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author | Arch Librarian <arch@canonical.com> | 2004-09-20 16:50:41 +0000 |
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committer | Arch Librarian <arch@canonical.com> | 2004-09-20 16:50:41 +0000 |
commit | 6c139d6e362f04a1582e8a8f511f8aeab031fecf (patch) | |
tree | c200b8f51da9bcfe612b7ceb645e6eec9ebac9f1 /apt-pkg/orderlist.cc | |
parent | 2246928b428c3ece2c2743da5b0bb63257e37a85 (diff) | |
download | apt-6c139d6e362f04a1582e8a8f511f8aeab031fecf.tar.gz |
Sync
Author: jgg
Date: 1998-07-07 04:17:00 GMT
Sync
Diffstat (limited to 'apt-pkg/orderlist.cc')
-rw-r--r-- | apt-pkg/orderlist.cc | 829 |
1 files changed, 829 insertions, 0 deletions
diff --git a/apt-pkg/orderlist.cc b/apt-pkg/orderlist.cc new file mode 100644 index 000000000..f79a063bd --- /dev/null +++ b/apt-pkg/orderlist.cc @@ -0,0 +1,829 @@ +// -*- mode: cpp; mode: fold -*- +// Description /*{{{*/ +// $Id: orderlist.cc,v 1.1 1998/07/07 04:17:01 jgg Exp $ +/* ###################################################################### + + Order List - Represents and Manipulates an ordered list of packages. + + A list of packages can be ordered by a number of conflicting criteria + each given a specific priority. Each package also has a set of flags + indicating some usefull things about it that are derived in the + course of sorting. The pkgPackageManager class uses this class for + all of it's installation ordering needs. + + This is a modified version of Manoj's Routine B. It consists of four + independent ordering algorithms that can be applied at for different + points in the ordering. By appling progressivly fewer ordering + operations it is possible to give each consideration it's own + priority and create an order that satisfies the lowest applicable + consideration. + + The rules for unpacking ordering are: + 1) Unpacking ignores Depends: on all packages + 2) Unpacking requires Conflicts: on -ALL- packages to be satisfied + 3) Unpacking requires PreDepends: on this package only to be satisfied + 4) Removing requires that no packages depend on the package to be + removed. + + And the rule for configuration ordering is: + 1) Configuring requires that the Depends: of the package be satisfied + Conflicts+PreDepends are ignored because unpacking says they are + already correct [exageration, it does check but we need not be + concerned] + + And some features that are valuable for unpacking ordering. + f1) Unpacking a new package should advoid breaking dependencies of + configured packages + f2) Removal should not require a force, corrolory of f1 + f3) Unpacking should order by depends rather than fall back to random + ordering. + + Each of the features can be enabled in the sorting routine at an + arbitary priority to give quite abit of control over the final unpacking + order. + + The rules listed above my never be violated and are called Critical. + When a critical rule is violated then a loop condition is recorded + and will have to be delt with in the caller. + + ##################################################################### */ + /*}}}*/ +// Include Files /*{{{*/ +#ifdef __GNUG__ +#pragma implementation "pkglib/orderlist.h" +#endif +#include <pkglib/orderlist.h> +#include <pkglib/depcache.h> +#include <pkglib/error.h> +#include <pkglib/version.h> + /*}}}*/ + +pkgOrderList *pkgOrderList::Me = 0; + +// OrderList::pkgOrderList - Constructor /*{{{*/ +// --------------------------------------------------------------------- +/* */ +pkgOrderList::pkgOrderList(pkgDepCache &Cache) : Cache(Cache) +{ + Primary = 0; + Secondary = 0; + RevDepends = 0; + Remove = 0; + LoopCount = -1; + + /* Construct the arrays, egcs 1.0.1 bug requires the package count + hack */ + unsigned long Size = Cache.HeaderP->PackageCount; + Flags = new unsigned char[Size]; + End = List = new Package *[Size]; + memset(Flags,0,sizeof(*Flags)*Size); +} + /*}}}*/ +// OrderList::~pkgOrderList - Destructor /*{{{*/ +// --------------------------------------------------------------------- +/* */ +pkgOrderList::~pkgOrderList() +{ + delete [] List; + delete [] Flags; +} + /*}}}*/ + +// OrderList::DoRun - Does an order run /*{{{*/ +// --------------------------------------------------------------------- +/* The caller is expeted to have setup the desired probe state */ +bool pkgOrderList::DoRun() +{ + // Temp list + unsigned long Size = Cache.HeaderP->PackageCount; + Package **NList = new Package *[Size]; + + Depth = 0; + WipeFlags(Added | AddPending | Loop | InList); + + for (iterator I = List; I != End; I++) + Flag(*I,InList); + + // Rebuild the main list into the temp list. + iterator OldEnd = End; + End = NList; + for (iterator I = List; I != OldEnd; I++) + if (VisitNode(PkgIterator(Cache,*I)) == false) + { + End = OldEnd; + delete [] NList; + return false; + } + + // Swap the main list to the new list + delete [] List; + List = NList; + return true; +} + /*}}}*/ +// OrderList::OrderCritical - Perform critical unpacking ordering /*{{{*/ +// --------------------------------------------------------------------- +/* This performs predepends and immediate configuration ordering only. + This is termed critical unpacking ordering. Any loops that form are + fatal and indicate that the packages cannot be installed. */ +bool pkgOrderList::OrderCritical() +{ + Primary = &DepUnPackPre; + Secondary = 0; + RevDepends = 0; + Remove = 0; + LoopCount = 0; + + // Sort + Me = this; + qsort(List,End - List,sizeof(*List),&OrderCompareB); + + if (DoRun() == false) + return false; + + if (LoopCount != 0) + return _error->Error("Fatal, predepends looping detected"); + return true; +} + /*}}}*/ +// OrderList::OrderUnpack - Perform complete unpacking ordering /*{{{*/ +// --------------------------------------------------------------------- +/* This performs complete unpacking ordering and creates an order that is + suitable for unpacking */ +bool pkgOrderList::OrderUnpack() +{ + Primary = &DepUnPackCrit; + Secondary = &DepConfigure; + RevDepends = &DepUnPackDep; + Remove = &DepRemove; + LoopCount = -1; + + // Sort + Me = this; + qsort(List,End - List,sizeof(*List),&OrderCompareA); + + if (DoRun() == false) + return false; + + Secondary = 0; + if (DoRun() == false) + return false; + + LoopCount = 0; + RevDepends = 0; + Remove = 0; // Otherwise the libreadline remove problem occures + if (DoRun() == false) + return false; + + LoopCount = 0; + Primary = &DepUnPackPre; + if (DoRun() == false) + return false; + +/* cout << "----------END" << endl; + + for (iterator I = List; I != End; I++) + { + PkgIterator P(Cache,*I); + cout << P.Name() << endl; + }*/ + + return true; +} + /*}}}*/ +// OrderList::OrderConfigure - Perform configuration ordering /*{{{*/ +// --------------------------------------------------------------------- +/* This orders by depends only and produces an order which is suitable + for configuration */ +bool pkgOrderList::OrderConfigure() +{ + Primary = &DepConfigure; + Secondary = 0; + RevDepends = 0; + Remove = 0; + LoopCount = -1; + return DoRun(); +} + /*}}}*/ + +// OrderList::Score - Score the package for sorting /*{{{*/ +// --------------------------------------------------------------------- +/* Higher scores order earlier */ +int pkgOrderList::Score(PkgIterator Pkg) +{ + // Removal is always done first + if (Cache[Pkg].Delete() == true) + return 200; + + int Score = 0; + if ((Pkg->Flags & pkgCache::Flag::Essential) == pkgCache::Flag::Essential) + Score += 100; + + for (DepIterator D = Cache[Pkg].InstVerIter(Cache).DependsList(); + D.end() == false; D++) + if (D->Type == pkgCache::Dep::PreDepends) + { + Score += 50; + break; + } + + // Important Required Standard Optional Extra + signed short PrioMap[] = {0,5,4,3,1,0}; + if (Cache[Pkg].InstVerIter(Cache)->Priority <= 5) + Score += PrioMap[Cache[Pkg].InstVerIter(Cache)->Priority]; + return Score; +} + /*}}}*/ +// OrderList::FileCmp - Compare by package file /*{{{*/ +// --------------------------------------------------------------------- +/* This compares by the package file that the install version is in. */ +int pkgOrderList::FileCmp(PkgIterator A,PkgIterator B) +{ + if (Cache[A].Delete() == true && Cache[B].Delete() == true) + return 0; + if (Cache[A].Delete() == true) + return -1; + if (Cache[B].Delete() == true) + return 1; + + if (Cache[A].InstVerIter(Cache).FileList().end() == true) + return -1; + if (Cache[A].InstVerIter(Cache).FileList().end() == true) + return 1; + + pkgCache::PackageFile *FA = Cache[A].InstVerIter(Cache).FileList().File(); + pkgCache::PackageFile *FB = Cache[B].InstVerIter(Cache).FileList().File(); + if (FA < FB) + return -1; + if (FA > FB) + return 1; + return 0; +} + /*}}}*/ +// OrderList::OrderCompareA - Order the installation by op /*{{{*/ +// --------------------------------------------------------------------- +/* This provides a first-pass sort of the list and gives a decent starting + point for further complete ordering. It is used by OrderUnpack only */ +int pkgOrderList::OrderCompareA(const void *a, const void *b) +{ + PkgIterator A(Me->Cache,*(Package **)a); + PkgIterator B(Me->Cache,*(Package **)b); + + if (A.State() != pkgCache::PkgIterator::NeedsNothing && + B.State() == pkgCache::PkgIterator::NeedsNothing) + return -1; + + if (A.State() == pkgCache::PkgIterator::NeedsNothing && + B.State() != pkgCache::PkgIterator::NeedsNothing) + return 1; + + int ScoreA = Me->Score(A); + int ScoreB = Me->Score(B); + if (ScoreA > ScoreB) + return -1; + + if (ScoreA < ScoreB) + return 1; + + return strcmp(A.Name(),B.Name()); +} + /*}}}*/ +// OrderList::OrderCompareB - Order the installation by source /*{{{*/ +// --------------------------------------------------------------------- +/* This orders by installation source. This is usefull to handle + inter-source breaks */ +int pkgOrderList::OrderCompareB(const void *a, const void *b) +{ + PkgIterator A(Me->Cache,*(Package **)a); + PkgIterator B(Me->Cache,*(Package **)b); + + if (A.State() != pkgCache::PkgIterator::NeedsNothing && + B.State() == pkgCache::PkgIterator::NeedsNothing) + return -1; + + if (A.State() == pkgCache::PkgIterator::NeedsNothing && + B.State() != pkgCache::PkgIterator::NeedsNothing) + return 1; + + int F = Me->FileCmp(A,B); + if (F != 0) + { + if (F > 0) + return -1; + return 1; + } + + int ScoreA = Me->Score(A); + int ScoreB = Me->Score(B); + if (ScoreA > ScoreB) + return -1; + + if (ScoreA < ScoreB) + return 1; + + return strcmp(A.Name(),B.Name()); +} + /*}}}*/ + +// OrderList::VisitDeps - Visit forward install dependencies /*{{{*/ +// --------------------------------------------------------------------- +/* This calls the dependency function for the normal forwards dependencies + of the package */ +bool pkgOrderList::VisitDeps(DepFunc F,PkgIterator Pkg) +{ + if (F == 0 || Pkg.end() == true || Cache[Pkg].InstallVer == 0) + return true; + + return (this->*F)(Cache[Pkg].InstVerIter(Cache).DependsList()); +} + /*}}}*/ +// OrderList::VisitRDeps - Visit reverse dependencies /*{{{*/ +// --------------------------------------------------------------------- +/* This calls the dependency function for all of the normal reverse depends + of the package */ +bool pkgOrderList::VisitRDeps(DepFunc F,PkgIterator Pkg) +{ + if (F == 0 || Pkg.end() == true) + return true; + + return (this->*F)(Pkg.RevDependsList()); +} + /*}}}*/ +// OrderList::VisitRProvides - Visit provides reverse dependencies /*{{{*/ +// --------------------------------------------------------------------- +/* This calls the dependency function for all reverse dependencies + generated by the provides line on the package. */ +bool pkgOrderList::VisitRProvides(DepFunc F,VerIterator Ver) +{ + if (F == 0 || Ver.end() == true) + return true; + + bool Res = true; + for (PrvIterator P = Ver.ProvidesList(); P.end() == false; P++) + Res &= (this->*F)(P.ParentPkg().RevDependsList()); + return true; +} + /*}}}*/ +// OrderList::VisitProvides - Visit all of the providing packages /*{{{*/ +// --------------------------------------------------------------------- +/* This routine calls visit on all providing packages. */ +bool pkgOrderList::VisitProvides(DepIterator D) +{ + Version **List = D.AllTargets(); + for (Version **I = List; *I != 0; I++) + { + VerIterator Ver(Cache,*I); + PkgIterator Pkg = Ver.ParentPkg(); + + if (Cache[Pkg].Keep() == true) + continue; + + if (D->Type != pkgCache::Dep::Conflicts && Cache[Pkg].InstallVer != *I) + continue; + + if (D->Type == pkgCache::Dep::Conflicts && (Version *)Pkg.CurrentVer() != *I) + continue; + + if (VisitNode(Pkg) == false) + { + delete [] List; + return false; + } + } + delete [] List; + return true; +} + /*}}}*/ +// OrderList::VisitNode - Recursive ordering director /*{{{*/ +// --------------------------------------------------------------------- +/* This is the core ordering routine. It calls the set dependency + consideration functions which then potentialy call this again. Finite + depth is achived through the colouring mechinism. */ +bool pkgOrderList::VisitNode(PkgIterator Pkg) +{ + // Looping or irrelevent. + if (Pkg.end() == true || IsFlag(Pkg,Added) == true || + IsFlag(Pkg,AddPending) == true || IsFlag(Pkg,InList) == false) + return true; + +/* for (int j = 0; j != Depth; j++) cout << ' '; + cout << "Visit " << Pkg.Name() << endl;*/ + Depth++; + + // Color grey + Flag(Pkg,AddPending); + + DepFunc Old = Primary; + + // Perform immedate configuration of the package if so flagged. + if (IsFlag(Pkg,Immediate) == true && Primary != &DepUnPackPre) + Primary = &DepUnPackPreD; + + bool Res = true; + if (Cache[Pkg].Delete() == false) + { + // Primary + Res &= Res && VisitDeps(Primary,Pkg); + Res &= Res && VisitRDeps(Primary,Pkg); + Res &= Res && VisitRProvides(Primary,Pkg.CurrentVer()); + Res &= Res && VisitRProvides(Primary,Cache[Pkg].InstVerIter(Cache)); + + // RevDep + Res &= Res && VisitRDeps(RevDepends,Pkg); + Res &= Res && VisitRProvides(RevDepends,Pkg.CurrentVer()); + Res &= Res && VisitRProvides(RevDepends,Cache[Pkg].InstVerIter(Cache)); + + // Secondary + Res &= Res && VisitDeps(Secondary,Pkg); + Res &= Res && VisitRDeps(Secondary,Pkg); + Res &= Res && VisitRProvides(Secondary,Pkg.CurrentVer()); + Res &= Res && VisitRProvides(Secondary,Cache[Pkg].InstVerIter(Cache)); + } + else + { + // RevDep + Res &= Res && VisitRDeps(Remove,Pkg); + Res &= Res && VisitRProvides(Remove,Pkg.CurrentVer()); + } + + if (IsFlag(Pkg,Added) == false) + { + Flag(Pkg,Added,Added | AddPending); + *End = Pkg; + End++; + } + + Primary = Old; + Depth--; + +/* for (int j = 0; j != Depth; j++) cout << ' '; + cout << "Leave " << Pkg.Name() << ' ' << IsFlag(Pkg,Added) << ',' << IsFlag(Pkg,AddPending) << endl;*/ + + return true; +} + /*}}}*/ + +// OrderList::DepUnPackCrit - Critical UnPacking ordering /*{{{*/ +// --------------------------------------------------------------------- +/* Critical unpacking ordering strives to satisfy Conflicts: and + PreDepends: only. When a prdepends is encountered the Primary + DepFunc is changed to be DepUnPackPreD. + + Loops are preprocessed and logged. */ +bool pkgOrderList::DepUnPackCrit(DepIterator D) +{ + for (; D.end() == false; D++) + { + if (D.Reverse() == true) + { + /* Reverse depenanices are only interested in conflicts, + predepend breakage is ignored here */ + if (D->Type != pkgCache::Dep::Conflicts) + continue; + + // Duplication elimination, consider only the current version + if (D.ParentPkg().CurrentVer() != D.ParentVer()) + continue; + + /* For reverse dependencies we wish to check if the + dependency is satisifed in the install state. The + target package (caller) is going to be in the installed + state. */ + if (CheckDep(D) == true) + continue; + + if (VisitNode(D.ParentPkg()) == false) + return false; + } + else + { + /* Forward critical dependencies MUST be correct before the + package can be unpacked. */ + if (D->Type != pkgCache::Dep::Conflicts && D->Type != pkgCache::Dep::PreDepends) + continue; + + /* We wish to check if the dep is okay in the now state of the + target package against the install state of this package. */ + if (CheckDep(D) == true) + { + /* We want to catch predepends loops with the code below. + Conflicts loops that are Dep OK are ignored */ + if (IsFlag(D.TargetPkg(),AddPending) == false || + D->Type != pkgCache::Dep::PreDepends) + continue; + } + + // This is the loop detection + if (IsFlag(D.TargetPkg(),Added) == true || + IsFlag(D.TargetPkg(),AddPending) == true) + { + if (IsFlag(D.TargetPkg(),AddPending) == true) + AddLoop(D); + continue; + } + + /* Predepends require a special ordering stage, they must have + all dependents installed as well */ + DepFunc Old = Primary; + bool Res = false; + if (D->Type == pkgCache::Dep::PreDepends) + Primary = &DepUnPackPreD; + Res = VisitProvides(D); + Primary = Old; + if (Res == false) + return false; + } + } + return true; +} + /*}}}*/ +// OrderList::DepUnPackPreD - Critical UnPacking ordering with depends /*{{{*/ +// --------------------------------------------------------------------- +/* Critical PreDepends (also configure immediate and essential) strives to + ensure not only that all conflicts+predepends are met but that this + package will be immediately configurable when it is unpacked. + + Loops are preprocessed and logged. */ +bool pkgOrderList::DepUnPackPreD(DepIterator D) +{ + if (D.Reverse() == true) + return DepUnPackCrit(D); + + for (; D.end() == false; D++) + { + if (D.IsCritical() == false) + continue; + + /* We wish to check if the dep is okay in the now state of the + target package against the install state of this package. */ + if (CheckDep(D) == true) + { + /* We want to catch predepends loops with the code below. + Conflicts loops that are Dep OK are ignored */ + if (IsFlag(D.TargetPkg(),AddPending) == false || + D->Type != pkgCache::Dep::PreDepends) + continue; + } + + // This is the loop detection + if (IsFlag(D.TargetPkg(),Added) == true || + IsFlag(D.TargetPkg(),AddPending) == true) + { + if (IsFlag(D.TargetPkg(),AddPending) == true) + AddLoop(D); + continue; + } + + if (VisitProvides(D) == false) + return false; + } + return true; +} + /*}}}*/ +// OrderList::DepUnPackPre - Critical Predepends ordering /*{{{*/ +// --------------------------------------------------------------------- +/* Critical PreDepends (also configure immediate and essential) strives to + ensure not only that all conflicts+predepends are met but that this + package will be immediately configurable when it is unpacked. + + Loops are preprocessed and logged. All loops will be fatal. */ +bool pkgOrderList::DepUnPackPre(DepIterator D) +{ + if (D.Reverse() == true) + return true; + + for (; D.end() == false; D++) + { + /* Only consider the PreDepends or Depends. Depends are only + considered at the lowest depth or in the case of immediate + configure */ + if (D->Type != pkgCache::Dep::PreDepends) + { + if (D->Type == pkgCache::Dep::Depends) + { + if (Depth == 1 && IsFlag(D.ParentPkg(),Immediate) == false) + continue; + } + else + continue; + } + + /* We wish to check if the dep is okay in the now state of the + target package against the install state of this package. */ + if (CheckDep(D) == true) + { + /* We want to catch predepends loops with the code below. + Conflicts loops that are Dep OK are ignored */ + if (IsFlag(D.TargetPkg(),AddPending) == false) + continue; + } + + // This is the loop detection + if (IsFlag(D.TargetPkg(),Added) == true || + IsFlag(D.TargetPkg(),AddPending) == true) + { + if (IsFlag(D.TargetPkg(),AddPending) == true) + AddLoop(D); + continue; + } + + if (VisitProvides(D) == false) + return false; + } + return true; +} + /*}}}*/ +// OrderList::DepUnPackDep - Reverse dependency considerations /*{{{*/ +// --------------------------------------------------------------------- +/* Reverse dependencies are considered to determine if unpacking this + package will break any existing dependencies. If so then those + packages are ordered before this one so that they are in the + UnPacked state. + + The forwards depends loop is designed to bring the packages dependents + close to the package. This helps reduce deconfigure time. + + Loops are irrelevent to this. */ +bool pkgOrderList::DepUnPackDep(DepIterator D) +{ + + for (; D.end() == false; D++) + if (D.IsCritical() == true) + { + if (D.Reverse() == true) + { + /* Duplication prevention. We consider rev deps only on + the current version, a not installed package + cannot break */ + if (D.ParentPkg()->CurrentVer == 0 || + D.ParentPkg().CurrentVer() != D.ParentVer()) + continue; + + // The dep will not break so it is irrelevent. + if (CheckDep(D) == true) + continue; + + if (VisitNode(D.ParentPkg()) == false) + return false; + } + else + if (D->Type == pkgCache::Dep::Depends) + if (VisitProvides(D) == false) + return false; + } + return true; +} + /*}}}*/ +// OrderList::DepConfigure - Configuration ordering /*{{{*/ +// --------------------------------------------------------------------- +/* Configuration only ordering orders by the Depends: line only. It + orders configuration so that when a package comes to be configured it's + dependents are configured. + + Loops are ingored. Depends loop entry points are chaotic. */ +bool pkgOrderList::DepConfigure(DepIterator D) +{ + // Never consider reverse configuration dependencies. + if (D.Reverse() == true) + return true; + + for (; D.end() == false; D++) + if (D->Type == pkgCache::Dep::Depends) + if (VisitProvides(D) == false) + return false; + return true; +} + /*}}}*/ +// OrderList::DepRemove - Removal ordering /*{{{*/ +// --------------------------------------------------------------------- +/* Removal visits all reverse depends. It considers if the dependency + of the Now state version to see if it is okay with removing this + package. This check should always fail, but is provided for symetery + with the other critical handlers. + + Loops are preprocessed and logged. Removal loops can also be + detected in the critical handler. They are characterized by an + old version of A depending on B but the new version of A conflicting + with B, thus either A or B must break to install. */ +bool pkgOrderList::DepRemove(DepIterator D) +{ + if (D.Reverse() == false) + return true; + for (; D.end() == false; D++) + if (D->Type == pkgCache::Dep::Depends || D->Type == pkgCache::Dep::PreDepends) + { + // Duplication elimination, consider the current version only + if (D.ParentPkg().CurrentVer() != D.ParentVer()) + continue; + + /* We wish to see if the dep on the parent package is okay + in the removed (install) state of the target pkg. */ + if (CheckDep(D) == true) + { + // We want to catch loops with the code below. + if (IsFlag(D.ParentPkg(),AddPending) == false) + continue; + } + + // This is the loop detection + if (IsFlag(D.ParentPkg(),Added) == true || + IsFlag(D.ParentPkg(),AddPending) == true) + { + if (IsFlag(D.ParentPkg(),AddPending) == true) + AddLoop(D); + continue; + } + + if (VisitNode(D.ParentPkg()) == false) + return false; + } + + return true; +} + /*}}}*/ + +// OrderList::AddLoop - Add a loop to the loop list /*{{{*/ +// --------------------------------------------------------------------- +/* We record the loops. This is a relic since loop breaking is done + genericaly as part of the safety routines. */ +bool pkgOrderList::AddLoop(DepIterator D) +{ + if (LoopCount < 0 || LoopCount >= 20) + return false; + + // Skip dups + if (LoopCount != 0) + { + if (Loops[LoopCount - 1].ParentPkg() == D.ParentPkg() || + Loops[LoopCount - 1].TargetPkg() == D.ParentPkg()) + return true; + } + + Loops[LoopCount++] = D; + + // Mark the packages as being part of a loop. + Flag(D.TargetPkg(),Loop); + Flag(D.ParentPkg(),Loop); + return true; +} + /*}}}*/ +// OrderList::WipeFlags - Unset the given flags from all packages /*{{{*/ +// --------------------------------------------------------------------- +/* */ +void pkgOrderList::WipeFlags(unsigned long F) +{ + unsigned long Size = Cache.HeaderP->PackageCount; + for (unsigned long I = 0; I != Size; I++) + Flags[I] &= ~F; +} + /*}}}*/ +// OrderList::CheckDep - Check a dependency for truth /*{{{*/ +// --------------------------------------------------------------------- +/* This performs a complete analysis of the dependency wrt to the + current add list. It returns true if after all events are + performed it is still true. This sort of routine can be approximated + by examining the DepCache, however in convoluted cases of provides + this fails to produce a suitable result. */ +bool pkgOrderList::CheckDep(DepIterator D) +{ + Version **List = D.AllTargets(); + for (Version **I = List; *I != 0; I++) + { + VerIterator Ver(Cache,*I); + PkgIterator Pkg = Ver.ParentPkg(); + + /* The meaning of Added and AddPending is subtle. AddPending is + an indication that the package is looping. Because of the + way ordering works Added means the package will be unpacked + before this one and AddPending means after. It is therefore + correct to ignore AddPending in all cases, but that exposes + reverse-ordering loops which should be ignore. */ + if (IsFlag(Pkg,Added) == true || + (IsFlag(Pkg,AddPending) == true && D.Reverse() == true)) + { + if (Cache[Pkg].InstallVer != *I) + continue; + } + else + if ((Version *)Pkg.CurrentVer() != *I || + Pkg.State() != PkgIterator::NeedsNothing) + continue; + + delete [] List; + + /* Conflicts requires that all versions are not present, depends + just needs one */ + if (D->Type != pkgCache::Dep::Conflicts) + return true; + else + return false; + } + delete [] List; + + /* Conflicts requires that all versions are not present, depends + just needs one */ + if (D->Type == pkgCache::Dep::Conflicts) + return true; + return false; +} + /*}}}*/ |