// Copyright 2014 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. //! Code to save/load the dep-graph from files. use rustc::dep_graph::DepNode; use rustc::hir::def_id::DefId; use rustc::hir::svh::Svh; use rustc::session::Session; use rustc::ty::TyCtxt; use rustc_data_structures::fx::{FxHashSet, FxHashMap}; use rustc_serialize::Decodable as RustcDecodable; use rustc_serialize::opaque::Decoder; use std::path::{Path}; use IncrementalHashesMap; use ich::Fingerprint; use super::data::*; use super::directory::*; use super::dirty_clean; use super::hash::*; use super::fs::*; use super::file_format; use super::work_product; pub type DirtyNodes = FxHashSet>; /// If we are in incremental mode, and a previous dep-graph exists, /// then load up those nodes/edges that are still valid into the /// dep-graph for this session. (This is assumed to be running very /// early in compilation, before we've really done any work, but /// actually it doesn't matter all that much.) See `README.md` for /// more general overview. pub fn load_dep_graph<'a, 'tcx>(tcx: TyCtxt<'a, 'tcx, 'tcx>, incremental_hashes_map: &IncrementalHashesMap) { if tcx.sess.opts.incremental.is_none() { return; } match prepare_session_directory(tcx) { Ok(true) => { // We successfully allocated a session directory and there is // something in it to load, so continue } Ok(false) => { // We successfully allocated a session directory, but there is no // dep-graph data in it to load (because this is the first // compilation session with this incr. comp. dir.) return } Err(()) => { // Something went wrong while trying to allocate the session // directory. Don't try to use it any further. return } } let _ignore = tcx.dep_graph.in_ignore(); load_dep_graph_if_exists(tcx, incremental_hashes_map); } fn load_dep_graph_if_exists<'a, 'tcx>(tcx: TyCtxt<'a, 'tcx, 'tcx>, incremental_hashes_map: &IncrementalHashesMap) { let dep_graph_path = dep_graph_path(tcx.sess); let dep_graph_data = match load_data(tcx.sess, &dep_graph_path) { Some(p) => p, None => return // no file }; let work_products_path = work_products_path(tcx.sess); let work_products_data = match load_data(tcx.sess, &work_products_path) { Some(p) => p, None => return // no file }; match decode_dep_graph(tcx, incremental_hashes_map, &dep_graph_data, &work_products_data) { Ok(dirty_nodes) => dirty_nodes, Err(err) => { tcx.sess.warn( &format!("decoding error in dep-graph from `{}` and `{}`: {}", dep_graph_path.display(), work_products_path.display(), err)); } } } fn load_data(sess: &Session, path: &Path) -> Option> { match file_format::read_file(sess, path) { Ok(Some(data)) => return Some(data), Ok(None) => { // The file either didn't exist or was produced by an incompatible // compiler version. Neither is an error. } Err(err) => { sess.err( &format!("could not load dep-graph from `{}`: {}", path.display(), err)); } } if let Err(err) = delete_all_session_dir_contents(sess) { sess.err(&format!("could not clear incompatible incremental \ compilation session directory `{}`: {}", path.display(), err)); } None } /// Decode the dep graph and load the edges/nodes that are still clean /// into `tcx.dep_graph`. pub fn decode_dep_graph<'a, 'tcx>(tcx: TyCtxt<'a, 'tcx, 'tcx>, incremental_hashes_map: &IncrementalHashesMap, dep_graph_data: &[u8], work_products_data: &[u8]) -> Result<(), String> { // Decode the list of work_products let mut work_product_decoder = Decoder::new(work_products_data, 0); let work_products = >::decode(&mut work_product_decoder)?; // Deserialize the directory and dep-graph. let mut dep_graph_decoder = Decoder::new(dep_graph_data, 0); let prev_commandline_args_hash = u64::decode(&mut dep_graph_decoder)?; if prev_commandline_args_hash != tcx.sess.opts.dep_tracking_hash() { if tcx.sess.opts.debugging_opts.incremental_info { println!("incremental: completely ignoring cache because of \ differing commandline arguments"); } // We can't reuse the cache, purge it. debug!("decode_dep_graph: differing commandline arg hashes"); for swp in work_products { delete_dirty_work_product(tcx, swp); } // No need to do any further work return Ok(()); } let directory = DefIdDirectory::decode(&mut dep_graph_decoder)?; let serialized_dep_graph = SerializedDepGraph::decode(&mut dep_graph_decoder)?; // Retrace the paths in the directory to find their current location (if any). let retraced = directory.retrace(tcx); // Compute the set of Hir nodes whose data has changed or which // have been removed. These are "raw" source nodes, which means // that they still use the original `DefPathIndex` values from the // encoding, rather than having been retraced to a `DefId`. The // reason for this is that this way we can include nodes that have // been removed (which no longer have a `DefId` in the current // compilation). let dirty_raw_source_nodes = dirty_nodes(tcx, incremental_hashes_map, &serialized_dep_graph.hashes, &retraced); // Create a list of (raw-source-node -> // retracted-target-node) edges. In the process of retracing the // target nodes, we may discover some of them def-paths no longer exist, // in which case there is no need to mark the corresopnding nodes as dirty // (they are just not present). So this list may be smaller than the original. // // Note though that in the common case the target nodes are // `DepNode::WorkProduct` instances, and those don't have a // def-id, so they will never be considered to not exist. Instead, // we do a secondary hashing step (later, in trans) when we know // the set of symbols that go into a work-product: if any symbols // have been removed (or added) the hash will be different and // we'll ignore the work-product then. let retraced_edges: Vec<_> = serialized_dep_graph.edges.iter() .filter_map(|&(ref raw_source_node, ref raw_target_node)| { retraced.map(raw_target_node) .map(|target_node| (raw_source_node, target_node)) }) .collect(); // Compute which work-products have an input that has changed or // been removed. Put the dirty ones into a set. let mut dirty_target_nodes = FxHashSet(); for &(raw_source_node, ref target_node) in &retraced_edges { if dirty_raw_source_nodes.contains(raw_source_node) { if !dirty_target_nodes.contains(target_node) { dirty_target_nodes.insert(target_node.clone()); if tcx.sess.opts.debugging_opts.incremental_info { // It'd be nice to pretty-print these paths better than just // using the `Debug` impls, but wev. println!("incremental: module {:?} is dirty because {:?} \ changed or was removed", target_node, raw_source_node.map_def(|&index| { Some(directory.def_path_string(tcx, index)) }).unwrap()); } } } } // For work-products that are still clean, add their deps into the // graph. This is needed because later we will have to save this // back out again! let dep_graph = tcx.dep_graph.clone(); for (raw_source_node, target_node) in retraced_edges { if dirty_target_nodes.contains(&target_node) { continue; } let source_node = retraced.map(raw_source_node).unwrap(); debug!("decode_dep_graph: clean edge: {:?} -> {:?}", source_node, target_node); let _task = dep_graph.in_task(target_node); dep_graph.read(source_node); } // Add in work-products that are still clean, and delete those that are // dirty. reconcile_work_products(tcx, work_products, &dirty_target_nodes); dirty_clean::check_dirty_clean_annotations(tcx, &dirty_raw_source_nodes, &retraced); load_prev_metadata_hashes(tcx, &retraced, &mut *incremental_hashes_map.prev_metadata_hashes.borrow_mut()); Ok(()) } /// Computes which of the original set of def-ids are dirty. Stored in /// a bit vector where the index is the DefPathIndex. fn dirty_nodes<'a, 'tcx>(tcx: TyCtxt<'a, 'tcx, 'tcx>, incremental_hashes_map: &IncrementalHashesMap, serialized_hashes: &[SerializedHash], retraced: &RetracedDefIdDirectory) -> DirtyNodes { let mut hcx = HashContext::new(tcx, incremental_hashes_map); let mut dirty_nodes = FxHashSet(); for hash in serialized_hashes { if let Some(dep_node) = retraced.map(&hash.dep_node) { let current_hash = hcx.hash(&dep_node).unwrap(); if current_hash == hash.hash { debug!("initial_dirty_nodes: {:?} is clean (hash={:?})", dep_node.map_def(|&def_id| Some(tcx.def_path(def_id))).unwrap(), current_hash); continue; } if tcx.sess.opts.debugging_opts.incremental_dump_hash { println!("node {:?} is dirty as hash is {:?} was {:?}", dep_node.map_def(|&def_id| Some(tcx.def_path(def_id))).unwrap(), current_hash, hash.hash); } debug!("initial_dirty_nodes: {:?} is dirty as hash is {:?}, was {:?}", dep_node.map_def(|&def_id| Some(tcx.def_path(def_id))).unwrap(), current_hash, hash.hash); } else { if tcx.sess.opts.debugging_opts.incremental_dump_hash { println!("node {:?} is dirty as it was removed", hash.dep_node); } debug!("initial_dirty_nodes: {:?} is dirty as it was removed", hash.dep_node); } dirty_nodes.insert(hash.dep_node.clone()); } dirty_nodes } /// Go through the list of work-products produced in the previous run. /// Delete any whose nodes have been found to be dirty or which are /// otherwise no longer applicable. fn reconcile_work_products<'a, 'tcx>(tcx: TyCtxt<'a, 'tcx, 'tcx>, work_products: Vec, dirty_target_nodes: &FxHashSet>) { debug!("reconcile_work_products({:?})", work_products); for swp in work_products { if dirty_target_nodes.contains(&DepNode::WorkProduct(swp.id.clone())) { debug!("reconcile_work_products: dep-node for {:?} is dirty", swp); delete_dirty_work_product(tcx, swp); } else { let mut all_files_exist = true; for &(_, ref file_name) in swp.work_product.saved_files.iter() { let path = in_incr_comp_dir_sess(tcx.sess, file_name); if !path.exists() { all_files_exist = false; if tcx.sess.opts.debugging_opts.incremental_info { println!("incremental: could not find file for up-to-date work product: {}", path.display()); } } } if all_files_exist { debug!("reconcile_work_products: all files for {:?} exist", swp); tcx.dep_graph.insert_previous_work_product(&swp.id, swp.work_product); } else { debug!("reconcile_work_products: some file for {:?} does not exist", swp); delete_dirty_work_product(tcx, swp); } } } } fn delete_dirty_work_product(tcx: TyCtxt, swp: SerializedWorkProduct) { debug!("delete_dirty_work_product({:?})", swp); work_product::delete_workproduct_files(tcx.sess, &swp.work_product); } fn load_prev_metadata_hashes(tcx: TyCtxt, retraced: &RetracedDefIdDirectory, output: &mut FxHashMap) { if !tcx.sess.opts.debugging_opts.query_dep_graph { return } debug!("load_prev_metadata_hashes() - Loading previous metadata hashes"); let file_path = metadata_hash_export_path(tcx.sess); if !file_path.exists() { debug!("load_prev_metadata_hashes() - Couldn't find file containing \ hashes at `{}`", file_path.display()); return } debug!("load_prev_metadata_hashes() - File: {}", file_path.display()); let data = match file_format::read_file(tcx.sess, &file_path) { Ok(Some(data)) => data, Ok(None) => { debug!("load_prev_metadata_hashes() - File produced by incompatible \ compiler version: {}", file_path.display()); return } Err(err) => { debug!("load_prev_metadata_hashes() - Error reading file `{}`: {}", file_path.display(), err); return } }; debug!("load_prev_metadata_hashes() - Decoding hashes"); let mut decoder = Decoder::new(&data, 0); let _ = Svh::decode(&mut decoder).unwrap(); let serialized_hashes = SerializedMetadataHashes::decode(&mut decoder).unwrap(); debug!("load_prev_metadata_hashes() - Mapping DefIds"); assert_eq!(serialized_hashes.index_map.len(), serialized_hashes.hashes.len()); for serialized_hash in serialized_hashes.hashes { let def_path_index = serialized_hashes.index_map[&serialized_hash.def_index]; if let Some(def_id) = retraced.def_id(def_path_index) { let old = output.insert(def_id, serialized_hash.hash); assert!(old.is_none(), "already have hash for {:?}", def_id); } } debug!("load_prev_metadata_hashes() - successfully loaded {} hashes", serialized_hashes.index_map.len()); }