/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim: set ts=8 sts=2 et sw=2 tw=80: */ /* This code is made available to you under your choice of the following sets * of licensing terms: */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ /* Copyright 2013 Mozilla Contributors * * 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 * * http://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 mozilla_pkix_Input_h #define mozilla_pkix_Input_h #include #include "mozpkix/Result.h" #include "stdint.h" namespace mozilla { namespace pkix { class Reader; // An Input is a safety-oriented immutable weak reference to a array of bytes // of a known size. The data can only be legally accessed by constructing a // Reader object, which guarantees all accesses to the data are memory safe. // Neither Input not Reader provide any facilities for modifying the data // they reference. // // Inputs are small and should usually be passed by value, not by reference, // though for inline functions the distinction doesn't matter: // // Result GoodExample(Input input); // Result BadExample(const Input& input); // Result WorseExample(const uint8_t* input, size_t len); // // Note that in the example, GoodExample has the same performance // characteristics as WorseExample, but with much better safety guarantees. class Input final { public: typedef uint16_t size_type; // This constructor is useful for inputs that are statically known to be of a // fixed size, e.g.: // // static const uint8_t EXPECTED_BYTES[] = { 0x00, 0x01, 0x02 }; // const Input expected(EXPECTED_BYTES); // // This is equivalent to (and preferred over): // // static const uint8_t EXPECTED_BYTES[] = { 0x00, 0x01, 0x02 }; // Input expected; // Result rv = expected.Init(EXPECTED_BYTES, sizeof EXPECTED_BYTES); template explicit Input(const uint8_t (&aData)[N]) : data(aData), len(N) {} // Construct a valid, empty, Init-able Input. Input() : data(nullptr), len(0u) {} // This is intentionally not explicit in order to allow value semantics. Input(const Input&) = default; // Initialize the input. data must be non-null and len must be less than // 65536. Init may not be called more than once. Result Init(const uint8_t* aData, size_t aLen) { if (this->data) { // already initialized return Result::FATAL_ERROR_INVALID_ARGS; } if (!aData || aLen > 0xffffu) { // input too large return Result::ERROR_BAD_DER; } this->data = aData; this->len = aLen; return Success; } // Initialize the input to be equivalent to the given input. Init may not be // called more than once. // // This is basically operator=, but it wasn't given that name because // normally callers do not check the result of operator=, and normally // operator= can be used multiple times. Result Init(Input other) { return Init(other.data, other.len); } // Returns the length of the input. // // Having the return type be size_type instead of size_t avoids the need for // callers to ensure that the result is small enough. size_type GetLength() const { return static_cast(len); } // Don't use this. It is here because we have some "friend" functions that we // don't want to declare in this header file. const uint8_t* UnsafeGetData() const { return data; } private: const uint8_t* data; size_t len; void operator=(const Input&) = delete; // Use Init instead. }; inline bool InputsAreEqual(const Input& a, const Input& b) { return a.GetLength() == b.GetLength() && std::equal(a.UnsafeGetData(), a.UnsafeGetData() + a.GetLength(), b.UnsafeGetData()); } // An Reader is a cursor/iterator through the contents of an Input, designed to // maximize safety during parsing while minimizing the performance cost of that // safety. In particular, all methods do strict bounds checking to ensure // buffer overflows are impossible, and they are all inline so that the // compiler can coalesce as many of those checks together as possible. // // In general, Reader allows for one byte of lookahead and no backtracking. // However, the Match* functions internally may have more lookahead. class Reader final { public: Reader() : input(nullptr), end(nullptr) {} explicit Reader(Input aInput) : input(aInput.UnsafeGetData()), end(aInput.UnsafeGetData() + aInput.GetLength()) {} Result Init(Input aInput) { if (this->input) { return Result::FATAL_ERROR_INVALID_ARGS; } this->input = aInput.UnsafeGetData(); this->end = aInput.UnsafeGetData() + aInput.GetLength(); return Success; } bool Peek(uint8_t expectedByte) const { return input < end && *input == expectedByte; } Result Read(uint8_t& out) { Result rv = EnsureLength(1); if (rv != Success) { return rv; } out = *input++; return Success; } Result Read(uint16_t& out) { Result rv = EnsureLength(2); if (rv != Success) { return rv; } out = *input++; out <<= 8u; out |= *input++; return Success; } template bool MatchRest(const uint8_t (&toMatch)[N]) { // Normally we use EnsureLength which compares (input + len < end), but // here we want to be sure that there is nothing following the matched // bytes if (static_cast(end - input) != N) { return false; } if (!std::equal(input, end, toMatch)) { return false; } input = end; return true; } bool MatchRest(Input toMatch) { // Normally we use EnsureLength which compares (input + len < end), but // here we want to be sure that there is nothing following the matched // bytes size_t remaining = static_cast(end - input); if (toMatch.GetLength() != remaining) { return false; } if (!std::equal(input, end, toMatch.UnsafeGetData())) { return false; } input = end; return true; } Result Skip(Input::size_type len) { Result rv = EnsureLength(len); if (rv != Success) { return rv; } input += len; return Success; } Result Skip(Input::size_type len, Reader& skipped) { Result rv = EnsureLength(len); if (rv != Success) { return rv; } rv = skipped.Init(input, len); if (rv != Success) { return rv; } input += len; return Success; } Result Skip(Input::size_type len, /*out*/ Input& skipped) { Result rv = EnsureLength(len); if (rv != Success) { return rv; } rv = skipped.Init(input, len); if (rv != Success) { return rv; } input += len; return Success; } void SkipToEnd() { input = end; } Result SkipToEnd(/*out*/ Input& skipped) { return Skip(static_cast(end - input), skipped); } Result EnsureLength(Input::size_type len) { if (static_cast(end - input) < len) { return Result::ERROR_BAD_DER; } return Success; } bool AtEnd() const { return input == end; } class Mark final { public: Mark(const Mark&) = default; // Intentionally not explicit. private: friend class Reader; Mark(const Reader& aInput, const uint8_t* aMark) : input(aInput), mark(aMark) {} const Reader& input; const uint8_t* const mark; void operator=(const Mark&) = delete; }; Mark GetMark() const { return Mark(*this, input); } Result GetInput(const Mark& mark, /*out*/ Input& item) { if (&mark.input != this || mark.mark > input) { return NotReached("invalid mark", Result::FATAL_ERROR_INVALID_ARGS); } return item.Init(mark.mark, static_cast(input - mark.mark)); } private: Result Init(const uint8_t* data, Input::size_type len) { if (input) { // already initialized return Result::FATAL_ERROR_INVALID_ARGS; } input = data; end = data + len; return Success; } const uint8_t* input; const uint8_t* end; Reader(const Reader&) = delete; void operator=(const Reader&) = delete; }; inline bool InputContains(const Input& input, uint8_t toFind) { Reader reader(input); for (;;) { uint8_t b; if (reader.Read(b) != Success) { return false; } if (b == toFind) { return true; } } } } } // namespace mozilla::pkix #endif // mozilla_pkix_Input_h