/* * Copyright 2020-2022 F4PGA Authors * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * SPDX-License-Identifier: Apache-2.0 */ #include "kernel/log.h" #include "kernel/register.h" #include "kernel/rtlil.h" #include "kernel/sigtools.h" USING_YOSYS_NAMESPACE PRIVATE_NAMESPACE_BEGIN // ============================================================================ struct QlDspSimdPass : public Pass { QlDspSimdPass() : Pass("ql_dsp_simd", "merge QuickLogic K6N10f DSP pairs to operate in SIMD mode") {} void help() override { // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| log("\n"); log(" ql_dsp_simd [selection]\n"); log("\n"); log("This pass identifies K6N10f DSP cells with identical configuration and pack pairs\n"); log("of them together into other DSP cells that can perform SIMD operation.\n"); } // .......................................... /// Describes DSP config unique to a whole DSP cell struct DspConfig { // Port connections dict connections; DspConfig() = default; DspConfig(const DspConfig &ref) = default; DspConfig(DspConfig &&ref) = default; unsigned int hash() const { return connections.hash(); } bool operator==(const DspConfig &ref) const { return connections == ref.connections; } }; // .......................................... const int m_ModeBitsSize = 80; // DSP parameters const std::vector m_DspParams = {"COEFF_3", "COEFF_2", "COEFF_1", "COEFF_0"}; /// Temporary SigBit to SigBit helper map. SigMap sigmap; // .......................................... void execute(std::vector a_Args, RTLIL::Design *a_Design) override { log_header(a_Design, "Executing QL_DSP_SIMD pass.\n"); // DSP control and config ports to consider and how to map them to ports // of the target DSP cell static const std::vector> m_DspCfgPorts = { std::make_pair(ID(clock_i), ID(clk)), std::make_pair(ID(reset_i), ID(reset)), std::make_pair(ID(feedback_i), ID(feedback)), std::make_pair(ID(load_acc_i), ID(load_acc)), std::make_pair(ID(unsigned_a_i), ID(unsigned_a)), std::make_pair(ID(unsigned_b_i), ID(unsigned_b)), std::make_pair(ID(subtract_i), ID(subtract)), std::make_pair(ID(output_select_i), ID(output_select)), std::make_pair(ID(saturate_enable_i), ID(saturate_enable)), std::make_pair(ID(shift_right_i), ID(shift_right)), std::make_pair(ID(round_i), ID(round)), std::make_pair(ID(register_inputs_i), ID(register_inputs)) }; // DSP data ports and how to map them to ports of the target DSP cell static const std::vector> m_DspDataPorts = { std::make_pair(ID(a_i), ID(a)), std::make_pair(ID(b_i), ID(b)), std::make_pair(ID(acc_fir_i), ID(acc_fir)), std::make_pair(ID(z_o), ID(z)), std::make_pair(ID(dly_b_o), ID(dly_b)) }; // Source DSP cell type (SISD) static const IdString m_SisdDspType = ID(dsp_t1_10x9x32); // Target DSP cell types for the SIMD mode static const IdString m_SimdDspType = ID(QL_DSP2); // Parse args extra_args(a_Args, 1, a_Design); // Process modules for (auto module : a_Design->selected_modules()) { // Setup the SigMap sigmap.set(module); // Assemble DSP cell groups dict> groups; for (auto cell : module->selected_cells()) { // Check if this is a DSP cell we are looking for (type starts with m_SisdDspType) if (cell->type != m_SisdDspType) continue; // Skip if it has the (* keep *) attribute set if (cell->has_keep_attr()) continue; // Add to a group const auto key = getDspConfig(cell, m_DspCfgPorts); groups[key].push_back(cell); } std::vector cellsToRemove; // Map cell pairs to the target DSP SIMD cell for (const auto &it : groups) { const auto &group = it.second; const auto &config = it.first; // Ensure an even number size_t count = group.size(); if (count & 1) count--; // Map SIMD pairs for (size_t i = 0; i < count; i += 2) { Cell *dsp_a = group[i]; Cell *dsp_b = group[i + 1]; // Create the new cell Cell *simd = module->addCell(NEW_ID, m_SimdDspType); log(" SIMD: %s (%s) + %s (%s) => %s (%s)\n", log_id(dsp_a), log_id(dsp_a->type), log_id(dsp_b), log_id(dsp_b->type), log_id(simd), log_id(simd->type)); // Check if the target cell is known (important to know // its port widths) if (!simd->known()) log_error(" The target cell type '%s' is not known!", log_id(simd)); // Connect common ports for (const auto &it : m_DspCfgPorts) simd->setPort(it.first, config.connections.at(it.second)); // Connect data ports for (const auto &it : m_DspDataPorts) { size_t width; bool isOutput; std::tie(width, isOutput) = getPortInfo(simd, it.second); auto getConnection = [&](const RTLIL::Cell *cell) { RTLIL::SigSpec sigspec; if (cell->hasPort(it.first)) { const auto &sig = cell->getPort(it.first); sigspec.append(sig); } int padding = width / 2 - sigspec.bits().size(); if (padding) { if (!isOutput) sigspec.append(RTLIL::SigSpec(RTLIL::Sx, padding)); else sigspec.append(module->addWire(NEW_ID, padding)); } return sigspec; }; RTLIL::SigSpec sigspec; sigspec.append(getConnection(dsp_a)); sigspec.append(getConnection(dsp_b)); simd->setPort(it.second, sigspec); } // Concatenate FIR coefficient parameters into the single // MODE_BITS parameter Const mode_bits; for (const auto &it : m_DspParams) { auto val_a = dsp_a->getParam(it); auto val_b = dsp_b->getParam(it); mode_bits.bits.insert(mode_bits.end(), val_a.begin(), val_a.end()); mode_bits.bits.insert(mode_bits.end(), val_b.begin(), val_b.end()); } // Enable the fractured mode by connecting the control // port. simd->setPort(ID(f_mode), State::S1); simd->setParam(ID(MODE_BITS), mode_bits); log_assert(mode_bits.size() == m_ModeBitsSize); // Handle the "is_inferred" attribute. If one of the fragments // is not inferred mark the whole DSP as not inferred bool is_inferred_a = dsp_a->get_bool_attribute(ID(is_inferred)); bool is_inferred_b = dsp_b->get_bool_attribute(ID(is_inferred)); simd->set_bool_attribute(ID(is_inferred), is_inferred_a && is_inferred_b); // Mark DSP parts for removal cellsToRemove.push_back(dsp_a); cellsToRemove.push_back(dsp_b); } } // Remove old cells for (auto cell : cellsToRemove) module->remove(cell); } } // .......................................... /// Looks up port width and direction in the cell definition and returns it. /// Returns (0, false) if it cannot be determined. std::pair getPortInfo(RTLIL::Cell *a_Cell, RTLIL::IdString a_Port) { if (!a_Cell->known()) { return std::make_pair(0, false); } // Get the module defining the cell (the previous condition ensures // that the pointers are valid) RTLIL::Module *mod = a_Cell->module->design->module(a_Cell->type); if (mod == nullptr) { return std::make_pair(0, false); } // Get the wire representing the port RTLIL::Wire *wire = mod->wire(a_Port); if (wire == nullptr) { return std::make_pair(0, false); } return std::make_pair(wire->width, wire->port_output); } /// Given a DSP cell populates and returns a DspConfig struct for it. DspConfig getDspConfig(RTLIL::Cell *a_Cell, const std::vector> &dspCfgPorts) { DspConfig config; for (const auto &it : dspCfgPorts) { auto port = it.first; // Port unconnected if (!a_Cell->hasPort(port)) continue; config.connections[port] = sigmap(a_Cell->getPort(port)); } return config; } } QlDspSimdPass; PRIVATE_NAMESPACE_END