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/*
* Copyright (c) 2015-2017, Intel Corporation
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* * Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* * Neither the name of Intel Corporation nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*/
#include "rose_build_role_aliasing.h"
#include "ue2common.h"
#include "rose_build_impl.h"
#include "rose_build_merge.h"
#include "rose_build_util.h"
#include "grey.h"
#include "nfa/castlecompile.h"
#include "nfa/goughcompile.h"
#include "nfa/mcclellancompile_util.h"
#include "nfagraph/ng_holder.h"
#include "nfagraph/ng_is_equal.h"
#include "nfagraph/ng_limex.h"
#include "nfagraph/ng_prune.h"
#include "nfagraph/ng_uncalc_components.h"
#include "nfagraph/ng_util.h"
#include "util/bitutils.h"
#include "util/compile_context.h"
#include "util/container.h"
#include "util/flat_containers.h"
#include "util/graph.h"
#include "util/graph_range.h"
#include "util/hash.h"
#include "util/order_check.h"
#include <algorithm>
#include <numeric>
#include <vector>
#include <boost/graph/adjacency_iterator.hpp>
#include <boost/range/adaptor/map.hpp>
using namespace std;
using boost::adaptors::map_values;
namespace ue2 {
static constexpr size_t MERGE_GROUP_SIZE_MAX = 200;
namespace {
// Used for checking edge sets (both in- and out-) against each other.
struct EdgeAndVertex {
EdgeAndVertex(const RoseEdge &e, const RoseVertex v_,
const RoseGraph &g) : v(v_), eprops(g[e]) {}
virtual ~EdgeAndVertex() {}
virtual bool operator<(const EdgeAndVertex &a) const {
if (v != a.v) {
return v < a.v;
}
if (eprops.minBound != a.eprops.minBound) {
return eprops.minBound < a.eprops.minBound;
}
if (eprops.maxBound != a.eprops.maxBound) {
return eprops.maxBound < a.eprops.maxBound;
}
if (eprops.rose_top != a.eprops.rose_top) {
return eprops.rose_top < a.eprops.rose_top;
}
return eprops.history < a.eprops.history;
}
virtual bool operator==(const EdgeAndVertex &a) const {
return v == a.v &&
eprops.minBound == a.eprops.minBound &&
eprops.maxBound == a.eprops.maxBound &&
eprops.rose_top == a.eprops.rose_top &&
eprops.history == a.eprops.history;
}
private:
RoseVertex v;
const RoseEdgeProps &eprops;
};
struct AliasOutEdge : EdgeAndVertex {
AliasOutEdge(const RoseEdge &e, const RoseGraph &g) :
EdgeAndVertex(e, target(e, g), g) {}
};
struct AliasInEdge : EdgeAndVertex {
AliasInEdge(const RoseEdge &e, const RoseGraph &g) :
EdgeAndVertex(e, source(e, g), g) {}
};
class CandidateSet {
public:
using key_type = RoseVertex;
using iterator = set<RoseVertex>::iterator;
using const_iterator = set<RoseVertex>::const_iterator;
iterator begin() { return main_cont.begin(); }
iterator end() { return main_cont.end(); }
const_iterator begin() const { return main_cont.begin(); }
const_iterator end() const { return main_cont.end(); }
bool contains(RoseVertex a) const {
return hash_cont.find(a) != hash_cont.end();
}
void insert(RoseVertex a) {
main_cont.insert(a);
hash_cont.insert(a);
}
void erase(iterator aa) {
RoseVertex a = *aa;
main_cont.erase(aa);
hash_cont.erase(a);
}
void erase(RoseVertex a) {
main_cont.erase(a);
hash_cont.erase(a);
}
size_t size() const {
assert(hash_cont.size() == main_cont.size());
return main_cont.size();
}
bool empty() const {
assert(hash_cont.size() == main_cont.size());
return main_cont.empty();
}
private:
/* if a vertex is worth storing, it is worth storing twice */
set<RoseVertex> main_cont; /* deterministic iterator */
unordered_set<RoseVertex> hash_cont; /* member checks */
};
struct RoseAliasingInfo {
RoseAliasingInfo(const RoseBuildImpl &build) {
const auto &g = build.g;
// Populate reverse leftfix map.
for (auto v : vertices_range(g)) {
if (g[v].left) {
rev_leftfix[g[v].left].insert(v);
}
}
// Populate reverse ghost vertex map.
for (const auto &m : build.ghost) {
rev_ghost[m.second].insert(m.first);
}
}
/** \brief Mapping from leftfix to vertices. */
unordered_map<left_id, set<RoseVertex>> rev_leftfix;
/** \brief Mapping from undelayed ghost to delayed vertices. */
unordered_map<RoseVertex, set<RoseVertex>> rev_ghost;
};
} // namespace
// Check successor set: must lead to the same vertices via edges with the
// same properties.
static
bool sameSuccessors(RoseVertex a, RoseVertex b, const RoseGraph &g) {
if (out_degree(a, g) != out_degree(b, g)) {
return false;
}
set<AliasOutEdge> succs_a, succs_b;
for (const auto &e : out_edges_range(a, g)) {
succs_a.insert(AliasOutEdge(e, g));
}
for (const auto &e : out_edges_range(b, g)) {
succs_b.insert(AliasOutEdge(e, g));
}
return (succs_a == succs_b);
}
/* unlike LeftEngInfo::==, this does a deep check to see if the leftfixes are
* equivalent rather than checking for pointer equality. */
static
bool hasEqualLeftfixes(RoseVertex a, RoseVertex b, const RoseGraph &g) {
assert(g[a].left || g[b].left);
if (!g[a].left || !g[b].left) {
return false;
}
const LeftEngInfo &a_left = g[a].left;
const LeftEngInfo &b_left = g[b].left;
if (a_left.castle && b_left.castle) {
return is_equal(*a_left.castle, a_left.leftfix_report,
*b_left.castle, b_left.leftfix_report);
}
if (a_left.graph && b_left.graph) {
/* non-castle engines have graphs */
return is_equal(*a_left.graph, a_left.leftfix_report, *b_left.graph,
b_left.leftfix_report);
}
/* graph <-> castle cases are not equal */
return false;
}
// Check predecessor set: must come from the same vertices via edges with
// the same properties.
static
bool samePredecessors(RoseVertex a, RoseVertex b, const RoseGraph &g) {
if (in_degree(a, g) != in_degree(b, g)) {
return false;
}
set<AliasInEdge> preds_a, preds_b;
for (const auto &e : in_edges_range(a, g)) {
preds_a.insert(AliasInEdge(e, g));
}
for (const auto &e : in_edges_range(b, g)) {
preds_b.insert(AliasInEdge(e, g));
}
if (preds_a != preds_b) {
return false;
}
if (g[a].left || g[b].left) {
if (!hasEqualLeftfixes(a, b, g)) {
return false;
}
for (const auto &e_a : in_edges_range(a, g)) {
RoseEdge e = edge(source(e_a, g), b, g);
if (!e || g[e].rose_top != g[e_a].rose_top) {
DEBUG_PRINTF("bad tops\n");
return false;
}
}
}
return true;
}
static
bool hasCommonSuccWithBadBounds(RoseVertex a, RoseVertex b,
const RoseGraph &g) {
for (const auto &e_a : out_edges_range(a, g)) {
if (RoseEdge e = edge(b, target(e_a, g), g)) {
if (g[e_a].maxBound < g[e].minBound
|| g[e].maxBound < g[e_a].minBound) {
return true;
}
if (g[e_a].rose_top != g[e].rose_top) {
// Can't trigger two tops on the same leftfix, we can't merge
// this.
return true;
}
}
}
return false;
}
static
bool hasCommonPredWithBadBounds(RoseVertex a, RoseVertex b,
const RoseGraph &g) {
for (const auto &e_a : in_edges_range(a, g)) {
if (RoseEdge e = edge(source(e_a, g), b, g)) {
if (g[e_a].maxBound < g[e].minBound
|| g[e].maxBound < g[e_a].minBound) {
return true;
}
// XXX: if we're merging two vertices with different roses, we
// cannot allow them to share a pred, as we would be unable to
// merge the (necessarily different) tops on the in-edges. This
// could be relaxed if we made the tops mergeable (by making
// edge_top a bitfield, for example).
if (g[a].left != g[b].left) {
return true;
}
}
}
return false;
}
static
bool canMergeLiterals(RoseVertex a, RoseVertex b, const RoseBuildImpl &build) {
const auto &lits_a = build.g[a].literals;
const auto &lits_b = build.g[b].literals;
assert(!lits_a.empty() && !lits_b.empty());
// If both vertices have only pseudo-dotstar in-edges, we can merge
// literals of different lengths and can avoid the check below.
if (build.hasOnlyPseudoStarInEdges(a) &&
build.hasOnlyPseudoStarInEdges(b)) {
DEBUG_PRINTF("both have pseudo-dotstar in-edges\n");
return true;
}
// Otherwise, all the literals involved must have the same length.
for (u32 a_id : lits_a) {
const rose_literal_id &la = build.literals.at(a_id);
for (u32 b_id : lits_b) {
const rose_literal_id &lb = build.literals.at(b_id);
if (la.elength() != lb.elength()) {
DEBUG_PRINTF("bad merge %zu!=%zu '%s', '%s'\n", la.elength(),
lb.elength(), la.s.c_str(), lb.s.c_str());
return false;
}
}
}
return true;
}
static
bool isAliasingCandidate(RoseVertex v, const RoseBuildImpl &build) {
const RoseVertexProps &props = build.g[v];
// Must have literals.
if (props.literals.empty()) {
return false;
}
assert(*props.literals.begin() != MO_INVALID_IDX);
return true;
}
static
bool sameGhostProperties(const RoseBuildImpl &build,
const RoseAliasingInfo &rai, RoseVertex a,
RoseVertex b) {
// If these are ghost mapping keys, then they must map to the same vertex.
if (contains(build.ghost, a) || contains(build.ghost, b)) {
DEBUG_PRINTF("checking ghost key compat\n");
if (!contains(build.ghost, a) || !contains(build.ghost, b)) {
DEBUG_PRINTF("missing ghost mapping\n");
return false;
}
if (build.ghost.at(a) != build.ghost.at(b)) {
DEBUG_PRINTF("diff ghost mapping\n");
return false;
}
DEBUG_PRINTF("ghost mappings ok\n");
return true;
}
// If they are ghost vertices, then they must have the same literals.
if (contains(rai.rev_ghost, a) || contains(rai.rev_ghost, b)) {
if (!contains(rai.rev_ghost, a) || !contains(rai.rev_ghost, b)) {
DEBUG_PRINTF("missing ghost reverse mapping\n");
return false;
}
return build.g[a].literals == build.g[b].literals;
}
return true;
}
static
bool sameRoleProperties(const RoseBuildImpl &build, const RoseAliasingInfo &rai,
RoseVertex a, RoseVertex b) {
const RoseGraph &g = build.g;
const RoseVertexProps &aprops = g[a], &bprops = g[b];
if (aprops.eod_accept != bprops.eod_accept) {
return false;
}
// We don't want to merge a role with LAST_BYTE history with one without,
// as a role that can only be triggered at EOD cannot safely precede
// "ordinary" roles.
if (hasLastByteHistorySucc(g, a) != hasLastByteHistorySucc(g, b)) {
return false;
}
// We certainly don't want to merge root roles with non-root roles.
/* TODO: explain */
if (build.isRootSuccessor(a) != build.isRootSuccessor(b)) {
return false;
}
if (aprops.som_adjust != bprops.som_adjust) {
return false;
}
if (!sameGhostProperties(build, rai, a, b)) {
return false;
}
/* "roses are mergeable" check are handled elsewhere */
return true;
}
/* Checks compatibility of role properties if we require that two roles are
* right equiv. */
static
bool sameRightRoleProperties(const RoseBuildImpl &build, RoseVertex a,
RoseVertex b) {
const RoseGraph &g = build.g;
const RoseVertexProps &aprops = g[a], &bprops = g[b];
if (aprops.reports != bprops.reports) {
return false;
}
if (hasAnchHistorySucc(g, a) != hasAnchHistorySucc(g, b)) {
return false;
}
// If the history type is ANCH, then we need to be careful that we only
// merge literals that occur at the same offsets.
if (hasAnchHistorySucc(g, a) || hasAnchHistorySucc(g, b)) {
if (aprops.min_offset != bprops.min_offset
|| aprops.max_offset != bprops.max_offset) {
return false;
}
}
if (aprops.suffix != bprops.suffix) {
return false;
}
return true;
}
static
void mergeEdgeAdd(RoseVertex u, RoseVertex v, const RoseEdge &from_edge,
const RoseEdge *to_edge, RoseGraph &g) {
const RoseEdgeProps &from_props = g[from_edge];
if (!to_edge) {
DEBUG_PRINTF("adding edge [%zu,%zu]\n", g[u].index, g[v].index);
add_edge(u, v, from_props, g);
} else {
// union of the two edges.
DEBUG_PRINTF("updating edge [%zu,%zu]\n", g[u].index, g[v].index);
RoseEdgeProps &to_props = g[*to_edge];
to_props.minBound = min(to_props.minBound, from_props.minBound);
to_props.maxBound = max(to_props.maxBound, from_props.maxBound);
assert(to_props.rose_top == from_props.rose_top);
}
}
/* clone a's edges onto b */
static
void mergeEdges(RoseVertex a, RoseVertex b, RoseGraph &g) {
// All the edges to or from b for quick lookup.
typedef map<RoseVertex, RoseEdge> EdgeCache;
EdgeCache b_edges;
// Cache b's in-edges so we can look them up by source quickly.
for (const auto &e : in_edges_range(b, g)) {
RoseVertex u = source(e, g);
b_edges.emplace(u, e);
}
// Add a's in-edges to b, merging them in where b already has the new edge.
// Once handled, the in-edges to a are removed.
RoseGraph::in_edge_iterator ei, ee;
tie(ei, ee) = in_edges(a, g);
while (ei != ee) {
RoseVertex u = source(*ei, g);
EdgeCache::const_iterator it = b_edges.find(u);
const RoseEdge *to_edge = (it == b_edges.end() ? nullptr : &it->second);
mergeEdgeAdd(u, b, *ei, to_edge, g);
remove_edge(*ei++, g);
}
// Cache b's out-edges so we can look them up by target quickly.
b_edges.clear();
for (const auto &e : out_edges_range(b, g)) {
RoseVertex v = target(e, g);
b_edges.emplace(v, e);
}
// Add a's out-edges to b, merging them in where b already has the new edge.
// Once handled, the out-edges to a are removed.
RoseGraph::out_edge_iterator oi, oe;
tie(oi, oe) = out_edges(a, g);
while (oi != oe) {
RoseVertex v = target(*oi, g);
EdgeCache::const_iterator it = b_edges.find(v);
const RoseEdge *to_edge = (it == b_edges.end() ? nullptr : &it->second);
mergeEdgeAdd(b, v, *oi, to_edge, g);
remove_edge(*oi++, g);
}
// Vertex a should no longer have any in- or out-edges.
assert(degree(a, g) == 0);
}
static
void mergeLiteralSets(RoseVertex a, RoseVertex b, RoseBuildImpl &build) {
RoseGraph &g = build.g;
const auto &a_literals = g[a].literals;
for (u32 lit_id : a_literals) {
auto &lit_vertices = build.literal_info[lit_id].vertices;
lit_vertices.erase(a);
lit_vertices.insert(b);
}
insert(&g[b].literals, a_literals);
}
static
void updateAliasingInfo(RoseBuildImpl &build, RoseAliasingInfo &rai,
RoseVertex a, RoseVertex b) {
if (build.g[a].left) {
const left_id left(build.g[a].left);
assert(contains(rai.rev_leftfix[left], a));
rai.rev_leftfix[left].erase(a);
}
if (contains(build.ghost, a)) {
auto ghost = build.ghost.at(a);
assert(contains(build.ghost, b) && ghost == build.ghost.at(b));
build.ghost.erase(a);
rai.rev_ghost[ghost].erase(a);
}
if (contains(rai.rev_ghost, a)) {
for (const auto &v : rai.rev_ghost[a]) {
build.ghost[v] = b;
rai.rev_ghost[b].insert(v);
}
rai.rev_ghost.erase(a);
}
}
/** \brief Common role merge code used by variants below. */
static
void mergeCommon(RoseBuildImpl &build, RoseAliasingInfo &rai, RoseVertex a,
RoseVertex b) {
RoseGraph &g = build.g;
assert(g[a].eod_accept == g[b].eod_accept);
assert(g[a].left == g[b].left);
assert(!g[a].suffix || g[a].suffix == g[b].suffix);
// In some situations (ghost roles etc), we can have different groups.
assert(!g[a].groups && !g[b].groups); /* current structure means groups
* haven't been assigned yet */
g[b].groups |= g[a].groups;
mergeLiteralSets(a, b, build);
updateAliasingInfo(build, rai, a, b);
// Our min and max_offsets should be sane.
assert(g[b].min_offset <= g[b].max_offset);
// Safety check: we should not have created through a merge a vertex that
// has an out-edge with ANCH history but is not fixed-offset.
assert(!hasAnchHistorySucc(g, b) || g[b].fixedOffset());
}
/** \brief Merge role 'a' into 'b', left merge path. */
static
void mergeVerticesLeft(RoseVertex a, RoseVertex b, RoseBuildImpl &build,
RoseAliasingInfo &rai) {
RoseGraph &g = build.g;
DEBUG_PRINTF("merging vertex %zu into %zu\n", g[a].index, g[b].index);
insert(&g[b].reports, g[a].reports);
// Since it is a left merge (identical LHS) we should pick the tighter
// bound.
g[b].min_offset = max(g[a].min_offset, g[b].min_offset);
g[b].max_offset = min(g[a].max_offset, g[b].max_offset);
if (!g[b].suffix) {
g[b].suffix = g[a].suffix;
}
mergeEdges(a, b, g);
mergeCommon(build, rai, a, b);
}
/** \brief Merge role 'a' into 'b', right merge path. */
static
void mergeVerticesRight(RoseVertex a, RoseVertex b, RoseBuildImpl &build,
RoseAliasingInfo &rai) {
RoseGraph &g = build.g;
DEBUG_PRINTF("merging vertex %zu into %zu\n", g[a].index, g[b].index);
insert(&g[b].reports, g[a].reports);
g[b].min_offset = min(g[a].min_offset, g[b].min_offset);
g[b].max_offset = max(g[a].max_offset, g[b].max_offset);
mergeEdges(a, b, g);
mergeCommon(build, rai, a, b);
}
/**
* Faster version of \ref mergeVertices for diamond merges, for which we know
* that the in- and out-edge sets, reports and suffixes are identical.
*/
static
void mergeVerticesDiamond(RoseVertex a, RoseVertex b, RoseBuildImpl &build,
RoseAliasingInfo &rai) {
RoseGraph &g = build.g;
DEBUG_PRINTF("merging vertex %zu into %zu\n", g[a].index, g[b].index);
// For a diamond merge, most properties are already the same (with the
// notable exception of the literal set).
assert(g[a].reports == g[b].reports);
assert(g[a].suffix == g[b].suffix);
g[b].min_offset = min(g[a].min_offset, g[b].min_offset);
g[b].max_offset = max(g[a].max_offset, g[b].max_offset);
mergeCommon(build, rai, a, b);
}
static never_inline
void findCandidates(const RoseBuildImpl &build, CandidateSet *candidates) {
for (auto v : vertices_range(build.g)) {
if (isAliasingCandidate(v, build)) {
DEBUG_PRINTF("candidate %zu\n", build.g[v].index);
DEBUG_PRINTF("lits: %u\n", *build.g[v].literals.begin());
candidates->insert(v);
}
}
assert(candidates->size() <= num_vertices(build.g));
DEBUG_PRINTF("found %zu/%zu candidates\n", candidates->size(),
num_vertices(build.g));
}
static
RoseVertex pickPred(const RoseVertex v, const RoseGraph &g,
const RoseBuildImpl &build) {
RoseGraph::in_edge_iterator ei, ee;
tie(ei, ee) = in_edges(v, g);
if (ei == ee) {
assert(0); // every candidate should have in-degree!
return RoseGraph::null_vertex();
}
// Avoid roots if we have other options, since it doesn't matter to the
// merge pass which predecessor we pick.
RoseVertex u = source(*ei, g);
while (build.isAnyStart(u) && ++ei != ee) {
u = source(*ei, g);
}
return u;
}
template<>
bool contains<>(const CandidateSet &container, const RoseVertex &key) {
return container.contains(key);
}
// Simplified version of hasCommonPredWithBadBounds for diamond merges.
static
bool hasCommonPredWithDiffRoses(RoseVertex a, RoseVertex b,
const RoseGraph &g) {
if (!g[a].left || !g[b].left) {
DEBUG_PRINTF("one of (a, b) doesn't have a prefix\n");
return true;
}
// XXX: if we're merging two vertices with different leftfixes, we
// cannot allow them to share a pred, as we would be unable to
// merge the (necessarily different) tops on the in-edges. This
// could be relaxed if we made the tops mergeable (by making
// edge_top a bitfield, for example).
const bool equal_roses = hasEqualLeftfixes(a, b, g);
for (const auto &e_a : in_edges_range(a, g)) {
if (RoseEdge e = edge(source(e_a, g), b, g)) {
DEBUG_PRINTF("common pred, e_r=%d r_t %u,%u\n",
(int)equal_roses, g[e].rose_top, g[e_a].rose_top);
if (!equal_roses) {
DEBUG_PRINTF("different roses\n");
return true;
}
if (g[e].rose_top != g[e_a].rose_top) {
DEBUG_PRINTF("bad tops\n");
return true;
}
}
}
DEBUG_PRINTF("ok\n");
return false;
}
static
void pruneReportIfUnused(const RoseBuildImpl &build, shared_ptr<NGHolder> h,
const set<RoseVertex> &verts, ReportID report) {
DEBUG_PRINTF("trying to prune %u from %p (v %zu)\n", report, h.get(),
verts.size());
for (RoseVertex v : verts) {
if (build.g[v].left.graph == h &&
build.g[v].left.leftfix_report == report) {
DEBUG_PRINTF("report %u still in use\n", report);
return;
}
}
if (!verts.empty()) {
// Report no longer in use, but graph h is still alive: we should prune
// the report if we can do so without rendering the graph
// unimplementable.
DEBUG_PRINTF("report %u has been merged away, pruning\n", report);
assert(h->kind == (build.isRootSuccessor(*verts.begin()) ? NFA_PREFIX
: NFA_INFIX));
unique_ptr<NGHolder> h_new = cloneHolder(*h);
pruneReport(*h_new, report);
if (isImplementableNFA(*h_new, nullptr, build.cc)) {
clear_graph(*h);
cloneHolder(*h, *h_new);
} else {
DEBUG_PRINTF("prune produced unimplementable graph, "
"leaving as-is\n");
}
}
}
/** \brief Remove any tops that don't lead to the given report from this
* Castle. */
static
void pruneCastle(CastleProto &castle, ReportID report) {
unordered_set<u32> dead; // tops to remove.
for (const auto &m : castle.repeats) {
if (!contains(m.second.reports, report)) {
dead.insert(m.first);
}
}
for (const auto &top : dead) {
castle.erase(top);
}
assert(!castle.repeats.empty());
}
/** \brief Set all reports to the given one. */
static
void setReports(CastleProto &castle, ReportID report) {
castle.report_map.clear();
for (auto &e : castle.repeats) {
u32 top = e.first;
auto &repeat = e.second;
repeat.reports.clear();
repeat.reports.insert(report);
castle.report_map[report].insert(top);
}
}
static
void updateEdgeTops(RoseGraph &g, RoseVertex v, const map<u32, u32> &top_map) {
for (const auto &e : in_edges_range(v, g)) {
g[e].rose_top = top_map.at(g[e].rose_top);
}
}
static
void pruneUnusedTops(CastleProto &castle, const RoseGraph &g,
const set<RoseVertex> &verts) {
unordered_set<u32> used_tops;
for (auto v : verts) {
assert(g[v].left.castle.get() == &castle);
for (const auto &e : in_edges_range(v, g)) {
u32 top = g[e].rose_top;
assert(contains(castle.repeats, top));
used_tops.insert(top);
}
}
DEBUG_PRINTF("castle has %zu tops, graph has %zu tops\n",
castle.repeats.size(), used_tops.size());
for (u32 top : assoc_keys(castle.repeats)) {
if (!contains(used_tops, top)) {
DEBUG_PRINTF("removing unused top %u\n", top);
castle.erase(top);
}
}
}
static
void pruneUnusedTops(NGHolder &h, const RoseGraph &g,
const set<RoseVertex> &verts) {
if (!is_triggered(h)) {
DEBUG_PRINTF("not triggered, no tops\n");
return;
}
assert(isCorrectlyTopped(h));
DEBUG_PRINTF("pruning unused tops\n");
flat_set<u32> used_tops;
for (auto v : verts) {
assert(g[v].left.graph.get() == &h);
for (const auto &e : in_edges_range(v, g)) {
u32 top = g[e].rose_top;
used_tops.insert(top);
}
}
vector<NFAEdge> dead;
for (const auto &e : out_edges_range(h.start, h)) {
NFAVertex v = target(e, h);
if (v == h.startDs) {
continue; // stylised edge, leave it alone.
}
flat_set<u32> pruned_tops;
auto pt_inserter = inserter(pruned_tops, pruned_tops.end());
set_intersection(h[e].tops.begin(), h[e].tops.end(),
used_tops.begin(), used_tops.end(), pt_inserter);
h[e].tops = std::move(pruned_tops);
if (h[e].tops.empty()) {
DEBUG_PRINTF("edge (start,%zu) has only unused tops\n", h[v].index);
dead.push_back(e);
}
}
if (dead.empty()) {
return;
}
remove_edges(dead, h);
pruneUseless(h);
clearReports(h); // As we may have removed vacuous edges.
}
static
bool mergeSameCastle(RoseBuildImpl &build, RoseVertex a, RoseVertex b,
RoseAliasingInfo &rai) {
RoseGraph &g = build.g;
LeftEngInfo &a_left = g[a].left;
LeftEngInfo &b_left = g[b].left;
CastleProto &castle = *a_left.castle;
DEBUG_PRINTF("a report=%u, b report=%u\n", a_left.leftfix_report,
b_left.leftfix_report);
u32 merge_count = 0;
for (const auto &c : castle.repeats) {
DEBUG_PRINTF("top %u -> %s report %u\n", c.first,
c.second.bounds.str().c_str(), *c.second.reports.begin());
if (contains(c.second.reports, a_left.leftfix_report) ||
contains(c.second.reports, b_left.leftfix_report)) {
merge_count++;
}
}
if (castle.repeats.size() + merge_count > castle.max_occupancy) {
DEBUG_PRINTF("too big to merge\n");
return false;
}
const ReportID new_report = build.getNewNfaReport();
map<u32, u32> a_top_map, b_top_map;
for (const auto &c : castle.repeats) {
u32 old_top = c.first;
if (contains(c.second.reports, a_left.leftfix_report)) {
PureRepeat pr = c.second;
pr.reports.clear();
pr.reports.insert(new_report);
u32 new_top = castle.merge(pr);
assert(new_top < castle.max_occupancy);
a_top_map[old_top] = new_top;
} else if (contains(c.second.reports, b_left.leftfix_report)) {
PureRepeat pr = c.second;
pr.reports.clear();
pr.reports.insert(new_report);
u32 new_top = castle.merge(pr);
assert(new_top < castle.max_occupancy);
b_top_map[old_top] = new_top;
}
}
assert(contains(rai.rev_leftfix[b_left], b));
rai.rev_leftfix[b_left].erase(b);
rai.rev_leftfix[a_left].insert(b);
a_left.leftfix_report = new_report;
b_left.leftfix_report = new_report;
assert(a_left == b_left);
updateEdgeTops(g, a, a_top_map);
updateEdgeTops(g, b, b_top_map);
pruneUnusedTops(castle, g, rai.rev_leftfix[a_left]);
return true;
}
static
bool attemptRoseCastleMerge(RoseBuildImpl &build, bool preds_same, RoseVertex a,
RoseVertex b, bool trivialCasesOnly,
RoseAliasingInfo &rai) {
RoseGraph &g = build.g;
LeftEngInfo &a_left = g[a].left;
LeftEngInfo &b_left = g[b].left;
left_id a_left_id(a_left);
left_id b_left_id(b_left);
CastleProto &a_castle = *a_left_id.castle();
CastleProto &b_castle = *b_left_id.castle();
if (a_castle.reach() != b_castle.reach()) {
DEBUG_PRINTF("different reach\n");
return false;
}
DEBUG_PRINTF("a castle=%p, report=%u\n", &a_castle, a_left.leftfix_report);
DEBUG_PRINTF("b castle=%p, report=%u\n", &b_castle, b_left.leftfix_report);
if (&a_castle == &b_castle) {
DEBUG_PRINTF("castles are the same\n");
return mergeSameCastle(build, a, b, rai);
}
if (is_equal(a_castle, a_left.leftfix_report, b_castle,
b_left.leftfix_report)) {
DEBUG_PRINTF("castles are equiv with respect to reports\n");
if (rai.rev_leftfix[a_left_id].size() == 1) {
/* nobody else is using a_castle */
rai.rev_leftfix[b_left_id].erase(b);
rai.rev_leftfix[a_left_id].insert(b);
pruneUnusedTops(b_castle, g, rai.rev_leftfix[b_left_id]);
b_left.castle = a_left.castle;
b_left.leftfix_report = a_left.leftfix_report;
DEBUG_PRINTF("OK -> only user of a_castle\n");
return true;
}
if (rai.rev_leftfix[b_left_id].size() == 1) {
/* nobody else is using b_castle */
rai.rev_leftfix[a_left_id].erase(a);
rai.rev_leftfix[b_left_id].insert(a);
pruneUnusedTops(a_castle, g, rai.rev_leftfix[a_left_id]);
a_left.castle = b_left.castle;
a_left.leftfix_report = b_left.leftfix_report;
DEBUG_PRINTF("OK -> only user of b_castle\n");
return true;
}
if (preds_same) {
/* preds are the same anyway in diamond/left merges just need to
* check that all the literals in rev_leftfix[b_h] can handle a_h */
for (auto v : rai.rev_leftfix[b_left_id]) {
if (!mergeableRoseVertices(build, a, v)) {
goto literal_mismatch_1;
}
}
rai.rev_leftfix[a_left_id].erase(a);
rai.rev_leftfix[b_left_id].insert(a);
pruneUnusedTops(a_castle, g, rai.rev_leftfix[a_left_id]);
a_left.castle = b_left.castle;
a_left.leftfix_report = b_left.leftfix_report;
DEBUG_PRINTF("OK -> same preds ???\n");
return true;
literal_mismatch_1:
/* preds are the same anyway in diamond/left merges just need to
* check that all the literals in rev_leftfix[a_h] can handle b_h */
for (auto v : rai.rev_leftfix[a_left_id]) {
if (!mergeableRoseVertices(build, v, b)) {
goto literal_mismatch_2;
}
}
rai.rev_leftfix[b_left_id].erase(b);
rai.rev_leftfix[a_left_id].insert(b);
pruneUnusedTops(b_castle, g, rai.rev_leftfix[b_left_id]);
b_left.castle = a_left.castle;
b_left.leftfix_report = a_left.leftfix_report;
DEBUG_PRINTF("OK -> same preds ???\n");
return true;
literal_mismatch_2:;
}
DEBUG_PRINTF("OK -> create new\n");
/* we need to create a new graph as there may be other people
* using b_left and it would be bad if a's preds started triggering it
*/
ReportID new_report = build.getNewNfaReport();
shared_ptr<CastleProto> new_castle = make_shared<CastleProto>(a_castle);
pruneCastle(*new_castle, a_left.leftfix_report);
setReports(*new_castle, new_report);
rai.rev_leftfix[a_left_id].erase(a);
rai.rev_leftfix[b_left_id].erase(b);
pruneUnusedTops(*a_left.castle, g, rai.rev_leftfix[a_left_id]);
pruneUnusedTops(*b_left.castle, g, rai.rev_leftfix[b_left_id]);
a_left.leftfix_report = new_report;
b_left.leftfix_report = new_report;
a_left.castle = new_castle;
b_left.castle = new_castle;
assert(a_left == b_left);
rai.rev_leftfix[a_left].insert(a);
rai.rev_leftfix[a_left].insert(b);
pruneUnusedTops(*new_castle, g, rai.rev_leftfix[a_left]);
return true;
}
// Everything after this point requires more work, so we guard it with the
// trivial cases argument..
if (trivialCasesOnly) {
return false;
}
// Only infixes. Prefixes require special care when doing non-trivial
// merges.
if (!build.isNonRootSuccessor(a) || !build.isNonRootSuccessor(b)) {
return false;
}
set<RoseVertex> &b_verts = rai.rev_leftfix[b_left_id];
set<RoseVertex> aa;
aa.insert(a);
if (!mergeableRoseVertices(build, aa, b_verts)) {
DEBUG_PRINTF("vertices not mergeable\n");
return false;
}
if (!build.cc.grey.roseMultiTopRoses || !build.cc.grey.allowCastle) {
return false;
}
DEBUG_PRINTF("merging into new castle\n");
// Clone new castle with a's repeats in it, set to a new report.
ReportID new_report = build.getNewNfaReport();
shared_ptr<CastleProto> m_castle = make_shared<CastleProto>(a_castle);
pruneCastle(*m_castle, a_left.leftfix_report);
setReports(*m_castle, new_report);
// Merge in the relevant repeats from b with the new report. Note that
// we'll have to remap tops appropriately.
map<u32, u32> b_top_map;
for (const auto &e : in_edges_range(b, g)) {
u32 top = g[e].rose_top;
assert(contains(b_castle.repeats, top));
PureRepeat pr = b_castle.repeats[top]; // mutable copy
pr.reports.clear();
pr.reports.insert(new_report);
// We should be protected from merging common preds with tops leading
// to completely different repeats by earlier checks, but just in
// case...
if (RoseEdge a_edge = edge(source(e, g), a, g)) {
u32 a_top = g[a_edge].rose_top;
const PureRepeat &a_pr = m_castle->repeats[a_top]; // new report
if (pr != a_pr) {
DEBUG_PRINTF("merge failed, common pred with diff repeat\n");
return false;
}
}
u32 new_top = m_castle->merge(pr);
if (new_top == CastleProto::max_occupancy) {
DEBUG_PRINTF("merge failed\n");
return false;
}
b_top_map[top] = new_top;
}
updateEdgeTops(g, b, b_top_map);
DEBUG_PRINTF("merged into castle containing %zu repeats\n",
m_castle->repeats.size());
rai.rev_leftfix[a_left_id].erase(a);
rai.rev_leftfix[b_left_id].erase(b);
pruneUnusedTops(*a_left.castle, g, rai.rev_leftfix[a_left_id]);
pruneUnusedTops(*b_left.castle, g, rai.rev_leftfix[b_left_id]);
a_left.castle = m_castle;
a_left.leftfix_report = new_report;
b_left.castle = m_castle;
b_left.leftfix_report = new_report;
assert(a_left == b_left);
rai.rev_leftfix[a_left].insert(a);
rai.rev_leftfix[a_left].insert(b);
pruneUnusedTops(*m_castle, g, rai.rev_leftfix[a_left]);
return true;
}
static
bool attemptRoseGraphMerge(RoseBuildImpl &build, bool preds_same, RoseVertex a,
RoseVertex b, bool trivialCasesOnly,
RoseAliasingInfo &rai) {
RoseGraph &g = build.g;
LeftEngInfo &a_left = g[a].left;
LeftEngInfo &b_left = g[b].left;
left_id a_left_id(a_left);
left_id b_left_id(b_left);
shared_ptr<NGHolder> a_h = a_left.graph;
shared_ptr<NGHolder> b_h = b_left.graph;
assert(a_h && b_h);
assert(isImplementableNFA(*a_h, nullptr, build.cc));
assert(isImplementableNFA(*b_h, nullptr, build.cc));
// If we only differ in reports, this is a very easy merge. Just use b's
// report for both.
/* Actually not so easy, there may be other poor suckers using a and/or b's
* reports who will be surprised by this change */
if (a_h == b_h) {
DEBUG_PRINTF("OK -> same actual holder\n");
ReportID a_oldreport = a_left.leftfix_report;
ReportID b_oldreport = b_left.leftfix_report;
ReportID new_report = build.getNewNfaReport();
duplicateReport(*a_h, a_left.leftfix_report, new_report);
duplicateReport(*b_h, b_left.leftfix_report, new_report);
a_left.leftfix_report = new_report;
b_left.leftfix_report = new_report;
pruneReportIfUnused(build, b_h, rai.rev_leftfix[b_left_id],
a_oldreport);
pruneReportIfUnused(build, b_h, rai.rev_leftfix[b_left_id],
b_oldreport);
pruneUnusedTops(*b_h, g, rai.rev_leftfix[b_left_id]);
assert(a_left == b_left);
return true;
}
/* if it is the same graph, it is also fairly easy */
if (is_equal(*a_h, a_left.leftfix_report, *b_h, b_left.leftfix_report)) {
if (rai.rev_leftfix[a_left_id].size() == 1) {
/* nobody else is using a_h */
rai.rev_leftfix[b_left_id].erase(b);
rai.rev_leftfix[a_left_id].insert(b);
b_left.graph = a_h;
b_left.leftfix_report = a_left.leftfix_report;
pruneUnusedTops(*b_h, g, rai.rev_leftfix[b_left_id]);
DEBUG_PRINTF("OK -> only user of a_h\n");
return true;
}
if (rai.rev_leftfix[b_left_id].size() == 1) {
/* nobody else is using b_h */
rai.rev_leftfix[a_left_id].erase(a);
rai.rev_leftfix[b_left_id].insert(a);
a_left.graph = b_h;
a_left.leftfix_report = b_left.leftfix_report;
pruneUnusedTops(*a_h, g, rai.rev_leftfix[a_left_id]);
DEBUG_PRINTF("OK -> only user of b_h\n");
return true;
}
if (preds_same) {
/* preds are the same anyway in diamond/left merges just need to
* check that all the literals in rev_leftfix[b_h] can handle a_h */
for (auto v : rai.rev_leftfix[b_left_id]) {
if (!mergeableRoseVertices(build, a, v)) {
goto literal_mismatch_1;
}
}
rai.rev_leftfix[a_left_id].erase(a);
rai.rev_leftfix[b_left_id].insert(a);
a_left.graph = b_h;
a_left.leftfix_report = b_left.leftfix_report;
pruneUnusedTops(*a_h, g, rai.rev_leftfix[a_left_id]);
DEBUG_PRINTF("OK -> same preds ???\n");
return true;
literal_mismatch_1:
/* preds are the same anyway in diamond/left merges just need to
* check that all the literals in rev_leftfix[a_h] can handle b_h */
for (auto v : rai.rev_leftfix[a_left_id]) {
if (!mergeableRoseVertices(build, v, b)) {
goto literal_mismatch_2;
}
}
rai.rev_leftfix[b_left_id].erase(b);
rai.rev_leftfix[a_left_id].insert(b);
b_left.graph = a_h;
b_left.leftfix_report = a_left.leftfix_report;
pruneUnusedTops(*b_h, g, rai.rev_leftfix[b_left_id]);
DEBUG_PRINTF("OK -> same preds ???\n");
return true;
literal_mismatch_2:;
}
DEBUG_PRINTF("OK -> create new\n");
/* we need to create a new graph as there may be other people
* using b_left and it would be bad if a's preds started triggering it
*/
ReportID new_report = build.getNewNfaReport();
shared_ptr<NGHolder> new_graph = cloneHolder(*b_h);
duplicateReport(*new_graph, b_left.leftfix_report, new_report);
pruneAllOtherReports(*new_graph, new_report);
if (!isImplementableNFA(*new_graph, nullptr, build.cc)) {
DEBUG_PRINTF("new graph not implementable\n");
return false;
}
rai.rev_leftfix[a_left_id].erase(a);
rai.rev_leftfix[b_left_id].erase(b);
pruneUnusedTops(*a_h, g, rai.rev_leftfix[a_left_id]);
pruneUnusedTops(*b_h, g, rai.rev_leftfix[b_left_id]);
a_left.leftfix_report = new_report;
b_left.leftfix_report = new_report;
a_left.graph = new_graph;
b_left.graph = new_graph;
rai.rev_leftfix[a_left].insert(a);
rai.rev_leftfix[a_left].insert(b);
pruneUnusedTops(*new_graph, g, rai.rev_leftfix[a_left]);
return true;
}
// Everything after this point requires merging via the uncalc code, so we
// guard it with the trivial cases arg.
if (trivialCasesOnly) {
return false;
}
// Only infixes. Prefixes require special care when doing non-trivial
// merges.
if (!build.isNonRootSuccessor(a) || !build.isNonRootSuccessor(b)) {
return false;
}
DEBUG_PRINTF("attempting merge of roses on vertices %zu and %zu\n",
g[a].index, g[b].index);
set<RoseVertex> &b_verts = rai.rev_leftfix[b_left];
set<RoseVertex> aa;
aa.insert(a);
if (!mergeableRoseVertices(build, aa, b_verts)) {
DEBUG_PRINTF("vertices not mergeable\n");
return false;
}
if (!build.cc.grey.roseMultiTopRoses) {
return false;
}
// Clone a copy of a's NFA to operate on, and store a copy of its in-edge
// properties.
/* We need to allocate a new report id because */
ReportID a_oldreport = a_left.leftfix_report;
ReportID b_oldreport = b_left.leftfix_report;
ReportID new_report = build.getNewNfaReport();
duplicateReport(*b_h, b_left.leftfix_report, new_report);
b_left.leftfix_report = new_report;
pruneReportIfUnused(build, b_h, rai.rev_leftfix[b_left_id], b_oldreport);
NGHolder victim;
cloneHolder(victim, *a_h);
duplicateReport(victim, a_left.leftfix_report, new_report);
pruneAllOtherReports(victim, new_report);
map<RoseVertex, RoseEdgeProps> a_props;
for (const auto &e : in_edges_range(a, g)) {
a_props[source(e, g)] = g[e];
}
DEBUG_PRINTF("victim %zu states\n", num_vertices(*a_h));
DEBUG_PRINTF("winner %zu states\n", num_vertices(*b_h));
if (!setDistinctRoseTops(g, victim, *b_h, deque<RoseVertex>(1, a))) {
assert(roseHasTops(build, a));
assert(roseHasTops(build, b));
return false;
}
assert(victim.kind == b_h->kind);
assert(!generates_callbacks(*b_h));
if (!mergeNfaPair(victim, *b_h, nullptr, build.cc)) {
DEBUG_PRINTF("merge failed\n");
// Restore in-edge properties.
for (const auto &e : in_edges_range(a, g)) {
g[e] = a_props[source(e, g)];
}
assert(roseHasTops(build, a));
assert(roseHasTops(build, b));
return false;
}
DEBUG_PRINTF("merge succeeded -> %zu vertices\n", num_vertices(*b_h));
// update A's rose data to point to the merged graph.
a_left.graph = b_h;
a_left.leftfix_report = new_report;
assert(contains(rai.rev_leftfix[a_left_id], a));
assert(contains(rai.rev_leftfix[b_left_id], b));
rai.rev_leftfix[a_left_id].erase(a);
rai.rev_leftfix[b_left_id].insert(a);
pruneUnusedTops(*a_h, g, rai.rev_leftfix[a_left_id]);
pruneUnusedTops(*b_h, g, rai.rev_leftfix[b_left_id]);
// Prune A's report from its old prefix if it was only used by A.
pruneReportIfUnused(build, a_h, rai.rev_leftfix[a_left_id], a_oldreport);
reduceImplementableGraph(*b_h, SOM_NONE, nullptr, build.cc);
assert(roseHasTops(build, a));
assert(roseHasTops(build, b));
assert(isImplementableNFA(*b_h, nullptr, build.cc));
return true;
}
// Called by the role aliasing pass: Attempt to merge rose a into b, updating
// the two LeftEngInfo structures to be the same. Returns false if the merge
// is not possible.
static
bool attemptRoseMerge(RoseBuildImpl &build, bool preds_same, RoseVertex a,
RoseVertex b, bool trivialCasesOnly,
RoseAliasingInfo &rai) {
DEBUG_PRINTF("attempting rose merge, vertices a=%zu, b=%zu\n",
build.g[a].index, build.g[b].index);
assert(a != b);
RoseGraph &g = build.g;
LeftEngInfo &a_left = g[a].left;
LeftEngInfo &b_left = g[b].left;
// Trivial case.
if (a_left == b_left) {
DEBUG_PRINTF("roses are identical, no leftfix or already merged\n");
return true;
}
const left_id a_left_id(a_left);
const left_id b_left_id(b_left);
/* Haig merges not supported at the moment */
if (a_left.haig || b_left.haig) {
return false;
}
/* dfa merges not supported at the moment (no multitop) */
if (a_left.dfa || b_left.dfa) {
return false;
}
// Only non-transients for the moment.
if (contains(build.transient, a_left_id) ||
contains(build.transient, b_left_id)) {
return false;
}
/* It is not possible to merge roles with different lags as we can only
* test the leftfix at one location relative to the literal match */
if (a_left.lag != b_left.lag) {
return false;
}
assert(roseHasTops(build, a));
assert(roseHasTops(build, b));
if (a_left_id.graph() && b_left_id.graph()) {
return attemptRoseGraphMerge(build, preds_same, a, b, trivialCasesOnly,
rai);
}
if (a_left_id.castle() && b_left_id.castle()) {
return attemptRoseCastleMerge(build, preds_same, a, b, trivialCasesOnly,
rai);
}
return false;
}
/**
* \brief Buckets that only contain one vertex are never going to lead to a
* merge.
*/
static
void removeSingletonBuckets(vector<vector<RoseVertex>> &buckets) {
auto it = remove_if(
begin(buckets), end(buckets),
[](const vector<RoseVertex> &bucket) { return bucket.size() < 2; });
if (it != end(buckets)) {
DEBUG_PRINTF("deleting %zu singleton buckets\n",
distance(it, end(buckets)));
buckets.erase(it, end(buckets));
}
}
static
void buildInvBucketMap(const vector<vector<RoseVertex>> &buckets,
unordered_map<RoseVertex, size_t> &inv) {
inv.clear();
for (size_t i = 0; i < buckets.size(); i++) {
for (auto v : buckets[i]) {
assert(!contains(inv, v));
inv.emplace(v, i);
}
}
}
/**
* \brief Generic splitter that will use the given split function to partition
* the vector of buckets, then remove buckets with <= 1 entry.
*/
template <class SplitFunction>
void splitAndFilterBuckets(vector<vector<RoseVertex>> &buckets,
const SplitFunction &make_split_key) {
if (buckets.empty()) {
return;
}
vector<vector<RoseVertex>> out;
// Mapping from split key value to new bucket index.
using key_type = decltype(make_split_key(RoseGraph::null_vertex()));
unordered_map<key_type, size_t> dest_map;
dest_map.reserve(buckets.front().size());
for (const auto &bucket : buckets) {
assert(!bucket.empty());
dest_map.clear();
for (RoseVertex v : bucket) {
auto p = dest_map.emplace(make_split_key(v), out.size());
if (p.second) { // New key, add a bucket.
out.emplace_back();
}
auto out_bucket = p.first->second;
out[out_bucket].push_back(v);
}
}
if (out.size() == buckets.size()) {
return; // No new buckets created.
}
buckets = std::move(out);
removeSingletonBuckets(buckets);
}
static
void splitByReportSuffixBehaviour(const RoseGraph &g,
vector<vector<RoseVertex>> &buckets) {
// Split by report set and suffix info.
auto make_split_key = [&g](RoseVertex v) {
return hash_all(g[v].reports, g[v].suffix);
};
splitAndFilterBuckets(buckets, make_split_key);
}
static
void splitByLiteralTable(const RoseBuildImpl &build,
vector<vector<RoseVertex>> &buckets) {
const RoseGraph &g = build.g;
// Split by literal table.
auto make_split_key = [&](RoseVertex v) {
const auto &lits = g[v].literals;
assert(!lits.empty());
auto table = build.literals.at(*lits.begin()).table;
return std::underlying_type<decltype(table)>::type(table);
};
splitAndFilterBuckets(buckets, make_split_key);
}
static
void splitByNeighbour(const RoseGraph &g, vector<vector<RoseVertex>> &buckets,
unordered_map<RoseVertex, size_t> &inv, bool succ) {
vector<vector<RoseVertex>> extras;
map<size_t, vector<RoseVertex>> neighbours_by_bucket;
set<RoseVertex> picked;
vector<RoseVertex> leftovers;
for (RoseVertex u : vertices_range(g)) {
/* once split by v, stays split. also keeps iterator in buckets valid */
extras.clear();
neighbours_by_bucket.clear();
if (succ) {
/* forward pass */
for (RoseVertex v : adjacent_vertices_range(u, g)) {
auto it = inv.find(v);
if (it != end(inv)) {
neighbours_by_bucket[it->second].push_back(v);
}
}
} else {
/* backward pass */
for (RoseVertex v : inv_adjacent_vertices_range(u, g)) {
auto it = inv.find(v);
if (it != end(inv)) {
neighbours_by_bucket[it->second].push_back(v);
}
}
}
for (const auto &e : neighbours_by_bucket) {
size_t old_key = e.first;
if (buckets[old_key].size() == e.second.size()) {
/* did not split */
continue;
}
assert(!e.second.empty());
picked.clear();
picked.insert(begin(e.second), end(e.second));
size_t new_key = buckets.size() + extras.size();
leftovers.clear();
for (RoseVertex v : buckets[old_key]) {
if (contains(picked, v)) {
inv[v] = new_key;
} else {
leftovers.push_back(v);
}
}
assert(!leftovers.empty());
assert(e.second.size() + leftovers.size()
== buckets[old_key].size());
extras.push_back(e.second);
buckets[old_key].swap(leftovers);
}
insert(&buckets, buckets.end(), extras);
}
removeSingletonBuckets(buckets);
buildInvBucketMap(buckets, inv);
}
static
vector<vector<RoseVertex>>
splitDiamondMergeBuckets(CandidateSet &candidates, const RoseBuildImpl &build) {
const RoseGraph &g = build.g;
vector<vector<RoseVertex>> buckets(1);
buckets[0].reserve(candidates.size());
insert(&buckets[0], buckets[0].end(), candidates);
DEBUG_PRINTF("at start, %zu candidates in 1 bucket\n", candidates.size());
splitByReportSuffixBehaviour(g, buckets);
DEBUG_PRINTF("split by report/suffix, %zu buckets\n", buckets.size());
if (buckets.empty()) {
return buckets;
}
splitByLiteralTable(build, buckets);
DEBUG_PRINTF("split by lit table, %zu buckets\n", buckets.size());
if (buckets.empty()) {
return buckets;
}
// Neighbour splits require inverse map.
unordered_map<RoseVertex, size_t> inv;
buildInvBucketMap(buckets, inv);
splitByNeighbour(g, buckets, inv, true);
DEBUG_PRINTF("split by successor, %zu buckets\n", buckets.size());
if (buckets.empty()) {
return buckets;
}
splitByNeighbour(g, buckets, inv, false);
DEBUG_PRINTF("split by predecessor, %zu buckets\n", buckets.size());
return buckets;
}
static never_inline
void diamondMergePass(CandidateSet &candidates, RoseBuildImpl &build,
vector<RoseVertex> *dead, bool mergeRoses,
RoseAliasingInfo &rai) {
DEBUG_PRINTF("begin\n");
RoseGraph &g = build.g;
if (candidates.empty()) {
return;
}
/* Vertices may only be diamond merged with others in the same bucket */
auto cand_buckets = splitDiamondMergeBuckets(candidates, build);
for (const vector<RoseVertex> &siblings : cand_buckets) {
for (auto it = siblings.begin(); it != siblings.end();) {
RoseVertex a = *it;
++it;
assert(contains(candidates, a));
DEBUG_PRINTF("trying to merge %zu into somebody\n", g[a].index);
for (auto jt = it; jt != siblings.end(); ++jt) {
RoseVertex b = *jt;
assert(contains(candidates, b));
if (!sameRoleProperties(build, rai, a, b)) {
DEBUG_PRINTF("diff role prop\n");
continue;
}
// Check "diamond" requirements: must have same right side
// (successors, reports) and left side (predecessors).
/* Note: bucketing does not check edge properties (bounds, tops)
* so we still have to checks successors and predecessors. */
if (!sameSuccessors(a, b, g)
|| !sameRightRoleProperties(build, a, b)
|| !samePredecessors(a, b, g)) {
DEBUG_PRINTF("not diamond\n");
continue;
}
if (!canMergeLiterals(a, b, build)) {
DEBUG_PRINTF("incompatible lits\n");
continue;
}
if (!attemptRoseMerge(build, true, a, b, !mergeRoses, rai)) {
DEBUG_PRINTF("rose fail\n");
continue;
}
mergeVerticesDiamond(a, b, build, rai);
dead->push_back(a);
candidates.erase(a);
break; // next a
}
}
}
DEBUG_PRINTF("%zu candidates remaining\n", candidates.size());
}
static
vector<RoseVertex>::iterator findLeftMergeSibling(
vector<RoseVertex>::iterator it,
const vector<RoseVertex>::iterator &end,
const RoseVertex a, const RoseBuildImpl &build,
const RoseAliasingInfo &rai,
const CandidateSet &candidates) {
const RoseGraph &g = build.g;
for (; it != end; ++it) {
RoseVertex b = *it;
if (a == b) {
continue;
}
if (!contains(candidates, b)) {
continue;
}
if (!sameRoleProperties(build, rai, a, b)) {
continue;
}
// Check left-equivalence: must have same predecessors and same
// literals.
if (g[a].literals != g[b].literals) {
continue;
}
if (!samePredecessors(a, b, g)) {
continue;
}
if (hasCommonSuccWithBadBounds(a, b, g)) {
continue;
}
if (g[a].suffix && g[b].suffix && g[a].suffix != g[b].suffix) {
continue; /* we can only trigger one suffix */
}
return it;
}
return end;
}
static
void getLeftMergeSiblings(const RoseBuildImpl &build, RoseVertex a,
vector<RoseVertex> &siblings) {
// We have to find a sibling to merge `a' with, and we select between
// two approaches to minimize the number of vertices we have to
// examine; which we use depends on the shape of the graph.
const RoseGraph &g = build.g;
assert(!g[a].literals.empty());
u32 lit_id = *g[a].literals.begin();
const auto &verts = build.literal_info.at(lit_id).vertices;
RoseVertex pred = pickPred(a, g, build);
siblings.clear();
if (pred == RoseGraph::null_vertex() || build.isAnyStart(pred) ||
out_degree(pred, g) > verts.size()) {
// Select sibling from amongst the vertices that share a literal.
insert(&siblings, siblings.end(), verts);
} else {
// Select sibling from amongst the vertices that share a
// predecessor.
insert(&siblings, siblings.end(), adjacent_vertices(pred, g));
}
}
static never_inline
void leftMergePass(CandidateSet &candidates, RoseBuildImpl &build,
vector<RoseVertex> *dead, RoseAliasingInfo &rai) {
DEBUG_PRINTF("begin (%zu)\n", candidates.size());
vector<RoseVertex> siblings;
auto it = candidates.begin();
while (it != candidates.end()) {
RoseVertex a = *it;
CandidateSet::iterator ait = it;
++it;
getLeftMergeSiblings(build, a, siblings);
auto jt = siblings.begin();
while (jt != siblings.end()) {
jt = findLeftMergeSibling(jt, siblings.end(), a, build, rai,
candidates);
if (jt == siblings.end()) {
break;
}
RoseVertex b = *jt;
if (attemptRoseMerge(build, true, a, b, false, rai)) {
mergeVerticesLeft(a, b, build, rai);
dead->push_back(a);
candidates.erase(ait);
break; // consider next a
}
++jt;
}
}
DEBUG_PRINTF("%zu candidates remaining\n", candidates.size());
assert(!hasOrphanedTops(build));
}
// Can't merge vertices with different root predecessors.
static
bool safeRootPreds(RoseVertex a, RoseVertex b, const RoseGraph &g) {
set<RoseVertex> a_roots, b_roots;
for (auto u : inv_adjacent_vertices_range(a, g)) {
if (!in_degree(u, g)) {
a_roots.insert(u);
}
}
for (auto u : inv_adjacent_vertices_range(b, g)) {
if (!in_degree(u, g)) {
b_roots.insert(u);
}
}
assert(a_roots.size() <= 1);
assert(b_roots.size() <= 1);
return a_roots == b_roots;
}
static never_inline
vector<RoseVertex>::const_iterator findRightMergeSibling(
vector<RoseVertex>::const_iterator it,
const vector<RoseVertex>::const_iterator &end,
const RoseVertex a, const RoseBuildImpl &build,
const RoseAliasingInfo &rai,
const CandidateSet &candidates) {
const RoseGraph &g = build.g;
for (; it != end; ++it) {
RoseVertex b = *it;
if (a == b) {
continue;
}
if (!contains(candidates, b)) {
continue;
}
if (!sameRoleProperties(build, rai, a, b)) {
continue;
}
// Check right-equivalence: must have same successors, reports and same
// literals.
if (g[a].literals != g[b].literals) {
continue;
}
if (!sameSuccessors(a, b, g)
|| !sameRightRoleProperties(build, a, b)) {
continue;
}
// An extra wrinkle: we cannot merge two vertices that are root
// successors if their preds are different. (e.g. one is anchored and
// one is not)
if (!safeRootPreds(a, b, g)) {
continue;
}
if (hasCommonPredWithBadBounds(a, b, g)) {
continue;
}
if (hasCommonPredWithDiffRoses(a, b, g)) {
continue;
}
return it;
}
return end;
}
static
void splitByRightProps(const RoseGraph &g,
vector<vector<RoseVertex>> &buckets) {
// Successor vector used in make_split_key. We declare it here so we can
// reuse storage.
vector<RoseVertex> succ;
// Split by {successors, literals, reports}.
auto make_split_key = [&](RoseVertex v) {
succ.clear();
insert(&succ, succ.end(), adjacent_vertices(v, g));
sort(succ.begin(), succ.end());
return hash_all(g[v].literals, g[v].reports, succ);
};
splitAndFilterBuckets(buckets, make_split_key);
}
static never_inline
vector<vector<RoseVertex>>
splitRightMergeBuckets(const CandidateSet &candidates,
const RoseBuildImpl &build) {
const RoseGraph &g = build.g;
vector<vector<RoseVertex>> buckets(1);
buckets[0].reserve(candidates.size());
insert(&buckets[0], buckets[0].end(), candidates);
DEBUG_PRINTF("at start, %zu candidates in 1 bucket\n", candidates.size());
splitByReportSuffixBehaviour(g, buckets);
DEBUG_PRINTF("split by report/suffix, %zu buckets\n", buckets.size());
if (buckets.empty()) {
return buckets;
}
splitByRightProps(g, buckets);
DEBUG_PRINTF("split by right-merge properties, %zu buckets\n",
buckets.size());
if (buckets.empty()) {
return buckets;
}
return buckets;
}
static never_inline
void rightMergePass(CandidateSet &candidates, RoseBuildImpl &build,
vector<RoseVertex> *dead, bool mergeRoses,
RoseAliasingInfo &rai) {
DEBUG_PRINTF("begin\n");
if (candidates.empty()) {
return;
}
auto buckets = splitRightMergeBuckets(candidates, build);
for (const auto &bucket : buckets) {
assert(!bucket.empty());
for (auto it = bucket.begin(); it != bucket.end(); it++) {
RoseVertex a = *it;
for (auto jt = bucket.begin(); jt != bucket.end(); jt++) {
jt = findRightMergeSibling(jt, bucket.end(), a, build, rai,
candidates);
if (jt == bucket.end()) {
break;
}
RoseVertex b = *jt;
if (attemptRoseMerge(build, false, a, b, !mergeRoses, rai)) {
mergeVerticesRight(a, b, build, rai);
dead->push_back(a);
candidates.erase(a);
break; // consider next a
}
}
}
}
DEBUG_PRINTF("%zu candidates remaining\n", candidates.size());
assert(!hasOrphanedTops(build));
}
/**
* \brief True if the given vertex has no siblings for the purposes of a
* diamond merge.
*
* This is the case if it has no successors with more than one predecessor
* (itself), or no predecessors with more than one successor (itself).
*/
static
bool hasNoDiamondSiblings(const RoseGraph &g, RoseVertex v) {
if (has_successor(v, g)) {
bool only_succ = true;
for (const auto &w : adjacent_vertices_range(v, g)) {
if (in_degree(w, g) > 1) {
only_succ = false;
break;
}
}
if (only_succ) {
return true;
}
}
// Any candidate vertex will have a predecessor; the only vertices without
// preds are the root vertices.
assert(in_edges(v, g).first != in_edges(v, g).second);
bool only_pred = true;
for (const auto &u : inv_adjacent_vertices_range(v, g)) {
if (out_degree(u, g) > 1) {
only_pred = false;
break;
}
}
return only_pred;
}
/**
* \brief Filter out some merge candidates that are not mergeable by a diamond
* merge.
*/
static
void filterDiamondCandidates(RoseGraph &g, CandidateSet &candidates) {
DEBUG_PRINTF("%zu candidates enter\n", candidates.size());
vector<RoseVertex> dead;
for (const auto &v : candidates) {
if (hasNoDiamondSiblings(g, v)) {
dead.push_back(v);
}
}
for (const auto &v : dead) {
candidates.erase(v);
}
DEBUG_PRINTF("pruned %zu candidates, leaving %zu\n", dead.size(),
candidates.size());
}
void aliasRoles(RoseBuildImpl &build, bool mergeRoses) {
const CompileContext &cc = build.cc;
RoseGraph &g = build.g;
assert(!hasOrphanedTops(build));
assert(canImplementGraphs(build));
if (!cc.grey.roseRoleAliasing || !cc.grey.roseGraphReduction) {
return;
}
DEBUG_PRINTF("doing role aliasing mr=%d\n", (int)mergeRoses);
RoseAliasingInfo rai(build);
mergeRoses &= cc.grey.mergeRose & cc.grey.roseMergeRosesDuringAliasing;
CandidateSet candidates;
findCandidates(build, &candidates);
DEBUG_PRINTF("candidates %zu\n", candidates.size());
vector<RoseVertex> dead;
size_t old_dead_size = 0;
do {
old_dead_size = dead.size();
leftMergePass(candidates, build, &dead, rai);
rightMergePass(candidates, build, &dead, mergeRoses, rai);
} while (old_dead_size != dead.size());
/* Diamond merge passes cannot create extra merges as they require the same
* succ and preds before merging --> that if a succ/pred was ineligible due
* to a merge to different pred/succ before a diamond merge, it will still
* be afterwards. */
filterDiamondCandidates(g, candidates);
diamondMergePass(candidates, build, &dead, mergeRoses, rai);
DEBUG_PRINTF("killed %zu vertices\n", dead.size());
build.removeVertices(dead);
assert(!hasOrphanedTops(build));
assert(canImplementGraphs(build));
}
namespace {
struct DupeLeafKey {
explicit DupeLeafKey(const RoseVertexProps &litv)
: literals(litv.literals), reports(litv.reports),
eod_accept(litv.eod_accept), suffix(litv.suffix), left(litv.left),
som_adjust(litv.som_adjust) {
DEBUG_PRINTF("eod_accept %d\n", (int)eod_accept);
DEBUG_PRINTF("report %u\n", left.leftfix_report);
DEBUG_PRINTF("lag %u\n", left.lag);
}
bool operator<(const DupeLeafKey &b) const {
const DupeLeafKey &a = *this;
ORDER_CHECK(literals);
ORDER_CHECK(eod_accept);
ORDER_CHECK(suffix);
ORDER_CHECK(reports);
ORDER_CHECK(som_adjust);
ORDER_CHECK(left.leftfix_report);
ORDER_CHECK(left.lag);
return false;
}
flat_set<u32> literals;
flat_set<ReportID> reports;
bool eod_accept;
suffix_id suffix;
LeftEngInfo left;
u32 som_adjust;
};
struct UncalcLeafKey {
UncalcLeafKey(const RoseGraph &g, RoseVertex v)
: literals(g[v].literals), rose(g[v].left) {
for (const auto &e : in_edges_range(v, g)) {
RoseVertex u = source(e, g);
preds.insert(make_pair(u, g[e]));
}
}
bool operator<(const UncalcLeafKey &b) const {
const UncalcLeafKey &a = *this;
ORDER_CHECK(literals);
ORDER_CHECK(preds);
ORDER_CHECK(rose);
return false;
}
flat_set<u32> literals;
flat_set<pair<RoseVertex, RoseEdgeProps>> preds;
LeftEngInfo rose;
};
} // namespace
/**
* This function merges leaf vertices with the same literals and report
* id/suffix. The leaf vertices of the graph are inspected and a mapping of
* leaf vertex properties to vertices is built. If the same set of leaf
* properties has already been seen when we inspect a vertex, we attempt to
* merge the vertex in with the previously seen vertex. This process can fail
* if the vertices share a common predecessor vertex but have a differing,
* incompatible relationship (different bounds or infix) with the predecessor.
*
* This takes place after \ref dedupeSuffixes to increase effectiveness as the
* same suffix is required for a merge to occur.
*
* TODO: work if this is a subset of role aliasing (and if it can be eliminated)
* or clearly document cases that would not be covered by role aliasing.
*/
void mergeDupeLeaves(RoseBuildImpl &build) {
map<DupeLeafKey, RoseVertex> leaves;
vector<RoseVertex> changed;
RoseGraph &g = build.g;
for (auto v : vertices_range(g)) {
if (in_degree(v, g) == 0) {
assert(build.isAnyStart(v));
continue;
}
DEBUG_PRINTF("inspecting vertex index=%zu in_degree %zu "
"out_degree %zu\n", g[v].index, in_degree(v, g),
out_degree(v, g));
// Vertex must be a reporting leaf node
if (g[v].reports.empty() || !isLeafNode(v, g)) {
continue;
}
// At the moment, we ignore all successors of root or anchored_root,
// since many parts of our runtime assume that these have in-degree 1.
if (build.isRootSuccessor(v)) {
continue;
}
DupeLeafKey dupe(g[v]);
if (leaves.find(dupe) == leaves.end()) {
leaves.insert(make_pair(dupe, v));
continue;
}
RoseVertex t = leaves.find(dupe)->second;
DEBUG_PRINTF("found two leaf dupe roles, index=%zu,%zu\n", g[v].index,
g[t].index);
vector<RoseEdge> deadEdges;
for (const auto &e : in_edges_range(v, g)) {
RoseVertex u = source(e, g);
DEBUG_PRINTF("u index=%zu\n", g[u].index);
if (RoseEdge et = edge(u, t, g)) {
if (g[et].minBound <= g[e].minBound
&& g[et].maxBound >= g[e].maxBound) {
DEBUG_PRINTF("remove more constrained edge\n");
deadEdges.push_back(e);
}
} else {
DEBUG_PRINTF("rehome edge: add %zu->%zu\n", g[u].index,
g[t].index);
add_edge(u, t, g[e], g);
deadEdges.push_back(e);
}
}
if (!deadEdges.empty()) {
for (auto &e : deadEdges) {
remove_edge(e, g);
}
changed.push_back(v);
g[t].min_offset = min(g[t].min_offset, g[v].min_offset);
g[t].max_offset = max(g[t].max_offset, g[v].max_offset);
}
}
DEBUG_PRINTF("find loop done\n");
// Remove any vertices that now have no in-edges.
size_t countRemovals = 0;
for (size_t i = 0; i < changed.size(); i++) {
RoseVertex v = changed[i];
if (in_degree(v, g) == 0) {
DEBUG_PRINTF("remove vertex\n");
if (!build.isVirtualVertex(v)) {
for (u32 lit_id : g[v].literals) {
build.literal_info[lit_id].vertices.erase(v);
}
}
remove_vertex(v, g);
countRemovals++;
}
}
// if we've removed anything, we need to renumber vertices
if (countRemovals) {
renumber_vertices(g);
DEBUG_PRINTF("removed %zu vertices.\n", countRemovals);
}
}
/** Merges the suffixes on the (identical) vertices in \a vcluster, used by
* \ref uncalcLeaves. */
static
void mergeCluster(RoseGraph &g, const ReportManager &rm,
const vector<RoseVertex> &vcluster,
vector<RoseVertex> &dead, const CompileContext &cc) {
if (vcluster.size() <= 1) {
return; // No merge to perform.
}
// Note that we batch merges up fairly crudely for performance reasons.
vector<RoseVertex>::const_iterator it = vcluster.begin(), it2;
while (it != vcluster.end()) {
vector<NGHolder *> cluster;
map<NGHolder *, RoseVertex> rev;
for (it2 = it;
it2 != vcluster.end() && cluster.size() < MERGE_GROUP_SIZE_MAX;
++it2) {
RoseVertex v = *it2;
NGHolder *h = g[v].suffix.graph.get();
assert(!g[v].suffix.haig); /* should not be here if haig */
rev[h] = v;
cluster.push_back(h);
}
it = it2;
DEBUG_PRINTF("merging cluster %zu\n", cluster.size());
auto merged = mergeNfaCluster(cluster, &rm, cc);
DEBUG_PRINTF("done\n");
for (const auto &m : merged) {
NGHolder *h_victim = m.first; // mergee
NGHolder *h_winner = m.second;
RoseVertex victim = rev[h_victim];
RoseVertex winner = rev[h_winner];
LIMIT_TO_AT_MOST(&g[winner].min_offset, g[victim].min_offset);
ENSURE_AT_LEAST(&g[winner].max_offset, g[victim].max_offset);
insert(&g[winner].reports, g[victim].reports);
dead.push_back(victim);
}
}
}
static
void findUncalcLeavesCandidates(RoseBuildImpl &build,
map<UncalcLeafKey, vector<RoseVertex> > &clusters,
deque<UncalcLeafKey> &ordered) {
const RoseGraph &g = build.g;
vector<RoseVertex> suffix_vertices; // vertices with suffix graphs
unordered_map<const NGHolder *, u32> fcount; // ref count per graph
for (auto v : vertices_range(g)) {
if (g[v].suffix) {
if (!g[v].suffix.graph) {
continue; /* cannot uncalc (haig/mcclellan); TODO */
}
assert(g[v].suffix.graph->kind == NFA_SUFFIX);
// Ref count all suffixes, as we don't want to merge a suffix
// that happens to be shared with a non-leaf vertex somewhere.
DEBUG_PRINTF("vertex %zu has suffix %p\n", g[v].index,
g[v].suffix.graph.get());
fcount[g[v].suffix.graph.get()]++;
// Vertex must be a reporting pseudo accept
if (!isLeafNode(v, g)) {
continue;
}
suffix_vertices.push_back(v);
}
}
for (auto v : suffix_vertices) {
if (in_degree(v, g) == 0) {
assert(build.isAnyStart(v));
continue;
}
const NGHolder *h = g[v].suffix.graph.get();
assert(h);
DEBUG_PRINTF("suffix %p\n", h);
// We can't easily merge suffixes shared with other vertices, and
// creating a unique copy to do so may just mean we end up tracking
// more NFAs. Better to leave shared suffixes alone.
if (fcount[h] != 1) {
DEBUG_PRINTF("skipping shared suffix\n");
continue;
}
UncalcLeafKey key(g, v);
vector<RoseVertex> &vec = clusters[key];
if (vec.empty()) {
ordered.push_back(key);
}
vec.push_back(v);
}
DEBUG_PRINTF("find loop done\n");
}
/**
* This function attempts to combine identical roles (same literals, same
* predecessors, etc) with different suffixes into a single role which
* activates a larger suffix. The leaf vertices of the graph with a suffix are
* grouped into clusters which have members triggered by identical roles. The
* \ref mergeNfaCluster function (from ng_uncalc_components) is then utilised
* to build a set of larger (and still implementable) suffixes. The graph is
* then updated to point to the new suffixes and any unneeded roles are
* removed.
*
* Note: suffixes which are shared amongst multiple roles are not considered
* for this pass as the individual suffixes would have to continue to exist for
* the other roles to trigger resulting in the transformation not producing any
* savings.
*
* Note: as \ref mergeNfaCluster is slow when the cluster sizes are large,
* clusters of more than \ref MERGE_GROUP_SIZE_MAX roles are split into smaller
* chunks for processing.
*/
void uncalcLeaves(RoseBuildImpl &build) {
DEBUG_PRINTF("uncalcing\n");
map<UncalcLeafKey, vector<RoseVertex> > clusters;
deque<UncalcLeafKey> ordered;
findUncalcLeavesCandidates(build, clusters, ordered);
vector<RoseVertex> dead;
for (const auto &key : ordered) {
DEBUG_PRINTF("cluster of size %zu\n", clusters[key].size());
mergeCluster(build.g, build.rm, clusters[key], dead, build.cc);
}
build.removeVertices(dead);
}
} // namespace ue2
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