// Copyright 2021 The Abseil Authors // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // https://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #ifndef ABSL_STRINGS_INTERNAL_CORD_REP_BTREE_H_ #define ABSL_STRINGS_INTERNAL_CORD_REP_BTREE_H_ #include #include #include #include "absl/base/config.h" #include "absl/base/internal/raw_logging.h" #include "absl/base/optimization.h" #include "absl/strings/internal/cord_data_edge.h" #include "absl/strings/internal/cord_internal.h" #include "absl/strings/internal/cord_rep_flat.h" #include "absl/strings/string_view.h" #include "absl/types/span.h" namespace absl { ABSL_NAMESPACE_BEGIN namespace cord_internal { // `SetCordBtreeExhaustiveValidation()` can be set to force exhaustive // validation in debug assertions, and code that calls `IsValid()` // explicitly. By default, assertions should be relatively cheap and // AssertValid() can easily lead to O(n^2) complexity as recursive / full tree // validation is O(n). void SetCordBtreeExhaustiveValidation(bool do_exaustive_validation); bool IsCordBtreeExhaustiveValidationEnabled(); class CordRepBtreeNavigator; // CordRepBtree is as the name implies a btree implementation of a Cordrep tree. // Data is stored at the leaf level only, non leaf nodes contain down pointers // only. Allowed types of data edges are FLAT, EXTERNAL and SUBSTRINGs of FLAT // or EXTERNAL nodes. The implementation allows for data to be added to either // end of the tree only, it does not provide any 'insert' logic. This has the // benefit that we can expect good fill ratios: all nodes except the outer // 'legs' will have 100% fill ratios for trees built using Append/Prepend // methods. Merged trees will typically have a fill ratio well above 50% as in a // similar fashion, one side of the merged tree will typically have a 100% fill // ratio, and the 'open' end will average 50%. All operations are O(log(n)) or // better, and the tree never needs balancing. // // All methods accepting a CordRep* or CordRepBtree* adopt a reference on that // input unless explicitly stated otherwise. All functions returning a CordRep* // or CordRepBtree* instance transfer a reference back to the caller. // Simplified, callers both 'donate' and 'consume' a reference count on each // call, simplifying the API. An example of building a tree: // // CordRepBtree* tree = CordRepBtree::Create(MakeFlat("Hello")); // tree = CordRepBtree::Append(tree, MakeFlat("world")); // // In the above example, all inputs are consumed, making each call affecting // `tree` reference count neutral. The returned `tree` value can be different // from the input if the input is shared with other threads, or if the tree // grows in height, but callers typically never have to concern themselves with // that and trust that all methods DTRT at all times. class CordRepBtree : public CordRep { public: // EdgeType identifies `front` and `back` enum values. // Various implementations in CordRepBtree such as `Add` and `Edge` are // generic and templated on operating on either of the boundary edges. // For more information on the possible edges contained in a CordRepBtree // instance see the documentation for `edges_`. enum class EdgeType { kFront, kBack }; // Convenience constants into `EdgeType` static constexpr EdgeType kFront = EdgeType::kFront; static constexpr EdgeType kBack = EdgeType::kBack; // Maximum number of edges: based on experiments and performance data, we can // pick suitable values resulting in optimum cacheline aligned values. The // preferred values are based on 64-bit systems where we aim to align this // class onto 64 bytes, i.e.: 6 = 64 bytes, 14 = 128 bytes, etc. // TODO(b/192061034): experiment with alternative sizes. static constexpr size_t kMaxCapacity = 6; // Reasonable maximum height of the btree. We can expect a fill ratio of at // least 50%: trees are always expanded at the front or back. Concatenating // trees will then typically fold at the top most node, where the lower nodes // are at least at capacity on one side of joined inputs. At a lower fill // rate of 4 edges per node, we have capacity for ~16 million leaf nodes. // We will fail / abort if an application ever exceeds this height, which // should be extremely rare (near impossible) and be an indication of an // application error: we do not assume it reasonable for any application to // operate correctly with such monster trees. // Another compelling reason for the number `12` is that any contextual stack // required for navigation or insertion requires 12 words and 12 bytes, which // fits inside 2 cache lines with some room to spare, and is reasonable as a // local stack variable compared to Cord's current near 400 bytes stack use. // The maximum `height` value of a node is then `kMaxDepth - 1` as node height // values start with a value of 0 for leaf nodes. static constexpr size_t kMaxDepth = 12; // See comments on height() for why this is an int and not a size_t. static constexpr int kMaxHeight = static_cast(kMaxDepth - 1); // `Action` defines the action for unwinding changes done at the btree's leaf // level that need to be propagated up to the parent node(s). Each operation // on a node has an effect / action defined as follows: // - kSelf // The operation (add / update, etc) was performed directly on the node as // the node is private to the current thread (i.e.: not shared directly or // indirectly through a refcount > 1). Changes can be propagated directly to // all parent nodes as all parent nodes are also then private to the current // thread. // - kCopied // The operation (add / update, etc) was performed on a copy of the original // node, as the node is (potentially) directly or indirectly shared with // other threads. Changes need to be propagated into the parent nodes where // the old down pointer must be unreffed and replaced with this new copy. // Such changes to parent nodes may themselves require a copy if the parent // node is also shared. A kCopied action can propagate all the way to the // top node where we then must unref the `tree` input provided by the // caller, and return the new copy. // - kPopped // The operation (typically add) could not be satisfied due to insufficient // capacity in the targeted node, and a new 'leg' was created that needs to // be added into the parent node. For example, adding a FLAT inside a leaf // node that is at capacity will create a new leaf node containing that // FLAT, that needs to be 'popped' up the btree. Such 'pop' actions can // cascade up the tree if parent nodes are also at capacity. A 'Popped' // action propagating all the way to the top of the tree will result in // the tree becoming one level higher than the current tree through a final // `CordRepBtree::New(tree, popped)` call, resulting in a new top node // referencing the old tree and the new (fully popped upwards) 'leg'. enum Action { kSelf, kCopied, kPopped }; // Result of an operation on a node. See the `Action` enum for details. struct OpResult { CordRepBtree* tree; Action action; }; // Return value of the CopyPrefix and CopySuffix methods which can // return a node or data edge at any height inside the tree. // A height of 0 defines the lowest (leaf) node, a height of -1 identifies // `edge` as being a plain data node: EXTERNAL / FLAT or SUBSTRING thereof. struct CopyResult { CordRep* edge; int height; }; // Logical position inside a node: // - index: index of the edge. // - n: size or offset value depending on context. struct Position { size_t index; size_t n; }; // Creates a btree from the given input. Adopts a ref of `rep`. // If the input `rep` is itself a btree, i.e., `IsBtree()`, then this // function immediately returns `rep->btree()`. If the input is a valid data // edge (see IsDataEdge()), then a new leaf node is returned containing `rep` // as the sole data edge. Else, the input is assumed to be a (legacy) concat // tree, and the input is consumed and transformed into a btree(). static CordRepBtree* Create(CordRep* rep); // Destroys the provided tree. Should only be called by cord internal API's, // typically after a ref_count.Decrement() on the last reference count. static void Destroy(CordRepBtree* tree); // Destruction static void Delete(CordRepBtree* tree) { delete tree; } // Use CordRep::Unref() as we overload for absl::Span. using CordRep::Unref; // Unrefs all edges in `edges` which are assumed to be 'likely one'. static void Unref(absl::Span edges); // Appends / Prepends an existing CordRep instance to this tree. // The below methods accept three types of input: // 1) `rep` is a data node (See `IsDataNode` for valid data edges). // `rep` is appended or prepended to this tree 'as is'. // 2) `rep` is a BTREE. // `rep` is merged into `tree` respecting the Append/Prepend order. // 3) `rep` is some other (legacy) type. // `rep` is converted in place and added to `tree` // Requires `tree` and `rep` to be not null. static CordRepBtree* Append(CordRepBtree* tree, CordRep* rep); static CordRepBtree* Prepend(CordRepBtree* tree, CordRep* rep); // Append/Prepend the data in `data` to this tree. // The `extra` parameter defines how much extra capacity should be allocated // for any additional FLAT being allocated. This is an optimization hint from // the caller. For example, a caller may need to add 2 string_views of data // "abc" and "defghi" which are not consecutive. The caller can in this case // invoke `AddData(tree, "abc", 6)`, and any newly added flat is allocated // where possible with at least 6 bytes of extra capacity beyond `length`. // This helps avoiding data getting fragmented over multiple flats. // There is no limit on the size of `data`. If `data` can not be stored inside // a single flat, then the function will iteratively add flats until all data // has been consumed and appended or prepended to the tree. static CordRepBtree* Append(CordRepBtree* tree, string_view data, size_t extra = 0); static CordRepBtree* Prepend(CordRepBtree* tree, string_view data, size_t extra = 0); // Returns a new tree, containing `n` bytes of data from this instance // starting at offset `offset`. Where possible, the returned tree shares // (re-uses) data edges and nodes with this instance to minimize the // combined memory footprint of both trees. // Requires `offset + n <= length`. Returns `nullptr` if `n` is zero. CordRep* SubTree(size_t offset, size_t n); // Removes `n` trailing bytes from `tree`, and returns the resulting tree // or data edge. Returns `tree` if n is zero, and nullptr if n == length. // This function is logically identical to: // result = tree->SubTree(0, tree->length - n); // Unref(tree); // return result; // However, the actual implementation will as much as possible perform 'in // place' modifications on the tree on all nodes and edges that are mutable. // For example, in a fully privately owned tree with the last edge being a // flat of length 12, RemoveSuffix(1) will simply set the length of that data // edge to 11, and reduce the length of all nodes on the edge path by 1. static CordRep* RemoveSuffix(CordRepBtree* tree, size_t n); // Returns the character at the given offset. char GetCharacter(size_t offset) const; // Returns true if this node holds a single data edge, and if so, sets // `fragment` to reference the contained data. `fragment` is an optional // output parameter and allowed to be null. bool IsFlat(absl::string_view* fragment) const; // Returns true if the data of `n` bytes starting at offset `offset` // is contained in a single data edge, and if so, sets fragment to reference // the contained data. `fragment` is an optional output parameter and allowed // to be null. bool IsFlat(size_t offset, size_t n, absl::string_view* fragment) const; // Returns a span (mutable range of bytes) of up to `size` bytes into the // last FLAT data edge inside this tree under the following conditions: // - none of the nodes down into the FLAT node are shared. // - the last data edge in this tree is a non-shared FLAT. // - the referenced FLAT has additional capacity available. // If all these conditions are met, a non-empty span is returned, and the // length of the flat node and involved tree nodes have been increased by // `span.length()`. The caller is responsible for immediately assigning values // to all uninitialized data reference by the returned span. // Requires `this->refcount.IsOne()`: this function forces the caller to do // this fast path check on the top level node, as this is the most commonly // shared node of a cord tree. Span GetAppendBuffer(size_t size); // Extracts the right-most data edge from this tree iff: // - the tree and all internal edges to the right-most node are not shared. // - the right-most node is a FLAT node and not shared. // - the right-most node has at least the desired extra capacity. // // Returns {tree, nullptr} if any of the above conditions are not met. // This method effectively removes data from the tree. The intent of this // method is to allow applications appending small string data to use // pre-existing capacity, and add the modified rep back to the tree. // // Simplified such code would look similar to this: // void MyTreeBuilder::Append(string_view data) { // ExtractResult result = CordRepBtree::ExtractAppendBuffer(tree_, 1); // if (CordRep* rep = result.extracted) { // size_t available = rep->Capacity() - rep->length; // size_t n = std::min(data.size(), n); // memcpy(rep->Data(), data.data(), n); // rep->length += n; // data.remove_prefix(n); // if (!result.tree->IsBtree()) { // tree_ = CordRepBtree::Create(result.tree); // } // tree_ = CordRepBtree::Append(tree_, rep); // } // ... // // Remaining edge in `result.tree`. // } static ExtractResult ExtractAppendBuffer(CordRepBtree* tree, size_t extra_capacity = 1); // Returns the `height` of the tree. The height of a tree is limited to // kMaxHeight. `height` is implemented as an `int` as in some places we // use negative (-1) values for 'data edges'. int height() const { return static_cast(storage[0]); } // Properties: begin, back, end, front/back boundary indexes. size_t begin() const { return static_cast(storage[1]); } size_t back() const { return static_cast(storage[2]) - 1; } size_t end() const { return static_cast(storage[2]); } size_t index(EdgeType edge) const { return edge == kFront ? begin() : back(); } // Properties: size and capacity. // `capacity` contains the current capacity of this instance, where // `kMaxCapacity` contains the maximum capacity of a btree node. // For now, `capacity` and `kMaxCapacity` return the same value, but this may // change in the future if we see benefit in dynamically sizing 'small' nodes // to 'large' nodes for large data trees. size_t size() const { return end() - begin(); } size_t capacity() const { return kMaxCapacity; } // Edge access inline CordRep* Edge(size_t index) const; inline CordRep* Edge(EdgeType edge_type) const; inline absl::Span Edges() const; inline absl::Span Edges(size_t begin, size_t end) const; // Returns reference to the data edge at `index`. // Requires this instance to be a leaf node, and `index` to be valid index. inline absl::string_view Data(size_t index) const; // Diagnostics: returns true if `tree` is valid and internally consistent. // If `shallow` is false, then the provided top level node and all child nodes // below it are recursively checked. If `shallow` is true, only the provided // node in `tree` and the cumulative length, type and height of the direct // child nodes of `tree` are checked. The value of `shallow` is ignored if the // internal `cord_btree_exhaustive_validation` diagnostics variable is true, // in which case the performed validations works as if `shallow` were false. // This function is intended for debugging and testing purposes only. static bool IsValid(const CordRepBtree* tree, bool shallow = false); // Diagnostics: asserts that the provided tree is valid. // `AssertValid()` performs a shallow validation by default. `shallow` can be // set to false in which case an exhaustive validation is performed. This // function is implemented in terms of calling `IsValid()` and asserting the // return value to be true. See `IsValid()` for more information. // This function is intended for debugging and testing purposes only. static CordRepBtree* AssertValid(CordRepBtree* tree, bool shallow = true); static const CordRepBtree* AssertValid(const CordRepBtree* tree, bool shallow = true); // Diagnostics: dump the contents of this tree to `stream`. // This function is intended for debugging and testing purposes only. static void Dump(const CordRep* rep, std::ostream& stream); static void Dump(const CordRep* rep, absl::string_view label, std::ostream& stream); static void Dump(const CordRep* rep, absl::string_view label, bool include_contents, std::ostream& stream); // Adds the edge `edge` to this node if possible. `owned` indicates if the // current node is potentially shared or not with other threads. Returns: // - {kSelf, } // The edge was directly added to this node. // - {kCopied, } // The edge was added to a copy of this node. // - {kPopped, New(edge, height())} // A new leg with the edge was created as this node has no extra capacity. template inline OpResult AddEdge(bool owned, CordRep* edge, size_t delta); // Replaces the front or back edge with the provided new edge. Returns: // - {kSelf, } // The edge was directly set in this node. The old edge is unreffed. // - {kCopied, } // A copy of this node was created with the new edge value. // In both cases, the function adopts a reference on `edge`. template OpResult SetEdge(bool owned, CordRep* edge, size_t delta); // Creates a new empty node at the specified height. static CordRepBtree* New(int height = 0); // Creates a new node containing `rep`, with the height being computed // automatically based on the type of `rep`. static CordRepBtree* New(CordRep* rep); // Creates a new node containing both `front` and `back` at height // `front.height() + 1`. Requires `back.height() == front.height()`. static CordRepBtree* New(CordRepBtree* front, CordRepBtree* back); // Creates a fully balanced tree from the provided tree by rebuilding a new // tree from all data edges in the input. This function is automatically // invoked internally when the tree exceeds the maximum height. static CordRepBtree* Rebuild(CordRepBtree* tree); private: CordRepBtree() = default; ~CordRepBtree() = default; // Initializes the main properties `tag`, `begin`, `end`, `height`. inline void InitInstance(int height, size_t begin = 0, size_t end = 0); // Direct property access begin / end void set_begin(size_t begin) { storage[1] = static_cast(begin); } void set_end(size_t end) { storage[2] = static_cast(end); } // Decreases the value of `begin` by `n`, and returns the new value. Notice // how this returns the new value unlike atomic::fetch_add which returns the // old value. This is because this is used to prepend edges at 'begin - 1'. size_t sub_fetch_begin(size_t n) { storage[1] -= static_cast(n); return storage[1]; } // Increases the value of `end` by `n`, and returns the previous value. This // function is typically used to append edges at 'end'. size_t fetch_add_end(size_t n) { const uint8_t current = storage[2]; storage[2] = static_cast(current + n); return current; } // Returns the index of the last edge starting on, or before `offset`, with // `n` containing the relative offset of `offset` inside that edge. // Requires `offset` < length. Position IndexOf(size_t offset) const; // Returns the index of the last edge starting before `offset`, with `n` // containing the relative offset of `offset` inside that edge. // This function is useful to find the edges for some span of bytes ending at // `offset` (i.e., `n` bytes). For example: // // Position pos = IndexBefore(n) // edges = Edges(begin(), pos.index) // All full edges (may be empty) // last = Sub(Edge(pos.index), 0, pos.n) // Last partial edge (may be empty) // // Requires 0 < `offset` <= length. Position IndexBefore(size_t offset) const; // Returns the index of the edge ending at (or on) length `length`, and the // number of bytes inside that edge up to `length`. For example, if we have a // Node with 2 edges, one of 10 and one of 20 long, then IndexOfLength(27) // will return {1, 17}, and IndexOfLength(10) will return {0, 10}. Position IndexOfLength(size_t n) const; // Identical to the above function except starting from the position `front`. // This function is equivalent to `IndexBefore(front.n + offset)`, with // the difference that this function is optimized to start at `front.index`. Position IndexBefore(Position front, size_t offset) const; // Returns the index of the edge directly beyond the edge containing offset // `offset`, with `n` containing the distance of that edge from `offset`. // This function is useful for iteratively finding suffix nodes and remaining // partial bytes in left-most suffix nodes as for example in CopySuffix. // Requires `offset` < length. Position IndexBeyond(size_t offset) const; // Creates a new leaf node containing as much data as possible from `data`. // The data is added either forwards or reversed depending on `edge_type`. // Callers must check the length of the returned node to determine if all data // was copied or not. // See the `Append/Prepend` function for the meaning and purpose of `extra`. template static CordRepBtree* NewLeaf(absl::string_view data, size_t extra); // Creates a raw copy of this Btree node with the specified length, copying // all properties, but without adding any references to existing edges. CordRepBtree* CopyRaw(size_t new_length) const; // Creates a full copy of this Btree node, adding a reference on all edges. CordRepBtree* Copy() const; // Creates a partial copy of this Btree node, copying all edges up to `end`, // adding a reference on each copied edge, and sets the length of the newly // created copy to `new_length`. CordRepBtree* CopyBeginTo(size_t end, size_t new_length) const; // Returns a tree containing the edges [tree->begin(), end) and length // of `new_length`. This method consumes a reference on the provided // tree, and logically performs the following operation: // result = tree->CopyBeginTo(end, new_length); // CordRep::Unref(tree); // return result; static CordRepBtree* ConsumeBeginTo(CordRepBtree* tree, size_t end, size_t new_length); // Creates a partial copy of this Btree node, copying all edges starting at // `begin`, adding a reference on each copied edge, and sets the length of // the newly created copy to `new_length`. CordRepBtree* CopyToEndFrom(size_t begin, size_t new_length) const; // Extracts and returns the front edge from the provided tree. // This method consumes a reference on the provided tree, and logically // performs the following operation: // edge = CordRep::Ref(tree->Edge(kFront)); // CordRep::Unref(tree); // return edge; static CordRep* ExtractFront(CordRepBtree* tree); // Returns a tree containing the result of appending `right` to `left`. static CordRepBtree* MergeTrees(CordRepBtree* left, CordRepBtree* right); // Fallback functions for `Create()`, `Append()` and `Prepend()` which // deal with legacy / non conforming input, i.e.: CONCAT trees. static CordRepBtree* CreateSlow(CordRep* rep); static CordRepBtree* AppendSlow(CordRepBtree*, CordRep* rep); static CordRepBtree* PrependSlow(CordRepBtree*, CordRep* rep); // Recursively rebuilds `tree` into `stack`. If 'consume` is set to true, the // function will consume a reference on `tree`. `stack` is a null terminated // array containing the new tree's state, with the current leaf node at // stack[0], and parent nodes above that, or null for 'top of tree'. static void Rebuild(CordRepBtree** stack, CordRepBtree* tree, bool consume); // Aligns existing edges to start at index 0, to allow for a new edge to be // added to the back of the current edges. inline void AlignBegin(); // Aligns existing edges to end at `capacity`, to allow for a new edge to be // added in front of the current edges. inline void AlignEnd(); // Adds the provided edge to this node. // Requires this node to have capacity for the edge. Realigns / moves // existing edges as needed to prepend or append the new edge. template inline void Add(CordRep* rep); // Adds the provided edges to this node. // Requires this node to have capacity for the edges. Realigns / moves // existing edges as needed to prepend or append the new edges. template inline void Add(absl::Span); // Adds data from `data` to this node until either all data has been consumed, // or there is no more capacity for additional flat nodes inside this node. // Requires the current node to be a leaf node, data to be non empty, and the // current node to have capacity for at least one more data edge. // Returns any remaining data from `data` that was not added, which is // depending on the edge type (front / back) either the remaining prefix of // suffix of the input. // See the `Append/Prepend` function for the meaning and purpose of `extra`. template absl::string_view AddData(absl::string_view data, size_t extra); // Replace the front or back edge with the provided value. // Adopts a reference on `edge` and unrefs the old edge. template inline void SetEdge(CordRep* edge); // Returns a partial copy of the current tree containing the first `n` bytes // of data. `CopyResult` contains both the resulting edge and its height. The // resulting tree may be less high than the current tree, or even be a single // matching data edge if `allow_folding` is set to true. // For example, if `n == 1`, then the result will be the single data edge, and // height will be set to -1 (one below the owning leaf node). If n == 0, this // function returns null. Requires `n <= length` CopyResult CopyPrefix(size_t n, bool allow_folding = true); // Returns a partial copy of the current tree containing all data starting // after `offset`. `CopyResult` contains both the resulting edge and its // height. The resulting tree may be less high than the current tree, or even // be a single matching data edge. For example, if `n == length - 1`, then the // result will be a single data edge, and height will be set to -1 (one below // the owning leaf node). // Requires `offset < length` CopyResult CopySuffix(size_t offset); // Returns a OpResult value of {this, kSelf} or {Copy(), kCopied} // depending on the value of `owned`. inline OpResult ToOpResult(bool owned); // Adds `rep` to the specified tree, returning the modified tree. template static CordRepBtree* AddCordRep(CordRepBtree* tree, CordRep* rep); // Adds `data` to the specified tree, returning the modified tree. // See the `Append/Prepend` function for the meaning and purpose of `extra`. template static CordRepBtree* AddData(CordRepBtree* tree, absl::string_view data, size_t extra = 0); // Merges `src` into `dst` with `src` being added either before (kFront) or // after (kBack) `dst`. Requires the height of `dst` to be greater than or // equal to the height of `src`. template static CordRepBtree* Merge(CordRepBtree* dst, CordRepBtree* src); // Fallback version of GetAppendBuffer for large trees: GetAppendBuffer() // implements an inlined version for trees of limited height (3 levels), // GetAppendBufferSlow implements the logic for large trees. Span GetAppendBufferSlow(size_t size); // `edges_` contains all edges starting from this instance. // These are explicitly `child` edges only, a cord btree (or any cord tree in // that respect) does not store `parent` pointers anywhere: multiple trees / // parents can reference the same shared child edge. The type of these edges // depends on the height of the node. `Leaf nodes` (height == 0) contain `data // edges` (external or flat nodes, or sub-strings thereof). All other nodes // (height > 0) contain pointers to BTREE nodes with a height of `height - 1`. CordRep* edges_[kMaxCapacity]; friend class CordRepBtreeTestPeer; friend class CordRepBtreeNavigator; }; inline CordRepBtree* CordRep::btree() { assert(IsBtree()); return static_cast(this); } inline const CordRepBtree* CordRep::btree() const { assert(IsBtree()); return static_cast(this); } inline void CordRepBtree::InitInstance(int height, size_t begin, size_t end) { tag = BTREE; storage[0] = static_cast(height); storage[1] = static_cast(begin); storage[2] = static_cast(end); } inline CordRep* CordRepBtree::Edge(size_t index) const { assert(index >= begin()); assert(index < end()); return edges_[index]; } inline CordRep* CordRepBtree::Edge(EdgeType edge_type) const { return edges_[edge_type == kFront ? begin() : back()]; } inline absl::Span CordRepBtree::Edges() const { return {edges_ + begin(), size()}; } inline absl::Span CordRepBtree::Edges(size_t begin, size_t end) const { assert(begin <= end); assert(begin >= this->begin()); assert(end <= this->end()); return {edges_ + begin, static_cast(end - begin)}; } inline absl::string_view CordRepBtree::Data(size_t index) const { assert(height() == 0); return EdgeData(Edge(index)); } inline CordRepBtree* CordRepBtree::New(int height) { CordRepBtree* tree = new CordRepBtree; tree->length = 0; tree->InitInstance(height); return tree; } inline CordRepBtree* CordRepBtree::New(CordRep* rep) { CordRepBtree* tree = new CordRepBtree; int height = rep->IsBtree() ? rep->btree()->height() + 1 : 0; tree->length = rep->length; tree->InitInstance(height, /*begin=*/0, /*end=*/1); tree->edges_[0] = rep; return tree; } inline CordRepBtree* CordRepBtree::New(CordRepBtree* front, CordRepBtree* back) { assert(front->height() == back->height()); CordRepBtree* tree = new CordRepBtree; tree->length = front->length + back->length; tree->InitInstance(front->height() + 1, /*begin=*/0, /*end=*/2); tree->edges_[0] = front; tree->edges_[1] = back; return tree; } inline void CordRepBtree::Unref(absl::Span edges) { for (CordRep* edge : edges) { if (ABSL_PREDICT_FALSE(!edge->refcount.Decrement())) { CordRep::Destroy(edge); } } } inline CordRepBtree* CordRepBtree::CopyRaw(size_t new_length) const { CordRepBtree* tree = new CordRepBtree; // `length` and `refcount` are the first members of `CordRepBtree`. // We initialize `length` using the given length, have `refcount` be set to // ref = 1 through its default constructor, and copy all data beyond // 'refcount' which starts with `tag` using a single memcpy: all contents // except `refcount` is trivially copyable, and the compiler does not // efficiently coalesce member-wise copy of these members. // See https://gcc.godbolt.org/z/qY8zsca6z // LINT.IfChange(copy_raw) tree->length = new_length; uint8_t* dst = &tree->tag; const uint8_t* src = &tag; const ptrdiff_t offset = src - reinterpret_cast(this); memcpy(dst, src, sizeof(CordRepBtree) - static_cast(offset)); return tree; // LINT.ThenChange() } inline CordRepBtree* CordRepBtree::Copy() const { CordRepBtree* tree = CopyRaw(length); for (CordRep* rep : Edges()) CordRep::Ref(rep); return tree; } inline CordRepBtree* CordRepBtree::CopyToEndFrom(size_t begin, size_t new_length) const { assert(begin >= this->begin()); assert(begin <= this->end()); CordRepBtree* tree = CopyRaw(new_length); tree->set_begin(begin); for (CordRep* edge : tree->Edges()) CordRep::Ref(edge); return tree; } inline CordRepBtree* CordRepBtree::CopyBeginTo(size_t end, size_t new_length) const { assert(end <= capacity()); assert(end >= this->begin()); CordRepBtree* tree = CopyRaw(new_length); tree->set_end(end); for (CordRep* edge : tree->Edges()) CordRep::Ref(edge); return tree; } inline void CordRepBtree::AlignBegin() { // The below code itself does not need to be fast as typically we have // mono-directional append/prepend calls, and `begin` / `end` are typically // adjusted no more than once. But we want to avoid potential register clobber // effects, making the compiler emit register save/store/spills, and minimize // the size of code. const size_t delta = begin(); if (ABSL_PREDICT_FALSE(delta != 0)) { const size_t new_end = end() - delta; set_begin(0); set_end(new_end); // TODO(mvels): we can write this using 2 loads / 2 stores depending on // total size for the kMaxCapacity = 6 case. I.e., we can branch (switch) on // size, and then do overlapping load/store of up to 4 pointers (inlined as // XMM, YMM or ZMM load/store) and up to 2 pointers (XMM / YMM), which is a) // compact and b) not clobbering any registers. ABSL_ASSUME(new_end <= kMaxCapacity); #ifdef __clang__ #pragma unroll 1 #endif for (size_t i = 0; i < new_end; ++i) { edges_[i] = edges_[i + delta]; } } } inline void CordRepBtree::AlignEnd() { // See comments in `AlignBegin` for motivation on the hand-rolled for loops. const size_t delta = capacity() - end(); if (delta != 0) { const size_t new_begin = begin() + delta; const size_t new_end = end() + delta; set_begin(new_begin); set_end(new_end); ABSL_ASSUME(new_end <= kMaxCapacity); #ifdef __clang__ #pragma unroll 1 #endif for (size_t i = new_end - 1; i >= new_begin; --i) { edges_[i] = edges_[i - delta]; } } } template <> inline void CordRepBtree::Add(CordRep* rep) { AlignBegin(); edges_[fetch_add_end(1)] = rep; } template <> inline void CordRepBtree::Add( absl::Span edges) { AlignBegin(); size_t new_end = end(); for (CordRep* edge : edges) edges_[new_end++] = edge; set_end(new_end); } template <> inline void CordRepBtree::Add(CordRep* rep) { AlignEnd(); edges_[sub_fetch_begin(1)] = rep; } template <> inline void CordRepBtree::Add( absl::Span edges) { AlignEnd(); size_t new_begin = begin() - edges.size(); set_begin(new_begin); for (CordRep* edge : edges) edges_[new_begin++] = edge; } template inline void CordRepBtree::SetEdge(CordRep* edge) { const int idx = edge_type == kFront ? begin() : back(); CordRep::Unref(edges_[idx]); edges_[idx] = edge; } inline CordRepBtree::OpResult CordRepBtree::ToOpResult(bool owned) { return owned ? OpResult{this, kSelf} : OpResult{Copy(), kCopied}; } inline CordRepBtree::Position CordRepBtree::IndexOf(size_t offset) const { assert(offset < length); size_t index = begin(); while (offset >= edges_[index]->length) offset -= edges_[index++]->length; return {index, offset}; } inline CordRepBtree::Position CordRepBtree::IndexBefore(size_t offset) const { assert(offset > 0); assert(offset <= length); size_t index = begin(); while (offset > edges_[index]->length) offset -= edges_[index++]->length; return {index, offset}; } inline CordRepBtree::Position CordRepBtree::IndexBefore(Position front, size_t offset) const { size_t index = front.index; offset = offset + front.n; while (offset > edges_[index]->length) offset -= edges_[index++]->length; return {index, offset}; } inline CordRepBtree::Position CordRepBtree::IndexOfLength(size_t n) const { assert(n <= length); size_t index = back(); size_t strip = length - n; while (strip >= edges_[index]->length) strip -= edges_[index--]->length; return {index, edges_[index]->length - strip}; } inline CordRepBtree::Position CordRepBtree::IndexBeyond( const size_t offset) const { // We need to find the edge which `starting offset` is beyond (>=)`offset`. // For this we can't use the `offset -= length` logic of IndexOf. Instead, we // track the offset of the `current edge` in `off`, which we increase as we // iterate over the edges until we find the matching edge. size_t off = 0; size_t index = begin(); while (offset > off) off += edges_[index++]->length; return {index, off - offset}; } inline CordRepBtree* CordRepBtree::Create(CordRep* rep) { if (IsDataEdge(rep)) return New(rep); return CreateSlow(rep); } inline Span CordRepBtree::GetAppendBuffer(size_t size) { assert(refcount.IsOne()); CordRepBtree* tree = this; const int height = this->height(); CordRepBtree* n1 = tree; CordRepBtree* n2 = tree; CordRepBtree* n3 = tree; switch (height) { case 3: tree = tree->Edge(kBack)->btree(); if (!tree->refcount.IsOne()) return {}; n2 = tree; ABSL_FALLTHROUGH_INTENDED; case 2: tree = tree->Edge(kBack)->btree(); if (!tree->refcount.IsOne()) return {}; n1 = tree; ABSL_FALLTHROUGH_INTENDED; case 1: tree = tree->Edge(kBack)->btree(); if (!tree->refcount.IsOne()) return {}; ABSL_FALLTHROUGH_INTENDED; case 0: CordRep* edge = tree->Edge(kBack); if (!edge->refcount.IsOne()) return {}; if (edge->tag < FLAT) return {}; size_t avail = edge->flat()->Capacity() - edge->length; if (avail == 0) return {}; size_t delta = (std::min)(size, avail); Span span = {edge->flat()->Data() + edge->length, delta}; edge->length += delta; switch (height) { case 3: n3->length += delta; ABSL_FALLTHROUGH_INTENDED; case 2: n2->length += delta; ABSL_FALLTHROUGH_INTENDED; case 1: n1->length += delta; ABSL_FALLTHROUGH_INTENDED; case 0: tree->length += delta; return span; } break; } return GetAppendBufferSlow(size); } extern template CordRepBtree* CordRepBtree::AddCordRep( CordRepBtree* tree, CordRep* rep); extern template CordRepBtree* CordRepBtree::AddCordRep( CordRepBtree* tree, CordRep* rep); inline CordRepBtree* CordRepBtree::Append(CordRepBtree* tree, CordRep* rep) { if (ABSL_PREDICT_TRUE(IsDataEdge(rep))) { return CordRepBtree::AddCordRep(tree, rep); } return AppendSlow(tree, rep); } inline CordRepBtree* CordRepBtree::Prepend(CordRepBtree* tree, CordRep* rep) { if (ABSL_PREDICT_TRUE(IsDataEdge(rep))) { return CordRepBtree::AddCordRep(tree, rep); } return PrependSlow(tree, rep); } #ifdef NDEBUG inline CordRepBtree* CordRepBtree::AssertValid(CordRepBtree* tree, bool /* shallow */) { return tree; } inline const CordRepBtree* CordRepBtree::AssertValid(const CordRepBtree* tree, bool /* shallow */) { return tree; } #endif } // namespace cord_internal ABSL_NAMESPACE_END } // namespace absl #endif // ABSL_STRINGS_INTERNAL_CORD_REP_BTREE_H_