/* * yosys -- Yosys Open SYnthesis Suite * * Copyright (C) 2012 Clifford Wolf * * Permission to use, copy, modify, and/or distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. * */ #include "kernel/yosys.h" #include "kernel/sigtools.h" #undef LOG_MATRICES #undef PYPLOT_EDGES USING_YOSYS_NAMESPACE PRIVATE_NAMESPACE_BEGIN static uint32_t xorshift32_state; static double xorshift32() { xorshift32_state ^= xorshift32_state << 13; xorshift32_state ^= xorshift32_state >> 17; xorshift32_state ^= xorshift32_state << 5; return (xorshift32_state % 1000000) / 1e6; } struct QwpConfig { bool ltr; bool alpha; double grid; std::ofstream dump_file; QwpConfig() { ltr = false; alpha = false; grid = 1.0 / 16; } }; struct QwpWorker { QwpConfig &config; Module *module; char direction; struct Node { Cell *cell; bool tied, alt_tied; // pos = position in current direction // alt_pos = position in the other direction double pos, alt_pos; Node() { cell = nullptr; tied = false; pos = xorshift32(); alt_tied = false; alt_pos = xorshift32(); } void tie(double v) { tied = true; pos = v; } void alt_tie(double v) { alt_tied = true; alt_pos = v; } void swap_alt() { std::swap(tied, alt_tied); std::swap(pos, alt_pos); } void proj_left(double midpos) { cell = nullptr; tie(pos > midpos ? midpos : pos); } void proj_right(double midpos) { cell = nullptr; tie(pos < midpos ? midpos : pos); } }; vector nodes; dict, double> edges; dict cell_to_node; // worker state variables double midpos; double radius; double alt_midpos; double alt_radius; QwpWorker(QwpConfig &config, Module *module, char direction = 'x') : config(config), module(module), direction(direction) { log_assert(direction == 'x' || direction == 'y'); } void load_module() { log_assert(direction == 'x'); SigMap sigmap(module); dict> bits_to_nodes; if (config.ltr || config.alpha) { dict alpha_inputs, alpha_outputs; if (config.alpha) { dict alpha_order; for (auto wire : module->wires()) { if (wire->port_input || wire->port_output) alpha_order[wire->name.str()] = wire; } alpha_order.sort(); for (auto &it : alpha_order) { if (it.second->port_input) { int idx = GetSize(alpha_inputs); alpha_inputs[it.second] = idx + 0.5; } if (it.second->port_output) { int idx = GetSize(alpha_outputs); alpha_outputs[it.second] = idx + 0.5; } } } for (auto wire : module->wires()) { if (!wire->port_input && !wire->port_output) continue; int idx = GetSize(nodes); nodes.push_back(Node()); if (config.ltr) { if (wire->port_input) nodes[idx].tie(0.0); else nodes[idx].tie(1.0); } if (config.alpha) { if (wire->port_input) nodes[idx].alt_tie(alpha_inputs.at(wire) / GetSize(alpha_inputs)); else nodes[idx].alt_tie(alpha_outputs.at(wire) / GetSize(alpha_outputs)); } for (auto bit : sigmap(wire)) bits_to_nodes[bit].insert(idx); } } for (auto cell : module->selected_cells()) { log_assert(cell_to_node.count(cell) == 0); int idx = GetSize(nodes); nodes.push_back(Node()); cell_to_node[cell] = GetSize(nodes); nodes[idx].cell = cell; for (auto &conn : cell->connections()) for (auto bit : sigmap(conn.second)) bits_to_nodes[bit].insert(idx); } for (auto &it : bits_to_nodes) { if (GetSize(it.second) > 100) continue; for (int idx1 : it.second) for (int idx2 : it.second) if (idx1 < idx2) edges[pair(idx1, idx2)] += 1.0 / GetSize(it.second); } } void solve(bool alt_mode = false) { // A := constraint_matrix // y := constraint_rhs_vector // // AA = A' * A // Ay = A' * y // // M := [AA Ay] // Row major order int N = GetSize(nodes), N1 = N+1; vector M(N * N1); // Edge constraints: // A[i,:] := [ 0 0 .... 0 weight 0 ... 0 -weight 0 ... 0 0], y[i] := 0 // // i.e. nonzero columns in A[i,:] at the two node indices. for (auto &edge : edges) { int idx1 = edge.first.first; int idx2 = edge.first.second; double weight = edge.second * (1.0 + xorshift32() * 1e-3); M[idx1 + idx1*N1] += weight * weight; M[idx2 + idx2*N1] += weight * weight; M[idx1 + idx2*N1] += -weight * weight; M[idx2 + idx1*N1] += -weight * weight; } // Node constraints: // A[i,:] := [ 0 0 .... 0 weight 0 ... 0 0], y[i] := weight * pos // // i.e. nonzero column in A[i,:] at the node index // // "tied" nodes have a large weight, pinning them in position. Untied // nodes have a small weight, giving then a tiny preference to stay at // the current position, making sure that AA never is singular. for (int idx = 0; idx < GetSize(nodes); idx++) { auto &node = nodes[idx]; double rhs = (alt_mode ? node.alt_pos : node.pos); double weight = 1e-3; if (alt_mode ? node.alt_tied : node.tied) weight = 1e3; weight *= (1.0 + xorshift32() * 1e-3); M[idx + idx*N1] += weight * weight; M[N + idx*N1] += rhs * weight * weight; } #ifdef LOG_MATRICES log("\n"); for (int i = 0; i < N; i++) { for (int j = 0; j < N+1; j++) log(" %10.2e", M[(N+1)*i + j]); log("\n"); } #endif // Solve "AA*x = Ay" // (least squares fit for "A*x = y") // // Using gaussian elimination to get M := [Id x] vector pivot_cache; vector queue; for (int i = 0; i < N; i++) queue.push_back(i); // gaussian elimination for (int i = 0; i < N; i++) { // find best row int best_row = queue.front(); int best_row_queue_idx = 0; double best_row_absval = 0; for (int k = 0; k < GetSize(queue); k++) { int row = queue[k]; double absval = fabs(M[i + row*N1]); if (absval > best_row_absval) { best_row = row; best_row_queue_idx = k; best_row_absval = absval; } } int row = best_row; pivot_cache.push_back(row); queue[best_row_queue_idx] = queue.back(); queue.pop_back(); // normalize row for (int k = i+1; k < N1; k++) M[k + row*N1] /= M[i + row*N1]; M[i + row*N1] = 1.0; // elimination for (int other_row : queue) { double d = M[i + other_row*N1]; for (int k = i+1; k < N1; k++) M[k + other_row*N1] -= d*M[k + row*N1]; M[i + other_row*N1] = 0.0; } } log_assert(queue.empty()); log_assert(GetSize(pivot_cache) == N); // back substitution for (int i = N-1; i >= 0; i--) for (int j = i+1; j < N; j++) { int row = pivot_cache[i]; int other_row = pivot_cache[j]; M[N + row*N1] -= M[j + row*N1] * M[N + other_row*N1]; M[j + row*N1] = 0.0; } #ifdef LOG_MATRICES log("\n"); for (int i = 0; i < N; i++) { for (int j = 0; j < N+1; j++) log(" %10.2e", M[(N+1)*i + j]); log("\n"); } #endif // update node positions for (int i = 0; i < N; i++) { double v = M[(N+1)*i + N]; double c = alt_mode ? alt_midpos : midpos; double r = alt_mode ? alt_radius : radius; if (std::isfinite(v)) { v = min(v, c+r); v = max(v, c-r); } else { v = c; } if (alt_mode) { if (!nodes[i].alt_tied) nodes[i].alt_pos = v; } else { if (!nodes[i].tied) nodes[i].pos = v; } } } void log_cell_coordinates(int indent, bool log_all_nodes = false) { for (auto &node : nodes) { if (node.cell == nullptr && !log_all_nodes) continue; for (int i = 0; i < indent; i++) log(" "); if (direction == 'x') log("X=%.2f, Y=%.2f", node.pos, node.alt_pos); else log("X=%.2f, Y=%.2f", node.alt_pos, node.pos); if (node.tied) log(" [%c-tied]", direction); if (node.alt_tied) log(" [%c-tied]", direction == 'x' ? 'y' : 'x'); if (node.cell != nullptr) log(" %s (%s)", log_id(node.cell), log_id(node.cell->type)); else log(" (none)"); log("\n"); } } void dump_svg(const pool *green_nodes = nullptr, double median = -1) { double x_center = direction == 'x' ? midpos : alt_midpos; double y_center = direction == 'y' ? midpos : alt_midpos; double x_radius = direction == 'x' ? radius : alt_radius; double y_radius = direction == 'y' ? radius : alt_radius; config.dump_file << stringf("\n"); config.dump_file << stringf("\n"); config.dump_file << stringf("\n"); config.dump_file << stringf("\n"); double win_x = 250 + 200 * (direction == 'x' ? midpos - radius : alt_midpos - alt_radius); double win_y = 20 + 200 * (direction == 'y' ? midpos - radius : alt_midpos - alt_radius); double win_w = 200 * (direction == 'x' ? 2*radius : 2*alt_radius); double win_h = 200 * (direction == 'y' ? 2*radius : 2*alt_radius); config.dump_file << stringf("\n", win_x, win_y, win_w, win_h); if (median >= 0) { double x1 = 20.0, x2 = 220.0, y1 = 20.0, y2 = 220.0; if (direction == 'x') x1 = x2 = 120 + 100 * (median - x_center) / x_radius; else y1 = y2 = 120 + 100 * (median - y_center) / y_radius; config.dump_file << stringf("\n", x1, y1, x2, y2); } for (auto &edge : edges) { auto &node1 = nodes[edge.first.first]; auto &node2 = nodes[edge.first.second]; double x1 = direction == 'x' ? node1.pos : node1.alt_pos; double y1 = direction == 'y' ? node1.pos : node1.alt_pos; double x2 = direction == 'x' ? node2.pos : node2.alt_pos; double y2 = direction == 'y' ? node2.pos : node2.alt_pos; x1 = 120 + 100 * (x1 - x_center) / x_radius; y1 = 120 + 100 * (y1 - y_center) / y_radius; x2 = 120 + 100 * (x2 - x_center) / x_radius; y2 = 120 + 100 * (y2 - y_center) / y_radius; config.dump_file << stringf("\n", x1, y1, x2, y2); } for (int i = 0; i < GetSize(nodes); i++) { auto &node = nodes[i]; double x = direction == 'x' ? node.pos : node.alt_pos; double y = direction == 'y' ? node.pos : node.alt_pos; x = 120 + 100 * (x - x_center) / x_radius; y = 120 + 100 * (y - y_center) / y_radius; const char *color = node.cell == nullptr ? "blue" : "red"; if (green_nodes != nullptr && green_nodes->count(i)) color = "green"; config.dump_file << stringf("\n", x, y, color); } config.dump_file << stringf("\n"); } void run_worker(int indent) { int count_cells = 0; for (auto &node : nodes) if (node.cell != nullptr) count_cells++; for (int i = 0; i < indent; i++) log(" "); string range_str; if (direction == 'x') range_str = stringf("X=%.2f:%.2f, Y=%.2f:%.2f", midpos - radius, midpos + radius, alt_midpos - alt_radius, alt_midpos + alt_radius); else range_str = stringf("X=%.2f:%.2f, Y=%.2f:%.2f", alt_midpos - alt_radius, alt_midpos + alt_radius, midpos - radius, midpos + radius); log("%c-qwp on %s with %d cells, %d nodes, and %d edges.\n", direction, range_str.c_str(), count_cells, GetSize(nodes), GetSize(edges)); solve(); solve(true); // detect median position and check for break condition vector> sorted_pos; for (int i = 0; i < GetSize(nodes); i++) if (nodes[i].cell != nullptr) sorted_pos.push_back(pair(nodes[i].pos, i)); std::sort(sorted_pos.begin(), sorted_pos.end()); int median_sidx = GetSize(sorted_pos)/2; double median = sorted_pos[median_sidx].first; double left_scale = radius / (median - (midpos - radius)); double right_scale = radius / ((midpos + radius) - median); if (config.dump_file.is_open()) { config.dump_file << stringf("

LSQ %c-Solution for %s:

\n", direction, range_str.c_str()); pool green_nodes; for (int i = 0; i < median_sidx; i++) green_nodes.insert(sorted_pos[i].second); dump_svg(&green_nodes, median); } for (auto &node : nodes) { double rel_pos = node.pos - median; if (rel_pos < 0) { node.pos = midpos + left_scale*rel_pos; if (std::isfinite(node.pos)) { node.pos = min(node.pos, midpos); node.pos = max(node.pos, midpos - radius); } else node.pos = midpos - radius/2; } else { node.pos = midpos + right_scale*rel_pos; if (std::isfinite(node.pos)) { node.pos = max(node.pos, midpos); node.pos = min(node.pos, midpos + radius); } else node.pos = midpos + radius/2; } } if (GetSize(sorted_pos) < 2 || (2*radius <= config.grid && 2*alt_radius <= config.grid)) { log_cell_coordinates(indent + 1); return; } // create child workers char child_direction = direction == 'x' ? 'y' : 'x'; QwpWorker left_worker(config, module, child_direction); QwpWorker right_worker(config, module, child_direction); // duplicate nodes into child workers dict left_nodes, right_nodes; for (int k = 0; k < GetSize(sorted_pos); k++) { int i = sorted_pos[k].second; if (k < median_sidx) { left_nodes[i] = GetSize(left_worker.nodes); left_worker.nodes.push_back(nodes[i]); if (left_worker.nodes.back().pos > midpos) left_worker.nodes.back().pos = midpos; left_worker.nodes.back().swap_alt(); } else { right_nodes[i] = GetSize(right_worker.nodes); right_worker.nodes.push_back(nodes[i]); if (right_worker.nodes.back().pos < midpos) right_worker.nodes.back().pos = midpos; right_worker.nodes.back().swap_alt(); } } // duplicate edges into child workers, project nodes as needed for (auto &edge : edges) { int idx1 = edge.first.first; int idx2 = edge.first.second; double weight = edge.second; if (nodes[idx1].cell == nullptr && nodes[idx2].cell == nullptr) continue; int left_idx1 = left_nodes.count(idx1) ? left_nodes.at(idx1) : -1; int left_idx2 = left_nodes.count(idx2) ? left_nodes.at(idx2) : -1; int right_idx1 = right_nodes.count(idx1) ? right_nodes.at(idx1) : -1; int right_idx2 = right_nodes.count(idx2) ? right_nodes.at(idx2) : -1; if (left_idx1 >= 0 && left_worker.nodes[left_idx1].cell && left_idx2 < 0) { left_idx2 = left_nodes[idx2] = GetSize(left_worker.nodes); left_worker.nodes.push_back(nodes[idx2]); left_worker.nodes.back().proj_left(midpos); left_worker.nodes.back().swap_alt(); } else if (left_idx2 >= 0 && left_worker.nodes[left_idx2].cell && left_idx1 < 0) { left_idx1 = left_nodes[idx1] = GetSize(left_worker.nodes); left_worker.nodes.push_back(nodes[idx1]); left_worker.nodes.back().proj_left(midpos); left_worker.nodes.back().swap_alt(); } if (right_idx1 >= 0 && right_worker.nodes[right_idx1].cell && right_idx2 < 0) { right_idx2 = right_nodes[idx2] = GetSize(right_worker.nodes); right_worker.nodes.push_back(nodes[idx2]); right_worker.nodes.back().proj_right(midpos); right_worker.nodes.back().swap_alt(); } else if (right_idx2 >= 0 && right_worker.nodes[right_idx2].cell && right_idx1 < 0) { right_idx1 = right_nodes[idx1] = GetSize(right_worker.nodes); right_worker.nodes.push_back(nodes[idx1]); right_worker.nodes.back().proj_right(midpos); right_worker.nodes.back().swap_alt(); } if (left_idx1 >= 0 && left_idx2 >= 0) left_worker.edges[pair(left_idx1, left_idx2)] += weight; if (right_idx1 >= 0 && right_idx2 >= 0) right_worker.edges[pair(right_idx1, right_idx2)] += weight; } // run child workers left_worker.midpos = right_worker.midpos = alt_midpos; left_worker.radius = right_worker.radius = alt_radius; left_worker.alt_midpos = midpos - radius/2; right_worker.alt_midpos = midpos + radius/2; left_worker.alt_radius = right_worker.alt_radius = radius/2; left_worker.run_worker(indent+1); right_worker.run_worker(indent+1); // re-integrate results for (auto &it : left_nodes) if (left_worker.nodes[it.second].cell != nullptr) { nodes[it.first].pos = left_worker.nodes[it.second].alt_pos; nodes[it.first].alt_pos = left_worker.nodes[it.second].pos; } for (auto &it : right_nodes) if (right_worker.nodes[it.second].cell != nullptr) { nodes[it.first].pos = right_worker.nodes[it.second].alt_pos; nodes[it.first].alt_pos = right_worker.nodes[it.second].pos; } if (config.dump_file.is_open()) { config.dump_file << stringf("

Final %c-Solution for %s:

\n", direction, range_str.c_str()); dump_svg(); } } void histogram(const vector &values) { if (values.empty()) { log("no data\n"); return; } double min_value = values.front(); double max_value = values.front(); for (auto &v : values) { min_value = min(min_value, v); max_value = max(max_value, v); } if (fabs(max_value - min_value) < 0.001) { log("all values in range %f .. %f\n", min_value, max_value); return; } vector buckets(60); int max_bucket_val = 0; for (auto &v : values) { int idx = min(int(GetSize(buckets) * (v - min_value) / (max_value - min_value)), GetSize(buckets)-1); max_bucket_val = max(max_bucket_val, ++buckets.at(idx)); } for (int i = 4; i >= 0; i--) { for (int k = 0; k < GetSize(buckets); k++) { int v = 10 * buckets[k] / max_bucket_val; if (v >= 2*i+1) log(v == 2*i+1 ? "." : ":"); else log(i == 0 ? (buckets[k] > 0 ? "," : "_") : " "); } log("\n"); } log("%-30f%30f\n", min_value, max_value); } void run() { log("\n"); log("Running qwp on module %s..\n", log_id(module)); if (config.dump_file.is_open()) config.dump_file << stringf("

QWP protocol for module %s:

\n", log_id(module)); load_module(); midpos = 0.5; radius = 0.5; alt_midpos = 0.5; alt_radius = 0.5; run_worker(1); for (auto &node : nodes) if (node.cell != nullptr) node.cell->attributes["\\qwp_position"] = stringf("%f %f", node.pos, node.alt_pos); vector edge_lengths; vector weighted_edge_lengths; double total_edge_length = 0; double total_weighted_edge_length = 0; for (auto &edge : edges) { auto &node1 = nodes[edge.first.first]; auto &node2 = nodes[edge.first.second]; double distance = sqrt(pow(node1.pos - node2.pos, 2) + pow(node1.alt_pos - node2.alt_pos, 2)); double weighted_distance = distance * edge.second; edge_lengths.push_back(distance); weighted_edge_lengths.push_back(weighted_distance); total_edge_length += distance; total_weighted_edge_length += weighted_distance; } log("\n"); log("Summary for module %s:\n", log_id(module)); log("Number of edges: %d\n", GetSize(edges)); log("Total edge length: %f\n", total_edge_length); log("Total weighted edge length: %f\n", total_weighted_edge_length); log("\n"); log("Histogram over edge lengths:\n"); histogram(edge_lengths); log("\n"); log("Histogram over weighted edge lengths:\n"); histogram(weighted_edge_lengths); } }; struct QwpPass : public Pass { QwpPass() : Pass("qwp", "quadratic wirelength placer") { } virtual void help() { // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| log("\n"); log(" qwp [options] [selection]\n"); log("\n"); log("This command runs quadratic wirelength placement on the selected modules and\n"); log("annotates the cells in the design with 'qwp_position' attributes.\n"); log("\n"); log(" -ltr\n"); log(" Add left-to-right constraints: constrain all inputs on the left border\n"); log(" outputs to the right border.\n"); log("\n"); log(" -alpha\n"); log(" Add constraints for inputs/outputs to be placed in alphanumerical\n"); log(" order along the y-axis (top-to-bottom).\n"); log("\n"); log(" -grid N\n"); log(" Number of grid divisions in x- and y-direction. (default=16)\n"); log("\n"); log(" -dump \n"); log(" Dump a protocol of the placement algorithm to the html file.\n"); log("\n"); log("Note: This implementation of a quadratic wirelength placer uses exact\n"); log("dense matrix operations. It is only a toy-placer for small circuits.\n"); log("\n"); } virtual void execute(std::vector args, RTLIL::Design *design) { QwpConfig config; xorshift32_state = 123456789; log_header("Executing QWP pass (quadratic wirelength placer).\n"); size_t argidx; for (argidx = 1; argidx < args.size(); argidx++) { if (args[argidx] == "-ltr") { config.ltr = true; continue; } if (args[argidx] == "-alpha") { config.alpha = true; continue; } if (args[argidx] == "-grid" && argidx+1 < args.size()) { config.grid = 1.0 / atoi(args[++argidx].c_str()); continue; } if (args[argidx] == "-dump" && argidx+1 < args.size()) { config.dump_file.open(args[++argidx], std::ofstream::trunc); continue; } break; } extra_args(args, argidx, design); for (auto module : design->selected_modules()) { QwpWorker worker(config, module); worker.run(); #ifdef PYPLOT_EDGES log("\n"); log("plt.figure(figsize=(10, 10));\n"); for (auto &edge : worker.edges) { log("plt.plot([%.2f, %.2f], [%.2f, %.2f], \"r-\");\n", worker.nodes[edge.first.first].pos, worker.nodes[edge.first.second].pos, worker.nodes[edge.first.first].alt_pos, worker.nodes[edge.first.second].alt_pos); } for (auto &node : worker.nodes) { const char *style = node.cell != nullptr ? "ko" : "ks"; log("plt.plot([%.2f], [%.2f], \"%s\");\n", node.pos, node.alt_pos, style); } #endif } } } QwpPass; PRIVATE_NAMESPACE_END