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|
/*
* nextpnr -- Next Generation Place and Route
*
* Copyright (C) 2019 gatecat <gatecat@ds0.me>
*
* 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.
*
* Core routing algorithm based on CRoute:
*
* CRoute: A Fast High-quality Timing-driven Connection-based FPGA Router
* Dries Vercruyce, Elias Vansteenkiste and Dirk Stroobandt
* DOI 10.1109/FCCM.2019.00017 [PDF on SciHub]
*
* Modified for the nextpnr Arch API and data structures; optimised for
* real-world FPGA architectures in particular ECP5 and Xilinx UltraScale+
*
*/
#include "router2.h"
#include <algorithm>
#include <boost/container/flat_map.hpp>
#include <chrono>
#include <deque>
#include <fstream>
#include <queue>
#include "log.h"
#include "nextpnr.h"
#include "router1.h"
#include "scope_lock.h"
#include "timing.h"
#include "util.h"
NEXTPNR_NAMESPACE_BEGIN
namespace {
struct Router2
{
struct PerArcData
{
WireId sink_wire;
ArcBounds bb;
bool routed = false;
};
// As we allow overlap at first; the nextpnr bind functions can't be used
// as the primary relation between arcs and wires/pips
struct PerNetData
{
WireId src_wire;
dict<WireId, std::pair<PipId, int>> wires;
std::vector<std::vector<PerArcData>> arcs;
ArcBounds bb;
// Coordinates of the center of the net, used for the weight-to-average
int cx, cy, hpwl;
int total_route_us = 0;
float max_crit = 0;
int fail_count = 0;
};
struct WireScore
{
float cost;
float togo_cost;
float total() const { return cost + togo_cost; }
};
struct PerWireData
{
// nextpnr
WireId w;
// Historical congestion cost
int curr_cong = 0;
float hist_cong_cost = 1.0;
// Wire is unavailable as locked to another arc
bool unavailable = false;
// This wire has to be used for this net
int reserved_net = -1;
// The notional location of the wire, to guarantee thread safety
int16_t x = 0, y = 0;
// Visit data
PipId pip_fwd, pip_bwd;
bool visited_fwd = false, visited_bwd = false;
};
Context *ctx;
Router2Cfg cfg;
Router2(Context *ctx, const Router2Cfg &cfg) : ctx(ctx), cfg(cfg), tmg(ctx) { tmg.setup(); }
// Use 'udata' for fast net lookups and indexing
std::vector<NetInfo *> nets_by_udata;
std::vector<PerNetData> nets;
bool timing_driven, timing_driven_ripup;
TimingAnalyser tmg;
void setup_nets()
{
// Populate per-net and per-arc structures at start of routing
nets.resize(ctx->nets.size());
nets_by_udata.resize(ctx->nets.size());
size_t i = 0;
for (auto &net : ctx->nets) {
NetInfo *ni = net.second.get();
ni->udata = i;
nets_by_udata.at(i) = ni;
nets.at(i).arcs.resize(ni->users.size());
// Start net bounding box at overall min/max
nets.at(i).bb.x0 = std::numeric_limits<int>::max();
nets.at(i).bb.x1 = std::numeric_limits<int>::min();
nets.at(i).bb.y0 = std::numeric_limits<int>::max();
nets.at(i).bb.y1 = std::numeric_limits<int>::min();
nets.at(i).cx = 0;
nets.at(i).cy = 0;
if (ni->driver.cell != nullptr) {
Loc drv_loc = ctx->getBelLocation(ni->driver.cell->bel);
nets.at(i).cx += drv_loc.x;
nets.at(i).cy += drv_loc.y;
}
for (size_t j = 0; j < ni->users.size(); j++) {
auto &usr = ni->users.at(j);
WireId src_wire = ctx->getNetinfoSourceWire(ni);
for (auto &dst_wire : ctx->getNetinfoSinkWires(ni, usr)) {
nets.at(i).src_wire = src_wire;
if (ni->driver.cell == nullptr)
src_wire = dst_wire;
if (ni->driver.cell == nullptr && dst_wire == WireId())
continue;
if (src_wire == WireId())
log_error("No wire found for port %s on source cell %s.\n", ctx->nameOf(ni->driver.port),
ctx->nameOf(ni->driver.cell));
if (dst_wire == WireId())
log_error("No wire found for port %s on destination cell %s.\n", ctx->nameOf(usr.port),
ctx->nameOf(usr.cell));
nets.at(i).arcs.at(j).emplace_back();
auto &ad = nets.at(i).arcs.at(j).back();
ad.sink_wire = dst_wire;
// Set bounding box for this arc
ad.bb = ctx->getRouteBoundingBox(src_wire, dst_wire);
// Expand net bounding box to include this arc
nets.at(i).bb.x0 = std::min(nets.at(i).bb.x0, ad.bb.x0);
nets.at(i).bb.x1 = std::max(nets.at(i).bb.x1, ad.bb.x1);
nets.at(i).bb.y0 = std::min(nets.at(i).bb.y0, ad.bb.y0);
nets.at(i).bb.y1 = std::max(nets.at(i).bb.y1, ad.bb.y1);
}
// Add location to centroid sum
Loc usr_loc = ctx->getBelLocation(usr.cell->bel);
nets.at(i).cx += usr_loc.x;
nets.at(i).cy += usr_loc.y;
}
nets.at(i).hpwl = std::max(
std::abs(nets.at(i).bb.y1 - nets.at(i).bb.y0) + std::abs(nets.at(i).bb.x1 - nets.at(i).bb.x0), 1);
nets.at(i).cx /= int(ni->users.size() + 1);
nets.at(i).cy /= int(ni->users.size() + 1);
if (ctx->debug)
log_info("%s: bb=(%d, %d)->(%d, %d) c=(%d, %d) hpwl=%d\n", ctx->nameOf(ni), nets.at(i).bb.x0,
nets.at(i).bb.y0, nets.at(i).bb.x1, nets.at(i).bb.y1, nets.at(i).cx, nets.at(i).cy,
nets.at(i).hpwl);
nets.at(i).bb.x0 = std::max(nets.at(i).bb.x0 - cfg.bb_margin_x, 0);
nets.at(i).bb.y0 = std::max(nets.at(i).bb.y0 - cfg.bb_margin_y, 0);
nets.at(i).bb.x1 = std::min(nets.at(i).bb.x1 + cfg.bb_margin_x, ctx->getGridDimX());
nets.at(i).bb.y1 = std::min(nets.at(i).bb.y1 + cfg.bb_margin_y, ctx->getGridDimY());
i++;
}
}
dict<WireId, int> wire_to_idx;
std::vector<PerWireData> flat_wires;
PerWireData &wire_data(WireId w) { return flat_wires[wire_to_idx.at(w)]; }
void setup_wires()
{
// Set up per-wire structures, so that MT parts don't have to do any memory allocation
// This is possibly quite wasteful and not cache-optimal; further consideration necessary
for (auto wire : ctx->getWires()) {
PerWireData pwd;
pwd.w = wire;
NetInfo *bound = ctx->getBoundWireNet(wire);
if (bound != nullptr) {
auto iter = bound->wires.find(wire);
if (iter != bound->wires.end()) {
auto &nd = nets.at(bound->udata);
nd.wires[wire] = std::make_pair(bound->wires.at(wire).pip, 0);
pwd.curr_cong = 1;
if (bound->wires.at(wire).strength == STRENGTH_PLACER) {
pwd.reserved_net = bound->udata;
} else if (bound->wires.at(wire).strength > STRENGTH_PLACER) {
pwd.unavailable = true;
}
}
}
ArcBounds wire_loc = ctx->getRouteBoundingBox(wire, wire);
pwd.x = (wire_loc.x0 + wire_loc.x1) / 2;
pwd.y = (wire_loc.y0 + wire_loc.y1) / 2;
wire_to_idx[wire] = int(flat_wires.size());
flat_wires.push_back(pwd);
}
for (auto &net_pair : ctx->nets) {
auto *net = net_pair.second.get();
auto &nd = nets.at(net->udata);
for (size_t usr = 0; usr < net->users.size(); usr++) {
auto &ad = nd.arcs.at(usr);
for (size_t phys_pin = 0; phys_pin < ad.size(); phys_pin++) {
if (check_arc_routing(net, usr, phys_pin)) {
record_prerouted_net(net, usr, phys_pin);
}
}
}
}
}
struct QueuedWire
{
explicit QueuedWire(int wire = -1, WireScore score = WireScore{}, int randtag = 0)
: wire(wire), score(score), randtag(randtag){};
int wire;
WireScore score;
int randtag = 0;
struct Greater
{
bool operator()(const QueuedWire &lhs, const QueuedWire &rhs) const noexcept
{
float lhs_score = lhs.score.cost + lhs.score.togo_cost,
rhs_score = rhs.score.cost + rhs.score.togo_cost;
return lhs_score == rhs_score ? lhs.randtag > rhs.randtag : lhs_score > rhs_score;
}
};
};
bool hit_test_pip(ArcBounds &bb, Loc l) { return l.x >= bb.x0 && l.x <= bb.x1 && l.y >= bb.y0 && l.y <= bb.y1; }
double curr_cong_weight, hist_cong_weight, estimate_weight;
struct ThreadContext
{
// Nets to route
std::vector<NetInfo *> route_nets;
// Nets that failed routing
std::vector<NetInfo *> failed_nets;
std::vector<std::pair<size_t, size_t>> route_arcs;
std::priority_queue<QueuedWire, std::vector<QueuedWire>, QueuedWire::Greater> fwd_queue, bwd_queue;
// Special case where one net has multiple logical arcs to the same physical sink
pool<WireId> processed_sinks;
std::vector<int> dirty_wires;
// Thread bounding box
ArcBounds bb;
DeterministicRNG rng;
// Used to add existing routing to the heap
pool<WireId> in_wire_by_loc;
dict<std::pair<int, int>, pool<WireId>> wire_by_loc;
};
bool thread_test_wire(ThreadContext &t, PerWireData &w)
{
return w.x >= t.bb.x0 && w.x <= t.bb.x1 && w.y >= t.bb.y0 && w.y <= t.bb.y1;
}
enum ArcRouteResult
{
ARC_SUCCESS,
ARC_RETRY_WITHOUT_BB,
ARC_FATAL,
};
// Define to make sure we don't print in a multithreaded context
#define ARC_LOG_ERR(...) \
do { \
if (is_mt) \
return ARC_FATAL; \
else \
log_error(__VA_ARGS__); \
} while (0)
#define ROUTE_LOG_DBG(...) \
do { \
if (!is_mt && ctx->debug) \
log(__VA_ARGS__); \
} while (0)
void bind_pip_internal(PerNetData &net, size_t user, int wire, PipId pip)
{
auto &wd = flat_wires.at(wire);
auto found = net.wires.find(wd.w);
if (found == net.wires.end()) {
// Not yet used for any arcs of this net, add to list
net.wires.emplace(wd.w, std::make_pair(pip, 1));
// Increase bound count of wire by 1
++wd.curr_cong;
} else {
// Already used for at least one other arc of this net
// Don't allow two uphill PIPs for the same net and wire
NPNR_ASSERT(found->second.first == pip);
// Increase the count of bound arcs
++found->second.second;
}
}
void unbind_pip_internal(PerNetData &net, size_t user, WireId wire)
{
auto &wd = wire_data(wire);
auto &b = net.wires.at(wd.w);
--b.second;
if (b.second == 0) {
// No remaining arcs of this net bound to this wire
--wd.curr_cong;
net.wires.erase(wd.w);
}
}
void ripup_arc(NetInfo *net, size_t user, size_t phys_pin)
{
auto &nd = nets.at(net->udata);
auto &ad = nd.arcs.at(user).at(phys_pin);
if (!ad.routed)
return;
WireId src = nets.at(net->udata).src_wire;
WireId cursor = ad.sink_wire;
while (cursor != src) {
PipId pip = nd.wires.at(cursor).first;
unbind_pip_internal(nd, user, cursor);
cursor = ctx->getPipSrcWire(pip);
}
ad.routed = false;
}
float score_wire_for_arc(NetInfo *net, size_t user, size_t phys_pin, WireId wire, PipId pip, float crit_weight)
{
auto &wd = wire_data(wire);
auto &nd = nets.at(net->udata);
float base_cost = cfg.get_base_cost(ctx, wire, pip, crit_weight);
int overuse = wd.curr_cong;
float hist_cost = 1.0f + crit_weight * (wd.hist_cong_cost - 1.0f);
float bias_cost = 0;
int source_uses = 0;
if (nd.wires.count(wire)) {
overuse -= 1;
source_uses = nd.wires.at(wire).second;
}
float present_cost = 1.0f + overuse * curr_cong_weight * crit_weight;
if (pip != PipId()) {
Loc pl = ctx->getPipLocation(pip);
bias_cost = cfg.bias_cost_factor * (base_cost / int(net->users.size())) *
((std::abs(pl.x - nd.cx) + std::abs(pl.y - nd.cy)) / float(nd.hpwl));
}
return base_cost * hist_cost * present_cost / (1 + (source_uses * crit_weight)) + bias_cost;
}
float get_togo_cost(NetInfo *net, size_t user, int wire, WireId src_sink, float crit_weight, bool bwd = false)
{
auto &nd = nets.at(net->udata);
auto &wd = flat_wires[wire];
int source_uses = 0;
if (nd.wires.count(wd.w)) {
source_uses = nd.wires.at(wd.w).second;
}
// FIXME: timing/wirelength balance?
delay_t est_delay = ctx->estimateDelay(bwd ? src_sink : wd.w, bwd ? wd.w : src_sink);
return (ctx->getDelayNS(est_delay) / (1 + source_uses * crit_weight)) + cfg.ipin_cost_adder;
}
bool check_arc_routing(NetInfo *net, size_t usr, size_t phys_pin)
{
auto &nd = nets.at(net->udata);
auto &ad = nd.arcs.at(usr).at(phys_pin);
WireId src_wire = nets.at(net->udata).src_wire;
WireId cursor = ad.sink_wire;
while (nd.wires.count(cursor)) {
auto &wd = wire_data(cursor);
if (wd.curr_cong != 1)
return false;
auto &uh = nd.wires.at(cursor).first;
if (uh == PipId())
break;
cursor = ctx->getPipSrcWire(uh);
}
return (cursor == src_wire);
}
void record_prerouted_net(NetInfo *net, size_t usr, size_t phys_pin)
{
auto &nd = nets.at(net->udata);
auto &ad = nd.arcs.at(usr).at(phys_pin);
ad.routed = true;
WireId src = nets.at(net->udata).src_wire;
WireId cursor = ad.sink_wire;
while (cursor != src) {
size_t wire_idx = wire_to_idx.at(cursor);
PipId pip = nd.wires.at(cursor).first;
bind_pip_internal(nd, usr, wire_idx, pip);
cursor = ctx->getPipSrcWire(pip);
}
}
// Returns true if a wire contains no source ports or driving pips
bool is_wire_undriveable(WireId wire, const NetInfo *net, int iter_count = 0)
{
// This is specifically designed to handle a particularly icky case that the current router struggles with in
// the nexus device,
// C -> C lut input only
// C; D; or F from another lut -> D lut input
// D or M -> M ff input
// without careful reservation of C for C lut input and D for D lut input, there is fighting for D between FF
// and LUT
if (iter_count > 7)
return false; // heuristic to assume we've hit general routing
if (wire_data(wire).unavailable)
return true;
if (wire_data(wire).reserved_net != -1 && wire_data(wire).reserved_net != net->udata)
return true; // reserved for another net
for (auto bp : ctx->getWireBelPins(wire))
if ((net->driver.cell == nullptr || bp.bel == net->driver.cell->bel) &&
ctx->getBelPinType(bp.bel, bp.pin) != PORT_IN)
return false;
for (auto p : ctx->getPipsUphill(wire))
if (ctx->checkPipAvail(p)) {
if (!is_wire_undriveable(ctx->getPipSrcWire(p), net, iter_count + 1))
return false;
}
return true;
}
// Find all the wires that must be used to route a given arc
bool reserve_wires_for_arc(NetInfo *net, size_t i)
{
bool did_something = false;
WireId src = ctx->getNetinfoSourceWire(net);
for (auto sink : ctx->getNetinfoSinkWires(net, net->users.at(i))) {
pool<WireId> rsv;
WireId cursor = sink;
bool done = false;
if (ctx->debug)
log("reserving wires for arc %d of net %s\n", int(i), ctx->nameOf(net));
while (!done) {
auto &wd = wire_data(cursor);
if (ctx->debug)
log(" %s\n", ctx->nameOfWire(cursor));
did_something |= (wd.reserved_net != net->udata);
wd.reserved_net = net->udata;
if (cursor == src)
break;
WireId next_cursor;
for (auto uh : ctx->getPipsUphill(cursor)) {
WireId w = ctx->getPipSrcWire(uh);
if (is_wire_undriveable(w, net))
continue;
if (next_cursor != WireId()) {
done = true;
break;
}
next_cursor = w;
}
if (next_cursor == WireId())
break;
cursor = next_cursor;
}
}
return did_something;
}
void find_all_reserved_wires()
{
// Run iteratively, as reserving wires for one net might limit choices for another
bool did_something = false;
do {
did_something = false;
for (auto net : nets_by_udata) {
WireId src = ctx->getNetinfoSourceWire(net);
if (src == WireId())
continue;
for (size_t i = 0; i < net->users.size(); i++)
did_something |= reserve_wires_for_arc(net, i);
}
} while (did_something);
}
void reset_wires(ThreadContext &t)
{
for (auto w : t.dirty_wires) {
flat_wires[w].pip_fwd = PipId();
flat_wires[w].pip_bwd = PipId();
flat_wires[w].visited_fwd = false;
flat_wires[w].visited_bwd = false;
}
t.dirty_wires.clear();
}
// These nets have very-high-fanout pips and special rules must be followed (only working backwards) to avoid
// crippling perf
bool is_pseudo_const_net(const NetInfo *net)
{
#ifdef ARCH_NEXUS
if (net->driver.cell != nullptr && net->driver.cell->type == id_VCC_DRV)
return true;
#endif
return false;
}
void update_wire_by_loc(ThreadContext &t, NetInfo *net, size_t i, size_t phys_pin, bool is_mt)
{
if (is_pseudo_const_net(net))
return;
auto &nd = nets.at(net->udata);
auto &ad = nd.arcs.at(i).at(phys_pin);
WireId cursor = ad.sink_wire;
if (!nd.wires.count(cursor))
return;
while (cursor != nd.src_wire) {
if (!t.in_wire_by_loc.count(cursor)) {
t.in_wire_by_loc.insert(cursor);
for (auto dh : ctx->getPipsDownhill(cursor)) {
Loc dh_loc = ctx->getPipLocation(dh);
t.wire_by_loc[std::make_pair(dh_loc.x, dh_loc.y)].insert(cursor);
}
}
cursor = ctx->getPipSrcWire(nd.wires.at(cursor).first);
}
}
// Functions for marking wires as visited, and checking if they have already been visited
void set_visited_fwd(ThreadContext &t, int wire, PipId pip)
{
auto &wd = flat_wires.at(wire);
if (!wd.visited_fwd && !wd.visited_bwd)
t.dirty_wires.push_back(wire);
wd.pip_fwd = pip;
wd.visited_fwd = true;
}
void set_visited_bwd(ThreadContext &t, int wire, PipId pip)
{
auto &wd = flat_wires.at(wire);
if (!wd.visited_fwd && !wd.visited_bwd)
t.dirty_wires.push_back(wire);
wd.pip_bwd = pip;
wd.visited_bwd = true;
}
bool was_visited_fwd(int wire) { return flat_wires.at(wire).visited_fwd; }
bool was_visited_bwd(int wire) { return flat_wires.at(wire).visited_bwd; }
float get_arc_crit(NetInfo *net, size_t i)
{
if (!timing_driven)
return 0;
return tmg.get_criticality(CellPortKey(net->users.at(i)));
}
bool arc_failed_slack(NetInfo *net, size_t usr_idx)
{
return timing_driven_ripup &&
(tmg.get_setup_slack(CellPortKey(net->users.at(usr_idx))) < (2 * ctx->getDelayEpsilon()));
}
ArcRouteResult route_arc(ThreadContext &t, NetInfo *net, size_t i, size_t phys_pin, bool is_mt, bool is_bb = true)
{
// Do some initial lookups and checks
auto arc_start = std::chrono::high_resolution_clock::now();
auto &nd = nets[net->udata];
auto &ad = nd.arcs.at(i).at(phys_pin);
auto &usr = net->users.at(i);
ROUTE_LOG_DBG("Routing arc %d of net '%s' (%d, %d) -> (%d, %d)\n", int(i), ctx->nameOf(net), ad.bb.x0, ad.bb.y0,
ad.bb.x1, ad.bb.y1);
WireId src_wire = ctx->getNetinfoSourceWire(net), dst_wire = ctx->getNetinfoSinkWire(net, usr, phys_pin);
if (src_wire == WireId())
ARC_LOG_ERR("No wire found for port %s on source cell %s.\n", ctx->nameOf(net->driver.port),
ctx->nameOf(net->driver.cell));
if (dst_wire == WireId())
ARC_LOG_ERR("No wire found for port %s on destination cell %s.\n", ctx->nameOf(usr.port),
ctx->nameOf(usr.cell));
int src_wire_idx = wire_to_idx.at(src_wire);
int dst_wire_idx = wire_to_idx.at(dst_wire);
// Calculate a timing weight based on criticality
float crit = get_arc_crit(net, i);
float crit_weight = (1.0f - std::pow(crit, 2));
ROUTE_LOG_DBG(" crit=%.3f crit_weight=%.3f\n", crit, crit_weight);
// Check if arc was already done _in this iteration_
if (t.processed_sinks.count(dst_wire))
return ARC_SUCCESS;
// We have two modes:
// 0. starting within a small range of existing routing
// 1. expanding from all routing
int mode = 0;
if (net->users.size() < 4 || nd.wires.empty() || (crit > 0.95))
mode = 1;
// This records the point where forwards and backwards routing met
int midpoint_wire = -1;
int explored = 1;
for (; mode < 2; mode++) {
// Clear out the queues
if (!t.fwd_queue.empty()) {
std::priority_queue<QueuedWire, std::vector<QueuedWire>, QueuedWire::Greater> new_queue;
t.fwd_queue.swap(new_queue);
}
if (!t.bwd_queue.empty()) {
std::priority_queue<QueuedWire, std::vector<QueuedWire>, QueuedWire::Greater> new_queue;
t.bwd_queue.swap(new_queue);
}
// Unvisit any previously visited wires
reset_wires(t);
ROUTE_LOG_DBG("src_wire = %s -> dst_wire = %s\n", ctx->nameOfWire(src_wire), ctx->nameOfWire(dst_wire));
// Add 'forward' direction startpoints to queue
auto seed_queue_fwd = [&](WireId wire, float wire_cost = 0) {
WireScore base_score;
base_score.cost = wire_cost;
int wire_idx = wire_to_idx.at(wire);
base_score.togo_cost = get_togo_cost(net, i, wire_idx, dst_wire, false, crit_weight);
t.fwd_queue.push(QueuedWire(wire_idx, base_score));
set_visited_fwd(t, wire_idx, PipId());
};
auto &dst_data = flat_wires.at(dst_wire_idx);
// Look for nearby existing routing
for (int dy = -cfg.bb_margin_y; dy <= cfg.bb_margin_y; dy++)
for (int dx = -cfg.bb_margin_x; dx <= cfg.bb_margin_x; dx++) {
auto fnd = t.wire_by_loc.find(std::make_pair(dst_data.x + dx, dst_data.y + dy));
if (fnd == t.wire_by_loc.end())
continue;
for (WireId wire : fnd->second) {
ROUTE_LOG_DBG(" seeding with %s\n", ctx->nameOfWire(wire));
seed_queue_fwd(wire);
}
}
if (mode == 0 && t.fwd_queue.size() < 4)
continue;
if (mode == 1 && !is_pseudo_const_net(net)) {
// Seed forwards with the source wire, if less than 8 existing wires added
seed_queue_fwd(src_wire);
} else {
set_visited_fwd(t, src_wire_idx, PipId());
}
auto seed_queue_bwd = [&](WireId wire) {
WireScore base_score;
base_score.cost = 0;
int wire_idx = wire_to_idx.at(wire);
base_score.togo_cost = get_togo_cost(net, i, wire_idx, src_wire, true, crit_weight);
t.bwd_queue.push(QueuedWire(wire_idx, base_score));
set_visited_bwd(t, wire_idx, PipId());
};
// Seed backwards with the dest wire
seed_queue_bwd(dst_wire);
int toexplore = 25000 * std::max(1, (ad.bb.x1 - ad.bb.x0) + (ad.bb.y1 - ad.bb.y0));
int iter = 0;
// Mode 0 required both queues to be live
while (((mode == 0) ? (!t.fwd_queue.empty() && !t.bwd_queue.empty())
: (!t.fwd_queue.empty() || !t.bwd_queue.empty())) &&
(!is_bb || iter < toexplore)) {
++iter;
if (!t.fwd_queue.empty()) {
// Explore forwards
auto curr = t.fwd_queue.top();
t.fwd_queue.pop();
++explored;
if (was_visited_bwd(curr.wire)) {
// Meet in the middle; done
midpoint_wire = curr.wire;
break;
}
auto &curr_data = flat_wires.at(curr.wire);
for (PipId dh : ctx->getPipsDownhill(curr_data.w)) {
// Skip pips outside of box in bounding-box mode
if (is_bb && !hit_test_pip(nd.bb, ctx->getPipLocation(dh)))
continue;
if (!ctx->checkPipAvailForNet(dh, net))
continue;
WireId next = ctx->getPipDstWire(dh);
int next_idx = wire_to_idx.at(next);
if (was_visited_fwd(next_idx)) {
// Don't expand the same node twice.
continue;
}
auto &nwd = flat_wires.at(next_idx);
if (nwd.unavailable)
continue;
// Reserved for another net
if (nwd.reserved_net != -1 && nwd.reserved_net != net->udata)
continue;
// Don't allow the same wire to be bound to the same net with a different driving pip
auto fnd_wire = nd.wires.find(next);
if (fnd_wire != nd.wires.end() && fnd_wire->second.first != dh)
continue;
if (!thread_test_wire(t, nwd))
continue; // thread safety issue
WireScore next_score;
next_score.cost = curr.score.cost + score_wire_for_arc(net, i, phys_pin, next, dh, crit_weight);
next_score.togo_cost =
cfg.estimate_weight * get_togo_cost(net, i, next_idx, dst_wire, false, crit_weight);
set_visited_fwd(t, next_idx, dh);
t.fwd_queue.push(QueuedWire(next_idx, next_score, t.rng.rng()));
}
}
if (!t.bwd_queue.empty()) {
// Explore backwards
auto curr = t.bwd_queue.top();
t.bwd_queue.pop();
++explored;
if (was_visited_fwd(curr.wire)) {
// Meet in the middle; done
midpoint_wire = curr.wire;
break;
}
auto &curr_data = flat_wires.at(curr.wire);
// Don't allow the same wire to be bound to the same net with a different driving pip
PipId bound_pip;
auto fnd_wire = nd.wires.find(curr_data.w);
if (fnd_wire != nd.wires.end())
bound_pip = fnd_wire->second.first;
for (PipId uh : ctx->getPipsUphill(curr_data.w)) {
if (bound_pip != PipId() && bound_pip != uh)
continue;
if (is_bb && !hit_test_pip(nd.bb, ctx->getPipLocation(uh)))
continue;
if (!ctx->checkPipAvailForNet(uh, net))
continue;
WireId next = ctx->getPipSrcWire(uh);
int next_idx = wire_to_idx.at(next);
if (was_visited_bwd(next_idx)) {
// Don't expand the same node twice.
continue;
}
auto &nwd = flat_wires.at(next_idx);
if (nwd.unavailable)
continue;
// Reserved for another net
if (nwd.reserved_net != -1 && nwd.reserved_net != net->udata)
continue;
if (!thread_test_wire(t, nwd))
continue; // thread safety issue
WireScore next_score;
next_score.cost = curr.score.cost + score_wire_for_arc(net, i, phys_pin, next, uh, crit_weight);
next_score.togo_cost =
cfg.estimate_weight * get_togo_cost(net, i, next_idx, src_wire, true, crit_weight);
set_visited_bwd(t, next_idx, uh);
t.bwd_queue.push(QueuedWire(next_idx, next_score, t.rng.rng()));
}
}
}
if (midpoint_wire != -1)
break;
}
ArcRouteResult result = ARC_SUCCESS;
if (midpoint_wire != -1) {
ROUTE_LOG_DBG(" Routed (explored %d wires): ", explored);
int cursor_bwd = midpoint_wire;
while (was_visited_fwd(cursor_bwd)) {
PipId pip = flat_wires.at(cursor_bwd).pip_fwd;
if (pip == PipId() && cursor_bwd != src_wire_idx)
break;
bind_pip_internal(nd, i, cursor_bwd, pip);
if (ctx->debug && !is_mt) {
auto &wd = flat_wires.at(cursor_bwd);
ROUTE_LOG_DBG(" fwd wire: %s (curr %d hist %f share %d)\n", ctx->nameOfWire(wd.w),
wd.curr_cong - 1, wd.hist_cong_cost, nd.wires.at(wd.w).second);
}
if (pip == PipId()) {
break;
}
ROUTE_LOG_DBG(" fwd pip: %s (%d, %d)\n", ctx->nameOfPip(pip), ctx->getPipLocation(pip).x,
ctx->getPipLocation(pip).y);
cursor_bwd = wire_to_idx.at(ctx->getPipSrcWire(pip));
}
while (cursor_bwd != src_wire_idx) {
// Tack onto existing routing
WireId bwd_w = flat_wires.at(cursor_bwd).w;
if (!nd.wires.count(bwd_w))
break;
auto &bound = nd.wires.at(bwd_w);
PipId pip = bound.first;
if (ctx->debug && !is_mt) {
auto &wd = flat_wires.at(cursor_bwd);
ROUTE_LOG_DBG(" ext wire: %s (curr %d hist %f share %d)\n", ctx->nameOfWire(wd.w),
wd.curr_cong - 1, wd.hist_cong_cost, bound.second);
}
bind_pip_internal(nd, i, cursor_bwd, pip);
if (pip == PipId())
break;
cursor_bwd = wire_to_idx.at(ctx->getPipSrcWire(pip));
}
NPNR_ASSERT(cursor_bwd == src_wire_idx);
int cursor_fwd = midpoint_wire;
while (was_visited_bwd(cursor_fwd)) {
PipId pip = flat_wires.at(cursor_fwd).pip_bwd;
if (pip == PipId()) {
break;
}
ROUTE_LOG_DBG(" bwd pip: %s (%d, %d)\n", ctx->nameOfPip(pip), ctx->getPipLocation(pip).x,
ctx->getPipLocation(pip).y);
cursor_fwd = wire_to_idx.at(ctx->getPipDstWire(pip));
bind_pip_internal(nd, i, cursor_fwd, pip);
if (ctx->debug && !is_mt) {
auto &wd = flat_wires.at(cursor_fwd);
ROUTE_LOG_DBG(" bwd wire: %s (curr %d hist %f share %d)\n", ctx->nameOfWire(wd.w),
wd.curr_cong - 1, wd.hist_cong_cost, nd.wires.at(wd.w).second);
}
}
NPNR_ASSERT(cursor_fwd == dst_wire_idx);
update_wire_by_loc(t, net, i, phys_pin, is_mt);
t.processed_sinks.insert(dst_wire);
ad.routed = true;
auto arc_end = std::chrono::high_resolution_clock::now();
ROUTE_LOG_DBG("Routing arc %d of net '%s' (is_bb = %d) took %02fs\n", int(i), ctx->nameOf(net), is_bb,
std::chrono::duration<float>(arc_end - arc_start).count());
} else {
auto arc_end = std::chrono::high_resolution_clock::now();
ROUTE_LOG_DBG("Failed routing arc %d of net '%s' (is_bb = %d) took %02fs\n", int(i), ctx->nameOf(net),
is_bb, std::chrono::duration<float>(arc_end - arc_start).count());
result = ARC_RETRY_WITHOUT_BB;
}
reset_wires(t);
return result;
}
#undef ARC_ERR
bool route_net(ThreadContext &t, NetInfo *net, bool is_mt)
{
#ifdef ARCH_ECP5
if (net->is_global)
return true;
#endif
ROUTE_LOG_DBG("Routing net '%s'...\n", ctx->nameOf(net));
auto rstart = std::chrono::high_resolution_clock::now();
// Nothing to do if net is undriven
if (net->driver.cell == nullptr)
return true;
bool have_failures = false;
t.processed_sinks.clear();
t.route_arcs.clear();
t.wire_by_loc.clear();
t.in_wire_by_loc.clear();
auto &nd = nets.at(net->udata);
bool failed_slack = false;
for (size_t i = 0; i < net->users.size(); i++)
failed_slack |= arc_failed_slack(net, i);
for (size_t i = 0; i < net->users.size(); i++) {
auto &ad = nd.arcs.at(i);
for (size_t j = 0; j < ad.size(); j++) {
// Ripup failed arcs to start with
// Check if arc is already legally routed
if (!failed_slack && check_arc_routing(net, i, j)) {
update_wire_by_loc(t, net, i, j, true);
continue;
}
// Ripup arc to start with
ripup_arc(net, i, j);
t.route_arcs.emplace_back(i, j);
}
}
// Route most critical arc first
std::stable_sort(t.route_arcs.begin(), t.route_arcs.end(),
[&](std::pair<size_t, size_t> a, std::pair<size_t, size_t> b) {
return get_arc_crit(net, a.first) > get_arc_crit(net, b.first);
});
for (auto a : t.route_arcs) {
auto res1 = route_arc(t, net, a.first, a.second, is_mt, true);
if (res1 == ARC_FATAL)
return false; // Arc failed irrecoverably
else if (res1 == ARC_RETRY_WITHOUT_BB) {
if (is_mt) {
// Can't break out of bounding box in multi-threaded mode, so mark this arc as a failure
have_failures = true;
} else {
// Attempt a re-route without the bounding box constraint
ROUTE_LOG_DBG("Rerouting arc %d.%d of net '%s' without bounding box, possible tricky routing...\n",
int(a.first), int(a.second), ctx->nameOf(net));
auto res2 = route_arc(t, net, a.first, a.second, is_mt, false);
// If this also fails, no choice but to give up
if (res2 != ARC_SUCCESS) {
if (ctx->debug) {
log_info("Pre-bound routing: \n");
for (auto &wire_pair : net->wires) {
log(" %s", ctx->nameOfWire(wire_pair.first));
if (wire_pair.second.pip != PipId())
log(" %s", ctx->nameOfPip(wire_pair.second.pip));
log("\n");
}
}
log_error("Failed to route arc %d.%d of net '%s', from %s to %s.\n", int(a.first),
int(a.second), ctx->nameOf(net), ctx->nameOfWire(ctx->getNetinfoSourceWire(net)),
ctx->nameOfWire(ctx->getNetinfoSinkWire(net, net->users.at(a.first), a.second)));
}
}
}
}
if (cfg.perf_profile) {
auto rend = std::chrono::high_resolution_clock::now();
nets.at(net->udata).total_route_us +=
(std::chrono::duration_cast<std::chrono::microseconds>(rend - rstart).count());
}
return !have_failures;
}
#undef ROUTE_LOG_DBG
int total_wire_use = 0;
int overused_wires = 0;
int total_overuse = 0;
std::vector<int> route_queue;
std::set<int> failed_nets;
void update_congestion()
{
total_overuse = 0;
overused_wires = 0;
total_wire_use = 0;
failed_nets.clear();
pool<WireId> already_updated;
for (size_t i = 0; i < nets.size(); i++) {
auto &nd = nets.at(i);
for (const auto &w : nd.wires) {
++total_wire_use;
auto &wd = wire_data(w.first);
if (wd.curr_cong > 1) {
if (already_updated.count(w.first)) {
++total_overuse;
} else {
if (curr_cong_weight > 0)
wd.hist_cong_cost =
std::min(1e9, wd.hist_cong_cost + (wd.curr_cong - 1) * hist_cong_weight);
already_updated.insert(w.first);
++overused_wires;
}
failed_nets.insert(i);
}
}
}
for (int n : failed_nets) {
auto &net_data = nets.at(n);
++net_data.fail_count;
if ((net_data.fail_count % 3) == 0) {
// Every three times a net fails to route, expand the bounding box to increase the search space
#ifndef ARCH_MISTRAL
// This patch seems to make thing worse for CycloneV, as it slows down the resolution of TD congestion,
// disable it
net_data.bb.x0 = std::max(net_data.bb.x0 - 1, 0);
net_data.bb.y0 = std::max(net_data.bb.y0 - 1, 0);
net_data.bb.x1 = std::min(net_data.bb.x1 + 1, ctx->getGridDimX());
net_data.bb.y1 = std::min(net_data.bb.y1 + 1, ctx->getGridDimY());
#endif
}
}
}
bool bind_and_check(NetInfo *net, int usr_idx, int phys_pin)
{
#ifdef ARCH_ECP5
if (net->is_global)
return true;
#endif
bool success = true;
auto &nd = nets.at(net->udata);
auto &ad = nd.arcs.at(usr_idx).at(phys_pin);
auto &usr = net->users.at(usr_idx);
WireId src = ctx->getNetinfoSourceWire(net);
// Skip routes with no source
if (src == WireId())
return true;
WireId dst = ctx->getNetinfoSinkWire(net, usr, phys_pin);
if (dst == WireId())
return true;
// Skip routes where there is no routing (special cases)
if (!ad.routed) {
if ((src == dst) && ctx->getBoundWireNet(dst) != net)
ctx->bindWire(src, net, STRENGTH_WEAK);
if (ctx->debug) {
log("Net %s not routed, not binding\n", ctx->nameOf(net));
}
return true;
}
WireId cursor = dst;
std::vector<PipId> to_bind;
while (cursor != src) {
if (!ctx->checkWireAvail(cursor)) {
NetInfo *bound_net = ctx->getBoundWireNet(cursor);
if (bound_net != net) {
if (ctx->verbose) {
if (bound_net != nullptr) {
log_info("Failed to bind wire %s to net %s, bound to net %s\n", ctx->nameOfWire(cursor),
net->name.c_str(ctx), bound_net->name.c_str(ctx));
} else {
log_info("Failed to bind wire %s to net %s, bound net nullptr\n", ctx->nameOfWire(cursor),
net->name.c_str(ctx));
}
}
success = false;
break;
}
}
if (!nd.wires.count(cursor)) {
log("Failure details:\n");
log(" Cursor: %s\n", ctx->nameOfWire(cursor));
log_error("Internal error; incomplete route tree for arc %d of net %s.\n", usr_idx, ctx->nameOf(net));
}
PipId p = nd.wires.at(cursor).first;
if (ctx->checkPipAvailForNet(p, net)) {
NetInfo *bound_net = ctx->getBoundPipNet(p);
if (bound_net == nullptr) {
to_bind.push_back(p);
}
} else {
if (ctx->verbose) {
log_info("Failed to bind pip %s to net %s\n", ctx->nameOfPip(p), net->name.c_str(ctx));
}
success = false;
break;
}
cursor = ctx->getPipSrcWire(p);
}
if (success) {
if (ctx->getBoundWireNet(src) == nullptr)
ctx->bindWire(src, net, STRENGTH_WEAK);
for (auto tb : to_bind)
ctx->bindPip(tb, net, STRENGTH_WEAK);
} else {
ripup_arc(net, usr_idx, phys_pin);
failed_nets.insert(net->udata);
}
return success;
}
int arch_fail = 0;
bool bind_and_check_all()
{
// Make sure arch is internally consistent before we mess with it.
ctx->check();
bool success = true;
std::vector<WireId> net_wires;
for (auto net : nets_by_udata) {
#ifdef ARCH_ECP5
if (net->is_global)
continue;
#endif
// Ripup wires and pips used by the net in nextpnr's structures
net_wires.clear();
for (auto &w : net->wires) {
if (w.second.strength <= STRENGTH_STRONG) {
net_wires.push_back(w.first);
} else if (ctx->debug) {
log("Net %s didn't rip up wire %s because strength was %d\n", ctx->nameOf(net),
ctx->nameOfWire(w.first), w.second.strength);
}
}
for (auto w : net_wires)
ctx->unbindWire(w);
if (ctx->debug) {
log("Ripped up %zu wires on net %s\n", net_wires.size(), ctx->nameOf(net));
}
// Bind the arcs using the routes we have discovered
for (size_t i = 0; i < net->users.size(); i++) {
for (size_t phys_pin = 0; phys_pin < nets.at(net->udata).arcs.at(i).size(); phys_pin++) {
if (!bind_and_check(net, i, phys_pin)) {
++arch_fail;
success = false;
}
}
}
}
// Check that the arch is still internally consistent!
ctx->check();
return success;
}
void write_wiretype_heatmap(std::ostream &out)
{
dict<IdString, std::vector<int>> cong_by_type;
size_t max_cong = 0;
// Build histogram
for (auto &wd : flat_wires) {
size_t val = wd.curr_cong;
IdString type = ctx->getWireType(wd.w);
max_cong = std::max(max_cong, val);
if (cong_by_type[type].size() <= max_cong)
cong_by_type[type].resize(max_cong + 1);
cong_by_type[type].at(val) += 1;
}
// Write csv
out << "type,";
for (size_t i = 0; i <= max_cong; i++)
out << "bound=" << i << ",";
out << std::endl;
for (auto &ty : cong_by_type) {
out << ctx->nameOf(ty.first) << ",";
for (int count : ty.second)
out << count << ",";
out << std::endl;
}
}
int mid_x = 0, mid_y = 0;
void partition_nets()
{
// Create a histogram of positions in X and Y positions
std::map<int, int> cxs, cys;
for (auto &n : nets) {
if (n.cx != -1)
++cxs[n.cx];
if (n.cy != -1)
++cys[n.cy];
}
// 4-way split for now
int accum_x = 0, accum_y = 0;
int halfway = int(nets.size()) / 2;
for (auto &p : cxs) {
if (accum_x < halfway && (accum_x + p.second) >= halfway)
mid_x = p.first;
accum_x += p.second;
}
for (auto &p : cys) {
if (accum_y < halfway && (accum_y + p.second) >= halfway)
mid_y = p.first;
accum_y += p.second;
}
if (ctx->verbose) {
log_info(" x splitpoint: %d\n", mid_x);
log_info(" y splitpoint: %d\n", mid_y);
}
std::vector<int> bins(5, 0);
for (auto &n : nets) {
if (n.bb.x0 < mid_x && n.bb.x1 < mid_x && n.bb.y0 < mid_y && n.bb.y1 < mid_y)
++bins[0]; // TL
else if (n.bb.x0 >= mid_x && n.bb.x1 >= mid_x && n.bb.y0 < mid_y && n.bb.y1 < mid_y)
++bins[1]; // TR
else if (n.bb.x0 < mid_x && n.bb.x1 < mid_x && n.bb.y0 >= mid_y && n.bb.y1 >= mid_y)
++bins[2]; // BL
else if (n.bb.x0 >= mid_x && n.bb.x1 >= mid_x && n.bb.y0 >= mid_y && n.bb.y1 >= mid_y)
++bins[3]; // BR
else
++bins[4]; // cross-boundary
}
if (ctx->verbose)
for (int i = 0; i < 5; i++)
log_info(" bin %d N=%d\n", i, bins[i]);
}
void router_thread(ThreadContext &t, bool is_mt)
{
for (auto n : t.route_nets) {
bool result = route_net(t, n, is_mt);
if (!result)
t.failed_nets.push_back(n);
}
}
void do_route()
{
// Don't multithread if fewer than 200 nets (heuristic)
if (route_queue.size() < 200) {
ThreadContext st;
st.rng.rngseed(ctx->rng64());
st.bb = ArcBounds(0, 0, std::numeric_limits<int>::max(), std::numeric_limits<int>::max());
for (size_t j = 0; j < route_queue.size(); j++) {
route_net(st, nets_by_udata[route_queue[j]], false);
}
return;
}
const int Nq = 4, Nv = 2, Nh = 2;
const int N = Nq + Nv + Nh;
std::vector<ThreadContext> tcs(N + 1);
for (auto &th : tcs) {
th.rng.rngseed(ctx->rng64());
}
int le_x = mid_x;
int rs_x = mid_x;
int le_y = mid_y;
int rs_y = mid_y;
// Set up thread bounding boxes
tcs.at(0).bb = ArcBounds(0, 0, mid_x, mid_y);
tcs.at(1).bb = ArcBounds(mid_x + 1, 0, std::numeric_limits<int>::max(), le_y);
tcs.at(2).bb = ArcBounds(0, mid_y + 1, mid_x, std::numeric_limits<int>::max());
tcs.at(3).bb =
ArcBounds(mid_x + 1, mid_y + 1, std::numeric_limits<int>::max(), std::numeric_limits<int>::max());
tcs.at(4).bb = ArcBounds(0, 0, std::numeric_limits<int>::max(), mid_y);
tcs.at(5).bb = ArcBounds(0, mid_y + 1, std::numeric_limits<int>::max(), std::numeric_limits<int>::max());
tcs.at(6).bb = ArcBounds(0, 0, mid_x, std::numeric_limits<int>::max());
tcs.at(7).bb = ArcBounds(mid_x + 1, 0, std::numeric_limits<int>::max(), std::numeric_limits<int>::max());
tcs.at(8).bb = ArcBounds(0, 0, std::numeric_limits<int>::max(), std::numeric_limits<int>::max());
for (auto n : route_queue) {
auto &nd = nets.at(n);
auto ni = nets_by_udata.at(n);
int bin = N;
// Quadrants
if (nd.bb.x0 < le_x && nd.bb.x1 < le_x && nd.bb.y0 < le_y && nd.bb.y1 < le_y)
bin = 0;
else if (nd.bb.x0 >= rs_x && nd.bb.x1 >= rs_x && nd.bb.y0 < le_y && nd.bb.y1 < le_y)
bin = 1;
else if (nd.bb.x0 < le_x && nd.bb.x1 < le_x && nd.bb.y0 >= rs_y && nd.bb.y1 >= rs_y)
bin = 2;
else if (nd.bb.x0 >= rs_x && nd.bb.x1 >= rs_x && nd.bb.y0 >= rs_y && nd.bb.y1 >= rs_y)
bin = 3;
// Vertical split
else if (nd.bb.y0 < le_y && nd.bb.y1 < le_y)
bin = Nq + 0;
else if (nd.bb.y0 >= rs_y && nd.bb.y1 >= rs_y)
bin = Nq + 1;
// Horizontal split
else if (nd.bb.x0 < le_x && nd.bb.x1 < le_x)
bin = Nq + Nv + 0;
else if (nd.bb.x0 >= rs_x && nd.bb.x1 >= rs_x)
bin = Nq + Nv + 1;
tcs.at(bin).route_nets.push_back(ni);
}
if (ctx->verbose)
log_info("%d/%d nets not multi-threadable\n", int(tcs.at(N).route_nets.size()), int(route_queue.size()));
#ifdef NPNR_DISABLE_THREADS
// Singlethreaded routing - quadrants
for (int i = 0; i < Nq; i++) {
router_thread(tcs.at(i), /*is_mt=*/false);
}
// Vertical splits
for (int i = Nq; i < Nq + Nv; i++) {
router_thread(tcs.at(i), /*is_mt=*/false);
}
// Horizontal splits
for (int i = Nq + Nv; i < Nq + Nv + Nh; i++) {
router_thread(tcs.at(i), /*is_mt=*/false);
}
#else
// Multithreaded part of routing - quadrants
std::vector<boost::thread> threads;
for (int i = 0; i < Nq; i++) {
threads.emplace_back([this, &tcs, i]() { router_thread(tcs.at(i), /*is_mt=*/true); });
}
for (auto &t : threads)
t.join();
threads.clear();
// Vertical splits
for (int i = Nq; i < Nq + Nv; i++) {
threads.emplace_back([this, &tcs, i]() { router_thread(tcs.at(i), /*is_mt=*/true); });
}
for (auto &t : threads)
t.join();
threads.clear();
// Horizontal splits
for (int i = Nq + Nv; i < Nq + Nv + Nh; i++) {
threads.emplace_back([this, &tcs, i]() { router_thread(tcs.at(i), /*is_mt=*/true); });
}
for (auto &t : threads)
t.join();
threads.clear();
#endif
// Singlethreaded part of routing - nets that cross partitions
// or don't fit within bounding box
for (auto st_net : tcs.at(N).route_nets)
route_net(tcs.at(N), st_net, false);
// Failed nets
for (int i = 0; i < N; i++)
for (auto fail : tcs.at(i).failed_nets)
route_net(tcs.at(N), fail, false);
}
delay_t get_route_delay(int net, int usr_idx, int phys_idx)
{
auto &nd = nets.at(net);
auto &ad = nd.arcs.at(usr_idx).at(phys_idx);
WireId cursor = ad.sink_wire;
if (cursor == WireId() || nd.src_wire == WireId())
return 0;
delay_t delay = 0;
while (true) {
delay += ctx->getWireDelay(cursor).maxDelay();
if (!nd.wires.count(cursor))
break;
auto &bound = nd.wires.at(cursor);
if (bound.first == PipId())
break;
delay += ctx->getPipDelay(bound.first).maxDelay();
cursor = ctx->getPipSrcWire(bound.first);
}
NPNR_ASSERT(cursor == nd.src_wire);
return delay;
}
void update_route_delays()
{
for (int net : route_queue) {
NetInfo *ni = nets_by_udata.at(net);
#ifdef ARCH_ECP5
if (ni->is_global)
continue;
#endif
auto &nd = nets.at(net);
for (int i = 0; i < int(nd.arcs.size()); i++) {
delay_t arc_delay = 0;
for (int j = 0; j < int(nd.arcs.at(i).size()); j++)
arc_delay = std::max(arc_delay, get_route_delay(net, i, j));
tmg.set_route_delay(CellPortKey(ni->users.at(i)), DelayPair(arc_delay));
}
}
}
void operator()()
{
log_info("Running router2...\n");
log_info("Setting up routing resources...\n");
auto rstart = std::chrono::high_resolution_clock::now();
setup_nets();
setup_wires();
find_all_reserved_wires();
partition_nets();
curr_cong_weight = cfg.init_curr_cong_weight;
hist_cong_weight = cfg.hist_cong_weight;
ThreadContext st;
int iter = 1;
ScopeLock<Context> lock(ctx);
for (size_t i = 0; i < nets_by_udata.size(); i++)
route_queue.push_back(i);
timing_driven = ctx->setting<bool>("timing_driven");
if (ctx->settings.count(ctx->id("router2/tmg_ripup")))
timing_driven_ripup = timing_driven && ctx->setting<bool>("router2/tmg_ripup");
else
timing_driven_ripup = false;
log_info("Running main router loop...\n");
if (timing_driven)
tmg.run(true);
do {
ctx->sorted_shuffle(route_queue);
if (timing_driven) {
for (auto n : route_queue) {
NetInfo *ni = nets_by_udata.at(n);
auto &net = nets.at(n);
net.max_crit = 0;
for (auto &usr : ni->users) {
float c = tmg.get_criticality(CellPortKey(usr));
net.max_crit = std::max(net.max_crit, c);
}
}
std::stable_sort(route_queue.begin(), route_queue.end(),
[&](int na, int nb) { return nets.at(na).max_crit > nets.at(nb).max_crit; });
}
do_route();
update_route_delays();
route_queue.clear();
update_congestion();
if (!cfg.heatmap.empty()) {
std::string filename(cfg.heatmap + "_" + std::to_string(iter) + ".csv");
std::ofstream cong_map(filename);
if (!cong_map)
log_error("Failed to open wiretype heatmap %s for writing.\n", filename.c_str());
write_wiretype_heatmap(cong_map);
log_info(" wrote wiretype heatmap to %s.\n", filename.c_str());
}
int tmgfail = 0;
if (timing_driven)
tmg.run(false);
if (timing_driven_ripup && iter < 500) {
for (size_t i = 0; i < nets_by_udata.size(); i++) {
NetInfo *ni = nets_by_udata.at(i);
for (size_t j = 0; j < ni->users.size(); j++) {
if (arc_failed_slack(ni, j)) {
failed_nets.insert(i);
++tmgfail;
}
}
}
}
if (overused_wires == 0 && tmgfail == 0) {
// Try and actually bind nextpnr Arch API wires
bind_and_check_all();
}
for (auto cn : failed_nets)
route_queue.push_back(cn);
if (timing_driven_ripup)
log_info(" iter=%d wires=%d overused=%d overuse=%d tmgfail=%d archfail=%s\n", iter, total_wire_use,
overused_wires, total_overuse, tmgfail,
(overused_wires > 0 || tmgfail > 0) ? "NA" : std::to_string(arch_fail).c_str());
else
log_info(" iter=%d wires=%d overused=%d overuse=%d archfail=%s\n", iter, total_wire_use,
overused_wires, total_overuse,
(overused_wires > 0 || tmgfail > 0) ? "NA" : std::to_string(arch_fail).c_str());
++iter;
if (curr_cong_weight < 1e9)
curr_cong_weight += cfg.curr_cong_mult;
} while (!failed_nets.empty());
if (cfg.perf_profile) {
std::vector<std::pair<int, IdString>> nets_by_runtime;
for (auto &n : nets_by_udata) {
nets_by_runtime.emplace_back(nets.at(n->udata).total_route_us, n->name);
}
std::sort(nets_by_runtime.begin(), nets_by_runtime.end(), std::greater<std::pair<int, IdString>>());
log_info("1000 slowest nets by runtime:\n");
for (int i = 0; i < std::min(int(nets_by_runtime.size()), 1000); i++) {
log(" %80s %6d %.1fms\n", nets_by_runtime.at(i).second.c_str(ctx),
int(ctx->nets.at(nets_by_runtime.at(i).second)->users.size()),
nets_by_runtime.at(i).first / 1000.0);
}
}
auto rend = std::chrono::high_resolution_clock::now();
log_info("Router2 time %.02fs\n", std::chrono::duration<float>(rend - rstart).count());
log_info("Running router1 to check that route is legal...\n");
lock.unlock_early();
router1(ctx, Router1Cfg(ctx));
}
};
} // namespace
void router2(Context *ctx, const Router2Cfg &cfg)
{
Router2 rt(ctx, cfg);
rt.ctx = ctx;
rt();
}
Router2Cfg::Router2Cfg(Context *ctx)
{
backwards_max_iter = ctx->setting<int>("router2/bwdMaxIter", 20);
global_backwards_max_iter = ctx->setting<int>("router2/glbBwdMaxIter", 200);
bb_margin_x = ctx->setting<int>("router2/bbMargin/x", 3);
bb_margin_y = ctx->setting<int>("router2/bbMargin/y", 3);
ipin_cost_adder = ctx->setting<float>("router2/ipinCostAdder", 0.0f);
bias_cost_factor = ctx->setting<float>("router2/biasCostFactor", 0.25f);
init_curr_cong_weight = ctx->setting<float>("router2/initCurrCongWeight", 0.5f);
hist_cong_weight = ctx->setting<float>("router2/histCongWeight", 1.0f);
curr_cong_mult = ctx->setting<float>("router2/currCongWeightMult", 2.0f);
estimate_weight = ctx->setting<float>("router2/estimateWeight", 1.25f);
perf_profile = ctx->setting<bool>("router2/perfProfile", false);
if (ctx->settings.count(ctx->id("router2/heatmap")))
heatmap = ctx->settings.at(ctx->id("router2/heatmap")).as_string();
else
heatmap = "";
}
NEXTPNR_NAMESPACE_END
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