//! Resolution of mixing rlibs and dylibs //! //! When producing a final artifact, such as a dynamic library, the compiler has //! a choice between linking an rlib or linking a dylib of all upstream //! dependencies. The linking phase must guarantee, however, that a library only //! show up once in the object file. For example, it is illegal for library A to //! be statically linked to B and C in separate dylibs, and then link B and C //! into a crate D (because library A appears twice). //! //! The job of this module is to calculate what format each upstream crate //! should be used when linking each output type requested in this session. This //! generally follows this set of rules: //! //! 1. Each library must appear exactly once in the output. //! 2. Each rlib contains only one library (it's just an object file) //! 3. Each dylib can contain more than one library (due to static linking), //! and can also bring in many dynamic dependencies. //! //! With these constraints in mind, it's generally a very difficult problem to //! find a solution that's not "all rlibs" or "all dylibs". I have suspicions //! that NP-ness may come into the picture here... //! //! The current selection algorithm below looks mostly similar to: //! //! 1. If static linking is required, then require all upstream dependencies //! to be available as rlibs. If not, generate an error. //! 2. If static linking is requested (generating an executable), then //! attempt to use all upstream dependencies as rlibs. If any are not //! found, bail out and continue to step 3. //! 3. Static linking has failed, at least one library must be dynamically //! linked. Apply a heuristic by greedily maximizing the number of //! dynamically linked libraries. //! 4. Each upstream dependency available as a dynamic library is //! registered. The dependencies all propagate, adding to a map. It is //! possible for a dylib to add a static library as a dependency, but it //! is illegal for two dylibs to add the same static library as a //! dependency. The same dylib can be added twice. Additionally, it is //! illegal to add a static dependency when it was previously found as a //! dylib (and vice versa) //! 5. After all dynamic dependencies have been traversed, re-traverse the //! remaining dependencies and add them statically (if they haven't been //! added already). //! //! While not perfect, this algorithm should help support use-cases such as leaf //! dependencies being static while the larger tree of inner dependencies are //! all dynamic. This isn't currently very well battle tested, so it will likely //! fall short in some use cases. //! //! Currently, there is no way to specify the preference of linkage with a //! particular library (other than a global dynamic/static switch). //! Additionally, the algorithm is geared towards finding *any* solution rather //! than finding a number of solutions (there are normally quite a few). use crate::creader::CStore; use crate::errors::{ BadPanicStrategy, CrateDepMultiple, IncompatiblePanicInDropStrategy, LibRequired, RequiredPanicStrategy, RlibRequired, RustcLibRequired, TwoPanicRuntimes, }; use rustc_data_structures::fx::FxHashMap; use rustc_hir::def_id::CrateNum; use rustc_middle::middle::dependency_format::{Dependencies, DependencyList, Linkage}; use rustc_middle::ty::TyCtxt; use rustc_session::config::CrateType; use rustc_session::cstore::CrateDepKind; use rustc_session::cstore::LinkagePreference::{self, RequireDynamic, RequireStatic}; pub(crate) fn calculate(tcx: TyCtxt<'_>) -> Dependencies { tcx.sess .crate_types() .iter() .map(|&ty| { let linkage = calculate_type(tcx, ty); verify_ok(tcx, &linkage); (ty, linkage) }) .collect::>() } fn calculate_type(tcx: TyCtxt<'_>, ty: CrateType) -> DependencyList { let sess = &tcx.sess; if !sess.opts.output_types.should_codegen() { return Vec::new(); } let preferred_linkage = match ty { // Generating a dylib without `-C prefer-dynamic` means that we're going // to try to eagerly statically link all dependencies. This is normally // done for end-product dylibs, not intermediate products. // // Treat cdylibs similarly. If `-C prefer-dynamic` is set, the caller may // be code-size conscious, but without it, it makes sense to statically // link a cdylib. CrateType::Dylib | CrateType::Cdylib if !sess.opts.cg.prefer_dynamic => Linkage::Static, CrateType::Dylib | CrateType::Cdylib => Linkage::Dynamic, // If the global prefer_dynamic switch is turned off, or the final // executable will be statically linked, prefer static crate linkage. CrateType::Executable if !sess.opts.cg.prefer_dynamic || sess.crt_static(Some(ty)) => { Linkage::Static } CrateType::Executable => Linkage::Dynamic, // proc-macro crates are mostly cdylibs, but we also need metadata. CrateType::ProcMacro => Linkage::Static, // No linkage happens with rlibs, we just needed the metadata (which we // got long ago), so don't bother with anything. CrateType::Rlib => Linkage::NotLinked, // staticlibs must have all static dependencies. CrateType::Staticlib => Linkage::Static, }; if preferred_linkage == Linkage::NotLinked { // If the crate is not linked, there are no link-time dependencies. return Vec::new(); } if preferred_linkage == Linkage::Static { // Attempt static linkage first. For dylibs and executables, we may be // able to retry below with dynamic linkage. if let Some(v) = attempt_static(tcx) { return v; } // Staticlibs and static executables must have all static dependencies. // If any are not found, generate some nice pretty errors. if ty == CrateType::Staticlib || (ty == CrateType::Executable && sess.crt_static(Some(ty)) && !sess.target.crt_static_allows_dylibs) { for &cnum in tcx.crates(()).iter() { if tcx.dep_kind(cnum).macros_only() { continue; } let src = tcx.used_crate_source(cnum); if src.rlib.is_some() { continue; } sess.emit_err(RlibRequired { crate_name: tcx.crate_name(cnum) }); } return Vec::new(); } } let mut formats = FxHashMap::default(); // Sweep all crates for found dylibs. Add all dylibs, as well as their // dependencies, ensuring there are no conflicts. The only valid case for a // dependency to be relied upon twice is for both cases to rely on a dylib. for &cnum in tcx.crates(()).iter() { if tcx.dep_kind(cnum).macros_only() { continue; } let name = tcx.crate_name(cnum); let src = tcx.used_crate_source(cnum); if src.dylib.is_some() { info!("adding dylib: {}", name); add_library(tcx, cnum, RequireDynamic, &mut formats); let deps = tcx.dylib_dependency_formats(cnum); for &(depnum, style) in deps.iter() { info!("adding {:?}: {}", style, tcx.crate_name(depnum)); add_library(tcx, depnum, style, &mut formats); } } } // Collect what we've got so far in the return vector. let last_crate = tcx.crates(()).len(); let mut ret = (1..last_crate + 1) .map(|cnum| match formats.get(&CrateNum::new(cnum)) { Some(&RequireDynamic) => Linkage::Dynamic, Some(&RequireStatic) => Linkage::IncludedFromDylib, None => Linkage::NotLinked, }) .collect::>(); // Run through the dependency list again, and add any missing libraries as // static libraries. // // If the crate hasn't been included yet and it's not actually required // (e.g., it's an allocator) then we skip it here as well. for &cnum in tcx.crates(()).iter() { let src = tcx.used_crate_source(cnum); if src.dylib.is_none() && !formats.contains_key(&cnum) && tcx.dep_kind(cnum) == CrateDepKind::Explicit { assert!(src.rlib.is_some() || src.rmeta.is_some()); info!("adding staticlib: {}", tcx.crate_name(cnum)); add_library(tcx, cnum, RequireStatic, &mut formats); ret[cnum.as_usize() - 1] = Linkage::Static; } } // We've gotten this far because we're emitting some form of a final // artifact which means that we may need to inject dependencies of some // form. // // Things like allocators and panic runtimes may not have been activated // quite yet, so do so here. activate_injected_dep(CStore::from_tcx(tcx).injected_panic_runtime(), &mut ret, &|cnum| { tcx.is_panic_runtime(cnum) }); // When dylib B links to dylib A, then when using B we must also link to A. // It could be the case, however, that the rlib for A is present (hence we // found metadata), but the dylib for A has since been removed. // // For situations like this, we perform one last pass over the dependencies, // making sure that everything is available in the requested format. for (cnum, kind) in ret.iter().enumerate() { let cnum = CrateNum::new(cnum + 1); let src = tcx.used_crate_source(cnum); match *kind { Linkage::NotLinked | Linkage::IncludedFromDylib => {} Linkage::Static if src.rlib.is_some() => continue, Linkage::Dynamic if src.dylib.is_some() => continue, kind => { let kind = match kind { Linkage::Static => "rlib", _ => "dylib", }; let crate_name = tcx.crate_name(cnum); if crate_name.as_str().starts_with("rustc_") { sess.emit_err(RustcLibRequired { crate_name, kind }); } else { sess.emit_err(LibRequired { crate_name, kind }); } } } } ret } fn add_library( tcx: TyCtxt<'_>, cnum: CrateNum, link: LinkagePreference, m: &mut FxHashMap, ) { match m.get(&cnum) { Some(&link2) => { // If the linkages differ, then we'd have two copies of the library // if we continued linking. If the linkages are both static, then we // would also have two copies of the library (static from two // different locations). // // This error is probably a little obscure, but I imagine that it // can be refined over time. if link2 != link || link == RequireStatic { tcx.sess.emit_err(CrateDepMultiple { crate_name: tcx.crate_name(cnum) }); } } None => { m.insert(cnum, link); } } } fn attempt_static(tcx: TyCtxt<'_>) -> Option { let all_crates_available_as_rlib = tcx .crates(()) .iter() .copied() .filter_map(|cnum| { if tcx.dep_kind(cnum).macros_only() { return None; } Some(tcx.used_crate_source(cnum).rlib.is_some()) }) .all(|is_rlib| is_rlib); if !all_crates_available_as_rlib { return None; } // All crates are available in an rlib format, so we're just going to link // everything in explicitly so long as it's actually required. let mut ret = tcx .crates(()) .iter() .map(|&cnum| { if tcx.dep_kind(cnum) == CrateDepKind::Explicit { Linkage::Static } else { Linkage::NotLinked } }) .collect::>(); // Our allocator/panic runtime may not have been linked above if it wasn't // explicitly linked, which is the case for any injected dependency. Handle // that here and activate them. activate_injected_dep(CStore::from_tcx(tcx).injected_panic_runtime(), &mut ret, &|cnum| { tcx.is_panic_runtime(cnum) }); Some(ret) } // Given a list of how to link upstream dependencies so far, ensure that an // injected dependency is activated. This will not do anything if one was // transitively included already (e.g., via a dylib or explicitly so). // // If an injected dependency was not found then we're guaranteed the // metadata::creader module has injected that dependency (not listed as // a required dependency) in one of the session's field. If this field is not // set then this compilation doesn't actually need the dependency and we can // also skip this step entirely. fn activate_injected_dep( injected: Option, list: &mut DependencyList, replaces_injected: &dyn Fn(CrateNum) -> bool, ) { for (i, slot) in list.iter().enumerate() { let cnum = CrateNum::new(i + 1); if !replaces_injected(cnum) { continue; } if *slot != Linkage::NotLinked { return; } } if let Some(injected) = injected { let idx = injected.as_usize() - 1; assert_eq!(list[idx], Linkage::NotLinked); list[idx] = Linkage::Static; } } // After the linkage for a crate has been determined we need to verify that // there's only going to be one allocator in the output. fn verify_ok(tcx: TyCtxt<'_>, list: &[Linkage]) { let sess = &tcx.sess; if list.is_empty() { return; } let mut panic_runtime = None; for (i, linkage) in list.iter().enumerate() { if let Linkage::NotLinked = *linkage { continue; } let cnum = CrateNum::new(i + 1); if tcx.is_panic_runtime(cnum) { if let Some((prev, _)) = panic_runtime { let prev_name = tcx.crate_name(prev); let cur_name = tcx.crate_name(cnum); sess.emit_err(TwoPanicRuntimes { prev_name, cur_name }); } panic_runtime = Some(( cnum, tcx.required_panic_strategy(cnum).unwrap_or_else(|| { bug!("cannot determine panic strategy of a panic runtime"); }), )); } } // If we found a panic runtime, then we know by this point that it's the // only one, but we perform validation here that all the panic strategy // compilation modes for the whole DAG are valid. if let Some((runtime_cnum, found_strategy)) = panic_runtime { let desired_strategy = sess.panic_strategy(); // First up, validate that our selected panic runtime is indeed exactly // our same strategy. if found_strategy != desired_strategy { sess.emit_err(BadPanicStrategy { runtime: tcx.crate_name(runtime_cnum), strategy: desired_strategy, }); } // Next up, verify that all other crates are compatible with this panic // strategy. If the dep isn't linked, we ignore it, and if our strategy // is abort then it's compatible with everything. Otherwise all crates' // panic strategy must match our own. for (i, linkage) in list.iter().enumerate() { if let Linkage::NotLinked = *linkage { continue; } let cnum = CrateNum::new(i + 1); if cnum == runtime_cnum || tcx.is_compiler_builtins(cnum) { continue; } if let Some(found_strategy) = tcx.required_panic_strategy(cnum) && desired_strategy != found_strategy { sess.emit_err(RequiredPanicStrategy { crate_name: tcx.crate_name(cnum), found_strategy, desired_strategy}); } let found_drop_strategy = tcx.panic_in_drop_strategy(cnum); if tcx.sess.opts.unstable_opts.panic_in_drop != found_drop_strategy { sess.emit_err(IncompatiblePanicInDropStrategy { crate_name: tcx.crate_name(cnum), found_strategy: found_drop_strategy, desired_strategy: tcx.sess.opts.unstable_opts.panic_in_drop, }); } } } }