#include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "../lodepng.h" extern "C" { #include "aberth_kernel.h" } using namespace std; constexpr const int N = 18; using Com = complex; using Poly = array; using AApprox = array; template constexpr static T clearLowestBit(T value) { return value & (value - 1); } template constexpr static bool ispow2(T value) { return clearLowestBit(value) == 0; } template constexpr static T ceil2(T value) { T value2 = clearLowestBit(value); if (value2 == 0) return value; while (true) { value = value2; value2 = clearLowestBit(value); if (value2 == 0) return value << 1; } } __attribute__((unused)) static ostream& operator<<(ostream &os, const Poly &p) { static const char *supers[10] = { "⁰", "¹", "²", "³", "⁴", "⁵", "⁶", "⁷", "⁸", "⁹" }; os << p[0]; for (int i = 1; i < (int)p.size(); i++) { if (p[i] < 0) os << " - " << -p[i]; else if (p[i] > 0) os << " + " << p[i]; else continue; os << "x"; if (i == 1) continue; ostringstream ss; ss << i; string s = ss.str(); for (char c : s) os << supers[c - '0']; } return os; } template static T eval(const Poly &p, int nterms, T pt) { T value = p[nterms - 1]; for (int i = nterms - 2; i >= 0; i--) { value = pt * value + (double)p[i]; } return value; } template static T eval(const Poly &p, T pt) { return eval(p, p.size(), pt); } static Poly derivative(const Poly &p) { Poly res; for (int i = res.size() - 2; i >= 0; i--) { res[i] = (i+1) * p[i+1]; } return res; } static double maxRootNorm(const Poly &poly) { // Cauchy's bound: https://en.wikipedia.org/wiki/Geometrical_properties_of_polynomial_roots#Lagrange's_and_Cauchy's_bounds double value = 0; double last = (double)poly.back(); for (int i = 0; i < (int)poly.size() - 1; i++) { value = max(value, abs(poly[i] / last)); } return 1 + value; } static thread_local minstd_rand randgenerator = minstd_rand(random_device()()); struct AberthState { const Poly &poly; Poly deriv; Poly boundPoly; AApprox approx; double radius; void regenerate() { auto genCoord = [this]() { return uniform_real_distribution(-radius, radius)(randgenerator); }; for (int i = 0; i < N; i++) { approx[i] = Com(genCoord(), genCoord()); } } // boundPoly is 's' in the stop condition formulated at p.189-190 of // https://link.springer.com/article/10.1007%2FBF02207694 AberthState(const Poly &poly) : poly(poly), deriv(derivative(poly)), radius(maxRootNorm(poly)) { regenerate(); for (int i = 0; i <= N; i++) { boundPoly[i] = abs(poly[i]) * (4 * i + 1); } } // Lagrange-style step where the new elements are computed in parallel from the previous values bool step() { array pairs; for (int i = 0; i < N - 1; i++) { for (int j = i + 1; j < N; j++) { pairs[N * i + j] = 1.0 / (approx[i] - approx[j]); } } bool allConverged = true; AApprox newapprox; AApprox offsets; for (int i = 0; i < N; i++) { Com pval = eval(poly, approx[i]); Com derivval = eval(deriv, poly.size() - 1, approx[i]); Com quo = pval / derivval; Com sum = 0; for (int j = 0; j < i; j++) sum -= pairs[N * j + i]; for (int j = i + 1; j < N; j++) sum += pairs[N * i + j]; offsets[i] = quo / (1.0 - quo * sum); // approx[i] -= offsets[i]; newapprox[i] = approx[i] - offsets[i]; double sval = eval(boundPoly, abs(newapprox[i])); if (abs(pval) > 1e-9 * sval) allConverged = false; } approx = newapprox; return allConverged; } void iterate() { int tries = 1, stepIdx = 1; while (!step()) { stepIdx++; if (stepIdx > tries * 100) { regenerate(); stepIdx = 0; tries++; } } } }; static AApprox aberth(const Poly &poly) { AberthState state(poly); state.iterate(); return state.approx; } // Set the constant coefficient to 1; nextDerbyshire will never change it static Poly initDerbyshire() { Poly poly; poly[0] = 1; fill(poly.begin() + 1, poly.end(), -1); return poly; } // Returns whether we just looped around static bool nextDerbyshire(Poly &poly) { for (int i = 1; i < (int)poly.size(); i++) { if (poly[i] == -1) { poly[i] = 1; return false; } poly[i] = -1; } return true; } static Poly derbyshireAtIndex(int index) { Poly poly; poly[0] = 1; for (int i = 1; i <= N; i++) { poly[i] = index & 1 ? 1 : -1; index >>= 1; } assert(index == 0); return poly; } struct Job { Poly init; int numItems; }; static vector derbyshireJobs(int targetJobs) { int njobs = min(1 << N, ceil2(targetJobs)); int jobsize = (1 << N) / njobs; vector jobs(njobs); for (int i = 0; i < njobs; i++) { jobs[i].init = derbyshireAtIndex(i * jobsize); jobs[i].numItems = jobsize; } return jobs; } static tuple> computeCounts() { constexpr const int W = 900; constexpr const int H = 900; constexpr const int numThreads = 4; static_assert(ispow2(numThreads)); constexpr const Com bottomLeft = Com(-1.5, -1.5); constexpr const Com topRight = Com(1.5, 1.5); vector counts(W * H); mutex countsMutex; vector jobs = derbyshireJobs(numThreads); assert(jobs.size() == numThreads); vector threads(jobs.size()); for (int i = 0; i < (int)jobs.size(); i++) { threads[i] = thread([&counts, &countsMutex, job = jobs[i], bottomLeft, topRight]() { auto calcIndex = [](double value, double left, double right, int steps) -> int { return (value - left) / (right - left) * (steps - 1) + 0.5; }; auto calcPos = [bottomLeft, topRight, &calcIndex](Com z) -> pair { return make_pair( calcIndex(z.real(), bottomLeft.real(), topRight.real(), W), calcIndex(z.imag(), bottomLeft.imag(), topRight.imag(), H) ); }; vector localCounts(W * H); Poly poly = job.init; for (int i = 0; i < job.numItems; i++) { for (Com z : aberth(poly)) { int x, y; tie(x, y) = calcPos(z); if (0 <= x && x < W && 0 <= y && y < H) { localCounts[W * y + x]++; } } nextDerbyshire(poly); } lock_guard guard(countsMutex); for (int i = 0; i < W * H; i++) counts[i] += localCounts[i]; }); } for (thread &th : threads) th.join(); return make_tuple(W, H, counts); } static void writeCounts(int W, int H, const vector &counts, const char *fname) { ofstream f(fname); f << W << ' ' << H << '\n'; for (int y = 0; y < H; y++) { for (int x = 0; x < W; x++) { if (x != 0) f << ' '; f << counts[W * y + x]; } f << '\n'; } } static tuple> readCounts(const char *fname) { ifstream f(fname); int W, H; f >> W >> H; vector counts(W * H); for (int &v : counts) f >> v; return make_tuple(W, H, counts); } static int rankCounts(vector &counts) { int maxcount = 0; for (int i = 0; i < (int)counts.size(); i++) { maxcount = max(maxcount, counts[i]); } vector cumul(maxcount + 1, 0); for (int v : counts) cumul[v]++; cumul[0] = 0; for (int i = 1; i < (int)cumul.size(); i++) cumul[i] += cumul[i-1]; // assert(cumul[maxcount + 1] == (int)counts.size()); for (int &v : counts) v = cumul[v]; return cumul[maxcount]; } static vector drawImage(int W, int H, const vector &counts, int maxcount) { vector image(3 * W * H); for (int y = 0; y < H; y++) { for (int x = 0; x < W; x++) { double value = (double)counts[W * y + x] / maxcount * 255; image[3 * (W * y + x) + 0] = value; image[3 * (W * y + x) + 1] = value; image[3 * (W * y + x) + 2] = value; } } return image; } class Kernel { futhark_context *ctx; int32_t N; void check_ret(int ret) { if (ret != 0) { char *str = futhark_context_get_error(ctx); cerr << str << endl; free(str); exit(1); } }; public: static_assert(is_same::value); Kernel() { futhark_context_config *config = futhark_context_config_new(); // futhark_context_config_select_device_interactively(config); // futhark_context_config_set_debugging(config, 1); ctx = futhark_context_new(config); futhark_context_config_free(config); check_ret(futhark_entry_get_N(ctx, &N)); // The 31 check is to not exceed 32-bit signed integer bounds assert(N >= 1 && N < 31); } ~Kernel() { futhark_context_free(ctx); } void run_job( vector &dest, int32_t width, int32_t height, Com bottomLeft, Com topRight, int32_t seed, int32_t start_index, int32_t poly_count) { futhark_i32_1d *dest_arr; check_ret(futhark_entry_main_job( ctx, &dest_arr, start_index, poly_count, width, height, bottomLeft.real(), topRight.imag(), topRight.real(), bottomLeft.imag(), seed)); check_ret(futhark_context_sync(ctx)); int64_t shape = futhark_shape_i32_1d(ctx, dest_arr)[0]; assert(shape == width * height); dest.resize(width * height); check_ret(futhark_values_i32_1d(ctx, dest_arr, dest.data())); check_ret(futhark_free_i32_1d(ctx, dest_arr)); } void run_all( vector &dest, int32_t width, int32_t height, Com bottomLeft, Com topRight, int32_t seed) { run_job(dest, width, height, bottomLeft, topRight, seed, 0, 1 << N); } void run_chunked( vector &dest, int32_t width, int32_t height, Com bottomLeft, Com topRight, int32_t seed, int32_t chunk_size) { dest.clear(); dest.resize(width * height); int32_t start_index = 0; int32_t total = 1 << N; int32_t njobs = (total + chunk_size - 1) / chunk_size; cerr << "Running " << njobs << " jobs of size " << chunk_size << endl; cerr << string(njobs, '.') << '\r'; while (start_index < total) { int32_t num_polys = min(chunk_size, total - start_index); vector output; run_job( output, width, height, bottomLeft, topRight, seed, start_index, num_polys); for (int i = 0; i < width * height; i++) { dest[i] += output[i]; } start_index += num_polys; cerr << '|'; } cerr << endl; } }; int main(int argc, char **argv) { int W, H; vector counts; if (argc <= 1) { // tie(W, H, counts) = computeCounts(); W = H = 2000; Com bottomLeft = Com(0, -1.6); Com topRight = Com(1.6, 0); Kernel().run_chunked(counts, W, H, bottomLeft, topRight, 42, 1 << 14); writeCounts(W, H, counts, "out.txt"); } else if (argc == 2) { tie(W, H, counts) = readCounts(argv[1]); } else { cerr << "Usage: " << argv[0] << " -- compute and draw" << endl; cerr << "Usage: " << argv[0] << " -- draw already-computed data" << endl; return 1; } int maxcount = rankCounts(counts); vector image = drawImage(W, H, counts, maxcount); assert(lodepng_encode24_file("out.png", image.data(), W, H) == 0); }