/* * nextpnr -- Next Generation Place and Route * * Copyright (C) 2018 Clifford Wolf * Copyright (C) 2018 David Shah * Copyright (C) 2018 Serge Bazanski * * 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 #include #include #include "cells.h" #include "chains.h" #include "design_utils.h" #include "log.h" #include "util.h" NEXTPNR_NAMESPACE_BEGIN // Pack LUTs and LUT-FF pairs static void pack_lut_lutffs(Context *ctx) { log_info("Packing LUT-FFs..\n"); std::unordered_set packed_cells; std::vector> new_cells; for (auto cell : sorted(ctx->cells)) { CellInfo *ci = cell.second; if (ctx->verbose) log_info("cell '%s' is of type '%s'\n", ci->name.c_str(ctx), ci->type.c_str(ctx)); if (is_lut(ctx, ci)) { std::unique_ptr packed = create_ice_cell(ctx, ctx->id("ICESTORM_LC"), ci->name.str(ctx) + "_LC"); std::copy(ci->attrs.begin(), ci->attrs.end(), std::inserter(packed->attrs, packed->attrs.begin())); packed_cells.insert(ci->name); if (ctx->verbose) log_info("packed cell %s into %s\n", ci->name.c_str(ctx), packed->name.c_str(ctx)); // See if we can pack into a DFF // TODO: LUT cascade NetInfo *o = ci->ports.at(ctx->id("O")).net; CellInfo *dff = net_only_drives(ctx, o, is_ff, ctx->id("D"), true); auto lut_bel = ci->attrs.find(ctx->id("BEL")); bool packed_dff = false; if (dff) { if (ctx->verbose) log_info("found attached dff %s\n", dff->name.c_str(ctx)); auto dff_bel = dff->attrs.find(ctx->id("BEL")); if (lut_bel != ci->attrs.end() && dff_bel != dff->attrs.end() && lut_bel->second != dff_bel->second) { // Locations don't match, can't pack } else { lut_to_lc(ctx, ci, packed.get(), false); dff_to_lc(ctx, dff, packed.get(), false); ctx->nets.erase(o->name); if (dff_bel != dff->attrs.end()) packed->attrs[ctx->id("BEL")] = dff_bel->second; packed_cells.insert(dff->name); if (ctx->verbose) log_info("packed cell %s into %s\n", dff->name.c_str(ctx), packed->name.c_str(ctx)); packed_dff = true; } } if (!packed_dff) { lut_to_lc(ctx, ci, packed.get(), true); } new_cells.push_back(std::move(packed)); } } for (auto pcell : packed_cells) { ctx->cells.erase(pcell); } for (auto &ncell : new_cells) { ctx->cells[ncell->name] = std::move(ncell); } } // Pack FFs not packed as LUTFFs static void pack_nonlut_ffs(Context *ctx) { log_info("Packing non-LUT FFs..\n"); std::unordered_set packed_cells; std::vector> new_cells; for (auto cell : sorted(ctx->cells)) { CellInfo *ci = cell.second; if (is_ff(ctx, ci)) { std::unique_ptr packed = create_ice_cell(ctx, ctx->id("ICESTORM_LC"), ci->name.str(ctx) + "_DFFLC"); std::copy(ci->attrs.begin(), ci->attrs.end(), std::inserter(packed->attrs, packed->attrs.begin())); if (ctx->verbose) log_info("packed cell %s into %s\n", ci->name.c_str(ctx), packed->name.c_str(ctx)); packed_cells.insert(ci->name); dff_to_lc(ctx, ci, packed.get(), true); new_cells.push_back(std::move(packed)); } } for (auto pcell : packed_cells) { ctx->cells.erase(pcell); } for (auto &ncell : new_cells) { ctx->cells[ncell->name] = std::move(ncell); } } static bool net_is_constant(const Context *ctx, NetInfo *net, bool &value) { if (net == nullptr) return false; if (net->name == ctx->id("$PACKER_GND_NET") || net->name == ctx->id("$PACKER_VCC_NET")) { value = (net->name == ctx->id("$PACKER_VCC_NET")); return true; } else { return false; } } // Pack carry logic static void pack_carries(Context *ctx) { log_info("Packing carries..\n"); std::unordered_set exhausted_cells; std::unordered_set packed_cells; std::vector> new_cells; for (auto cell : sorted(ctx->cells)) { CellInfo *ci = cell.second; if (is_carry(ctx, ci)) { packed_cells.insert(cell.first); CellInfo *carry_ci_lc; bool ci_value; bool ci_const = net_is_constant(ctx, ci->ports.at(ctx->id("CI")).net, ci_value); if (ci_const) { carry_ci_lc = nullptr; } else { carry_ci_lc = net_only_drives(ctx, ci->ports.at(ctx->id("CI")).net, is_lc, ctx->id("I3"), false); } std::set i0_matches, i1_matches; NetInfo *i0_net = ci->ports.at(ctx->id("I0")).net; NetInfo *i1_net = ci->ports.at(ctx->id("I1")).net; // Find logic cells connected to both I0 and I1 if (i0_net) { for (auto usr : i0_net->users) { if (is_lc(ctx, usr.cell) && usr.port == ctx->id("I1")) { if (ctx->cells.find(usr.cell->name) != ctx->cells.end() && exhausted_cells.find(usr.cell->name) == exhausted_cells.end()) { // This clause stops us double-packing cells i0_matches.insert(usr.cell->name); if (!i1_net && !usr.cell->ports.at(ctx->id("I2")).net) { // I1 is don't care when disconnected, duplicate I0 i1_matches.insert(usr.cell->name); } } } } } if (i1_net) { for (auto usr : i1_net->users) { if (is_lc(ctx, usr.cell) && usr.port == ctx->id("I2")) { if (ctx->cells.find(usr.cell->name) != ctx->cells.end() && exhausted_cells.find(usr.cell->name) == exhausted_cells.end()) { // This clause stops us double-packing cells i1_matches.insert(usr.cell->name); if (!i0_net && !usr.cell->ports.at(ctx->id("I1")).net) { // I0 is don't care when disconnected, duplicate I1 i0_matches.insert(usr.cell->name); } } } } } std::set carry_lcs; std::set_intersection(i0_matches.begin(), i0_matches.end(), i1_matches.begin(), i1_matches.end(), std::inserter(carry_lcs, carry_lcs.end())); CellInfo *carry_lc = nullptr; if (carry_ci_lc && carry_lcs.find(carry_ci_lc->name) != carry_lcs.end()) { carry_lc = carry_ci_lc; } else { // No LC to pack into matching I0/I1, insert a new one std::unique_ptr created_lc = create_ice_cell(ctx, ctx->id("ICESTORM_LC"), cell.first.str(ctx) + "$CARRY"); carry_lc = created_lc.get(); created_lc->ports.at(ctx->id("I1")).net = i0_net; if (i0_net) { PortRef pr; pr.cell = created_lc.get(); pr.port = ctx->id("I1"); i0_net->users.push_back(pr); } created_lc->ports.at(ctx->id("I2")).net = i1_net; if (i1_net) { PortRef pr; pr.cell = created_lc.get(); pr.port = ctx->id("I2"); i1_net->users.push_back(pr); } new_cells.push_back(std::move(created_lc)); } carry_lc->params[ctx->id("CARRY_ENABLE")] = "1"; replace_port(ci, ctx->id("CI"), carry_lc, ctx->id("CIN")); replace_port(ci, ctx->id("CO"), carry_lc, ctx->id("COUT")); if (i0_net) { auto &i0_usrs = i0_net->users; i0_usrs.erase(std::remove_if(i0_usrs.begin(), i0_usrs.end(), [ci, ctx](const PortRef &pr) { return pr.cell == ci && pr.port == ctx->id("I0"); })); } if (i1_net) { auto &i1_usrs = i1_net->users; i1_usrs.erase(std::remove_if(i1_usrs.begin(), i1_usrs.end(), [ci, ctx](const PortRef &pr) { return pr.cell == ci && pr.port == ctx->id("I1"); })); } // Check for constant driver on CIN if (carry_lc->ports.at(ctx->id("CIN")).net != nullptr) { IdString cin_net = carry_lc->ports.at(ctx->id("CIN")).net->name; if (cin_net == ctx->id("$PACKER_GND_NET") || cin_net == ctx->id("$PACKER_VCC_NET")) { carry_lc->params[ctx->id("CIN_CONST")] = "1"; carry_lc->params[ctx->id("CIN_SET")] = cin_net == ctx->id("$PACKER_VCC_NET") ? "1" : "0"; carry_lc->ports.at(ctx->id("CIN")).net = nullptr; auto &cin_users = ctx->nets.at(cin_net)->users; cin_users.erase( std::remove_if(cin_users.begin(), cin_users.end(), [carry_lc, ctx](const PortRef &pr) { return pr.cell == carry_lc && pr.port == ctx->id("CIN"); })); } } exhausted_cells.insert(carry_lc->name); } } for (auto pcell : packed_cells) { ctx->cells.erase(pcell); } for (auto &ncell : new_cells) { ctx->cells[ncell->name] = std::move(ncell); } } // "Pack" RAMs static void pack_ram(Context *ctx) { log_info("Packing RAMs..\n"); std::unordered_set packed_cells; std::vector> new_cells; for (auto cell : sorted(ctx->cells)) { CellInfo *ci = cell.second; if (is_ram(ctx, ci)) { std::unique_ptr packed = create_ice_cell(ctx, ctx->id("ICESTORM_RAM"), ci->name.str(ctx) + "_RAM"); packed_cells.insert(ci->name); for (auto attr : ci->attrs) packed->attrs[attr.first] = attr.second; for (auto param : ci->params) packed->params[param.first] = param.second; packed->params[ctx->id("NEG_CLK_W")] = std::to_string(ci->type == ctx->id("SB_RAM40_4KNW") || ci->type == ctx->id("SB_RAM40_4KNRNW")); packed->params[ctx->id("NEG_CLK_R")] = std::to_string(ci->type == ctx->id("SB_RAM40_4KNR") || ci->type == ctx->id("SB_RAM40_4KNRNW")); packed->type = ctx->id("ICESTORM_RAM"); for (auto port : ci->ports) { PortInfo &pi = port.second; std::string newname = pi.name.str(ctx); size_t bpos = newname.find('['); if (bpos != std::string::npos) { newname = newname.substr(0, bpos) + "_" + newname.substr(bpos + 1, (newname.size() - bpos) - 2); } if (pi.name == ctx->id("RCLKN")) newname = "RCLK"; else if (pi.name == ctx->id("WCLKN")) newname = "WCLK"; replace_port(ci, ctx->id(pi.name.c_str(ctx)), packed.get(), ctx->id(newname)); } new_cells.push_back(std::move(packed)); } } for (auto pcell : packed_cells) { ctx->cells.erase(pcell); } for (auto &ncell : new_cells) { ctx->cells[ncell->name] = std::move(ncell); } } // Merge a net into a constant net static void set_net_constant(const Context *ctx, NetInfo *orig, NetInfo *constnet, bool constval) { orig->driver.cell = nullptr; for (auto user : orig->users) { if (user.cell != nullptr) { CellInfo *uc = user.cell; if (ctx->verbose) log_info("%s user %s\n", orig->name.c_str(ctx), uc->name.c_str(ctx)); if ((is_lut(ctx, uc) || is_lc(ctx, uc) || is_carry(ctx, uc)) && (user.port.str(ctx).at(0) == 'I') && !constval) { uc->ports[user.port].net = nullptr; } else if ((is_sb_mac16(ctx, uc) || uc->type == ctx->id("ICESTORM_DSP")) && (user.port != ctx->id("CLK") && ((constval && user.port == ctx->id("CE")) || (!constval && user.port != ctx->id("CE"))))) { uc->ports[user.port].net = nullptr; } else if (is_ram(ctx, uc) && !constval && user.port != ctx->id("RCLK") && user.port != ctx->id("RCLKN") && user.port != ctx->id("WCLK") && user.port != ctx->id("WCLKN") && user.port != ctx->id("RCLKE") && user.port != ctx->id("WCLKE")) { uc->ports[user.port].net = nullptr; } else { uc->ports[user.port].net = constnet; constnet->users.push_back(user); } } } orig->users.clear(); } // Pack constants (simple implementation) static void pack_constants(Context *ctx) { log_info("Packing constants..\n"); std::unique_ptr gnd_cell = create_ice_cell(ctx, ctx->id("ICESTORM_LC"), "$PACKER_GND"); gnd_cell->params[ctx->id("LUT_INIT")] = "0"; std::unique_ptr gnd_net = std::unique_ptr(new NetInfo); gnd_net->name = ctx->id("$PACKER_GND_NET"); gnd_net->driver.cell = gnd_cell.get(); gnd_net->driver.port = ctx->id("O"); gnd_cell->ports.at(ctx->id("O")).net = gnd_net.get(); NetInfo* gnd_net_info = gnd_net.get(); if (ctx->nets.find(ctx->id("$PACKER_GND_NET"))!=ctx->nets.end()) { gnd_net_info = ctx->nets.find(ctx->id("$PACKER_GND_NET"))->second.get(); } std::unique_ptr vcc_cell = create_ice_cell(ctx, ctx->id("ICESTORM_LC"), "$PACKER_VCC"); vcc_cell->params[ctx->id("LUT_INIT")] = "1"; std::unique_ptr vcc_net = std::unique_ptr(new NetInfo); vcc_net->name = ctx->id("$PACKER_VCC_NET"); vcc_net->driver.cell = vcc_cell.get(); vcc_net->driver.port = ctx->id("O"); vcc_cell->ports.at(ctx->id("O")).net = vcc_net.get(); NetInfo* vcc_net_info = vcc_net.get(); if (ctx->nets.find(ctx->id("$PACKER_VCC_NET"))!=ctx->nets.end()) { vcc_net_info = ctx->nets.find(ctx->id("$PACKER_VCC_NET"))->second.get(); } std::vector dead_nets; bool gnd_used = false; for (auto net : sorted(ctx->nets)) { NetInfo *ni = net.second; if (ni->driver.cell != nullptr && ni->driver.cell->type == ctx->id("GND")) { IdString drv_cell = ni->driver.cell->name; set_net_constant(ctx, ni, gnd_net_info, false); gnd_used = true; dead_nets.push_back(net.first); ctx->cells.erase(drv_cell); } else if (ni->driver.cell != nullptr && ni->driver.cell->type == ctx->id("VCC")) { IdString drv_cell = ni->driver.cell->name; set_net_constant(ctx, ni, vcc_net_info, true); dead_nets.push_back(net.first); ctx->cells.erase(drv_cell); } } if (gnd_used && (gnd_net_info == gnd_net.get())) { ctx->cells[gnd_cell->name] = std::move(gnd_cell); ctx->nets[gnd_net->name] = std::move(gnd_net); } // Vcc cell always inserted for now, as it may be needed during carry legalisation (TODO: trim later if actually // never used?) if (vcc_net_info == vcc_net.get()) { ctx->cells[vcc_cell->name] = std::move(vcc_cell); ctx->nets[vcc_net->name] = std::move(vcc_net); } for (auto dn : dead_nets) { ctx->nets.erase(dn); } } static BelId find_padin_gbuf(Context *ctx, BelId bel, IdString port_name) { BelId gb_bel; auto wire = ctx->getBelPinWire(bel, port_name); if (wire == WireId()) log_error("BEL '%s' has no global buffer connection available\n", ctx->getBelName(bel).c_str(ctx)); for (auto src_bel : ctx->getWireBelPins(wire)) { if (ctx->getBelType(src_bel.bel) == id_SB_GB && src_bel.pin == id_GLOBAL_BUFFER_OUTPUT) { gb_bel = src_bel.bel; break; } } return gb_bel; } static std::unique_ptr create_padin_gbuf(Context *ctx, CellInfo *cell, IdString port_name, std::string gbuf_name) { // Find the matching SB_GB BEL connected to the same global network BelId bel = ctx->getBelByName(ctx->id(cell->attrs[ctx->id("BEL")])); BelId gb_bel = find_padin_gbuf(ctx, bel, port_name); NPNR_ASSERT(gb_bel != BelId()); // Create a SB_GB Cell and lock it there std::unique_ptr gb = create_ice_cell(ctx, ctx->id("SB_GB"), gbuf_name); gb->attrs[ctx->id("FOR_PAD_IN")] = "1"; gb->attrs[ctx->id("BEL")] = ctx->getBelName(gb_bel).str(ctx); // Reconnect the net to that port for easier identification it's a global net replace_port(cell, port_name, gb.get(), id_GLOBAL_BUFFER_OUTPUT); return gb; } static bool is_nextpnr_iob(Context *ctx, CellInfo *cell) { return cell->type == ctx->id("$nextpnr_ibuf") || cell->type == ctx->id("$nextpnr_obuf") || cell->type == ctx->id("$nextpnr_iobuf"); } static bool is_ice_iob(const Context *ctx, const CellInfo *cell) { return is_sb_io(ctx, cell) || is_sb_gb_io(ctx, cell); } // Pack IO buffers static void pack_io(Context *ctx) { std::unordered_set packed_cells; std::unordered_set delete_nets; std::vector> new_cells; log_info("Packing IOs..\n"); for (auto cell : sorted(ctx->cells)) { CellInfo *ci = cell.second; if (is_nextpnr_iob(ctx, ci)) { CellInfo *sb = nullptr, *rgb = nullptr; if (ci->type == ctx->id("$nextpnr_ibuf") || ci->type == ctx->id("$nextpnr_iobuf")) { sb = net_only_drives(ctx, ci->ports.at(ctx->id("O")).net, is_ice_iob, ctx->id("PACKAGE_PIN"), true, ci); } else if (ci->type == ctx->id("$nextpnr_obuf")) { NetInfo *net = ci->ports.at(ctx->id("I")).net; sb = net_only_drives(ctx, net, is_ice_iob, ctx->id("PACKAGE_PIN"), true, ci); if (net && net->driver.cell && is_sb_rgba_drv(ctx, net->driver.cell)) rgb = net->driver.cell; } if (sb != nullptr) { // Trivial case, SB_IO used. Just destroy the net and the // iobuf log_info("%s feeds SB_IO %s, removing %s %s.\n", ci->name.c_str(ctx), sb->name.c_str(ctx), ci->type.c_str(ctx), ci->name.c_str(ctx)); NetInfo *net = sb->ports.at(ctx->id("PACKAGE_PIN")).net; if (((ci->type == ctx->id("$nextpnr_ibuf") || ci->type == ctx->id("$nextpnr_iobuf")) && net->users.size() > 1) || (ci->type == ctx->id("$nextpnr_obuf") && (net->users.size() > 2 || net->driver.cell != nullptr))) log_error("PACKAGE_PIN of %s '%s' connected to more than a single top level IO.\n", sb->type.c_str(ctx), sb->name.c_str(ctx)); if (net != nullptr) { delete_nets.insert(net->name); sb->ports.at(ctx->id("PACKAGE_PIN")).net = nullptr; } if (ci->type == ctx->id("$nextpnr_iobuf")) { NetInfo *net2 = ci->ports.at(ctx->id("I")).net; if (net2 != nullptr) { delete_nets.insert(net2->name); } } } else if (rgb != nullptr) { log_info("%s use by SB_RGBA_DRV %s, not creating SB_IO\n", ci->name.c_str(ctx), rgb->name.c_str(ctx)); disconnect_port(ctx, ci, ctx->id("I")); packed_cells.insert(ci->name); continue; } else { // Create a SB_IO buffer std::unique_ptr ice_cell = create_ice_cell(ctx, ctx->id("SB_IO"), ci->name.str(ctx) + "$sb_io"); nxio_to_sb(ctx, ci, ice_cell.get(), packed_cells); new_cells.push_back(std::move(ice_cell)); sb = new_cells.back().get(); } packed_cells.insert(ci->name); std::copy(ci->attrs.begin(), ci->attrs.end(), std::inserter(sb->attrs, sb->attrs.begin())); } else if (is_sb_io(ctx, ci) || is_sb_gb_io(ctx, ci)) { NetInfo *net = ci->ports.at(ctx->id("PACKAGE_PIN")).net; if ((net != nullptr) && (net->users.size() > 1)) log_error("PACKAGE_PIN of %s '%s' connected to more than a single top level IO.\n", ci->type.c_str(ctx), ci->name.c_str(ctx)); } } for (auto cell : sorted(ctx->cells)) { CellInfo *ci = cell.second; if (is_sb_gb_io(ctx, ci)) { // If something is connecto the GLOBAL OUTPUT, create the fake 'matching' SB_GB std::unique_ptr gb = create_padin_gbuf(ctx, ci, id_GLOBAL_BUFFER_OUTPUT, "$gbuf_" + ci->name.str(ctx) + "_io"); new_cells.push_back(std::move(gb)); // Make it a normal SB_IO with global marker ci->type = ctx->id("SB_IO"); ci->attrs[ctx->id("GLOBAL")] = "1"; } else if (is_sb_io(ctx, ci)) { // Disconnect unused inputs NetInfo *net_in0 = ci->ports.count(id_D_IN_0) ? ci->ports[id_D_IN_0].net : nullptr; NetInfo *net_in1 = ci->ports.count(id_D_IN_1) ? ci->ports[id_D_IN_1].net : nullptr; if (net_in0 != nullptr && net_in0->users.size() == 0) { delete_nets.insert(net_in0->name); ci->ports[id_D_IN_0].net = nullptr; } if (net_in1 != nullptr && net_in1->users.size() == 0) { delete_nets.insert(net_in1->name); ci->ports[id_D_IN_1].net = nullptr; } } } for (auto pcell : packed_cells) { ctx->cells.erase(pcell); } for (auto dnet : delete_nets) { ctx->nets.erase(dnet); } for (auto &ncell : new_cells) { ctx->cells[ncell->name] = std::move(ncell); } } // Return true if a port counts as "logic" for global promotion static bool is_logic_port(BaseCtx *ctx, const PortRef &port) { if (is_clock_port(ctx, port) || is_reset_port(ctx, port) || is_enable_port(ctx, port)) return false; return !is_sb_io(ctx, port.cell) && !is_sb_gb_io(ctx, port.cell) && !is_gbuf(ctx, port.cell) && !is_sb_pll40(ctx, port.cell); } static void insert_global(Context *ctx, NetInfo *net, bool is_reset, bool is_cen, bool is_logic, int fanout) { log_info("promoting %s%s%s%s (fanout %d)\n", net->name.c_str(ctx), is_reset ? " [reset]" : "", is_cen ? " [cen]" : "", is_logic ? " [logic]" : "", fanout); std::string glb_name = net->name.str(ctx) + std::string("_$glb_") + (is_reset ? "sr" : (is_cen ? "ce" : "clk")); std::unique_ptr gb = create_ice_cell(ctx, ctx->id("SB_GB"), "$gbuf_" + glb_name); gb->ports[ctx->id("USER_SIGNAL_TO_GLOBAL_BUFFER")].net = net; PortRef pr; pr.cell = gb.get(); pr.port = ctx->id("USER_SIGNAL_TO_GLOBAL_BUFFER"); net->users.push_back(pr); pr.cell = gb.get(); pr.port = ctx->id("GLOBAL_BUFFER_OUTPUT"); std::unique_ptr glbnet = std::unique_ptr(new NetInfo()); glbnet->name = ctx->id(glb_name); glbnet->driver = pr; gb->ports[ctx->id("GLOBAL_BUFFER_OUTPUT")].net = glbnet.get(); std::vector keep_users; for (auto user : net->users) { if (is_clock_port(ctx, user) || (is_reset && is_reset_port(ctx, user)) || (is_cen && is_enable_port(ctx, user)) || (is_logic && is_logic_port(ctx, user))) { user.cell->ports[user.port].net = glbnet.get(); glbnet->users.push_back(user); } else { keep_users.push_back(user); } } net->users = keep_users; if (net->clkconstr) { glbnet->clkconstr = std::unique_ptr(new ClockConstraint()); glbnet->clkconstr->low = net->clkconstr->low; glbnet->clkconstr->high = net->clkconstr->high; glbnet->clkconstr->period = net->clkconstr->period; } ctx->nets[glbnet->name] = std::move(glbnet); ctx->cells[gb->name] = std::move(gb); } // Simple global promoter (clock only) static void promote_globals(Context *ctx) { log_info("Promoting globals..\n"); const int logic_fanout_thresh = 15; const int enable_fanout_thresh = 15; const int reset_fanout_thresh = 15; std::map clock_count, reset_count, cen_count, logic_count; for (auto net : sorted(ctx->nets)) { NetInfo *ni = net.second; if (ni->driver.cell != nullptr && !ctx->isGlobalNet(ni)) { clock_count[net.first] = 0; reset_count[net.first] = 0; cen_count[net.first] = 0; for (auto user : ni->users) { if (is_clock_port(ctx, user)) clock_count[net.first]++; if (is_reset_port(ctx, user)) reset_count[net.first]++; if (is_enable_port(ctx, user)) cen_count[net.first]++; if (is_logic_port(ctx, user)) logic_count[net.first]++; } } } int prom_globals = 0, prom_resets = 0, prom_cens = 0, prom_logics = 0; int gbs_available = 8, resets_available = 4, cens_available = 4; for (auto &cell : ctx->cells) if (is_gbuf(ctx, cell.second.get())) { /* One less buffer available */ --gbs_available; /* And possibly limits what we can promote */ if (cell.second->attrs.find(ctx->id("BEL")) != cell.second->attrs.end()) { /* If the SB_GB is locked, doesn't matter what it drives */ BelId bel = ctx->getBelByName(ctx->id(cell.second->attrs[ctx->id("BEL")])); int glb_id = ctx->getDrivenGlobalNetwork(bel); if ((glb_id % 2) == 0) resets_available--; else if ((glb_id % 2) == 1) cens_available--; } else { /* If it's free to move around, then look at what it drives */ NetInfo *ni = cell.second->ports[id_GLOBAL_BUFFER_OUTPUT].net; for (auto user : ni->users) { if (is_reset_port(ctx, user)) { resets_available--; break; } else if (is_enable_port(ctx, user)) { cens_available--; break; } } } } while (prom_globals < gbs_available) { auto global_clock = std::max_element(clock_count.begin(), clock_count.end(), [](const std::pair &a, const std::pair &b) { return a.second < b.second; }); auto global_reset = std::max_element(reset_count.begin(), reset_count.end(), [](const std::pair &a, const std::pair &b) { return a.second < b.second; }); auto global_cen = std::max_element(cen_count.begin(), cen_count.end(), [](const std::pair &a, const std::pair &b) { return a.second < b.second; }); auto global_logic = std::max_element(logic_count.begin(), logic_count.end(), [](const std::pair &a, const std::pair &b) { return a.second < b.second; }); if (global_clock->second == 0 && prom_logics < 4 && global_logic->second > logic_fanout_thresh && (global_logic->second > global_cen->second || prom_cens >= cens_available) && (global_logic->second > global_reset->second || prom_resets >= resets_available) && bool_or_default(ctx->settings, ctx->id("promote_logic"), false)) { NetInfo *logicnet = ctx->nets[global_logic->first].get(); insert_global(ctx, logicnet, false, false, true, global_logic->second); ++prom_globals; ++prom_logics; clock_count.erase(logicnet->name); reset_count.erase(logicnet->name); cen_count.erase(logicnet->name); logic_count.erase(logicnet->name); } else if (global_reset->second > global_clock->second && prom_resets < resets_available && global_reset->second > reset_fanout_thresh) { NetInfo *rstnet = ctx->nets[global_reset->first].get(); insert_global(ctx, rstnet, true, false, false, global_reset->second); ++prom_globals; ++prom_resets; clock_count.erase(rstnet->name); reset_count.erase(rstnet->name); cen_count.erase(rstnet->name); logic_count.erase(rstnet->name); } else if (global_cen->second > global_clock->second && prom_cens < cens_available && global_cen->second > enable_fanout_thresh) { NetInfo *cennet = ctx->nets[global_cen->first].get(); insert_global(ctx, cennet, false, true, false, global_cen->second); ++prom_globals; ++prom_cens; clock_count.erase(cennet->name); reset_count.erase(cennet->name); cen_count.erase(cennet->name); logic_count.erase(cennet->name); } else if (global_clock->second != 0) { NetInfo *clknet = ctx->nets[global_clock->first].get(); insert_global(ctx, clknet, false, false, false, global_clock->second); ++prom_globals; clock_count.erase(clknet->name); reset_count.erase(clknet->name); cen_count.erase(clknet->name); logic_count.erase(clknet->name); } else { break; } } } // Figure out where to place PLLs static void place_plls(Context *ctx) { std::map> pll_all_bels; std::map pll_used_bels; std::vector pll_cells; std::map bel2io; std::map bel2gb; log_info("Placing PLLs..\n"); // Find all the PLLs BELs and matching IO sites and global networks for (auto bel : ctx->getBels()) { if (ctx->getBelType(bel) != id_ICESTORM_PLL) continue; if (ctx->isBelLocked(bel)) continue; auto io_a_pin = ctx->getIOBSharingPLLPin(bel, id_PLLOUT_A); auto io_b_pin = ctx->getIOBSharingPLLPin(bel, id_PLLOUT_B); auto gb_a = find_padin_gbuf(ctx, bel, id_PLLOUT_A_GLOBAL); auto gb_b = find_padin_gbuf(ctx, bel, id_PLLOUT_B_GLOBAL); pll_all_bels[bel] = std::make_tuple(io_a_pin, gb_a, io_b_pin, gb_b); } // Find all the PLLs cells we need to place and do pre-checks for (auto cell : sorted(ctx->cells)) { CellInfo *ci = cell.second; if (!is_sb_pll40(ctx, ci)) continue; // If it's constrained already, add to already used list if (ci->attrs.count(ctx->id("BEL"))) { BelId bel_constrain = ctx->getBelByName(ctx->id(ci->attrs[ctx->id("BEL")])); if (pll_all_bels.count(bel_constrain) == 0) log_error("PLL '%s' is constrained to invalid BEL '%s'\n", ci->name.c_str(ctx), ci->attrs[ctx->id("BEL")].c_str()); pll_used_bels[bel_constrain] = ci; } // Add it to our list of PLLs to process pll_cells.push_back(ci); } // Scan all the PAD PLLs for (auto ci : pll_cells) { if (!is_sb_pll40_pad(ctx, ci)) continue; // Check PACKAGEPIN connection if (!ci->ports.count(ctx->id("PACKAGEPIN"))) log_error("PLL '%s' is of PAD type but doesn't have a PACKAGEPIN port\n", ci->name.c_str(ctx)); NetInfo *ni = ci->ports.at(ctx->id("PACKAGEPIN")).net; if (ni == nullptr || ni->driver.cell == nullptr) log_error("PLL '%s' is of PAD type but doesn't have a valid PACKAGEPIN connection\n", ci->name.c_str(ctx)); CellInfo *io_cell = ni->driver.cell; if (io_cell->type != id_SB_IO || ni->driver.port != id_D_IN_0) log_error("PLL '%s' has a PACKAGEPIN driven by an %s, should be directly connected to an input " "SB_IO.D_IN_0 port\n", ci->name.c_str(ctx), io_cell->type.c_str(ctx)); if (ni->users.size() != 1) log_error("PLL '%s' clock input '%s' can only drive PLL\n", ci->name.c_str(ctx), ni->name.c_str(ctx)); if (!io_cell->attrs.count(ctx->id("BEL"))) log_error("PLL '%s' PACKAGEPIN SB_IO '%s' is unconstrained\n", ci->name.c_str(ctx), io_cell->name.c_str(ctx)); BelId io_bel = ctx->getBelByName(ctx->id(io_cell->attrs.at(ctx->id("BEL")))); BelId found_bel; // Find the PLL BEL that would suit that connection for (auto pll_bel : pll_all_bels) { if (std::get<0>(pll_bel.second).bel == io_bel) { found_bel = pll_bel.first; break; } } if (found_bel == BelId()) log_error("PLL '%s' PACKAGEPIN SB_IO '%s' is not connected to any PLL BEL\n", ci->name.c_str(ctx), io_cell->name.c_str(ctx)); if (pll_used_bels.count(found_bel)) { CellInfo *conflict_cell = pll_used_bels.at(found_bel); if (conflict_cell == ci) continue; log_error("PLL '%s' PACKAGEPIN forces it to BEL %s but BEL is already assigned to PLL '%s'\n", ci->name.c_str(ctx), ctx->getBelName(found_bel).c_str(ctx), conflict_cell->name.c_str(ctx)); } // Is it user constrained ? if (ci->attrs.count(ctx->id("BEL"))) { // Yes. Check it actually matches ! BelId bel_constrain = ctx->getBelByName(ctx->id(ci->attrs[ctx->id("BEL")])); if (bel_constrain != found_bel) log_error("PLL '%s' is user constrained to %s but can only be placed in %s based on its PACKAGEPIN " "connection\n", ci->name.c_str(ctx), ctx->getBelName(bel_constrain).c_str(ctx), ctx->getBelName(found_bel).c_str(ctx)); } else { // No, we can constrain it ourselves ci->attrs[ctx->id("BEL")] = ctx->getBelName(found_bel).str(ctx); pll_used_bels[found_bel] = ci; } // Inform user log_info(" constrained PLL '%s' to %s\n", ci->name.c_str(ctx), ctx->getBelName(found_bel).c_str(ctx)); } // Scan all SB_IOs to check for conflict with PLL BELs for (auto io_cell : sorted(ctx->cells)) { CellInfo *io_ci = io_cell.second; if (!is_sb_io(ctx, io_ci)) continue; // Only consider bound IO that are used as inputs if (!io_ci->attrs.count(ctx->id("BEL"))) continue; if ((!io_ci->ports.count(id_D_IN_0) || (io_ci->ports[id_D_IN_0].net == nullptr)) && (!io_ci->ports.count(id_D_IN_1) || (io_ci->ports[id_D_IN_1].net == nullptr))) continue; // Check all placed PLL (either forced by user, or forced by PACKAGEPIN) BelId io_bel = ctx->getBelByName(ctx->id(io_ci->attrs[ctx->id("BEL")])); for (auto placed_pll : pll_used_bels) { BelPin pll_io_a, pll_io_b; BelId gb_a, gb_b; std::tie(pll_io_a, gb_a, pll_io_b, gb_b) = pll_all_bels[placed_pll.first]; if (io_bel == pll_io_a.bel) { // All the PAD type PLL stuff already checked above,so only // check for conflict with a user placed CORE PLL if (!is_sb_pll40_pad(ctx, placed_pll.second)) log_error("PLL '%s' A output conflict with SB_IO '%s' that's used as input\n", placed_pll.second->name.c_str(ctx), io_cell.second->name.c_str(ctx)); } else if (io_bel == pll_io_b.bel) { if (is_sb_pll40_dual(ctx, placed_pll.second)) log_error("PLL '%s' B output conflicts with SB_IO '%s' that's used as input\n", placed_pll.second->name.c_str(ctx), io_cell.second->name.c_str(ctx)); } } // Save for later checks bel2io[io_bel] = io_ci; } // Scan all SB_GBs to check for conflicts with PLL BELs for (auto gb_cell : sorted(ctx->cells)) { CellInfo *gb_ci = gb_cell.second; if (!is_gbuf(ctx, gb_ci)) continue; // Only consider the bound ones if (!gb_ci->attrs.count(ctx->id("BEL"))) continue; // Check all placed PLL (either forced by user, or forced by PACKAGEPIN) BelId gb_bel = ctx->getBelByName(ctx->id(gb_ci->attrs[ctx->id("BEL")])); for (auto placed_pll : pll_used_bels) { CellInfo *ci = placed_pll.second; // Used global connections bool gb_a_used = ci->ports.count(id_PLLOUT_A_GLOBAL) && (ci->ports[id_PLLOUT_A_GLOBAL].net != nullptr) && (ci->ports[id_PLLOUT_A_GLOBAL].net->users.size() > 0); bool gb_b_used = is_sb_pll40_dual(ctx, ci) && ci->ports.count(id_PLLOUT_B_GLOBAL) && (ci->ports[id_PLLOUT_B_GLOBAL].net != nullptr) && (ci->ports[id_PLLOUT_B_GLOBAL].net->users.size() > 0); // Check for conflict BelPin pll_io_a, pll_io_b; BelId gb_a, gb_b; std::tie(pll_io_a, gb_a, pll_io_b, gb_b) = pll_all_bels[placed_pll.first]; if (gb_a_used && (gb_bel == gb_a)) { log_error("PLL '%s' A output conflict with SB_GB '%s'\n", placed_pll.second->name.c_str(ctx), gb_cell.second->name.c_str(ctx)); } if (gb_b_used && (gb_bel == gb_b)) { log_error("PLL '%s' B output conflicts with SB_GB '%s'\n", placed_pll.second->name.c_str(ctx), gb_cell.second->name.c_str(ctx)); } } // Save for later checks bel2gb[gb_bel] = gb_ci; } // Scan all the CORE PLLs and place them in remaining available PLL BELs // (in two pass ... first do the dual ones, harder to place, then single port) for (int i = 0; i < 2; i++) { for (auto ci : pll_cells) { if (is_sb_pll40_pad(ctx, ci)) continue; if (is_sb_pll40_dual(ctx, ci) ^ i) continue; // Check REFERENCECLK connection if (!ci->ports.count(id_REFERENCECLK)) log_error("PLL '%s' is of CORE type but doesn't have a REFERENCECLK port\n", ci->name.c_str(ctx)); NetInfo *ni = ci->ports.at(id_REFERENCECLK).net; if (ni == nullptr || ni->driver.cell == nullptr) log_error("PLL '%s' is of CORE type but doesn't have a valid REFERENCECLK connection\n", ci->name.c_str(ctx)); // Used global connections bool gb_a_used = ci->ports.count(id_PLLOUT_A_GLOBAL) && (ci->ports[id_PLLOUT_A_GLOBAL].net != nullptr) && (ci->ports[id_PLLOUT_A_GLOBAL].net->users.size() > 0); bool gb_b_used = is_sb_pll40_dual(ctx, ci) && ci->ports.count(id_PLLOUT_B_GLOBAL) && (ci->ports[id_PLLOUT_B_GLOBAL].net != nullptr) && (ci->ports[id_PLLOUT_B_GLOBAL].net->users.size() > 0); // Could this be a PAD PLL ? bool could_be_pad = false; BelId pad_bel; if (ni->users.size() == 1 && is_sb_io(ctx, ni->driver.cell) && ni->driver.cell->attrs.count(ctx->id("BEL"))) pad_bel = ctx->getBelByName(ctx->id(ni->driver.cell->attrs[ctx->id("BEL")])); // Find a BEL for it BelId found_bel; for (auto bel_pll : pll_all_bels) { if (pll_used_bels.count(bel_pll.first)) continue; BelPin pll_io_a, pll_io_b; BelId gb_a, gb_b; std::tie(pll_io_a, gb_a, pll_io_b, gb_b) = bel_pll.second; if (bel2io.count(pll_io_a.bel)) { if (pll_io_a.bel == pad_bel) could_be_pad = !bel2io.count(pll_io_b.bel) || !is_sb_pll40_dual(ctx, ci); continue; } if (bel2io.count(pll_io_b.bel) && is_sb_pll40_dual(ctx, ci)) continue; if (gb_a_used && bel2gb.count(gb_a)) continue; if (gb_b_used && bel2gb.count(gb_b)) continue; found_bel = bel_pll.first; break; } // Apply constrain & Inform user of result if (found_bel == BelId()) log_error("PLL '%s' couldn't be placed anywhere, no suitable BEL found.%s\n", ci->name.c_str(ctx), could_be_pad ? " Did you mean to use a PAD PLL ?" : ""); log_info(" constrained PLL '%s' to %s\n", ci->name.c_str(ctx), ctx->getBelName(found_bel).c_str(ctx)); if (could_be_pad) log_info(" (given its connections, this PLL could have been a PAD PLL)\n"); ci->attrs[ctx->id("BEL")] = ctx->getBelName(found_bel).str(ctx); pll_used_bels[found_bel] = ci; } } } // spliceLUT adds a pass-through LUT LC between the given cell's output port // and either all users or only non_LUT users. static std::unique_ptr spliceLUT(Context *ctx, CellInfo *ci, IdString portId, bool onlyNonLUTs) { auto port = ci->ports[portId]; NPNR_ASSERT(port.net != nullptr); // Create pass-through LUT. std::unique_ptr pt = create_ice_cell(ctx, ctx->id("ICESTORM_LC"), ci->name.str(ctx) + "$nextpnr_" + portId.str(ctx) + "_lut_through"); pt->params[ctx->id("LUT_INIT")] = "65280"; // output is always I3 // Create LUT output net. std::unique_ptr out_net = std::unique_ptr(new NetInfo); out_net->name = ctx->id(ci->name.str(ctx) + "$nextnr_" + portId.str(ctx) + "_lut_through_net"); out_net->driver.cell = pt.get(); out_net->driver.port = ctx->id("O"); pt->ports.at(ctx->id("O")).net = out_net.get(); // New users of the original cell's port std::vector new_users; for (const auto &user : port.net->users) { if (onlyNonLUTs && user.cell->type == ctx->id("ICESTORM_LC")) { new_users.push_back(user); continue; } // Rewrite pointer into net in user. user.cell->ports[user.port].net = out_net.get(); // Add user to net. PortRef pr; pr.cell = user.cell; pr.port = user.port; out_net->users.push_back(pr); } // Add LUT to new users. PortRef pr; pr.cell = pt.get(); pr.port = ctx->id("I3"); new_users.push_back(pr); pt->ports.at(ctx->id("I3")).net = port.net; // Replace users of the original net. port.net->users = new_users; ctx->nets[out_net->name] = std::move(out_net); return pt; } // Force placement for cells that are unique anyway static BelId cell_place_unique(Context *ctx, CellInfo *ci) { for (auto bel : ctx->getBels()) { if (ctx->getBelType(bel) != ci->type) continue; if (ctx->isBelLocked(bel)) continue; IdString bel_name = ctx->getBelName(bel); ci->attrs[ctx->id("BEL")] = bel_name.str(ctx); log_info(" constrained %s '%s' to %s\n", ci->type.c_str(ctx), ci->name.c_str(ctx), bel_name.c_str(ctx)); return bel; } log_error("Unable to place cell '%s' of type '%s'\n", ci->name.c_str(ctx), ci->type.c_str(ctx)); } // Pack special functions static void pack_special(Context *ctx) { log_info("Packing special functions..\n"); std::unordered_set packed_cells; std::vector> new_cells; for (auto cell : sorted(ctx->cells)) { CellInfo *ci = cell.second; if (is_sb_lfosc(ctx, ci)) { std::unique_ptr packed = create_ice_cell(ctx, ctx->id("ICESTORM_LFOSC"), ci->name.str(ctx) + "_OSC"); packed_cells.insert(ci->name); cell_place_unique(ctx, packed.get()); replace_port(ci, ctx->id("CLKLFEN"), packed.get(), ctx->id("CLKLFEN")); replace_port(ci, ctx->id("CLKLFPU"), packed.get(), ctx->id("CLKLFPU")); if (bool_or_default(ci->attrs, ctx->id("ROUTE_THROUGH_FABRIC"))) { replace_port(ci, ctx->id("CLKLF"), packed.get(), ctx->id("CLKLF_FABRIC")); } else { replace_port(ci, ctx->id("CLKLF"), packed.get(), ctx->id("CLKLF")); std::unique_ptr gb = create_padin_gbuf(ctx, packed.get(), ctx->id("CLKLF"), "$gbuf_" + ci->name.str(ctx) + "_lfosc"); new_cells.push_back(std::move(gb)); } new_cells.push_back(std::move(packed)); } else if (is_sb_hfosc(ctx, ci)) { std::unique_ptr packed = create_ice_cell(ctx, ctx->id("ICESTORM_HFOSC"), ci->name.str(ctx) + "_OSC"); packed_cells.insert(ci->name); cell_place_unique(ctx, packed.get()); packed->params[ctx->id("TRIM_EN")] = str_or_default(ci->params, ctx->id("TRIM_EN"), "0b0"); packed->params[ctx->id("CLKHF_DIV")] = str_or_default(ci->params, ctx->id("CLKHF_DIV"), "0b00"); replace_port(ci, ctx->id("CLKHFEN"), packed.get(), ctx->id("CLKHFEN")); replace_port(ci, ctx->id("CLKHFPU"), packed.get(), ctx->id("CLKHFPU")); for (int i = 0; i < 10; i++) { auto port = ctx->id("TRIM" + std::to_string(i)); replace_port(ci, port, packed.get(), port); } if (bool_or_default(ci->attrs, ctx->id("ROUTE_THROUGH_FABRIC"))) { replace_port(ci, ctx->id("CLKHF"), packed.get(), ctx->id("CLKHF_FABRIC")); } else { replace_port(ci, ctx->id("CLKHF"), packed.get(), ctx->id("CLKHF")); std::unique_ptr gb = create_padin_gbuf(ctx, packed.get(), ctx->id("CLKHF"), "$gbuf_" + ci->name.str(ctx) + "_hfosc"); new_cells.push_back(std::move(gb)); } new_cells.push_back(std::move(packed)); } else if (is_sb_spram(ctx, ci)) { std::unique_ptr packed = create_ice_cell(ctx, ctx->id("ICESTORM_SPRAM"), ci->name.str(ctx) + "_RAM"); packed_cells.insert(ci->name); for (auto attr : ci->attrs) packed->attrs[attr.first] = attr.second; for (auto port : ci->ports) { PortInfo &pi = port.second; std::string newname = pi.name.str(ctx); size_t bpos = newname.find('['); if (bpos != std::string::npos) { newname = newname.substr(0, bpos) + "_" + newname.substr(bpos + 1, (newname.size() - bpos) - 2); } replace_port(ci, ctx->id(pi.name.c_str(ctx)), packed.get(), ctx->id(newname)); } new_cells.push_back(std::move(packed)); } else if (is_sb_mac16(ctx, ci)) { std::unique_ptr packed = create_ice_cell(ctx, ctx->id("ICESTORM_DSP"), ci->name.str(ctx) + "_DSP"); packed_cells.insert(ci->name); for (auto attr : ci->attrs) packed->attrs[attr.first] = attr.second; for (auto param : ci->params) packed->params[param.first] = param.second; for (auto port : ci->ports) { PortInfo &pi = port.second; std::string newname = pi.name.str(ctx); size_t bpos = newname.find('['); if (bpos != std::string::npos) { newname = newname.substr(0, bpos) + "_" + newname.substr(bpos + 1, (newname.size() - bpos) - 2); } replace_port(ci, ctx->id(pi.name.c_str(ctx)), packed.get(), ctx->id(newname)); } new_cells.push_back(std::move(packed)); } else if (is_sb_rgba_drv(ctx, ci)) { /* Force placement (no choices anyway) */ cell_place_unique(ctx, ci); /* Disconnect all external ports and check there is no users (they should have been * dealth with during IO packing */ for (auto port : ci->ports) { PortInfo &pi = port.second; NetInfo *net = pi.net; if (net == nullptr) continue; if ((pi.name != ctx->id("RGB0")) && (pi.name != ctx->id("RGB1")) && (pi.name != ctx->id("RGB2"))) continue; if (net->users.size() > 0) log_error("SB_RGBA_DRV port connected to more than just package pin !\n"); ctx->nets.erase(net->name); } ci->ports.erase(ctx->id("RGB0")); ci->ports.erase(ctx->id("RGB1")); ci->ports.erase(ctx->id("RGB2")); } else if (is_sb_ledda_ip(ctx, ci)) { /* Force placement (no choices anyway) */ cell_place_unique(ctx, ci); } else if (is_sb_i2c(ctx, ci) || is_sb_spi(ctx, ci)) { const std::map, Loc> map_ba74 = { {std::make_tuple(id_SB_SPI, "0b0000"), Loc(0, 0, 0)}, {std::make_tuple(id_SB_I2C, "0b0001"), Loc(0, 31, 0)}, {std::make_tuple(id_SB_SPI, "0b0010"), Loc(25, 0, 1)}, {std::make_tuple(id_SB_I2C, "0b0011"), Loc(25, 31, 0)}, }; if (map_ba74.find(std::make_tuple(ci->type, ci->params[ctx->id("BUS_ADDR74")])) == map_ba74.end()) log_error("Invalid value for BUS_ADDR74 for cell '%s' of type '%s'\n", ci->name.c_str(ctx), ci->type.c_str(ctx)); Loc bel_loc = map_ba74.at(std::make_tuple(ci->type, ci->params[ctx->id("BUS_ADDR74")])); BelId bel = ctx->getBelByLocation(bel_loc); if (bel == BelId() || ctx->getBelType(bel) != ci->type) log_error("Unable to find placement for cell '%s' of type '%s'\n", ci->name.c_str(ctx), ci->type.c_str(ctx)); IdString bel_name = ctx->getBelName(bel); ci->attrs[ctx->id("BEL")] = bel_name.str(ctx); log_info(" constrained %s '%s' to %s\n", ci->type.c_str(ctx), ci->name.c_str(ctx), bel_name.c_str(ctx)); } else if (is_sb_pll40(ctx, ci)) { bool is_pad = is_sb_pll40_pad(ctx, ci); bool is_core = !is_pad; std::unique_ptr packed = create_ice_cell(ctx, ctx->id("ICESTORM_PLL"), ci->name.str(ctx) + "_PLL"); packed->attrs[ctx->id("TYPE")] = ci->type.str(ctx); packed_cells.insert(ci->name); if (!is_sb_pll40_dual(ctx, ci)) { // Remove second output, so a buffer isn't created for it, for these // cell types with only one output packed->ports.erase(ctx->id("PLLOUT_B")); packed->ports.erase(ctx->id("PLLOUT_B_GLOBAL")); } for (auto attr : ci->attrs) packed->attrs[attr.first] = attr.second; for (auto param : ci->params) packed->params[param.first] = param.second; const std::map pos_map_name = { {ctx->id("PLLOUT_SELECT"), ctx->id("PLLOUT_SELECT_A")}, {ctx->id("PLLOUT_SELECT_PORTA"), ctx->id("PLLOUT_SELECT_A")}, {ctx->id("PLLOUT_SELECT_PORTB"), ctx->id("PLLOUT_SELECT_B")}, }; const std::map pos_map_val = { {"GENCLK", 0}, {"GENCLK_HALF", 1}, {"SHIFTREG_90deg", 2}, {"SHIFTREG_0deg", 3}, }; for (auto param : ci->params) if (pos_map_name.find(param.first) != pos_map_name.end()) { if (pos_map_val.find(param.second) == pos_map_val.end()) log_error("Invalid PLL output selection '%s'\n", param.second.c_str()); packed->params[pos_map_name.at(param.first)] = std::to_string(pos_map_val.at(param.second)); } auto feedback_path = packed->params[ctx->id("FEEDBACK_PATH")]; std::string fbp_value = feedback_path == "DELAY" ? "0" : feedback_path == "SIMPLE" ? "1" : feedback_path == "PHASE_AND_DELAY" ? "2" : feedback_path == "EXTERNAL" ? "6" : std::string(feedback_path); if (!std::all_of(fbp_value.begin(), fbp_value.end(), isdigit)) log_error("PLL '%s' has unsupported FEEDBACK_PATH value '%s'\n", ci->name.c_str(ctx), feedback_path.c_str()); packed->params[ctx->id("FEEDBACK_PATH")] = fbp_value; packed->params[ctx->id("PLLTYPE")] = std::to_string(sb_pll40_type(ctx, ci)); NetInfo *pad_packagepin_net = nullptr; for (auto port : ci->ports) { PortInfo &pi = port.second; std::string newname = pi.name.str(ctx); size_t bpos = newname.find('['); if (bpos != std::string::npos) { newname = newname.substr(0, bpos) + "_" + newname.substr(bpos + 1, (newname.size() - bpos) - 2); } if (pi.name == ctx->id("PLLOUTCOREA") || pi.name == ctx->id("PLLOUTCORE")) newname = "PLLOUT_A"; if (pi.name == ctx->id("PLLOUTCOREB")) newname = "PLLOUT_B"; if (pi.name == ctx->id("PLLOUTGLOBALA") || pi.name == ctx->id("PLLOUTGLOBAL")) newname = "PLLOUT_A_GLOBAL"; if (pi.name == ctx->id("PLLOUTGLOBALB")) newname = "PLLOUT_B_GLOBAL"; if (pi.name == ctx->id("PACKAGEPIN")) { if (!is_pad) { log_error("PLL '%s' has a PACKAGEPIN but is not a PAD PLL\n", ci->name.c_str(ctx)); } else { // We drop this port and instead place the PLL adequately below. pad_packagepin_net = port.second.net; NPNR_ASSERT(pad_packagepin_net != nullptr); continue; } } if (pi.name == ctx->id("REFERENCECLK")) { if (!is_core) log_error("PLL '%s' has a REFERENCECLK but is not a CORE PLL\n", ci->name.c_str(ctx)); } if (packed->ports.count(ctx->id(newname)) == 0) { if (ci->ports[pi.name].net == nullptr) { log_warning("PLL '%s' has unknown unconnected port '%s' - ignoring\n", ci->name.c_str(ctx), pi.name.c_str(ctx)); continue; } else { if (ctx->force) { log_error("PLL '%s' has unknown connected port '%s'\n", ci->name.c_str(ctx), pi.name.c_str(ctx)); } else { log_warning("PLL '%s' has unknown connected port '%s' - ignoring\n", ci->name.c_str(ctx), pi.name.c_str(ctx)); continue; } } } replace_port(ci, ctx->id(pi.name.c_str(ctx)), packed.get(), ctx->id(newname)); } // PLL must have been placed already in place_plls() BelId pll_bel = ctx->getBelByName(ctx->id(packed->attrs[ctx->id("BEL")])); NPNR_ASSERT(pll_bel != BelId()); // Deal with PAD PLL peculiarities if (is_pad) { NPNR_ASSERT(pad_packagepin_net != nullptr); auto pll_packagepin_driver = pad_packagepin_net->driver; NPNR_ASSERT(pll_packagepin_driver.cell != nullptr); auto packagepin_cell = pll_packagepin_driver.cell; auto packagepin_bel_name = packagepin_cell->attrs.find(ctx->id("BEL")); // Set an attribute about this PLL's PAD SB_IO. packed->attrs[ctx->id("BEL_PAD_INPUT")] = packagepin_bel_name->second; // Disconnect PACKAGEPIN (it's a physical HW link) for (auto user : pad_packagepin_net->users) user.cell->ports.erase(user.port); packagepin_cell->ports.erase(pll_packagepin_driver.port); ctx->nets.erase(pad_packagepin_net->name); pad_packagepin_net = nullptr; } // The LOCK signal on iCE40 PLLs goes through the neigh_op_bnl_1 wire. // In practice, this means the LOCK signal can only directly reach LUT // inputs. // If we have a net connected to LOCK, make sure it only drives LUTs. auto port = packed->ports[ctx->id("LOCK")]; if (port.net != nullptr) { log_info(" PLL '%s' has LOCK output, need to pass all outputs via LUT\n", ci->name.c_str(ctx)); bool found_lut = false; bool all_luts = true; bool found_carry = false; unsigned int lut_count = 0; for (const auto &user : port.net->users) { NPNR_ASSERT(user.cell != nullptr); if (user.cell->type == ctx->id("ICESTORM_LC")) { if (bool_or_default(user.cell->params, ctx->id("CARRY_ENABLE"), false)) { found_carry = true; all_luts = false; } else { found_lut = true; lut_count++; } } else { all_luts = false; } } if (found_lut && all_luts && lut_count < 8) { // Every user is a LUT, carry on now. } else if (found_lut && !all_luts && !found_carry && lut_count < 8) { // Strategy: create a pass-through LUT, move all non-LUT users behind it. log_info(" LUT strategy for %s: move non-LUT users to new LUT\n", port.name.c_str(ctx)); auto pt = spliceLUT(ctx, packed.get(), port.name, true); new_cells.push_back(std::move(pt)); } else { // Strategy: create a pass-through LUT, move every user behind it. log_info(" LUT strategy for %s: move all users to new LUT\n", port.name.c_str(ctx)); auto pt = spliceLUT(ctx, packed.get(), port.name, false); new_cells.push_back(std::move(pt)); } // Find wire that will be driven by this port. const auto pll_out_wire = ctx->getBelPinWire(pll_bel, port.name); NPNR_ASSERT(pll_out_wire.index != -1); // Now, constrain all LUTs on the output of the signal to be at // the correct Bel relative to the PLL Bel. int x = ctx->chip_info->wire_data[pll_out_wire.index].x; int y = ctx->chip_info->wire_data[pll_out_wire.index].y; int z = 0; for (const auto &user : port.net->users) { NPNR_ASSERT(user.cell != nullptr); NPNR_ASSERT(user.cell->type == ctx->id("ICESTORM_LC")); // TODO(q3k): handle when the Bel might be already the // target of another constraint. NPNR_ASSERT(z < 8); auto target_bel = ctx->getBelByLocation(Loc(x, y, z++)); auto target_bel_name = ctx->getBelName(target_bel).str(ctx); user.cell->attrs[ctx->id("BEL")] = target_bel_name; log_info(" constrained '%s' to %s\n", user.cell->name.c_str(ctx), target_bel_name.c_str()); } } // Handle the global buffer connections for (auto port : packed->ports) { PortInfo &pi = port.second; bool is_b_port; if (pi.name == ctx->id("PLLOUT_A_GLOBAL")) is_b_port = false; else if (pi.name == ctx->id("PLLOUT_B_GLOBAL")) is_b_port = true; else continue; // Only if there is actually a net ... if (pi.net != nullptr) { // ... and it's used if (pi.net->users.size() > 0) { std::unique_ptr gb = create_padin_gbuf(ctx, packed.get(), pi.name, "$gbuf_" + ci->name.str(ctx) + "_pllout_" + (is_b_port ? "b" : "a")); new_cells.push_back(std::move(gb)); } else { // If not, remove it to avoid routing issues ctx->nets.erase(pi.net->name); packed->ports[pi.name].net = nullptr; } } } new_cells.push_back(std::move(packed)); } } for (auto pcell : packed_cells) { ctx->cells.erase(pcell); } for (auto &ncell : new_cells) { ctx->cells[ncell->name] = std::move(ncell); } } // Main pack function bool Arch::pack() { Context *ctx = getCtx(); try { log_break(); pack_constants(ctx); pack_io(ctx); pack_lut_lutffs(ctx); pack_nonlut_ffs(ctx); pack_carries(ctx); pack_ram(ctx); place_plls(ctx); pack_special(ctx); if (!bool_or_default(ctx->settings, ctx->id("no_promote_globals"), false)) promote_globals(ctx); ctx->assignArchInfo(); constrain_chains(ctx); ctx->assignArchInfo(); ctx->settings[ctx->id("pack")] = "1"; archInfoToAttributes(); log_info("Checksum: 0x%08x\n", ctx->checksum()); return true; } catch (log_execution_error_exception) { return false; } } NEXTPNR_NAMESPACE_END