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782 lines
25 KiB
C++
782 lines
25 KiB
C++
/*=========================================================================
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Program: CMake - Cross-Platform Makefile Generator
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Module: $RCSfile$
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Language: C++
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Date: $Date$
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Version: $Revision$
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Copyright (c) 2002 Kitware, Inc., Insight Consortium. All rights reserved.
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See Copyright.txt or http://www.cmake.org/HTML/Copyright.html for details.
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This software is distributed WITHOUT ANY WARRANTY; without even
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the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
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PURPOSE. See the above copyright notices for more information.
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=========================================================================*/
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#include "cmComputeLinkDepends.h"
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#include "cmComputeComponentGraph.h"
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#include "cmGlobalGenerator.h"
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#include "cmLocalGenerator.h"
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#include "cmMakefile.h"
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#include "cmTarget.h"
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#include <cmsys/stl/algorithm>
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#include <assert.h>
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/*
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This file computes an ordered list of link items to use when linking a
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single target in one configuration. Each link item is identified by
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the string naming it. A graph of dependencies is created in which
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each node corresponds to one item and directed eges lead from nodes to
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those which must *precede* them on the link line. For example, the
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graph
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C -> B -> A
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will lead to the link line order
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A B C
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The set of items placed in the graph is formed with a breadth-first
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search of the link dependencies starting from the main target.
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There are two types of items: those with known direct dependencies and
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those without known dependencies. We will call the two types "known
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items" and "unknown items", respecitvely. Known items are those whose
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names correspond to targets (built or imported) and those for which an
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old-style <item>_LIB_DEPENDS variable is defined. All other items are
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unknown and we must infer dependencies for them.
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Known items have dependency lists ordered based on how the user
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specified them. We can use this order to infer potential dependencies
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of unknown items. For example, if link items A and B are unknown and
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items X and Y are known, then we might have the following dependency
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lists:
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X: Y A B
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Y: A B
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The explicitly known dependencies form graph edges
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X <- Y , X <- A , X <- B , Y <- A , Y <- B
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We can also infer the edge
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A <- B
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because *every* time A appears B is seen on its right. We do not know
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whether A really needs symbols from B to link, but it *might* so we
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must preserve their order. This is the case also for the following
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explict lists:
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X: A B Y
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Y: A B
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Here, A is followed by the set {B,Y} in one list, and {B} in the other
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list. The intersection of these sets is {B}, so we can infer that A
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depends on at most B. Meanwhile B is followed by the set {Y} in one
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list and {} in the other. The intersection is {} so we can infer that
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B has no dependencies.
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Let's make a more complex example by adding unknown item C and
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considering these dependency lists:
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X: A B Y C
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Y: A C B
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The explicit edges are
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X <- Y , X <- A , X <- B , X <- C , Y <- A , Y <- B , Y <- C
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For the unknown items, we infer dependencies by looking at the
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"follow" sets:
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A: intersect( {B,Y,C} , {C,B} ) = {B,C} ; infer edges A <- B , A <- C
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B: intersect( {Y,C} , {} ) = {} ; infer no edges
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C: intersect( {} , {B} ) = {} ; infer no edges
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------------------------------------------------------------------------------
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Once the complete graph is formed from all known and inferred
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dependencies we must use it to produce a valid link line. If the
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dependency graph were known to be acyclic a simple depth-first-search
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would produce a correct link line. Unfortunately we cannot make this
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assumption so the following technique is used.
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The original graph is converted to a directed acyclic graph in which
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each node corresponds to a strongly connected component of the
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original graph. For example, the dependency graph
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X <- A <- B <- C <- A <- Y
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contains strongly connected components {X}, {A,B,C}, and {Y}. The
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implied directed acyclic graph (DAG) is
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{X} <- {A,B,C} <- {Y}
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The final list of link items is constructed by a series of
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depth-first-searches through this DAG of components. When visiting a
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component all outgoing edges are followed first because the neighbors
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must precede it. Once neighbors across all edges have been emitted it
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is safe to emit the current component.
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Trivial components (those with one item) are handled simply by
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emitting the item. Non-trivial components (those with more than one
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item) are assumed to consist only of static libraries that may be
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safely repeated on the link line. We emit members of the component
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multiple times (see code below for details). The final link line for
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the example graph might be
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X A B C A B C Y
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------------------------------------------------------------------------------
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The initial exploration of dependencies using a BFS associates an
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integer index with each link item. When the graph is built outgoing
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edges are sorted by this index.
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This preserves the original link
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order as much as possible subject to the dependencies.
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After the initial exploration of the link interface tree, any
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transitive (dependent) shared libraries that were encountered and not
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included in the interface are processed in their own BFS. This BFS
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follows only the dependent library lists and not the link interfaces.
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They are added to the link items with a mark indicating that the are
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transitive dependencies. Then cmComputeLinkInformation deals with
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them on a per-platform basis.
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*/
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//----------------------------------------------------------------------------
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cmComputeLinkDepends
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::cmComputeLinkDepends(cmTarget* target, const char* config)
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{
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// Store context information.
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this->Target = target;
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this->Makefile = this->Target->GetMakefile();
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this->LocalGenerator = this->Makefile->GetLocalGenerator();
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this->GlobalGenerator = this->LocalGenerator->GetGlobalGenerator();
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// The configuration being linked.
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this->Config = config;
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// Enable debug mode if requested.
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this->DebugMode = this->Makefile->IsOn("CMAKE_LINK_DEPENDS_DEBUG_MODE");
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}
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//----------------------------------------------------------------------------
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cmComputeLinkDepends::~cmComputeLinkDepends()
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{
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for(std::vector<DependSetList*>::iterator
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i = this->InferredDependSets.begin();
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i != this->InferredDependSets.end(); ++i)
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{
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delete *i;
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}
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}
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//----------------------------------------------------------------------------
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std::vector<cmComputeLinkDepends::LinkEntry> const&
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cmComputeLinkDepends::Compute()
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{
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// Follow the link dependencies of the target to be linked.
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this->AddTargetLinkEntries(-1, this->Target->GetOriginalLinkLibraries());
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// Complete the breadth-first search of dependencies.
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while(!this->BFSQueue.empty())
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{
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// Get the next entry.
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BFSEntry qe = this->BFSQueue.front();
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this->BFSQueue.pop();
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// Follow the entry's dependencies.
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this->FollowLinkEntry(qe);
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}
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// Complete the search of shared library dependencies.
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while(!this->SharedDepQueue.empty())
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{
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// Handle the next entry.
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this->HandleSharedDependency(this->SharedDepQueue.front());
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this->SharedDepQueue.pop();
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}
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// Infer dependencies of targets for which they were not known.
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this->InferDependencies();
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// Cleanup the constraint graph.
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this->CleanConstraintGraph();
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// Display the constraint graph.
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if(this->DebugMode)
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{
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fprintf(stderr,
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"---------------------------------------"
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"---------------------------------------\n");
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fprintf(stderr, "Link dependency analysis for target %s, config %s\n",
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this->Target->GetName(), this->Config?this->Config:"noconfig");
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this->DisplayConstraintGraph();
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}
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// Compute the final set of link entries.
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this->OrderLinkEntires();
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// Display the final set.
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if(this->DebugMode)
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{
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this->DisplayFinalEntries();
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}
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return this->FinalLinkEntries;
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}
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//----------------------------------------------------------------------------
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std::map<cmStdString, int>::iterator
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cmComputeLinkDepends::AllocateLinkEntry(std::string const& item)
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{
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std::map<cmStdString, int>::value_type
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index_entry(item, static_cast<int>(this->EntryList.size()));
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std::map<cmStdString, int>::iterator
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lei = this->LinkEntryIndex.insert(index_entry).first;
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this->EntryList.push_back(LinkEntry());
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this->InferredDependSets.push_back(0);
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this->EntryConstraintGraph.push_back(NodeList());
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return lei;
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}
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//----------------------------------------------------------------------------
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int cmComputeLinkDepends::AddLinkEntry(std::string const& item)
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{
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// Check if the item entry has already been added.
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std::map<cmStdString, int>::iterator lei = this->LinkEntryIndex.find(item);
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if(lei != this->LinkEntryIndex.end())
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{
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// Yes. We do not need to follow the item's dependencies again.
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return lei->second;
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}
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// Allocate a spot for the item entry.
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lei = this->AllocateLinkEntry(item);
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// Initialize the item entry.
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int index = lei->second;
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LinkEntry& entry = this->EntryList[index];
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entry.Item = item;
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entry.Target = this->Makefile->FindTargetToUse(entry.Item.c_str());
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// If the item has dependencies queue it to follow them.
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if(entry.Target)
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{
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// Target dependencies are always known. Follow them.
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BFSEntry qe = {index, 0};
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this->BFSQueue.push(qe);
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}
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else
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{
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// Look for an old-style <item>_LIB_DEPENDS variable.
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std::string var = entry.Item;
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var += "_LIB_DEPENDS";
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if(const char* val = this->Makefile->GetDefinition(var.c_str()))
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{
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// The item dependencies are known. Follow them.
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BFSEntry qe = {index, val};
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this->BFSQueue.push(qe);
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}
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else
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{
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// The item dependencies are not known. We need to infer them.
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this->InferredDependSets[index] = new DependSetList;
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}
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}
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return index;
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}
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//----------------------------------------------------------------------------
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void cmComputeLinkDepends::FollowLinkEntry(BFSEntry const& qe)
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{
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// Get this entry representation.
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int depender_index = qe.Index;
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LinkEntry const& entry = this->EntryList[depender_index];
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// Follow the item's dependencies.
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if(entry.Target)
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{
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// Follow the target dependencies.
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if(cmTargetLinkInterface const* iface =
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entry.Target->GetLinkInterface(this->Config))
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{
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// This target provides its own link interface information.
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this->AddLinkEntries(depender_index, iface->Libraries);
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// Handle dependent shared libraries.
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this->QueueSharedDependencies(depender_index, iface->SharedDeps);
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}
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else if(!entry.Target->IsImported() &&
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entry.Target->GetType() != cmTarget::EXECUTABLE)
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{
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// Use the target's link implementation as the interface.
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this->AddTargetLinkEntries(depender_index,
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entry.Target->GetOriginalLinkLibraries());
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}
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}
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else
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{
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// Follow the old-style dependency list.
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this->AddVarLinkEntries(depender_index, qe.LibDepends);
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}
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}
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//----------------------------------------------------------------------------
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void
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cmComputeLinkDepends
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::QueueSharedDependencies(int depender_index,
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std::vector<std::string> const& deps)
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{
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for(std::vector<std::string>::const_iterator li = deps.begin();
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li != deps.end(); ++li)
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{
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SharedDepEntry qe;
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qe.Item = *li;
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qe.DependerIndex = depender_index;
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this->SharedDepQueue.push(qe);
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}
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}
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//----------------------------------------------------------------------------
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void cmComputeLinkDepends::HandleSharedDependency(SharedDepEntry const& dep)
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{
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// Check if the target already has an entry.
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std::map<cmStdString, int>::iterator lei =
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this->LinkEntryIndex.find(dep.Item);
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if(lei == this->LinkEntryIndex.end())
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{
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// Allocate a spot for the item entry.
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lei = this->AllocateLinkEntry(dep.Item);
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// Initialize the item entry.
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LinkEntry& entry = this->EntryList[lei->second];
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entry.Item = dep.Item;
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entry.Target = this->Makefile->FindTargetToUse(dep.Item.c_str());
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// This item was added specifically because it is a dependent
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// shared library. It may get special treatment
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// in cmComputeLinkInformation.
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entry.IsSharedDep = true;
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}
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// Get the link entry for this target.
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int index = lei->second;
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LinkEntry& entry = this->EntryList[index];
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// This shared library dependency must be preceded by the item that
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// listed it.
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this->EntryConstraintGraph[index].push_back(dep.DependerIndex);
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// Target items may have their own dependencies.
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if(entry.Target)
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{
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if(cmTargetLinkInterface const* iface =
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entry.Target->GetLinkInterface(this->Config))
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{
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// We use just the shared dependencies, not the interface.
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this->QueueSharedDependencies(index, iface->SharedDeps);
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}
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}
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}
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//----------------------------------------------------------------------------
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void cmComputeLinkDepends::AddVarLinkEntries(int depender_index,
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const char* value)
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{
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// This is called to add the dependencies named by
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// <item>_LIB_DEPENDS. The variable contains a semicolon-separated
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// list. The list contains link-type;item pairs and just items.
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std::vector<std::string> deplist;
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cmSystemTools::ExpandListArgument(value, deplist);
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// Compute which library configuration to link.
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cmTarget::LinkLibraryType linkType = cmTarget::OPTIMIZED;
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if(this->Config && cmSystemTools::UpperCase(this->Config) == "DEBUG")
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{
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linkType = cmTarget::DEBUG;
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}
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// Look for entries meant for this configuration.
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std::vector<std::string> actual_libs;
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cmTarget::LinkLibraryType llt = cmTarget::GENERAL;
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bool haveLLT = false;
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for(std::vector<std::string>::const_iterator di = deplist.begin();
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di != deplist.end(); ++di)
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{
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if(*di == "debug")
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{
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llt = cmTarget::DEBUG;
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haveLLT = true;
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}
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else if(*di == "optimized")
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{
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llt = cmTarget::OPTIMIZED;
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haveLLT = true;
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}
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else if(*di == "general")
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{
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llt = cmTarget::GENERAL;
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haveLLT = true;
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}
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else if(!di->empty())
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{
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// If no explicit link type was given prior to this entry then
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// check if the entry has its own link type variable. This is
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// needed for compatibility with dependency files generated by
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// the export_library_dependencies command from CMake 2.4 and
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// lower.
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if(!haveLLT)
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{
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std::string var = *di;
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var += "_LINK_TYPE";
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if(const char* val = this->Makefile->GetDefinition(var.c_str()))
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{
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if(strcmp(val, "debug") == 0)
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{
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llt = cmTarget::DEBUG;
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}
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else if(strcmp(val, "optimized") == 0)
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{
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llt = cmTarget::OPTIMIZED;
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}
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}
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}
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// If the library is meant for this link type then use it.
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if(llt == cmTarget::GENERAL || llt == linkType)
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{
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actual_libs.push_back(*di);
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}
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// Reset the link type until another explicit type is given.
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llt = cmTarget::GENERAL;
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haveLLT = false;
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}
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}
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// Add the entries from this list.
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this->AddLinkEntries(depender_index, actual_libs);
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}
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//----------------------------------------------------------------------------
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void
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cmComputeLinkDepends::AddTargetLinkEntries(int depender_index,
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LinkLibraryVectorType const& libs)
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{
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// Compute which library configuration to link.
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cmTarget::LinkLibraryType linkType = cmTarget::OPTIMIZED;
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if(this->Config && cmSystemTools::UpperCase(this->Config) == "DEBUG")
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{
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linkType = cmTarget::DEBUG;
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}
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// Look for entries meant for this configuration.
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std::vector<std::string> actual_libs;
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for(cmTarget::LinkLibraryVectorType::const_iterator li = libs.begin();
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li != libs.end(); ++li)
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{
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if(li->second == cmTarget::GENERAL || li->second == linkType)
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{
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actual_libs.push_back(li->first);
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}
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}
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// Add these entries.
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this->AddLinkEntries(depender_index, actual_libs);
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}
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//----------------------------------------------------------------------------
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void
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cmComputeLinkDepends::AddLinkEntries(int depender_index,
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std::vector<std::string> const& libs)
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{
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// Track inferred dependency sets implied by this list.
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std::map<int, DependSet> dependSets;
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// Loop over the libraries linked directly by the depender.
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for(std::vector<std::string>::const_iterator li = libs.begin();
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li != libs.end(); ++li)
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{
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// Skip entries that will resolve to the target getting linked or
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// are empty.
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std::string item = this->CleanItemName(*li);
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if(item == this->Target->GetName() || item.empty())
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{
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continue;
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}
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// Add a link entry for this item.
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int dependee_index = this->AddLinkEntry(item);
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// The depender must come before the dependee.
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if(depender_index >= 0)
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{
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this->EntryConstraintGraph[dependee_index].push_back(depender_index);
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}
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// Update the inferred dependencies for earlier items.
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for(std::map<int, DependSet>::iterator dsi = dependSets.begin();
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dsi != dependSets.end(); ++dsi)
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{
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if(dependee_index != dsi->first)
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{
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dsi->second.insert(dependee_index);
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}
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}
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// If this item needs to have dependencies inferred, do so.
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if(this->InferredDependSets[dependee_index])
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{
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// Make sure an entry exists to hold the set for the item.
|
|
dependSets[dependee_index];
|
|
}
|
|
}
|
|
|
|
// Store the inferred dependency sets discovered for this list.
|
|
for(std::map<int, DependSet>::iterator dsi = dependSets.begin();
|
|
dsi != dependSets.end(); ++dsi)
|
|
{
|
|
this->InferredDependSets[dsi->first]->push_back(dsi->second);
|
|
}
|
|
}
|
|
|
|
//----------------------------------------------------------------------------
|
|
std::string cmComputeLinkDepends::CleanItemName(std::string const& item)
|
|
{
|
|
// Strip whitespace off the library names because we used to do this
|
|
// in case variables were expanded at generate time. We no longer
|
|
// do the expansion but users link to libraries like " ${VAR} ".
|
|
std::string lib = item;
|
|
std::string::size_type pos = lib.find_first_not_of(" \t\r\n");
|
|
if(pos != lib.npos)
|
|
{
|
|
lib = lib.substr(pos, lib.npos);
|
|
}
|
|
pos = lib.find_last_not_of(" \t\r\n");
|
|
if(pos != lib.npos)
|
|
{
|
|
lib = lib.substr(0, pos+1);
|
|
}
|
|
if(lib != item && !this->Makefile->NeedBackwardsCompatibility(2,4))
|
|
{
|
|
cmOStringStream e;
|
|
e << "Target \"" << this->Target->GetName() << "\" links to item \""
|
|
<< item << "\" which has leading or trailing whitespace. "
|
|
<< "CMake is stripping off the whitespace but this may not be "
|
|
<< "supported in the future. "
|
|
<< "Update the CMakeLists.txt files to avoid adding the whitespace. "
|
|
<< "Set CMAKE_BACKWARDS_COMPATIBILITY to 2.4 or lower to disable this "
|
|
<< "warning.";
|
|
cmSystemTools::Message(e.str().c_str());
|
|
}
|
|
return lib;
|
|
}
|
|
|
|
//----------------------------------------------------------------------------
|
|
void cmComputeLinkDepends::InferDependencies()
|
|
{
|
|
// The inferred dependency sets for each item list the possible
|
|
// dependencies. The intersection of the sets for one item form its
|
|
// inferred dependencies.
|
|
for(unsigned int depender_index=0;
|
|
depender_index < this->InferredDependSets.size(); ++depender_index)
|
|
{
|
|
// Skip items for which dependencies do not need to be inferred or
|
|
// for which the inferred dependency sets are empty.
|
|
DependSetList* sets = this->InferredDependSets[depender_index];
|
|
if(!sets || sets->empty())
|
|
{
|
|
continue;
|
|
}
|
|
|
|
// Intersect the sets for this item.
|
|
DependSetList::const_iterator i = sets->begin();
|
|
DependSet common = *i;
|
|
for(++i; i != sets->end(); ++i)
|
|
{
|
|
DependSet intersection;
|
|
cmsys_stl::set_intersection
|
|
(common.begin(), common.end(), i->begin(), i->end(),
|
|
std::inserter(intersection, intersection.begin()));
|
|
common = intersection;
|
|
}
|
|
|
|
// Add the inferred dependencies to the graph.
|
|
for(DependSet::const_iterator j = common.begin(); j != common.end(); ++j)
|
|
{
|
|
int dependee_index = *j;
|
|
this->EntryConstraintGraph[dependee_index].push_back(depender_index);
|
|
}
|
|
}
|
|
}
|
|
|
|
//----------------------------------------------------------------------------
|
|
void cmComputeLinkDepends::CleanConstraintGraph()
|
|
{
|
|
for(Graph::iterator i = this->EntryConstraintGraph.begin();
|
|
i != this->EntryConstraintGraph.end(); ++i)
|
|
{
|
|
// Sort the outgoing edges for each graph node so that the
|
|
// original order will be preserved as much as possible.
|
|
cmsys_stl::sort(i->begin(), i->end());
|
|
|
|
// Make the edge list unique.
|
|
NodeList::iterator last = cmsys_stl::unique(i->begin(), i->end());
|
|
i->erase(last, i->end());
|
|
}
|
|
}
|
|
|
|
//----------------------------------------------------------------------------
|
|
void cmComputeLinkDepends::DisplayConstraintGraph()
|
|
{
|
|
// Display the graph nodes and their edges.
|
|
cmOStringStream e;
|
|
for(unsigned int i=0; i < this->EntryConstraintGraph.size(); ++i)
|
|
{
|
|
NodeList const& nl = this->EntryConstraintGraph[i];
|
|
e << "item " << i << " is [" << this->EntryList[i].Item << "]\n";
|
|
for(NodeList::const_iterator j = nl.begin(); j != nl.end(); ++j)
|
|
{
|
|
e << " item " << *j << " must precede it\n";
|
|
}
|
|
}
|
|
fprintf(stderr, "%s\n", e.str().c_str());
|
|
}
|
|
|
|
//----------------------------------------------------------------------------
|
|
void cmComputeLinkDepends::OrderLinkEntires()
|
|
{
|
|
// Compute the DAG of strongly connected components. The algorithm
|
|
// used by cmComputeComponentGraph should identify the components in
|
|
// the same order in which the items were originally discovered in
|
|
// the BFS. This should preserve the original order when no
|
|
// constraints disallow it.
|
|
cmComputeComponentGraph ccg(this->EntryConstraintGraph);
|
|
Graph const& cgraph = ccg.GetComponentGraph();
|
|
if(this->DebugMode)
|
|
{
|
|
this->DisplayComponents(ccg);
|
|
}
|
|
|
|
// Setup visit tracking.
|
|
this->ComponentVisited.resize(cgraph.size(), 0);
|
|
|
|
// The component graph is guaranteed to be acyclic. Start a DFS
|
|
// from every entry.
|
|
for(unsigned int c=0; c < cgraph.size(); ++c)
|
|
{
|
|
this->VisitComponent(ccg, c);
|
|
}
|
|
}
|
|
|
|
//----------------------------------------------------------------------------
|
|
void
|
|
cmComputeLinkDepends::DisplayComponents(cmComputeComponentGraph const& ccg)
|
|
{
|
|
fprintf(stderr, "The strongly connected components are:\n");
|
|
std::vector<NodeList> const& components = ccg.GetComponents();
|
|
for(unsigned int c=0; c < components.size(); ++c)
|
|
{
|
|
fprintf(stderr, "Component (%u):\n", c);
|
|
NodeList const& nl = components[c];
|
|
for(NodeList::const_iterator ni = nl.begin(); ni != nl.end(); ++ni)
|
|
{
|
|
int i = *ni;
|
|
fprintf(stderr, " item %d [%s]\n", i,
|
|
this->EntryList[i].Item.c_str());
|
|
}
|
|
}
|
|
fprintf(stderr, "\n");
|
|
}
|
|
|
|
//----------------------------------------------------------------------------
|
|
void
|
|
cmComputeLinkDepends::VisitComponent(cmComputeComponentGraph const& ccg,
|
|
unsigned int c)
|
|
{
|
|
// Check if the node has already been visited.
|
|
if(this->ComponentVisited[c])
|
|
{
|
|
return;
|
|
}
|
|
|
|
// We are now visiting this component so mark it.
|
|
this->ComponentVisited[c] = 1;
|
|
|
|
// Visit the neighbors of the component first.
|
|
NodeList const& nl = ccg.GetComponentGraphEdges(c);
|
|
for(NodeList::const_iterator ni = nl.begin(); ni != nl.end(); ++ni)
|
|
{
|
|
this->VisitComponent(ccg, *ni);
|
|
}
|
|
|
|
// Now that all items required to come before this one have been
|
|
// emmitted, emit this component's items.
|
|
this->EmitComponent(ccg.GetComponent(c));
|
|
}
|
|
|
|
//----------------------------------------------------------------------------
|
|
void cmComputeLinkDepends::EmitComponent(NodeList const& nl)
|
|
{
|
|
assert(!nl.empty());
|
|
|
|
// Handle trivial components.
|
|
if(nl.size() == 1)
|
|
{
|
|
this->FinalLinkEntries.push_back(this->EntryList[nl[0]]);
|
|
return;
|
|
}
|
|
|
|
// This is a non-trivial strongly connected component of the
|
|
// original graph. It consists of two or more libraries (archives)
|
|
// that mutually require objects from one another. In the worst
|
|
// case we may have to repeat the list of libraries as many times as
|
|
// there are object files in the biggest archive. For now we just
|
|
// list them twice.
|
|
//
|
|
// The list of items in the component has been sorted by the order
|
|
// of discovery in the original BFS of dependencies. This has the
|
|
// advantage that the item directly linked by a target requiring
|
|
// this component will come first which minimizes the number of
|
|
// repeats needed.
|
|
for(NodeList::const_iterator ni = nl.begin(); ni != nl.end(); ++ni)
|
|
{
|
|
this->FinalLinkEntries.push_back(this->EntryList[*ni]);
|
|
}
|
|
for(NodeList::const_iterator ni = nl.begin(); ni != nl.end(); ++ni)
|
|
{
|
|
this->FinalLinkEntries.push_back(this->EntryList[*ni]);
|
|
}
|
|
}
|
|
|
|
//----------------------------------------------------------------------------
|
|
void cmComputeLinkDepends::DisplayFinalEntries()
|
|
{
|
|
fprintf(stderr, "target [%s] links to:\n", this->Target->GetName());
|
|
for(std::vector<LinkEntry>::const_iterator lei =
|
|
this->FinalLinkEntries.begin();
|
|
lei != this->FinalLinkEntries.end(); ++lei)
|
|
{
|
|
if(lei->Target)
|
|
{
|
|
fprintf(stderr, " target [%s]\n", lei->Target->GetName());
|
|
}
|
|
else
|
|
{
|
|
fprintf(stderr, " item [%s]\n", lei->Item.c_str());
|
|
}
|
|
}
|
|
fprintf(stderr, "\n");
|
|
}
|