/* * nextpnr -- Next Generation Place and Route * * Copyright (C) 2018 David Shah * * 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 "place_legaliser.h" #include #include #include "cells.h" #include "design_utils.h" #include "log.h" #include "util.h" NEXTPNR_NAMESPACE_BEGIN struct CellChain { std::vector cells; }; // Generic chain finder template std::vector find_chains(const Context *ctx, F1 cell_type_predicate, F2 get_previous, F3 get_next, size_t min_length = 2) { std::set chained; std::vector chains; for (auto cell : sorted(ctx->cells)) { if (chained.find(cell.first) != chained.end()) continue; CellInfo *ci = cell.second; if (cell_type_predicate(ctx, ci)) { CellInfo *start = ci; CellInfo *prev_start = ci; while (prev_start != nullptr) { start = prev_start; prev_start = get_previous(ctx, start); } CellChain chain; CellInfo *end = start; while (end != nullptr) { chain.cells.push_back(end); end = get_next(ctx, end); } if (chain.cells.size() >= min_length) { chains.push_back(chain); for (auto c : chain.cells) chained.insert(c->name); } } } return chains; } static void get_chain_midpoint(const Context *ctx, const CellChain &chain, float &x, float &y) { float total_x = 0, total_y = 0; int N = 0; for (auto cell : chain.cells) { if (cell->bel == BelId()) continue; int bel_x, bel_y; bool bel_gb; ctx->estimatePosition(cell->bel, bel_x, bel_y, bel_gb); total_x += bel_x; total_y += bel_y; N++; } assert(N > 0); x = total_x / N; y = total_y / N; } class PlacementLegaliser { public: PlacementLegaliser(Context *ctx) : ctx(ctx){}; bool legalise() { bool legalised_carries = legalise_carries(); if (!legalised_carries && !ctx->force) return false; return legalised_carries; } private: void init_logic_cells() { for (auto bel : ctx->getBels()) { // Initialise the logic bels vector with unavailable invalid bels, dimensions [0..width][0..height[0..7] logic_bels.resize(ctx->chip_info->width + 1, std::vector>>( ctx->chip_info->height + 1, std::vector>(8, std::make_pair(BelId(), true)))); if (ctx->getBelType(bel) == TYPE_ICESTORM_LC) { // Using the non-standard API here to get (x, y, z) rather than just (x, y) auto bi = ctx->chip_info->bel_data[bel.index]; int x = bi.x, y = bi.y, z = bi.z; IdString cell = ctx->getBoundBelCell(bel); if (cell != IdString() && ctx->cells.at(cell)->belStrength >= STRENGTH_FIXED) logic_bels.at(x).at(y).at(z) = std::make_pair(bel, true); else logic_bels.at(x).at(y).at(z) = std::make_pair(bel, false); } } } bool legalise_carries() { std::vector carry_chains = find_chains( ctx, is_lc, [](const Context *ctx, const CellInfo *cell) { return net_driven_by(ctx, cell->ports.at(ctx->id("CIN")).net, is_lc, ctx->id("COUT")); }, [](const Context *ctx, const CellInfo *cell) { return net_only_drives(ctx, cell->ports.at(ctx->id("COUT")).net, is_lc, ctx->id("CIN"), false); }); int width = ctx->chip_info->width, height = ctx->chip_info->height; for (auto &base_chain : carry_chains) { std::vector split_chains = split_carry_chain(base_chain); for (auto &chain : split_chains) { float mid_x, mid_y; get_chain_midpoint(ctx, chain, mid_x, mid_y); float base_x = mid_x, base_y = mid_y - (chain.cells.size() / 16.0f); // Find Bel meeting requirements closest to the target base } } return true; } // Find Bel closest to a location, meeting chain requirements BelId find_closest_bel(float x, float y, int chain_size) { // TODO return BelId(); } // Split a carry chain into multiple legal chains std::vector split_carry_chain(CellChain &carryc) { bool start_of_chain = true; std::vector chains; std::vector tile; const int max_length = (ctx->chip_info->height - 2) * 8 - 2; auto curr_cell = carryc.cells.begin(); while (curr_cell != carryc.cells.end()) { CellInfo *cell = *curr_cell; if (tile.size() >= 8) { tile.clear(); } if (start_of_chain) { tile.clear(); chains.emplace_back(); start_of_chain = false; if (cell->ports.at(ctx->id("CIN")).net) { // CIN is not constant and not part of a chain. Must feed in from fabric CellInfo *feedin = make_carry_feed_in(cell, cell->ports.at(ctx->id("CIN"))); chains.back().cells.push_back(feedin); tile.push_back(feedin); } } tile.push_back(cell); chains.back().cells.push_back(cell); bool split_chain = (!ctx->logicCellsCompatible(tile)) || (int(chains.back().cells.size()) > max_length); if (split_chain) { CellInfo *passout = make_carry_pass_out(cell->ports.at(ctx->id("COUT"))); tile.pop_back(); chains.back().cells.back() = passout; start_of_chain = true; } else { NetInfo *carry_net = cell->ports.at(ctx->id("COUT")).net; if (carry_net != nullptr && carry_net->users.size() > 1) { CellInfo *passout = make_carry_pass_out(cell->ports.at(ctx->id("COUT"))); chains.back().cells.push_back(passout); tile.push_back(passout); } ++curr_cell; } } return chains; } // Insert a logic cell to legalise a COUT->fabric connection CellInfo *make_carry_pass_out(PortInfo &cout_port) { assert(cout_port.net != nullptr); CellInfo *lc = create_ice_cell(ctx, ctx->id("ICESTORM_LC")); lc->params[ctx->id("LUT_INIT")] = "65280"; // 0xff00: O = I3 lc->params[ctx->id("CARRY_ENABLE")] = "1"; lc->ports.at(ctx->id("O")).net = cout_port.net; NetInfo *co_i3_net = new NetInfo(); co_i3_net->name = ctx->id(lc->name.str(ctx) + "$I3"); co_i3_net->driver = cout_port.net->driver; PortRef i3_r; i3_r.port = ctx->id("I3"); i3_r.cell = lc; co_i3_net->users.push_back(i3_r); PortRef o_r; o_r.port = ctx->id("O"); o_r.cell = lc; cout_port.net->driver = o_r; lc->ports.at(ctx->id("I3")).net = co_i3_net; // I1=1 feeds carry up the chain, so no need to actually break the chain lc->ports.at(ctx->id("I1")).net = ctx->nets.at(ctx->id("$PACKER_VCC_NET")); PortRef i1_r; i1_r.port = ctx->id("I1"); i1_r.cell = lc; ctx->nets.at(ctx->id("$PACKER_VCC_NET"))->users.push_back(i1_r); ctx->cells[lc->name] = lc; createdCells.insert(lc->name); return lc; } // Insert a logic cell to legalise a CIN->fabric connection CellInfo *make_carry_feed_in(CellInfo *cin_cell, PortInfo &cin_port) { assert(cin_port.net != nullptr); CellInfo *lc = create_ice_cell(ctx, ctx->id("ICESTORM_LC")); lc->params[ctx->id("CARRY_ENABLE")] = "1"; lc->params[ctx->id("CIN_CONST")] = "1"; lc->params[ctx->id("CIN_SET")] = "1"; lc->ports.at(ctx->id("I1")).net = cin_port.net; cin_port.net->users.erase(std::remove_if(cin_port.net->users.begin(), cin_port.net->users.end(), [cin_cell, cin_port](const PortRef &usr) { return usr.cell == cin_cell && usr.port == cin_port.name; })); NetInfo *out_net = new NetInfo(); out_net->name = ctx->id(lc->name.str(ctx) + "$O"); ctx->cells[lc->name] = lc; createdCells.insert(lc->name); return lc; } Context *ctx; std::unordered_set rippedCells; std::unordered_set createdCells; // Go from X and Y position to logic cells, setting occupied to true if a Bel is unavailable std::vector>>> logic_bels; }; bool legalise_design(Context *ctx) { PlacementLegaliser lg(ctx); return lg.legalise(); } NEXTPNR_NAMESPACE_END