dim, hidden_dim); o2 = create_mat(hidden_dim, 256); embed = std::vector(); for (int i = 0; i < 256; i++) { embed.emplace_back(hidden_dim * 3); embed[i].FillRandom(); } } void load_embed(fndarray embed_weights) { auto a_embed = embed_weights.unchecked<2>(); for (int i = 0; i < 256; i++) { for (int j = 0; j < hidden_dim * 3; j++) embed[i][j] = a_embed(i, j); } } mat load_linear(vec& bias, fndarray w, indarray mask, fndarray b) { auto w_ptr = static_cast(w.request().ptr); auto mask_ptr = static_cast(mask.request().ptr); auto rb = b.unchecked<1>(); // load bias, scale by 1/4 for (int i = 0; i < rb.shape(0); i++) bias[i] = rb(i) / 4; // load weights masked_mat mm(w.shape(0), w.shape(1), mask_ptr, w_ptr); mat mmm(mm); return mmm; } void load_weights(fndarray m, indarray m_mask, fndarray b, fndarray o1, indarray o1_mask, fndarray o1b, fndarray o2, indarray o2_mask, fndarray o2b) { this->m = load_linear(this->b, m, m_mask, b); this->o1 = load_linear(this->o1b, o1, o1_mask, o1b); this->o2 = load_linear(this->o2b, o2, o2_mask, o2b); } std::vector inference(fndarray ft, float temperature) { auto rft = ft.unchecked<2>(); int value = 127; std::vector signal(rft.shape(0) * repeat_factor); h.FillZero(); for (int index = 0; index < signal.size(); index++) { m.SpMM_bias(h, b, &zrh, false); for (int i = 0; i < 3 * hidden_dim; i++) t[i] = embed[value][i] + rft(index / repeat_factor, i); for (int i = 0; i < hidden_dim; i++) { z[i] = zrh[i] + t[i]; r[i] = zrh[hidden_dim + i] + t[hidden_dim + i]; } z.Sigmoid(); r.Sigmoid(); for (int i = 0; i < hidden_dim; i++) { hh[i] = zrh[hidden_dim * 2 + i] * r[i] + t[hidden_dim * 2 + i]; } hh.Tanh(); for (int i = 0; i < hidden_dim; i++) { h[i] = (1. - z[i]) * h[i] + z[i] * hh[i]; } o1.SpMM_bias(h, o1b, &fco1, true); o2.SpMM_bias(fco1, o2b, &fco2, false); // auto max_logit = fco2[0]; // for (int i = 1; i <= 255; ++i) { // max_logit = max(max_logit, fco2[i]); // } // float total = 0.0; // for (int i = 0; i <= 255; ++i) { // logits[i] = csrblocksparse::fast_exp(fco2[i] - max_logit); // total += logits[i]; // } // for (int i = 0; i <= 255; ++i) { // if (logits[i] < total / 1024.0) fco2[i] = -1e9; // } value = fco2.Sample(temperature); signal[index] = value; } return signal; } }; PYBIND11_MODULE(wavegru_mod, m) { py::class_(m, "WaveGRU") .def(py::init()) .def("load_embed", &WaveGRU::load_embed) .def("load_weights", &WaveGRU::load_weights) .def("inference", &WaveGRU::inference); }