// Copyright 2015 The Chromium Authors
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#ifndef NET_DER_INPUT_H_
#define NET_DER_INPUT_H_
#include <stddef.h>
#include <stdint.h>
#include <string>
#include "base/containers/span.h"
#include "net/base/net_export.h"
namespace net::der {
// An opaque class that represents a fixed buffer of data of a fixed length,
// to be used as an input to other operations. An Input object does not own
// the data it references, so callers are responsible for making sure that
// the data outlives the Input object and any other associated objects.
//
// All data access for an Input should be done through the ByteReader class.
// This class and associated classes are designed with safety in mind to make it
// difficult to read memory outside of an Input. ByteReader provides a simple
// API for reading through the Input sequentially. For more complicated uses,
// multiple instances of a ByteReader for a particular Input can be created.
class NET_EXPORT_PRIVATE Input {
public:
// Creates an empty Input, one from which no data can be read.
constexpr Input() = default;
// Creates an Input from a constant array |data|.
template <size_t N>
constexpr explicit Input(const uint8_t (&data)[N]) : data_(data), len_(N) {}
// Creates an Input from the given |data| and |len|.
constexpr explicit Input(const uint8_t* data, size_t len)
: data_(data), len_(len) {}
// Creates an Input from a std::string_view
explicit Input(std::string_view sp);
// Creates an Input from a std::string. The lifetimes are a bit subtle when
// using this function: The constructed Input is only valid so long as |s| is
// still alive and not mutated.
explicit Input(const std::string* s);
// Returns the length in bytes of an Input's data.
constexpr size_t Length() const { return len_; }
// Returns a pointer to the Input's data. This method is marked as "unsafe"
// because access to the Input's data should be done through ByteReader
// instead. This method should only be used where using a ByteReader truly
// is not an option.
constexpr const uint8_t* UnsafeData() const { return data_; }
// Returns a copy of the data represented by this object as a std::string.
std::string AsString() const;
// Returns a std::string_view pointing to the same data as the Input. The
// resulting string_view must not outlive the data that was used to construct
// this Input.
std::string_view AsStringView() const;
// Returns a base::span pointing to the same data as the Input. The resulting
// base::span must not outlive the data that was used to construct this
// Input.
base::span<const uint8_t> AsSpan() const;
private:
// This constructor is deleted to prevent constructing an Input from a
// std::string r-value. Since the Input points to memory owned by another
// object, such an Input would point to invalid memory. Without this deleted
// constructor, a std::string could be passed in to the base::StringPiece
// constructor because of StringPiece's implicit constructor.
Input(std::string) = delete;
const uint8_t* data_ = nullptr;
size_t len_ = 0;
};
// Return true if |lhs|'s data and |rhs|'s data are byte-wise equal.
NET_EXPORT_PRIVATE bool operator==(const Input& lhs, const Input& rhs);
// Return true if |lhs|'s data and |rhs|'s data are not byte-wise equal.
NET_EXPORT_PRIVATE bool operator!=(const Input& lhs, const Input& rhs);
// Returns true if |lhs|'s data is lexicographically less than |rhs|'s data.
NET_EXPORT_PRIVATE constexpr bool operator<(const Input& lhs,
const Input& rhs) {
// This is `std::lexicographical_compare`, but that's not `constexpr` until
// C++-20.
auto* it1 = lhs.UnsafeData();
auto* it2 = rhs.UnsafeData();
const auto* end1 = lhs.UnsafeData() + lhs.Length();
const auto* end2 = rhs.UnsafeData() + rhs.Length();
for (; it1 != end1 && it2 != end2; ++it1, ++it2) {
if (*it1 < *it2) {
return true;
} else if (*it2 < *it1) {
return false;
}
}
return it2 != end2;
}
// This class provides ways to read data from an Input in a bounds-checked way.
// The ByteReader is designed to read through the input sequentially. Once a
// byte has been read with a ByteReader, the caller can't go back and re-read
// that byte with the same reader. Of course, the caller can create multiple
// ByteReaders for the same input (or copy an existing ByteReader).
//
// For something simple like a single byte lookahead, the easiest way to do
// that is to copy the ByteReader and call ReadByte() on the copy - the original
// ByteReader will be unaffected and the peeked byte will be read through
// ReadByte(). For other read patterns, it can be useful to mark where one is
// in a ByteReader to be able to return to that spot.
//
// Some operations using Mark can also be done by creating a copy of the
// ByteReader. By using a Mark instead, you use less memory, but more
// importantly, you end up with an immutable object that matches the semantics
// of what is intended.
class NET_EXPORT_PRIVATE ByteReader {
public:
// Creates a ByteReader to read the data represented by an Input.
explicit ByteReader(const Input& in);
// Reads a single byte from the input source, putting the byte read in
// |*byte_p|. If a byte cannot be read from the input (because there is
// no input left), then this method returns false.
[[nodiscard]] bool ReadByte(uint8_t* out);
// Reads |len| bytes from the input source, and initializes an Input to
// point to that data. If there aren't enough bytes left in the input source,
// then this method returns false.
[[nodiscard]] bool ReadBytes(size_t len, Input* out);
// Returns how many bytes are left to read.
size_t BytesLeft() const { return len_; }
// Returns whether there is any more data to be read.
bool HasMore();
private:
void Advance(size_t len);
const uint8_t* data_;
size_t len_;
};
} // namespace net::der
#endif // NET_DER_INPUT_H_