src/net/der/parser.h - cobalt - Git at Google

 // Copyright 2015 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef NET_DER_PARSER_H_
 #define NET_DER_PARSER_H_

 #include "base/compiler_specific.h"
 #include "base/macros.h"
 #include "net/base/net_export.h"
 #include "net/der/input.h"
 #include "net/der/tag.h"
 #include "starboard/types.h"
 #include "third_party/boringssl/src/include/openssl/bytestring.h"

 namespace net {

 namespace der {

 class BitString;
 struct GeneralizedTime;

 // Parses a DER-encoded ASN.1 structure. DER (distinguished encoding rules)
 // encodes each data value with a tag, length, and value (TLV). The tag
 // indicates the type of the ASN.1 value. Depending on the type of the value,
 // it could contain arbitrary bytes, so the length of the value is encoded
 // after the tag and before the value to indicate how many bytes of value
 // follow. DER also defines how the values are encoded for particular types.
 //
 // This Parser places a few restrictions on the DER encoding it can parse. The
 // largest restriction is that it only supports tags which have a tag number
 // no greater than 30 - these are the tags that fit in a single octet. The
 // second restriction is that the maximum length for a value that can be parsed
 // is 4GB. Both of these restrictions should be fine for any reasonable input.
 //
 // The Parser class is mainly focused on parsing the TLV structure of DER
 // encoding, and does not directly handle parsing primitive values (other
 // functions in the net::der namespace are provided for this.) When a Parser
 // is created, it is passed in a reference to the encoded data. Because the
 // encoded data is not owned by the Parser, the data cannot change during the
 // lifespan of the Parser. The Parser functions by keeping a pointer to the
 // current TLV which starts at the beginning of the input and advancing through
 // the input as each TLV is read. As such, a Parser instance is thread-unsafe.
 //
 // Most methods for using the Parser write the current tag and/or value to
 // the output parameters provided and then advance the input to the next TLV.
 // None of the methods explicitly expose the length because it is part of the
 // value. All methods return a boolean indicating whether there was a parsing
 // error with the current TLV.
 //
 // Some methods are provided in the Parser class as convenience to both read
 // the current TLV from the input and also parse the DER encoded value,
 // converting it to a corresponding C++ type. These methods simply combine
 // ReadTag() with the appropriate ParseType() free function.
 //
 // The design of DER encoding allows for nested data structures with
 // constructed values, where the value is a series of TLVs. The Parser class
 // is not designed to traverse through a nested encoding from a single object,
 // but it does facilitate parsing nested data structures through the
 // convenience methods ReadSequence() and the more general ReadConstructed(),
 // which provide the user with another Parser object to traverse the next
 // level of TLVs.
 //
 // For a brief example of how to use the Parser, suppose we have the following
 // ASN.1 type definition:
 //
 //   Foo ::= SEQUENCE {
 //     bar OCTET STRING OPTIONAL,
 //     quux OCTET STRING }
 //
 // If we have a DER-encoded Foo in an Input |encoded_value|, the
 // following code shows an example of how to parse the quux field from the
 // encoded data.
 //
 //   bool ReadQuux(const Input& encoded_value, Input* quux_out) {
 //     Parser parser(encoded_value);
 //     Parser foo_parser;
 //     if (!parser.ReadSequence(&foo_parser))
 //       return false;
 //     if (!foo_parser->SkipOptionalTag(kOctetString))
 //       return false;
 //     if (!foo_parser->ReadTag(kOctetString, quux_out))
 //       return false;
 //     return true;
 //   }
 class NET_EXPORT Parser {
  public:
   // Default constructor; equivalent to calling Parser(Input()). This only
   // exists so that a Parser can be stack allocated and passed in to
   // ReadConstructed() and similar methods.
   Parser();

   // Creates a parser to parse over the data represented by input. This class
   // assumes that the underlying data will not change over the lifetime of
   // the Parser object.
   explicit Parser(const Input& input);

   // Returns whether there is any more data left in the input to parse. This
   // does not guarantee that the data is parseable.
   bool HasMore();

   // Reads the current TLV from the input and advances. If the tag or length
   // encoding for the current value is invalid, this method returns false and
   // does not advance the input. Otherwise, it returns true, putting the
   // read tag in |tag| and the value in |out|.
   bool ReadTagAndValue(Tag* tag, Input* out) WARN_UNUSED_RESULT;

   // Reads the current TLV from the input and advances. Unlike ReadTagAndValue
   // where only the value is put in |out|, this puts the raw bytes from the
   // tag, length, and value in |out|.
   bool ReadRawTLV(Input* out) WARN_UNUSED_RESULT;

   // Basic methods for reading or skipping the current TLV, with an
   // expectation of what the current tag should be. It should be possible
   // to parse any structure with these 4 methods; convenience methods are also
   // provided to make some cases easier.

   // If the current tag in the input is |tag|, it puts the corresponding value
   // in |out|, sets |was_present| to true, and advances the input to the next
   // TLV. If the current tag is something else, then |was_present| is set to
   // false and the input is not advanced. Like ReadTagAndValue, it returns
   // false if the encoding is invalid and does not advance the input.
   bool ReadOptionalTag(Tag tag,
                        Input* out,
                        bool* was_present) WARN_UNUSED_RESULT;

   // Like ReadOptionalTag, but the value is discarded.
   bool SkipOptionalTag(Tag tag, bool* was_present) WARN_UNUSED_RESULT;

   // If the current tag matches |tag|, it puts the current value in |out|,
   // advances the input, and returns true. Otherwise, it returns false.
   bool ReadTag(Tag tag, Input* out) WARN_UNUSED_RESULT;

   // Advances the input and returns true if the current tag matches |tag|;
   // otherwise it returns false.
   bool SkipTag(Tag tag) WARN_UNUSED_RESULT;

   // Convenience methods to combine parsing the TLV with parsing the DER
   // encoding for a specific type.

   // Reads the current TLV from the input, checks that the tag matches |tag|
   // and is a constructed tag, and creates a new Parser from the value.
   bool ReadConstructed(Tag tag, Parser* out) WARN_UNUSED_RESULT;

   // A more specific form of ReadConstructed that expects the current tag
   // to be 0x30 (SEQUENCE).
   bool ReadSequence(Parser* out) WARN_UNUSED_RESULT;

   // Expects the current tag to be kInteger, and calls ParseUint8 on the
   // current value. Note that DER-encoded integers are arbitrary precision,
   // so this method will fail for valid input that represents an integer
   // outside the range of an uint8_t.
   //
   // Note that on failure the Parser is left in an undefined state (the
   // input may or may not have been advanced).
   bool ReadUint8(uint8_t* out) WARN_UNUSED_RESULT;

   // Expects the current tag to be kInteger, and calls ParseUint64 on the
   // current value. Note that DER-encoded integers are arbitrary precision,
   // so this method will fail for valid input that represents an integer
   // outside the range of an uint64_t.
   //
   // Note that on failure the Parser is left in an undefined state (the
   // input may or may not have been advanced).
   bool ReadUint64(uint64_t* out) WARN_UNUSED_RESULT;

   // Reads a BIT STRING. On success fills |out| and returns true.
   //
   // Note that on failure the Parser is left in an undefined state (the
   // input may or may not have been advanced).
   bool ReadBitString(BitString* out) WARN_UNUSED_RESULT;

   // Reads a GeneralizeTime. On success fills |out| and returns true.
   //
   // Note that on failure the Parser is left in an undefined state (the
   // input may or may not have been advanced).
   bool ReadGeneralizedTime(GeneralizedTime* out) WARN_UNUSED_RESULT;

   // Lower level methods. The previous methods couple reading data from the
   // input with advancing the Parser's internal pointer to the next TLV; these
   // lower level methods decouple those two steps into methods that read from
   // the current TLV and a method that advances the internal pointer to the
   // next TLV.

   // Reads the current TLV from the input, putting the tag in |tag| and the raw
   // value in |out|, but does not advance the input. Returns true if the tag
   // and length are successfully read and the output exists.
   bool PeekTagAndValue(Tag* tag, Input* out) WARN_UNUSED_RESULT;

   // Advances the input to the next TLV. This method only needs to be called
   // after PeekTagAndValue; all other methods will advance the input if they
   // read something.
   bool Advance();

  private:
   CBS cbs_;
   size_t advance_len_;

   DISALLOW_COPY(Parser);
 };

 }  // namespace der

 }  // namespace net

 #endif  // NET_DER_PARSER_H_
	// Copyright 2015 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef NET_DER_PARSER_H_
	#define NET_DER_PARSER_H_

	#include "base/compiler_specific.h"
	#include "base/macros.h"
	#include "net/base/net_export.h"
	#include "net/der/input.h"
	#include "net/der/tag.h"
	#include "starboard/types.h"
	#include "third_party/boringssl/src/include/openssl/bytestring.h"

	namespace net {

	namespace der {

	class BitString;
	struct GeneralizedTime;

	// Parses a DER-encoded ASN.1 structure. DER (distinguished encoding rules)
	// encodes each data value with a tag, length, and value (TLV). The tag
	// indicates the type of the ASN.1 value. Depending on the type of the value,
	// it could contain arbitrary bytes, so the length of the value is encoded
	// after the tag and before the value to indicate how many bytes of value
	// follow. DER also defines how the values are encoded for particular types.
	//
	// This Parser places a few restrictions on the DER encoding it can parse. The
	// largest restriction is that it only supports tags which have a tag number
	// no greater than 30 - these are the tags that fit in a single octet. The
	// second restriction is that the maximum length for a value that can be parsed
	// is 4GB. Both of these restrictions should be fine for any reasonable input.
	//
	// The Parser class is mainly focused on parsing the TLV structure of DER
	// encoding, and does not directly handle parsing primitive values (other
	// functions in the net::der namespace are provided for this.) When a Parser
	// is created, it is passed in a reference to the encoded data. Because the
	// encoded data is not owned by the Parser, the data cannot change during the
	// lifespan of the Parser. The Parser functions by keeping a pointer to the
	// current TLV which starts at the beginning of the input and advancing through
	// the input as each TLV is read. As such, a Parser instance is thread-unsafe.
	//
	// Most methods for using the Parser write the current tag and/or value to
	// the output parameters provided and then advance the input to the next TLV.
	// None of the methods explicitly expose the length because it is part of the
	// value. All methods return a boolean indicating whether there was a parsing
	// error with the current TLV.
	//
	// Some methods are provided in the Parser class as convenience to both read
	// the current TLV from the input and also parse the DER encoded value,
	// converting it to a corresponding C++ type. These methods simply combine
	// ReadTag() with the appropriate ParseType() free function.
	//
	// The design of DER encoding allows for nested data structures with
	// constructed values, where the value is a series of TLVs. The Parser class
	// is not designed to traverse through a nested encoding from a single object,
	// but it does facilitate parsing nested data structures through the
	// convenience methods ReadSequence() and the more general ReadConstructed(),
	// which provide the user with another Parser object to traverse the next
	// level of TLVs.
	//
	// For a brief example of how to use the Parser, suppose we have the following
	// ASN.1 type definition:
	//
	// Foo ::= SEQUENCE {
	// bar OCTET STRING OPTIONAL,
	// quux OCTET STRING }
	//
	// If we have a DER-encoded Foo in an Input \|encoded_value\|, the
	// following code shows an example of how to parse the quux field from the
	// encoded data.
	//
	// bool ReadQuux(const Input& encoded_value, Input* quux_out) {
	// Parser parser(encoded_value);
	// Parser foo_parser;
	// if (!parser.ReadSequence(&foo_parser))
	// return false;
	// if (!foo_parser->SkipOptionalTag(kOctetString))
	// return false;
	// if (!foo_parser->ReadTag(kOctetString, quux_out))
	// return false;
	// return true;
	// }
	class NET_EXPORT Parser {
	public:
	// Default constructor; equivalent to calling Parser(Input()). This only
	// exists so that a Parser can be stack allocated and passed in to
	// ReadConstructed() and similar methods.
	Parser();

	// Creates a parser to parse over the data represented by input. This class
	// assumes that the underlying data will not change over the lifetime of
	// the Parser object.
	explicit Parser(const Input& input);

	// Returns whether there is any more data left in the input to parse. This
	// does not guarantee that the data is parseable.
	bool HasMore();

	// Reads the current TLV from the input and advances. If the tag or length
	// encoding for the current value is invalid, this method returns false and
	// does not advance the input. Otherwise, it returns true, putting the
	// read tag in \|tag\| and the value in \|out\|.
	bool ReadTagAndValue(Tag* tag, Input* out) WARN_UNUSED_RESULT;

	// Reads the current TLV from the input and advances. Unlike ReadTagAndValue
	// where only the value is put in \|out\|, this puts the raw bytes from the
	// tag, length, and value in \|out\|.
	bool ReadRawTLV(Input* out) WARN_UNUSED_RESULT;

	// Basic methods for reading or skipping the current TLV, with an
	// expectation of what the current tag should be. It should be possible
	// to parse any structure with these 4 methods; convenience methods are also
	// provided to make some cases easier.

	// If the current tag in the input is \|tag\|, it puts the corresponding value
	// in \|out\|, sets \|was_present\| to true, and advances the input to the next
	// TLV. If the current tag is something else, then \|was_present\| is set to
	// false and the input is not advanced. Like ReadTagAndValue, it returns
	// false if the encoding is invalid and does not advance the input.
	bool ReadOptionalTag(Tag tag,
	Input* out,
	bool* was_present) WARN_UNUSED_RESULT;

	// Like ReadOptionalTag, but the value is discarded.
	bool SkipOptionalTag(Tag tag, bool* was_present) WARN_UNUSED_RESULT;

	// If the current tag matches \|tag\|, it puts the current value in \|out\|,
	// advances the input, and returns true. Otherwise, it returns false.
	bool ReadTag(Tag tag, Input* out) WARN_UNUSED_RESULT;

	// Advances the input and returns true if the current tag matches \|tag\|;
	// otherwise it returns false.
	bool SkipTag(Tag tag) WARN_UNUSED_RESULT;

	// Convenience methods to combine parsing the TLV with parsing the DER
	// encoding for a specific type.

	// Reads the current TLV from the input, checks that the tag matches \|tag\|
	// and is a constructed tag, and creates a new Parser from the value.
	bool ReadConstructed(Tag tag, Parser* out) WARN_UNUSED_RESULT;

	// A more specific form of ReadConstructed that expects the current tag
	// to be 0x30 (SEQUENCE).
	bool ReadSequence(Parser* out) WARN_UNUSED_RESULT;

	// Expects the current tag to be kInteger, and calls ParseUint8 on the
	// current value. Note that DER-encoded integers are arbitrary precision,
	// so this method will fail for valid input that represents an integer
	// outside the range of an uint8_t.
	//
	// Note that on failure the Parser is left in an undefined state (the
	// input may or may not have been advanced).
	bool ReadUint8(uint8_t* out) WARN_UNUSED_RESULT;

	// Expects the current tag to be kInteger, and calls ParseUint64 on the
	// current value. Note that DER-encoded integers are arbitrary precision,
	// so this method will fail for valid input that represents an integer
	// outside the range of an uint64_t.
	//
	// Note that on failure the Parser is left in an undefined state (the
	// input may or may not have been advanced).
	bool ReadUint64(uint64_t* out) WARN_UNUSED_RESULT;

	// Reads a BIT STRING. On success fills \|out\| and returns true.
	//
	// Note that on failure the Parser is left in an undefined state (the
	// input may or may not have been advanced).
	bool ReadBitString(BitString* out) WARN_UNUSED_RESULT;

	// Reads a GeneralizeTime. On success fills \|out\| and returns true.
	//
	// Note that on failure the Parser is left in an undefined state (the
	// input may or may not have been advanced).
	bool ReadGeneralizedTime(GeneralizedTime* out) WARN_UNUSED_RESULT;

	// Lower level methods. The previous methods couple reading data from the
	// input with advancing the Parser's internal pointer to the next TLV; these
	// lower level methods decouple those two steps into methods that read from
	// the current TLV and a method that advances the internal pointer to the
	// next TLV.

	// Reads the current TLV from the input, putting the tag in \|tag\| and the raw
	// value in \|out\|, but does not advance the input. Returns true if the tag
	// and length are successfully read and the output exists.
	bool PeekTagAndValue(Tag* tag, Input* out) WARN_UNUSED_RESULT;

	// Advances the input to the next TLV. This method only needs to be called
	// after PeekTagAndValue; all other methods will advance the input if they
	// read something.
	bool Advance();

	private:
	CBS cbs_;
	size_t advance_len_;

	DISALLOW_COPY(Parser);
	};

	} // namespace der

	} // namespace net

	#endif // NET_DER_PARSER_H_