absl/strings/internal/cord_rep_btree_reader.h - external/github.com/abseil/abseil-cpp - Git at Google

 // 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_READER_H_
 #define ABSL_STRINGS_INTERNAL_CORD_REP_BTREE_READER_H_

 #include <cassert>

 #include "absl/base/config.h"
 #include "absl/strings/internal/cord_data_edge.h"
 #include "absl/strings/internal/cord_internal.h"
 #include "absl/strings/internal/cord_rep_btree.h"
 #include "absl/strings/internal/cord_rep_btree_navigator.h"
 #include "absl/strings/internal/cord_rep_flat.h"

 namespace absl {
 ABSL_NAMESPACE_BEGIN
 namespace cord_internal {

 // CordRepBtreeReader implements logic to iterate over cord btrees.
 // References to the underlying data are returned as absl::string_view values.
 // The most typical use case is a forward only iteration over tree data.
 // The class also provides `Skip()`, `Seek()` and `Read()` methods similar to
 // CordRepBtreeNavigator that allow more advanced navigation.
 //
 // Example: iterate over all data inside a cord btree:
 //
 //   CordRepBtreeReader reader;
 //   for (string_view sv = reader.Init(tree); !sv.Empty(); sv = sv.Next()) {
 //     DoSomethingWithDataIn(sv);
 //   }
 //
 // All navigation methods always return the next 'chunk' of data. The class
 // assumes that all data is directly 'consumed' by the caller. For example:
 // invoking `Skip()` will skip the desired number of bytes, and directly
 // read and return the next chunk of data directly after the skipped bytes.
 //
 // Example: iterate over all data inside a btree skipping the first 100 bytes:
 //
 //   CordRepBtreeReader reader;
 //   absl::string_view sv = reader.Init(tree);
 //   if (sv.length() > 100) {
 //     sv.RemovePrefix(100);
 //   } else {
 //     sv = reader.Skip(100 - sv.length());
 //   }
 //   while (!sv.empty()) {
 //     DoSomethingWithDataIn(sv);
 //     absl::string_view sv = reader.Next();
 //   }
 //
 // It is important to notice that `remaining` is based on the end position of
 // the last data edge returned to the caller, not the cumulative data returned
 // to the caller which can be less in cases of skipping or seeking over data.
 //
 // For example, consider a cord btree with five data edges: "abc", "def", "ghi",
 // "jkl" and "mno":
 //
 //   absl::string_view sv;
 //   CordRepBtreeReader reader;
 //
 //   sv = reader.Init(tree); // sv = "abc", remaining = 12
 //   sv = reader.Skip(4);    // sv = "hi",  remaining = 6
 //   sv = reader.Skip(2);    // sv = "l",   remaining = 3
 //   sv = reader.Next();     // sv = "mno", remaining = 0
 //   sv = reader.Seek(1);    // sv = "bc", remaining = 12
 //
 class CordRepBtreeReader {
  public:
   using ReadResult = CordRepBtreeNavigator::ReadResult;
   using Position = CordRepBtreeNavigator::Position;

   // Returns true if this instance is not empty.
   explicit operator bool() const { return navigator_.btree() != nullptr; }

   // Returns the tree referenced by this instance or nullptr if empty.
   CordRepBtree* btree() const { return navigator_.btree(); }

   // Returns the current data edge inside the referenced btree.
   // Requires that the current instance is not empty.
   CordRep* node() const { return navigator_.Current(); }

   // Returns the length of the referenced tree.
   // Requires that the current instance is not empty.
   size_t length() const;

   // Returns the number of remaining bytes available for iteration, which is the
   // number of bytes directly following the end of the last chunk returned.
   // This value will be zero if we iterated over the last edge in the bound
   // tree, in which case any call to Next() or Skip() will return an empty
   // string_view reflecting the EOF state.
   // Note that a call to `Seek()` resets `remaining` to a value based on the
   // end position of the chunk returned by that call.
   size_t remaining() const { return remaining_; }

   // Resets this instance to an empty value.
   void Reset() { navigator_.Reset(); }

   // Initializes this instance with `tree`. `tree` must not be null.
   // Returns a reference to the first data edge of the provided tree.
   absl::string_view Init(CordRepBtree* tree);

   // Navigates to and returns the next data edge of the referenced tree.
   // Returns an empty string_view if an attempt is made to read beyond the end
   // of the tree, i.e.: if `remaining()` is zero indicating an EOF condition.
   // Requires that the current instance is not empty.
   absl::string_view Next();

   // Skips the provided amount of bytes and returns a reference to the data
   // directly following the skipped bytes.
   absl::string_view Skip(size_t skip);

   // Reads `n` bytes into `tree`.
   // If `chunk_size` is zero, starts reading at the next data edge. If
   // `chunk_size` is non zero, the read starts at the last `chunk_size` bytes of
   // the last returned data edge. Effectively, this means that the read starts
   // at offset `consumed() - chunk_size`.
   // Requires that `chunk_size` is less than or equal to the length of the
   // last returned data edge. The purpose of `chunk_size` is to simplify code
   // partially consuming a returned chunk and wanting to include the remaining
   // bytes in the Read call. For example, the below code will read 1000 bytes of
   // data into a cord tree if the first chunk starts with "big:":
   //
   //   CordRepBtreeReader reader;
   //   absl::string_view sv = reader.Init(tree);
   //   if (absl::StartsWith(sv, "big:")) {
   //     CordRepBtree tree;
   //     sv = reader.Read(1000, sv.size() - 4 /* "big:" */, &tree);
   //   }
   //
   // This method will return an empty string view if all remaining data was
   // read. If `n` exceeded the amount of remaining data this function will
   // return an empty string view and `tree` will be set to nullptr.
   // In both cases, `consumed` will be set to `length`.
   absl::string_view Read(size_t n, size_t chunk_size, CordRep*& tree);

   // Navigates to the chunk at offset `offset`.
   // Returns a reference into the navigated to chunk, adjusted for the relative
   // position of `offset` into that chunk. For example, calling `Seek(13)` on a
   // cord tree containing 2 chunks of 10 and 20 bytes respectively will return
   // a string view into the second chunk starting at offset 3 with a size of 17.
   // Returns an empty string view if `offset` is equal to or greater than the
   // length of the referenced tree.
   absl::string_view Seek(size_t offset);

  private:
   size_t remaining_ = 0;
   CordRepBtreeNavigator navigator_;
 };

 inline size_t CordRepBtreeReader::length() const {
   assert(btree() != nullptr);
   return btree()->length;
 }

 inline absl::string_view CordRepBtreeReader::Init(CordRepBtree* tree) {
   assert(tree != nullptr);
   const CordRep* edge = navigator_.InitFirst(tree);
   remaining_ = tree->length - edge->length;
   return EdgeData(edge);
 }

 inline absl::string_view CordRepBtreeReader::Next() {
   if (remaining_ == 0) return {};
   const CordRep* edge = navigator_.Next();
   assert(edge != nullptr);
   remaining_ -= edge->length;
   return EdgeData(edge);
 }

 inline absl::string_view CordRepBtreeReader::Skip(size_t skip) {
   // As we are always positioned on the last 'consumed' edge, we
   // need to skip the current edge as well as `skip`.
   const size_t edge_length = navigator_.Current()->length;
   CordRepBtreeNavigator::Position pos = navigator_.Skip(skip + edge_length);
   if (ABSL_PREDICT_FALSE(pos.edge == nullptr)) {
     remaining_ = 0;
     return {};
   }
   // The combined length of all edges skipped before `pos.edge` is `skip -
   // pos.offset`, all of which are 'consumed', as well as the current edge.
   remaining_ -= skip - pos.offset + pos.edge->length;
   return EdgeData(pos.edge).substr(pos.offset);
 }

 inline absl::string_view CordRepBtreeReader::Seek(size_t offset) {
   const CordRepBtreeNavigator::Position pos = navigator_.Seek(offset);
   if (ABSL_PREDICT_FALSE(pos.edge == nullptr)) {
     remaining_ = 0;
     return {};
   }
   absl::string_view chunk = EdgeData(pos.edge).substr(pos.offset);
   remaining_ = length() - offset - chunk.length();
   return chunk;
 }

 }  // namespace cord_internal
 ABSL_NAMESPACE_END
 }  // namespace absl

 #endif  // ABSL_STRINGS_INTERNAL_CORD_REP_BTREE_READER_H_
	// 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_READER_H_
	#define ABSL_STRINGS_INTERNAL_CORD_REP_BTREE_READER_H_

	#include <cassert>

	#include "absl/base/config.h"
	#include "absl/strings/internal/cord_data_edge.h"
	#include "absl/strings/internal/cord_internal.h"
	#include "absl/strings/internal/cord_rep_btree.h"
	#include "absl/strings/internal/cord_rep_btree_navigator.h"
	#include "absl/strings/internal/cord_rep_flat.h"

	namespace absl {
	ABSL_NAMESPACE_BEGIN
	namespace cord_internal {

	// CordRepBtreeReader implements logic to iterate over cord btrees.
	// References to the underlying data are returned as absl::string_view values.
	// The most typical use case is a forward only iteration over tree data.
	// The class also provides `Skip()`, `Seek()` and `Read()` methods similar to
	// CordRepBtreeNavigator that allow more advanced navigation.
	//
	// Example: iterate over all data inside a cord btree:
	//
	// CordRepBtreeReader reader;
	// for (string_view sv = reader.Init(tree); !sv.Empty(); sv = sv.Next()) {
	// DoSomethingWithDataIn(sv);
	// }
	//
	// All navigation methods always return the next 'chunk' of data. The class
	// assumes that all data is directly 'consumed' by the caller. For example:
	// invoking `Skip()` will skip the desired number of bytes, and directly
	// read and return the next chunk of data directly after the skipped bytes.
	//
	// Example: iterate over all data inside a btree skipping the first 100 bytes:
	//
	// CordRepBtreeReader reader;
	// absl::string_view sv = reader.Init(tree);
	// if (sv.length() > 100) {
	// sv.RemovePrefix(100);
	// } else {
	// sv = reader.Skip(100 - sv.length());
	// }
	// while (!sv.empty()) {
	// DoSomethingWithDataIn(sv);
	// absl::string_view sv = reader.Next();
	// }
	//
	// It is important to notice that `remaining` is based on the end position of
	// the last data edge returned to the caller, not the cumulative data returned
	// to the caller which can be less in cases of skipping or seeking over data.
	//
	// For example, consider a cord btree with five data edges: "abc", "def", "ghi",
	// "jkl" and "mno":
	//
	// absl::string_view sv;
	// CordRepBtreeReader reader;
	//
	// sv = reader.Init(tree); // sv = "abc", remaining = 12
	// sv = reader.Skip(4); // sv = "hi", remaining = 6
	// sv = reader.Skip(2); // sv = "l", remaining = 3
	// sv = reader.Next(); // sv = "mno", remaining = 0
	// sv = reader.Seek(1); // sv = "bc", remaining = 12
	//
	class CordRepBtreeReader {
	public:
	using ReadResult = CordRepBtreeNavigator::ReadResult;
	using Position = CordRepBtreeNavigator::Position;

	// Returns true if this instance is not empty.
	explicit operator bool() const { return navigator_.btree() != nullptr; }

	// Returns the tree referenced by this instance or nullptr if empty.
	CordRepBtree* btree() const { return navigator_.btree(); }

	// Returns the current data edge inside the referenced btree.
	// Requires that the current instance is not empty.
	CordRep* node() const { return navigator_.Current(); }

	// Returns the length of the referenced tree.
	// Requires that the current instance is not empty.
	size_t length() const;

	// Returns the number of remaining bytes available for iteration, which is the
	// number of bytes directly following the end of the last chunk returned.
	// This value will be zero if we iterated over the last edge in the bound
	// tree, in which case any call to Next() or Skip() will return an empty
	// string_view reflecting the EOF state.
	// Note that a call to `Seek()` resets `remaining` to a value based on the
	// end position of the chunk returned by that call.
	size_t remaining() const { return remaining_; }

	// Resets this instance to an empty value.
	void Reset() { navigator_.Reset(); }

	// Initializes this instance with `tree`. `tree` must not be null.
	// Returns a reference to the first data edge of the provided tree.
	absl::string_view Init(CordRepBtree* tree);

	// Navigates to and returns the next data edge of the referenced tree.
	// Returns an empty string_view if an attempt is made to read beyond the end
	// of the tree, i.e.: if `remaining()` is zero indicating an EOF condition.
	// Requires that the current instance is not empty.
	absl::string_view Next();

	// Skips the provided amount of bytes and returns a reference to the data
	// directly following the skipped bytes.
	absl::string_view Skip(size_t skip);

	// Reads `n` bytes into `tree`.
	// If `chunk_size` is zero, starts reading at the next data edge. If
	// `chunk_size` is non zero, the read starts at the last `chunk_size` bytes of
	// the last returned data edge. Effectively, this means that the read starts
	// at offset `consumed() - chunk_size`.
	// Requires that `chunk_size` is less than or equal to the length of the
	// last returned data edge. The purpose of `chunk_size` is to simplify code
	// partially consuming a returned chunk and wanting to include the remaining
	// bytes in the Read call. For example, the below code will read 1000 bytes of
	// data into a cord tree if the first chunk starts with "big:":
	//
	// CordRepBtreeReader reader;
	// absl::string_view sv = reader.Init(tree);
	// if (absl::StartsWith(sv, "big:")) {
	// CordRepBtree tree;
	// sv = reader.Read(1000, sv.size() - 4 /* "big:" */, &tree);
	// }
	//
	// This method will return an empty string view if all remaining data was
	// read. If `n` exceeded the amount of remaining data this function will
	// return an empty string view and `tree` will be set to nullptr.
	// In both cases, `consumed` will be set to `length`.
	absl::string_view Read(size_t n, size_t chunk_size, CordRep*& tree);

	// Navigates to the chunk at offset `offset`.
	// Returns a reference into the navigated to chunk, adjusted for the relative
	// position of `offset` into that chunk. For example, calling `Seek(13)` on a
	// cord tree containing 2 chunks of 10 and 20 bytes respectively will return
	// a string view into the second chunk starting at offset 3 with a size of 17.
	// Returns an empty string view if `offset` is equal to or greater than the
	// length of the referenced tree.
	absl::string_view Seek(size_t offset);

	private:
	size_t remaining_ = 0;
	CordRepBtreeNavigator navigator_;
	};

	inline size_t CordRepBtreeReader::length() const {
	assert(btree() != nullptr);
	return btree()->length;
	}

	inline absl::string_view CordRepBtreeReader::Init(CordRepBtree* tree) {
	assert(tree != nullptr);
	const CordRep* edge = navigator_.InitFirst(tree);
	remaining_ = tree->length - edge->length;
	return EdgeData(edge);
	}

	inline absl::string_view CordRepBtreeReader::Next() {
	if (remaining_ == 0) return {};
	const CordRep* edge = navigator_.Next();
	assert(edge != nullptr);
	remaining_ -= edge->length;
	return EdgeData(edge);
	}

	inline absl::string_view CordRepBtreeReader::Skip(size_t skip) {
	// As we are always positioned on the last 'consumed' edge, we
	// need to skip the current edge as well as `skip`.
	const size_t edge_length = navigator_.Current()->length;
	CordRepBtreeNavigator::Position pos = navigator_.Skip(skip + edge_length);
	if (ABSL_PREDICT_FALSE(pos.edge == nullptr)) {
	remaining_ = 0;
	return {};
	}
	// The combined length of all edges skipped before `pos.edge` is `skip -
	// pos.offset`, all of which are 'consumed', as well as the current edge.
	remaining_ -= skip - pos.offset + pos.edge->length;
	return EdgeData(pos.edge).substr(pos.offset);
	}

	inline absl::string_view CordRepBtreeReader::Seek(size_t offset) {
	const CordRepBtreeNavigator::Position pos = navigator_.Seek(offset);
	if (ABSL_PREDICT_FALSE(pos.edge == nullptr)) {
	remaining_ = 0;
	return {};
	}
	absl::string_view chunk = EdgeData(pos.edge).substr(pos.offset);
	remaining_ = length() - offset - chunk.length();
	return chunk;
	}

	} // namespace cord_internal
	ABSL_NAMESPACE_END
	} // namespace absl

	#endif // ABSL_STRINGS_INTERNAL_CORD_REP_BTREE_READER_H_