#ifndef PERSISTENT_DATA_DATA_STRUCTURES_DAMAGE_VISITOR_H #define PERSISTENT_DATA_DATA_STRUCTURES_DAMAGE_VISITOR_H #include "persistent-data/data-structures/btree.h" #include "persistent-data/range.h" //---------------------------------------------------------------- namespace persistent_data { namespace btree_detail { struct damage { typedef boost::shared_ptr ptr; damage(range lost_keys, std::string const &desc) : lost_keys_(lost_keys), desc_(desc) { } range lost_keys_; std::string desc_; }; inline std::ostream &operator <<(std::ostream &out, damage const &d) { out << "btree damage[lost_keys = " << d.lost_keys_ << ", \"" << d.desc_ << "\"]"; return out; } // Tracks damage in a single level btree. Use multiple // trackers if you have a multilayer tree. class damage_tracker { public: damage_tracker() : damaged_(false), damage_begin_(0) { } typedef range range64; typedef boost::optional maybe_range64; void bad_node() { damaged_ = true; } maybe_range64 good_internal(block_address begin) { maybe_range64 r; if (damaged_) { r = maybe_range64(range64(damage_begin_, begin)); damaged_ = false; } damage_begin_ = begin; return r; } // remember 'end' is the one-past-the-end value, so // take the last key in the leaf and add one. maybe_range64 good_leaf(block_address begin, block_address end) { maybe_range64 r; if (damaged_) { r = maybe_range64(range64(damage_begin_, begin)); damaged_ = false; } damage_begin_ = end; return r; } maybe_range64 end() { if (damaged_) return maybe_range64(damage_begin_); else return maybe_range64(); } private: bool damaged_; block_address damage_begin_; }; // As we walk a btree we need to know if we've moved into a // different sub tree (by looking at the btree_path). class path_tracker { public: // returns the old path if the tree has changed. boost::optional next_path(btree_path const &p) { if (p != path_) { btree_path tmp(path_); path_ = p; return boost::optional(tmp); } return boost::optional(); } btree_path const ¤t_path() const { return path_; } private: btree_path path_; }; //---------------------------------------------------------------- // This class implements consistency checking for the btrees. It // also allows the caller to visit all accessible values. // Derive from this if you want some additional checks. It's worth // summarising what is checked: // // Implemented // ----------- // // - block_nr // - nr_entries < max_entries // - max_entries fits in block // - max_entries is divisible by 3 // - nr_entries > minimum (except for root nodes) // // Not implemented // --------------- // // - leaf | internal flags (this can be inferred from siblings) //---------------------------------------------------------------- template class btree_damage_visitor : public btree::visitor { public: typedef btree_detail::node_location node_location; typedef range range64; typedef boost::optional maybe_range64; btree_damage_visitor(block_counter &counter, ValueVisitor &value_visitor, DamageVisitor &damage_visitor) : counter_(counter), avoid_repeated_visits_(true), value_visitor_(value_visitor), damage_visitor_(damage_visitor) { } bool visit_internal(node_location const &loc, btree_detail::node_ref const &n) { update_path(loc.path); return check_internal(loc, n); } bool visit_internal_leaf(node_location const &loc, btree_detail::node_ref const &n) { update_path(loc.path); return check_leaf(loc, n); } bool visit_leaf(node_location const &loc, btree_detail::node_ref const &n) { update_path(loc.path); bool r = check_leaf(loc, n); // If anything goes wrong with the checks, we skip // the value visiting. if (!r) return false; visit_values(loc.path, n); return true; } void visit_complete() { end_walk(); } typedef typename btree::visitor::error_outcome error_outcome; error_outcome error_accessing_node(node_location const &l, block_address b, std::string const &what) { report_damage(what); return btree::visitor::EXCEPTION_HANDLED; } private: void visit_values(btree_path const &path, node_ref const &n) { unsigned nr = n.get_nr_entries(); for (unsigned i = 0; i < nr; i++) { btree_path p2(path); p2.push_back(n.key_at(i)); value_visitor_.visit(p2, n.value_at(i)); } } bool check_internal(node_location const &loc, btree_detail::node_ref const &n) { if (!already_visited(n) && check_block_nr(n) && check_max_entries(n) && check_nr_entries(n, loc.is_sub_root()) && check_ordered_keys(n) && check_parent_key(loc.is_sub_root() ? optional() : loc.key, n)) { if (loc.is_sub_root()) new_root(loc.level()); good_internal(n.key_at(0)); return true; } return false; } template bool check_leaf(node_location const &loc, btree_detail::node_ref const &n) { if (!already_visited(n) && check_block_nr(n) && check_max_entries(n) && check_nr_entries(n, loc.is_sub_root()) && check_ordered_keys(n) && check_parent_key(loc.is_sub_root() ? optional() : loc.key, n)) { if (loc.is_sub_root()) new_root(loc.level()); bool r = check_leaf_key(loc.level(), n); if (r && n.get_nr_entries() > 0) good_leaf(n.key_at(0), n.key_at(n.get_nr_entries() - 1) + 1); return r; } return false; } template bool already_visited(node const &n) { block_address b = n.get_location(); counter_.inc(b); if (avoid_repeated_visits_) { if (seen_.count(b) > 0) return true; seen_.insert(b); } return false; } template bool check_block_nr(node const &n) { if (n.get_location() != n.get_block_nr()) { std::ostringstream out; out << "block number mismatch: actually " << n.get_location() << ", claims " << n.get_block_nr(); report_damage(out.str()); return false; } return true; } template bool check_max_entries(node const &n) { size_t elt_size = sizeof(uint64_t) + n.get_value_size(); if (elt_size * n.get_max_entries() + sizeof(node_header) > MD_BLOCK_SIZE) { std::ostringstream out; out << "max entries too large: " << n.get_max_entries(); report_damage(out.str()); return false; } if (n.get_max_entries() % 3) { std::ostringstream out; out << "max entries is not divisible by 3: " << n.get_max_entries(); report_damage(out.str()); return false; } return true; } template bool check_nr_entries(node const &n, bool is_root) { if (n.get_nr_entries() > n.get_max_entries()) { std::ostringstream out; out << "bad nr_entries: " << n.get_nr_entries() << " < " << n.get_max_entries(); report_damage(out.str()); return false; } block_address min = n.get_max_entries() / 3; if (!is_root && (n.get_nr_entries() < min)) { ostringstream out; out << "too few entries in btree_node: " << n.get_nr_entries() << ", expected at least " << min << "(max_entries = " << n.get_max_entries() << ")"; report_damage(out.str()); return false; } return true; } template bool check_ordered_keys(node const &n) { unsigned nr_entries = n.get_nr_entries(); if (nr_entries == 0) return true; // can only happen if a root node uint64_t last_key = n.key_at(0); for (unsigned i = 1; i < nr_entries; i++) { uint64_t k = n.key_at(i); if (k <= last_key) { ostringstream out; out << "keys are out of order, " << k << " <= " << last_key; report_damage(out.str()); return false; } last_key = k; } return true; } template bool check_parent_key(boost::optional key, node const &n) { if (!key) return true; if (*key > n.key_at(0)) { ostringstream out; out << "parent key mismatch: parent was " << *key << ", but lowest in node was " << n.key_at(0); report_damage(out.str()); return false; } return true; } template bool check_leaf_key(unsigned level, node const &n) { if (n.get_nr_entries() == 0) return true; // can only happen if a root node if (last_leaf_key_[level] && *last_leaf_key_[level] >= n.key_at(0)) { ostringstream out; out << "the last key of the previous leaf was " << *last_leaf_key_[level] << " and the first key of this leaf is " << n.key_at(0); report_damage(out.str()); return false; } last_leaf_key_[level] = n.key_at(n.get_nr_entries() - 1); return true; } void new_root(unsigned level) { // we're starting a new subtree, so should // reset the last_leaf value. last_leaf_key_[level] = boost::optional(); } //-------------------------------- // damage tracking void report_damage(std::string const &desc) { damage_reasons_.push_back(desc); dt_.bad_node(); } void good_internal(block_address b) { maybe_range64 mr = dt_.good_internal(b); if (mr) issue_damage(path_tracker_.current_path(), *mr); } void good_leaf(block_address b, block_address e) { maybe_range64 mr = dt_.good_leaf(b, e); if (mr) issue_damage(path_tracker_.current_path(), *mr); } void end_walk() { maybe_issue_damage(path_tracker_.current_path()); } void issue_damage(btree_path const &path, range64 const &r) { damage d(r, build_damage_desc()); clear_damage_desc(); damage_visitor_.visit(path, d); } std::string build_damage_desc() const { std::string r; std::list::const_iterator it, end = damage_reasons_.end(); for (it = damage_reasons_.begin(); it != end; ++it) r += *it; return r; } void clear_damage_desc() { damage_reasons_.clear(); } void maybe_issue_damage(btree_path const &path) { maybe_range64 mr = dt_.end(); if (mr) issue_damage(path, *mr); } void update_path(btree_path const &path) { boost::optional old_path = path_tracker_.next_path(path); if (old_path) // we need to emit any errors that // were accrued against the old // path. maybe_issue_damage(*old_path); } //-------------------------------- block_counter &counter_; bool avoid_repeated_visits_; ValueVisitor &value_visitor_; DamageVisitor &damage_visitor_; std::set seen_; boost::optional last_leaf_key_[Levels]; path_tracker path_tracker_; damage_tracker dt_; std::list damage_reasons_; }; } template void btree_visit_values(btree const &tree, block_counter &counter, ValueVisitor &value_visitor, DamageVisitor &damage_visitor) { btree_detail::btree_damage_visitor v(counter, value_visitor, damage_visitor); tree.visit_depth_first(v); } } //---------------------------------------------------------------- #endif