#include<iterator>
#include <iosfwd>
#include <string>
+#ifdef APT_PKG_EXPOSE_STRING_VIEW
+#include <apt-pkg/string_view.h>
+#endif
#include<string.h>
inline const char *Name() const {return S->Name == 0?0:Owner->StrP + S->Name;}
inline PkgIterator PackageList() const;
PkgIterator FindPkg(std::string Arch = "any") const;
+#ifdef APT_PKG_EXPOSE_STRING_VIEW
+ APT_HIDDEN PkgIterator FindPkg(APT::StringView Arch = APT::StringView("any", 3)) const;
+ APT_HIDDEN PkgIterator FindPkg(const char *Arch) const;
+#endif
/** \brief find the package with the "best" architecture
The best architecture is either the "native" or the first
inline const char *Name() const { return Group().Name(); }
// Versions have sections - and packages can have different versions with different sections
// so this interface is broken by design. Run as fast as you can to Version.Section().
- APT_DEPRECATED inline const char *Section() const {
- APT_IGNORE_DEPRECATED_PUSH
- return S->Section == 0?0:Owner->StrP + S->Section;
- APT_IGNORE_DEPRECATED_POP
- }
+ APT_DEPRECATED_MSG("Use the .Section method of VerIterator instead") inline const char *Section() const;
inline bool Purge() const {return S->CurrentState == pkgCache::State::Purge ||
(S->CurrentVer == 0 && S->CurrentState == pkgCache::State::NotInstalled);}
inline const char *Arch() const {return S->Arch == 0?0:Owner->StrP + S->Arch;}
// Accessors
inline const char *VerStr() const {return S->VerStr == 0?0:Owner->StrP + S->VerStr;}
inline const char *Section() const {return S->Section == 0?0:Owner->StrP + S->Section;}
-#if APT_PKG_ABI >= 413
/** \brief source package name this version comes from
Always contains the name, even if it is the same as the binary name */
inline const char *SourcePkgName() const {return Owner->StrP + S->SourcePkgName;}
/** \brief source version this version comes from
Always contains the version string, even if it is the same as the binary version */
inline const char *SourceVerStr() const {return Owner->StrP + S->SourceVerStr;}
-#endif
inline const char *Arch() const {
if ((S->MultiArch & pkgCache::Version::All) == pkgCache::Version::All)
return "all";
bool IsNegative() const APT_PURE;
bool IsIgnorable(PrvIterator const &Prv) const APT_PURE;
bool IsIgnorable(PkgIterator const &Pkg) const APT_PURE;
- bool IsMultiArchImplicit() const APT_PURE;
+ /* MultiArch can be translated to SingleArch for an resolver and we did so,
+ by adding dependencies to help the resolver understand the problem, but
+ sometimes it is needed to identify these to ignore them… */
+ inline bool IsMultiArchImplicit() const APT_PURE {
+ return (S2->CompareOp & pkgCache::Dep::MultiArchImplicit) == pkgCache::Dep::MultiArchImplicit;
+ }
+ /* This covers additionally negative dependencies, which aren't arch-specific,
+ but change architecture nonetheless as a Conflicts: foo does applies for all archs */
+ bool IsImplicit() const APT_PURE;
+
bool IsSatisfied(VerIterator const &Ver) const APT_PURE;
bool IsSatisfied(PrvIterator const &Prv) const APT_PURE;
void GlobOr(DepIterator &Start,DepIterator &End);
{
map_stringitem_t &Version;
map_pointer_t &Package;
- should_be_map_id_t &ID;
+ map_id_t &ID;
unsigned char &Type;
unsigned char &CompareOp;
map_pointer_t &ParentVer;
map_pointer_t &DependencyData;
map_pointer_t &NextRevDepends;
map_pointer_t &NextDepends;
+ map_pointer_t &NextData;
DependencyProxy const * operator->() const { return this; }
DependencyProxy * operator->() { return this; }
};
- inline DependencyProxy operator->() const {return { S2->Version, S2->Package, S->ID, S2->Type, S2->CompareOp, S->ParentVer, S->DependencyData, S->NextRevDepends, S->NextDepends };}
- inline DependencyProxy operator->() {return { S2->Version, S2->Package, S->ID, S2->Type, S2->CompareOp, S->ParentVer, S->DependencyData, S->NextRevDepends, S->NextDepends };}
+ inline DependencyProxy operator->() const {return (DependencyProxy) { S2->Version, S2->Package, S->ID, S2->Type, S2->CompareOp, S->ParentVer, S->DependencyData, S->NextRevDepends, S->NextDepends, S2->NextData };}
+ inline DependencyProxy operator->() {return (DependencyProxy) { S2->Version, S2->Package, S->ID, S2->Type, S2->CompareOp, S->ParentVer, S->DependencyData, S->NextRevDepends, S->NextDepends, S2->NextData };}
void ReMap(void const * const oldMap, void const * const newMap)
{
Iterator<Dependency, DepIterator>::ReMap(oldMap, newMap);
inline VerIterator OwnerVer() const {return VerIterator(*Owner,Owner->VerP + S->Version);}
inline PkgIterator OwnerPkg() const {return PkgIterator(*Owner,Owner->PkgP + Owner->VerP[S->Version].ParentPkg);}
- bool IsMultiArchImplicit() const APT_PURE;
+ /* MultiArch can be translated to SingleArch for an resolver and we did so,
+ by adding provides to help the resolver understand the problem, but
+ sometimes it is needed to identify these to ignore them… */
+ bool IsMultiArchImplicit() const APT_PURE
+ { return (S->Flags & pkgCache::Flag::MultiArchImplicit) == pkgCache::Flag::MultiArchImplicit; }
+
inline PrvIterator() : Iterator<Provides, PrvIterator>(), Type(PrvVer) {}
inline PrvIterator(pkgCache &Owner, Provides *Trg, Version*) :
{return VerFileIterator(*Owner,Owner->VerFileP + S->FileList);}
inline pkgCache::DescFileIterator pkgCache::DescIterator::FileList() const
{return DescFileIterator(*Owner,Owner->DescFileP + S->FileList);}
+APT_DEPRECATED_MSG("Use the .Section method of VerIterator instead") inline const char * pkgCache::PkgIterator::Section() const
+ {return S->VersionList == 0 ? 0 : VersionList().Section();}
/*}}}*/
#endif