src/cppbor_parse.cpp - platform/external/libcppbor - Gitiles

 /*
  * Copyright 2019 Google LLC
  *
  * 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.
  */

 #include "cppbor_parse.h"

 #include <sstream>
 #include <stack>

 #ifndef __TRUSTY__
 #include <android-base/logging.h>
 #define LOG_TAG "CppBor"
 #else
 #define CHECK(x) (void)(x)
 #endif

 namespace cppbor {

 namespace {

 std::string insufficientLengthString(size_t bytesNeeded, size_t bytesAvail,
                                      const std::string& type) {
     char buf[1024];
     snprintf(buf, sizeof(buf), "Need %zu byte(s) for %s, have %zu.", bytesNeeded, type.c_str(),
              bytesAvail);
     return std::string(buf);
 }

 template <typename T, typename = std::enable_if_t<std::is_unsigned_v<T>>>
 std::tuple<bool, uint64_t, const uint8_t*> parseLength(const uint8_t* pos, const uint8_t* end,
                                                        ParseClient* parseClient) {
     if (pos + sizeof(T) > end) {
         parseClient->error(pos - 1, insufficientLengthString(sizeof(T), end - pos, "length field"));
         return {false, 0, pos};
     }

     const uint8_t* intEnd = pos + sizeof(T);
     T result = 0;
     do {
         result = static_cast<T>((result << 8) | *pos++);
     } while (pos < intEnd);
     return {true, result, pos};
 }

 std::tuple<const uint8_t*, ParseClient*> parseRecursively(const uint8_t* begin, const uint8_t* end,
                                                           bool emitViews, ParseClient* parseClient);

 std::tuple<const uint8_t*, ParseClient*> handleUint(uint64_t value, const uint8_t* hdrBegin,
                                                     const uint8_t* hdrEnd,
                                                     ParseClient* parseClient) {
     std::unique_ptr<Item> item = std::make_unique<Uint>(value);
     return {hdrEnd,
             parseClient->item(item, hdrBegin, hdrEnd /* valueBegin */, hdrEnd /* itemEnd */)};
 }

 std::tuple<const uint8_t*, ParseClient*> handleNint(uint64_t value, const uint8_t* hdrBegin,
                                                     const uint8_t* hdrEnd,
                                                     ParseClient* parseClient) {
     if (value > std::numeric_limits<int64_t>::max()) {
         parseClient->error(hdrBegin, "NINT values that don't fit in int64_t are not supported.");
         return {hdrBegin, nullptr /* end parsing */};
     }
     std::unique_ptr<Item> item = std::make_unique<Nint>(-1 - static_cast<int64_t>(value));
     return {hdrEnd,
             parseClient->item(item, hdrBegin, hdrEnd /* valueBegin */, hdrEnd /* itemEnd */)};
 }

 std::tuple<const uint8_t*, ParseClient*> handleBool(uint64_t value, const uint8_t* hdrBegin,
                                                     const uint8_t* hdrEnd,
                                                     ParseClient* parseClient) {
     std::unique_ptr<Item> item = std::make_unique<Bool>(value == TRUE);
     return {hdrEnd,
             parseClient->item(item, hdrBegin, hdrEnd /* valueBegin */, hdrEnd /* itemEnd */)};
 }

 std::tuple<const uint8_t*, ParseClient*> handleNull(const uint8_t* hdrBegin, const uint8_t* hdrEnd,
                                                     ParseClient* parseClient) {
     std::unique_ptr<Item> item = std::make_unique<Null>();
     return {hdrEnd,
             parseClient->item(item, hdrBegin, hdrEnd /* valueBegin */, hdrEnd /* itemEnd */)};
 }

 template <typename T>
 std::tuple<const uint8_t*, ParseClient*> handleString(uint64_t length, const uint8_t* hdrBegin,
                                                       const uint8_t* valueBegin, const uint8_t* end,
                                                       const std::string& errLabel,
                                                       ParseClient* parseClient) {
     ssize_t signed_length = static_cast<ssize_t>(length);
     if (end - valueBegin < signed_length || signed_length < 0) {
         parseClient->error(hdrBegin, insufficientLengthString(length, end - valueBegin, errLabel));
         return {hdrBegin, nullptr /* end parsing */};
     }

     std::unique_ptr<Item> item = std::make_unique<T>(valueBegin, valueBegin + length);
     return {valueBegin + length,
             parseClient->item(item, hdrBegin, valueBegin, valueBegin + length)};
 }

 class IncompleteItem {
   public:
     virtual ~IncompleteItem() {}
     virtual void add(std::unique_ptr<Item> item) = 0;
 };

 class IncompleteArray : public Array, public IncompleteItem {
   public:
     explicit IncompleteArray(size_t size) : mSize(size) {}

     // We return the "complete" size, rather than the actual size.
     size_t size() const override { return mSize; }

     void add(std::unique_ptr<Item> item) override {
         mEntries.reserve(mSize);
         mEntries.push_back(std::move(item));
     }

   private:
     size_t mSize;
 };

 class IncompleteMap : public Map, public IncompleteItem {
   public:
     explicit IncompleteMap(size_t size) : mSize(size) {}

     // We return the "complete" size, rather than the actual size.
     size_t size() const override { return mSize; }

     void add(std::unique_ptr<Item> item) override {
         if (mKeyHeldForAdding) {
             mEntries.reserve(mSize);
             mEntries.push_back({std::move(mKeyHeldForAdding), std::move(item)});
         } else {
             mKeyHeldForAdding = std::move(item);
         }
     }

   private:
     std::unique_ptr<Item> mKeyHeldForAdding;
     size_t mSize;
 };

 class IncompleteSemanticTag : public SemanticTag, public IncompleteItem {
   public:
     explicit IncompleteSemanticTag(uint64_t value) : SemanticTag(value) {}

     // We return the "complete" size, rather than the actual size.
     size_t size() const override { return 1; }

     void add(std::unique_ptr<Item> item) override { mTaggedItem = std::move(item); }
 };

 std::tuple<const uint8_t*, ParseClient*> handleEntries(size_t entryCount, const uint8_t* hdrBegin,
                                                        const uint8_t* pos, const uint8_t* end,
                                                        const std::string& typeName,
                                                        bool emitViews,
                                                        ParseClient* parseClient) {
     while (entryCount > 0) {
         --entryCount;
         if (pos == end) {
             parseClient->error(hdrBegin, "Not enough entries for " + typeName + ".");
             return {hdrBegin, nullptr /* end parsing */};
         }
         std::tie(pos, parseClient) = parseRecursively(pos, end, emitViews, parseClient);
         if (!parseClient) return {hdrBegin, nullptr};
     }
     return {pos, parseClient};
 }

 std::tuple<const uint8_t*, ParseClient*> handleCompound(
         std::unique_ptr<Item> item, uint64_t entryCount, const uint8_t* hdrBegin,
         const uint8_t* valueBegin, const uint8_t* end, const std::string& typeName,
         bool emitViews, ParseClient* parseClient) {
     parseClient =
             parseClient->item(item, hdrBegin, valueBegin, valueBegin /* don't know the end yet */);
     if (!parseClient) return {hdrBegin, nullptr};

     const uint8_t* pos;
     std::tie(pos, parseClient) =
             handleEntries(entryCount, hdrBegin, valueBegin, end, typeName, emitViews, parseClient);
     if (!parseClient) return {hdrBegin, nullptr};

     return {pos, parseClient->itemEnd(item, hdrBegin, valueBegin, pos)};
 }

 std::tuple<const uint8_t*, ParseClient*> parseRecursively(const uint8_t* begin, const uint8_t* end,
                                                           bool emitViews, ParseClient* parseClient) {
     if (begin == end) {
         parseClient->error(
                 begin,
                 "Input buffer is empty. Begin and end cannot point to the same location.");
         return {begin, nullptr};
     }

     const uint8_t* pos = begin;

     MajorType type = static_cast<MajorType>(*pos & 0xE0);
     uint8_t tagInt = *pos & 0x1F;
     ++pos;

     bool success = true;
     uint64_t addlData;
     if (tagInt < ONE_BYTE_LENGTH) {
         addlData = tagInt;
     } else if (tagInt > EIGHT_BYTE_LENGTH) {
         parseClient->error(
                 begin,
                 "Reserved additional information value or unsupported indefinite length item.");
         return {begin, nullptr};
     } else {
         switch (tagInt) {
             case ONE_BYTE_LENGTH:
                 std::tie(success, addlData, pos) = parseLength<uint8_t>(pos, end, parseClient);
                 break;

             case TWO_BYTE_LENGTH:
                 std::tie(success, addlData, pos) = parseLength<uint16_t>(pos, end, parseClient);
                 break;

             case FOUR_BYTE_LENGTH:
                 std::tie(success, addlData, pos) = parseLength<uint32_t>(pos, end, parseClient);
                 break;

             case EIGHT_BYTE_LENGTH:
                 std::tie(success, addlData, pos) = parseLength<uint64_t>(pos, end, parseClient);
                 break;

             default:
                 CHECK(false);  //  It's impossible to get here
                 break;
         }
     }

     if (!success) return {begin, nullptr};

     switch (type) {
         case UINT:
             return handleUint(addlData, begin, pos, parseClient);

         case NINT:
             return handleNint(addlData, begin, pos, parseClient);

         case BSTR:
             if (emitViews) {
                 return handleString<ViewBstr>(addlData, begin, pos, end, "byte string", parseClient);
             } else {
                 return handleString<Bstr>(addlData, begin, pos, end, "byte string", parseClient);
             }

         case TSTR:
             if (emitViews) {
                 return handleString<ViewTstr>(addlData, begin, pos, end, "text string", parseClient);
             } else {
                 return handleString<Tstr>(addlData, begin, pos, end, "text string", parseClient);
             }

         case ARRAY:
             return handleCompound(std::make_unique<IncompleteArray>(addlData), addlData, begin, pos,
                                   end, "array", emitViews, parseClient);

         case MAP:
             return handleCompound(std::make_unique<IncompleteMap>(addlData), addlData * 2, begin,
                                   pos, end, "map", emitViews, parseClient);

         case SEMANTIC:
             return handleCompound(std::make_unique<IncompleteSemanticTag>(addlData), 1, begin, pos,
                                   end, "semantic", emitViews, parseClient);

         case SIMPLE:
             switch (addlData) {
                 case TRUE:
                 case FALSE:
                     return handleBool(addlData, begin, pos, parseClient);
                 case NULL_V:
                     return handleNull(begin, pos, parseClient);
                 default:
                     parseClient->error(begin, "Unsupported floating-point or simple value.");
                     return {begin, nullptr};
             }
     }
     CHECK(false);  // Impossible to get here.
     return {};
 }

 class FullParseClient : public ParseClient {
   public:
     virtual ParseClient* item(std::unique_ptr<Item>& item, const uint8_t*, const uint8_t*,
                               const uint8_t* end) override {
         if (mParentStack.empty() && !item->isCompound()) {
             // This is the first and only item.
             mTheItem = std::move(item);
             mPosition = end;
             return nullptr;  //  We're done.
         }

         if (item->isCompound()) {
             // Starting a new compound data item, i.e. a new parent.  Save it on the parent stack.
             // It's safe to save a raw pointer because the unique_ptr is guaranteed to stay in
             // existence until the corresponding itemEnd() call.
             mParentStack.push(item.get());
             return this;
         } else {
             appendToLastParent(std::move(item));
             return this;
         }
     }

     virtual ParseClient* itemEnd(std::unique_ptr<Item>& item, const uint8_t*, const uint8_t*,
                                  const uint8_t* end) override {
         CHECK(item->isCompound() && item.get() == mParentStack.top());
         mParentStack.pop();

         if (mParentStack.empty()) {
             mTheItem = std::move(item);
             mPosition = end;
             return nullptr;  // We're done
         } else {
             appendToLastParent(std::move(item));
             return this;
         }
     }

     virtual void error(const uint8_t* position, const std::string& errorMessage) override {
         mPosition = position;
         mErrorMessage = errorMessage;
     }

     std::tuple<std::unique_ptr<Item> /* result */, const uint8_t* /* newPos */,
                std::string /* errMsg */>
     parseResult() {
         std::unique_ptr<Item> p = std::move(mTheItem);
         return {std::move(p), mPosition, std::move(mErrorMessage)};
     }

   private:
     void appendToLastParent(std::unique_ptr<Item> item) {
         auto parent = mParentStack.top();
 #if __has_feature(cxx_rtti)
         assert(dynamic_cast<IncompleteItem*>(parent));
 #endif

         IncompleteItem* parentItem{};
         if (parent->type() == ARRAY) {
             parentItem = static_cast<IncompleteArray*>(parent);
         } else if (parent->type() == MAP) {
             parentItem = static_cast<IncompleteMap*>(parent);
         } else if (parent->asSemanticTag()) {
             parentItem = static_cast<IncompleteSemanticTag*>(parent);
         } else {
             CHECK(false);  // Impossible to get here.
         }
         parentItem->add(std::move(item));
     }

     std::unique_ptr<Item> mTheItem;
     std::stack<Item*> mParentStack;
     const uint8_t* mPosition = nullptr;
     std::string mErrorMessage;
 };

 }  // anonymous namespace

 void parse(const uint8_t* begin, const uint8_t* end, ParseClient* parseClient) {
     parseRecursively(begin, end, false, parseClient);
 }

 std::tuple<std::unique_ptr<Item> /* result */, const uint8_t* /* newPos */,
            std::string /* errMsg */>
 parse(const uint8_t* begin, const uint8_t* end) {
     FullParseClient parseClient;
     parse(begin, end, &parseClient);
     return parseClient.parseResult();
 }

 void parseWithViews(const uint8_t* begin, const uint8_t* end, ParseClient* parseClient) {
     parseRecursively(begin, end, true, parseClient);
 }

 std::tuple<std::unique_ptr<Item> /* result */, const uint8_t* /* newPos */,
            std::string /* errMsg */>
 parseWithViews(const uint8_t* begin, const uint8_t* end) {
     FullParseClient parseClient;
     parseWithViews(begin, end, &parseClient);
     return parseClient.parseResult();
 }

 }  // namespace cppbor
	/*
	* Copyright 2019 Google LLC
	*
	* 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.
	*/

	#include "cppbor_parse.h"

	#include <sstream>
	#include <stack>

	#ifndef __TRUSTY__
	#include <android-base/logging.h>
	#define LOG_TAG "CppBor"
	#else
	#define CHECK(x) (void)(x)
	#endif

	namespace cppbor {

	namespace {

	std::string insufficientLengthString(size_t bytesNeeded, size_t bytesAvail,
	const std::string& type) {
	char buf[1024];
	snprintf(buf, sizeof(buf), "Need %zu byte(s) for %s, have %zu.", bytesNeeded, type.c_str(),
	bytesAvail);
	return std::string(buf);
	}

	template <typename T, typename = std::enable_if_t<std::is_unsigned_v<T>>>
	std::tuple<bool, uint64_t, const uint8_t> parseLength(const uint8_t pos, const uint8_t* end,
	ParseClient* parseClient) {
	if (pos + sizeof(T) > end) {
	parseClient->error(pos - 1, insufficientLengthString(sizeof(T), end - pos, "length field"));
	return {false, 0, pos};
	}

	const uint8_t* intEnd = pos + sizeof(T);
	T result = 0;
	do {
	result = static_cast<T>((result << 8) \| *pos++);
	} while (pos < intEnd);
	return {true, result, pos};
	}

	std::tuple<const uint8_t, ParseClient> parseRecursively(const uint8_t* begin, const uint8_t* end,
	bool emitViews, ParseClient* parseClient);

	std::tuple<const uint8_t, ParseClient> handleUint(uint64_t value, const uint8_t* hdrBegin,
	const uint8_t* hdrEnd,
	ParseClient* parseClient) {
	std::unique_ptr<Item> item = std::make_unique<Uint>(value);
	return {hdrEnd,
	parseClient->item(item, hdrBegin, hdrEnd /* valueBegin /, hdrEnd / itemEnd */)};
	}

	std::tuple<const uint8_t, ParseClient> handleNint(uint64_t value, const uint8_t* hdrBegin,
	const uint8_t* hdrEnd,
	ParseClient* parseClient) {
	if (value > std::numeric_limits<int64_t>::max()) {
	parseClient->error(hdrBegin, "NINT values that don't fit in int64_t are not supported.");
	return {hdrBegin, nullptr /* end parsing */};
	}
	std::unique_ptr<Item> item = std::make_unique<Nint>(-1 - static_cast<int64_t>(value));
	return {hdrEnd,
	parseClient->item(item, hdrBegin, hdrEnd /* valueBegin /, hdrEnd / itemEnd */)};
	}

	std::tuple<const uint8_t, ParseClient> handleBool(uint64_t value, const uint8_t* hdrBegin,
	const uint8_t* hdrEnd,
	ParseClient* parseClient) {
	std::unique_ptr<Item> item = std::make_unique<Bool>(value == TRUE);
	return {hdrEnd,
	parseClient->item(item, hdrBegin, hdrEnd /* valueBegin /, hdrEnd / itemEnd */)};
	}

	std::tuple<const uint8_t, ParseClient> handleNull(const uint8_t* hdrBegin, const uint8_t* hdrEnd,
	ParseClient* parseClient) {
	std::unique_ptr<Item> item = std::make_unique<Null>();
	return {hdrEnd,
	parseClient->item(item, hdrBegin, hdrEnd /* valueBegin /, hdrEnd / itemEnd */)};
	}

	template <typename T>
	std::tuple<const uint8_t, ParseClient> handleString(uint64_t length, const uint8_t* hdrBegin,
	const uint8_t* valueBegin, const uint8_t* end,
	const std::string& errLabel,
	ParseClient* parseClient) {
	ssize_t signed_length = static_cast<ssize_t>(length);
	if (end - valueBegin < signed_length \|\| signed_length < 0) {
	parseClient->error(hdrBegin, insufficientLengthString(length, end - valueBegin, errLabel));
	return {hdrBegin, nullptr /* end parsing */};
	}

	std::unique_ptr<Item> item = std::make_unique<T>(valueBegin, valueBegin + length);
	return {valueBegin + length,
	parseClient->item(item, hdrBegin, valueBegin, valueBegin + length)};
	}

	class IncompleteItem {
	public:
	virtual ~IncompleteItem() {}
	virtual void add(std::unique_ptr<Item> item) = 0;
	};

	class IncompleteArray : public Array, public IncompleteItem {
	public:
	explicit IncompleteArray(size_t size) : mSize(size) {}

	// We return the "complete" size, rather than the actual size.
	size_t size() const override { return mSize; }

	void add(std::unique_ptr<Item> item) override {
	mEntries.reserve(mSize);
	mEntries.push_back(std::move(item));
	}

	private:
	size_t mSize;
	};

	class IncompleteMap : public Map, public IncompleteItem {
	public:
	explicit IncompleteMap(size_t size) : mSize(size) {}

	// We return the "complete" size, rather than the actual size.
	size_t size() const override { return mSize; }

	void add(std::unique_ptr<Item> item) override {
	if (mKeyHeldForAdding) {
	mEntries.reserve(mSize);
	mEntries.push_back({std::move(mKeyHeldForAdding), std::move(item)});
	} else {
	mKeyHeldForAdding = std::move(item);
	}
	}

	private:
	std::unique_ptr<Item> mKeyHeldForAdding;
	size_t mSize;
	};

	class IncompleteSemanticTag : public SemanticTag, public IncompleteItem {
	public:
	explicit IncompleteSemanticTag(uint64_t value) : SemanticTag(value) {}

	// We return the "complete" size, rather than the actual size.
	size_t size() const override { return 1; }

	void add(std::unique_ptr<Item> item) override { mTaggedItem = std::move(item); }
	};

	std::tuple<const uint8_t, ParseClient> handleEntries(size_t entryCount, const uint8_t* hdrBegin,
	const uint8_t* pos, const uint8_t* end,
	const std::string& typeName,
	bool emitViews,
	ParseClient* parseClient) {
	while (entryCount > 0) {
	--entryCount;
	if (pos == end) {
	parseClient->error(hdrBegin, "Not enough entries for " + typeName + ".");
	return {hdrBegin, nullptr /* end parsing */};
	}
	std::tie(pos, parseClient) = parseRecursively(pos, end, emitViews, parseClient);
	if (!parseClient) return {hdrBegin, nullptr};
	}
	return {pos, parseClient};
	}

	std::tuple<const uint8_t, ParseClient> handleCompound(
	std::unique_ptr<Item> item, uint64_t entryCount, const uint8_t* hdrBegin,
	const uint8_t* valueBegin, const uint8_t* end, const std::string& typeName,
	bool emitViews, ParseClient* parseClient) {
	parseClient =
	parseClient->item(item, hdrBegin, valueBegin, valueBegin /* don't know the end yet */);
	if (!parseClient) return {hdrBegin, nullptr};

	const uint8_t* pos;
	std::tie(pos, parseClient) =
	handleEntries(entryCount, hdrBegin, valueBegin, end, typeName, emitViews, parseClient);
	if (!parseClient) return {hdrBegin, nullptr};

	return {pos, parseClient->itemEnd(item, hdrBegin, valueBegin, pos)};
	}

	std::tuple<const uint8_t, ParseClient> parseRecursively(const uint8_t* begin, const uint8_t* end,
	bool emitViews, ParseClient* parseClient) {
	if (begin == end) {
	parseClient->error(
	begin,
	"Input buffer is empty. Begin and end cannot point to the same location.");
	return {begin, nullptr};
	}

	const uint8_t* pos = begin;

	MajorType type = static_cast<MajorType>(*pos & 0xE0);
	uint8_t tagInt = *pos & 0x1F;
	++pos;

	bool success = true;
	uint64_t addlData;
	if (tagInt < ONE_BYTE_LENGTH) {
	addlData = tagInt;
	} else if (tagInt > EIGHT_BYTE_LENGTH) {
	parseClient->error(
	begin,
	"Reserved additional information value or unsupported indefinite length item.");
	return {begin, nullptr};
	} else {
	switch (tagInt) {
	case ONE_BYTE_LENGTH:
	std::tie(success, addlData, pos) = parseLength<uint8_t>(pos, end, parseClient);
	break;

	case TWO_BYTE_LENGTH:
	std::tie(success, addlData, pos) = parseLength<uint16_t>(pos, end, parseClient);
	break;

	case FOUR_BYTE_LENGTH:
	std::tie(success, addlData, pos) = parseLength<uint32_t>(pos, end, parseClient);
	break;

	case EIGHT_BYTE_LENGTH:
	std::tie(success, addlData, pos) = parseLength<uint64_t>(pos, end, parseClient);
	break;

	default:
	CHECK(false); // It's impossible to get here
	break;
	}
	}

	if (!success) return {begin, nullptr};

	switch (type) {
	case UINT:
	return handleUint(addlData, begin, pos, parseClient);

	case NINT:
	return handleNint(addlData, begin, pos, parseClient);

	case BSTR:
	if (emitViews) {
	return handleString<ViewBstr>(addlData, begin, pos, end, "byte string", parseClient);
	} else {
	return handleString<Bstr>(addlData, begin, pos, end, "byte string", parseClient);
	}

	case TSTR:
	if (emitViews) {
	return handleString<ViewTstr>(addlData, begin, pos, end, "text string", parseClient);
	} else {
	return handleString<Tstr>(addlData, begin, pos, end, "text string", parseClient);
	}

	case ARRAY:
	return handleCompound(std::make_unique<IncompleteArray>(addlData), addlData, begin, pos,
	end, "array", emitViews, parseClient);

	case MAP:
	return handleCompound(std::make_unique<IncompleteMap>(addlData), addlData * 2, begin,
	pos, end, "map", emitViews, parseClient);

	case SEMANTIC:
	return handleCompound(std::make_unique<IncompleteSemanticTag>(addlData), 1, begin, pos,
	end, "semantic", emitViews, parseClient);

	case SIMPLE:
	switch (addlData) {
	case TRUE:
	case FALSE:
	return handleBool(addlData, begin, pos, parseClient);
	case NULL_V:
	return handleNull(begin, pos, parseClient);
	default:
	parseClient->error(begin, "Unsupported floating-point or simple value.");
	return {begin, nullptr};
	}
	}
	CHECK(false); // Impossible to get here.
	return {};
	}

	class FullParseClient : public ParseClient {
	public:
	virtual ParseClient* item(std::unique_ptr<Item>& item, const uint8_t, const uint8_t,
	const uint8_t* end) override {
	if (mParentStack.empty() && !item->isCompound()) {
	// This is the first and only item.
	mTheItem = std::move(item);
	mPosition = end;
	return nullptr; // We're done.
	}

	if (item->isCompound()) {
	// Starting a new compound data item, i.e. a new parent. Save it on the parent stack.
	// It's safe to save a raw pointer because the unique_ptr is guaranteed to stay in
	// existence until the corresponding itemEnd() call.
	mParentStack.push(item.get());
	return this;
	} else {
	appendToLastParent(std::move(item));
	return this;
	}
	}

	virtual ParseClient* itemEnd(std::unique_ptr<Item>& item, const uint8_t, const uint8_t,
	const uint8_t* end) override {
	CHECK(item->isCompound() && item.get() == mParentStack.top());
	mParentStack.pop();

	if (mParentStack.empty()) {
	mTheItem = std::move(item);
	mPosition = end;
	return nullptr; // We're done
	} else {
	appendToLastParent(std::move(item));
	return this;
	}
	}

	virtual void error(const uint8_t* position, const std::string& errorMessage) override {
	mPosition = position;
	mErrorMessage = errorMessage;
	}

	std::tuple<std::unique_ptr<Item> /* result /, const uint8_t /* newPos */,
	std::string /* errMsg */>
	parseResult() {
	std::unique_ptr<Item> p = std::move(mTheItem);
	return {std::move(p), mPosition, std::move(mErrorMessage)};
	}

	private:
	void appendToLastParent(std::unique_ptr<Item> item) {
	auto parent = mParentStack.top();
	#if __has_feature(cxx_rtti)
	assert(dynamic_cast<IncompleteItem*>(parent));
	#endif

	IncompleteItem* parentItem{};
	if (parent->type() == ARRAY) {
	parentItem = static_cast<IncompleteArray*>(parent);
	} else if (parent->type() == MAP) {
	parentItem = static_cast<IncompleteMap*>(parent);
	} else if (parent->asSemanticTag()) {
	parentItem = static_cast<IncompleteSemanticTag*>(parent);
	} else {
	CHECK(false); // Impossible to get here.
	}
	parentItem->add(std::move(item));
	}

	std::unique_ptr<Item> mTheItem;
	std::stack<Item*> mParentStack;
	const uint8_t* mPosition = nullptr;
	std::string mErrorMessage;
	};

	} // anonymous namespace

	void parse(const uint8_t* begin, const uint8_t* end, ParseClient* parseClient) {
	parseRecursively(begin, end, false, parseClient);
	}

	std::tuple<std::unique_ptr<Item> /* result /, const uint8_t /* newPos */,
	std::string /* errMsg */>
	parse(const uint8_t* begin, const uint8_t* end) {
	FullParseClient parseClient;
	parse(begin, end, &parseClient);
	return parseClient.parseResult();
	}

	void parseWithViews(const uint8_t* begin, const uint8_t* end, ParseClient* parseClient) {
	parseRecursively(begin, end, true, parseClient);
	}

	std::tuple<std::unique_ptr<Item> /* result /, const uint8_t /* newPos */,
	std::string /* errMsg */>
	parseWithViews(const uint8_t* begin, const uint8_t* end) {
	FullParseClient parseClient;
	parseWithViews(begin, end, &parseClient);
	return parseClient.parseResult();
	}

	} // namespace cppbor