/* * Copyright 2013-2019 Software Radio Systems Limited * * This file is part of srsLTE. * * srsLTE is free software: you can redistribute it and/or modify * it under the terms of the GNU Affero General Public License as * published by the Free Software Foundation, either version 3 of * the License, or (at your option) any later version. * * srsLTE is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU Affero General Public License for more details. * * A copy of the GNU Affero General Public License can be found in * the LICENSE file in the top-level directory of this distribution * and at http://www.gnu.org/licenses/. * */ #ifndef SRSASN_COMMON_UTILS_H #define SRSASN_COMMON_UTILS_H #include "srslte/common/log.h" #include #include #include #include #include #include #include #include /* va_list, va_start, va_arg, va_end */ #include #include #include namespace asn1 { #define ASN_16K 16384 #define ASN_64K 65536 template constexpr Integer ceil_frac(Integer n, Integer d) { return (n + (d - 1)) / d; } /************************ logging ************************/ using srsasn_logger_level_t = srslte::LOG_LEVEL_ENUM; using srslte::LOG_LEVEL_DEBUG; using srslte::LOG_LEVEL_ERROR; using srslte::LOG_LEVEL_INFO; using srslte::LOG_LEVEL_WARNING; void vlog_print(srslte::log* log_ptr, srsasn_logger_level_t log_level, const char* format, va_list args); void srsasn_log_register_handler(srslte::log* ctx); void srsasn_log_print(srsasn_logger_level_t log_level, const char* format, ...); /************************ error handling ************************/ enum SRSASN_CODE { SRSASN_SUCCESS, SRSASN_ERROR_ENCODE_FAIL, SRSASN_ERROR_DECODE_FAIL }; void log_error_code(SRSASN_CODE code, const char* filename, int line); #define HANDLE_CODE(ret) \ do { \ SRSASN_CODE macrocode = ((ret)); \ if (macrocode != SRSASN_SUCCESS) { \ log_error_code(macrocode, __FILE__, __LINE__); \ return macrocode; \ } \ } while (0) /************************ bit_ref ************************/ struct ValOrError { uint32_t val; SRSASN_CODE code; ValOrError() : val(0), code(SRSASN_SUCCESS) {} ValOrError(uint32_t val_, SRSASN_CODE code_) : val(val_), code(code_) {} }; ValOrError unpack_bits(uint8_t*& ptr, uint8_t& offset, uint8_t* max_ptr, uint32_t n_bits); class bit_ref { public: bit_ref() = default; bit_ref(uint8_t* start_ptr_, uint32_t max_size_) : ptr(start_ptr_), start_ptr(start_ptr_), max_ptr(max_size_ + start_ptr_) { } int distance(const bit_ref& other) const; int distance(uint8_t* ref_ptr) const; int distance() const; int distance_bytes(uint8_t* ref_ptr) const; int distance_bytes() const; SRSASN_CODE pack(uint32_t val, uint32_t n_bits); SRSASN_CODE pack_bytes(const uint8_t* buf, uint32_t n_bytes); template SRSASN_CODE unpack(T& val, uint32_t n_bits) { ValOrError ret = unpack_bits(ptr, offset, max_ptr, n_bits); val = ret.val; return ret.code; } SRSASN_CODE unpack_bytes(uint8_t* buf, uint32_t n_bytes); SRSASN_CODE align_bytes(); SRSASN_CODE align_bytes_zero(); SRSASN_CODE advance_bits(uint32_t n_bits); void set(uint8_t* start_ptr_, uint32_t max_size_); private: uint8_t* ptr = nullptr; uint8_t offset = 0; uint8_t* start_ptr = nullptr; uint8_t* max_ptr = nullptr; }; /********************* function helpers *********************/ template class dyn_array { public: typedef T item_type; using iterator = T*; using const_iterator = const T*; dyn_array() = default; explicit dyn_array(uint32_t new_size) : size_(new_size), cap_(new_size) { data_ = new T[size_]; } dyn_array(const dyn_array& other) { size_ = other.size_; cap_ = other.cap_; data_ = new T[cap_]; std::copy(&other[0], &other[size_], data_); } ~dyn_array() { if (data_ != NULL) { delete[] data_; } } uint32_t size() const { return size_; } uint32_t capacity() const { return cap_; } T& operator[](uint32_t idx) { return data_[idx]; } const T& operator[](uint32_t idx) const { return data_[idx]; } dyn_array& operator=(const dyn_array& other) { if (this == &other) { return *this; } resize(other.size()); std::copy(&other[0], &other[size_], data_); return *this; } void resize(uint32_t new_size, uint32_t new_cap = 0) { if (new_size == size_) { return; } if (cap_ >= new_size) { size_ = new_size; return; } T* old_data = data_; cap_ = new_size > new_cap ? new_size : new_cap; if (cap_ > 0) { data_ = new T[cap_]; if (old_data != NULL) { std::copy(&old_data[0], &old_data[size_], data_); } } else { data_ = NULL; } size_ = new_size; if (old_data != NULL) { delete[] old_data; } } bool operator==(const dyn_array& other) const { return size() == other.size() and std::equal(data_, data_ + size(), other.data_); } void push_back(const T& elem) { resize(size() + 1, size() * 2); data_[size() - 1] = elem; } T& back() { return data_[size() - 1]; } const T& back() const { return data_[size() - 1]; } T* data() { return &data_[0]; } const T* data() const { return &data_[0]; } iterator begin() { return &data_[0]; } iterator end() { return &data_[size()]; } const_iterator begin() const { return &data_[0]; } const_iterator end() const { return &data_[size()]; } private: T* data_ = nullptr; uint32_t size_ = 0; uint32_t cap_ = 0; }; template class bounded_array { public: typedef T item_type; using iterator = T*; using const_iterator = const T*; bounded_array(uint32_t size_ = 0) : current_size(size_) {} static uint32_t capacity() { return MAX_N; } uint32_t size() const { return current_size; } T& operator[](uint32_t idx) { return data_[idx]; } const T& operator[](uint32_t idx) const { return data_[idx]; } bool operator==(const bounded_array& other) const { return size() == other.size() and std::equal(data_, data_ + size(), other.data_); } void resize(uint32_t new_size) { current_size = new_size; } void push_back(const T& elem) { if (current_size >= MAX_N) { srsasn_log_print(srslte::LOG_LEVEL_ERROR, "Maximum size %d achieved for bounded_array.\n", MAX_N); } data_[current_size++] = elem; } T& back() { return data_[current_size - 1]; } const T& back() const { return data_[current_size - 1]; } T* data() { return &data_[0]; } const T* data() const { return &data_[0]; } iterator begin() { return &data_[0]; } iterator end() { return &data_[size()]; } const_iterator begin() const { return &data_[0]; } const_iterator end() const { return &data_[size()]; } private: T data_[MAX_N]; uint32_t current_size; }; /** * This array does small buffer optimization. The array has a small stack (Nthres elements) to store elements. Once * the number of elements exceeds this stack, the array allocs on the heap. * @tparam T * @tparam Nthres number of elements T that can be stored in the stack */ template class ext_array { public: static const uint32_t small_buffer_size = Nthres; ext_array() : size_(0), head(&small_buffer.data[0]) {} explicit ext_array(uint32_t new_size) : ext_array() { resize(new_size); } ext_array(const ext_array& other) : ext_array(other.size_) { std::copy(other.head, other.head + other.size_, head); } ext_array(ext_array&& other) noexcept { size_ = other.size(); if (other.is_in_small_buffer()) { head = &small_buffer.data[0]; std::copy(other.data(), other.data() + other.size(), head); } else { head = other.head; small_buffer.cap_ = other.small_buffer.cap_; other.head = &other.small_buffer.data[0]; other.size_ = 0; } } ~ext_array() { if (not is_in_small_buffer()) { delete[] head; } } ext_array& operator=(const ext_array& other) { if (this != &other) { resize(other.size()); std::copy(other.data(), other.data() + other.size(), head); } return *this; } uint32_t size() const { return size_; } uint32_t capacity() const { return is_in_small_buffer() ? Nthres : small_buffer.cap_; } T& operator[](uint32_t index) { return head[index]; } const T& operator[](uint32_t index) const { return head[index]; } T* data() { return &head[0]; } const T* data() const { return &head[0]; } T& back() { return head[size() - 1]; } const T& back() const { return head[size() - 1]; } bool operator==(const ext_array& other) const { return other.size() == size() and std::equal(other.data(), other.data() + other.size(), data()); } void push_back(const T& elem) { resize(size() + 1); head[size() - 1] = elem; } void resize(uint32_t new_size) { if (new_size == size_) { return; } if (capacity() >= new_size) { size_ = new_size; return; } T* old_data = head; uint32_t newcap = new_size + 5; head = new T[newcap]; std::copy(&small_buffer.data[0], &small_buffer.data[size_], head); size_ = new_size; if (old_data != &small_buffer.data[0]) { delete[] old_data; } small_buffer.cap_ = newcap; } bool is_in_small_buffer() const { return head == &small_buffer.data[0]; } private: union { T data[Nthres]; uint32_t cap_; } small_buffer; uint32_t size_; T* head; }; /********************* ext packing *********************/ SRSASN_CODE pack_unsupported_ext_flag(bit_ref& bref, bool ext); SRSASN_CODE unpack_unsupported_ext_flag(bool& ext, bit_ref& bref); /************************ asn1 null packing ************************/ struct asn1_null_t { SRSASN_CODE pack(bit_ref& bref) const { return SRSASN_SUCCESS; } SRSASN_CODE unpack(bit_ref& bref) const { return SRSASN_SUCCESS; } }; /************************ enum packing ************************/ SRSASN_CODE pack_enum(bit_ref& bref, uint32_t enum_val, uint32_t nbits); SRSASN_CODE pack_enum(bit_ref& bref, uint32_t enum_val, uint32_t nbits, uint32_t nof_noext); SRSASN_CODE pack_enum(bit_ref& bref, uint32_t e, uint32_t nof_types, uint32_t nof_exts, bool has_ext); ValOrError unpack_enum(uint32_t nof_types, uint32_t nof_exts, bool has_ext, bit_ref& bref); template SRSASN_CODE pack_enum(bit_ref& bref, EnumType e) { return pack_enum(bref, e, EnumType::nof_types, EnumType::nof_exts, EnumType::has_ext); } template SRSASN_CODE unpack_enum(EnumType& e, bit_ref& bref) { ValOrError ret = unpack_enum(EnumType::nof_types, EnumType::nof_exts, EnumType::has_ext, bref); e = (typename EnumType::options)ret.val; return ret.code; } struct EnumPacker { template SRSASN_CODE pack(bit_ref& bref, EnumType e) { return pack_enum(bref, e); } template SRSASN_CODE unpack(EnumType& e, bit_ref& bref) { return unpack_enum(e, bref); } }; template bool string_to_enum(EnumType& e, const std::string& s) { for (uint32_t i = 0; i < EnumType::nof_types; ++i) { e = (typename EnumType::options)i; if (e.to_string() == s) { return true; } } return false; } template bool number_to_enum(EnumType& e, NumberType val) { for (uint32_t i = 0; i < e.nof_types; ++i) { e = (typename EnumType::options)i; if (e.to_number() == val) { return true; } } return false; } template bool number_string_to_enum(EnumType& e, const std::string& val) { for (uint32_t i = 0; i < e.nof_types; ++i) { e = (typename EnumType::options)i; if (e.to_number_string() == val) { return true; } } return false; } template class enumerated : public EnumType { public: static const uint32_t nof_types = EnumType::nulltype, nof_exts = M; static const bool has_ext = E; enumerated() { EnumType::value = EnumType::nulltype; } enumerated(typename EnumType::options o) { EnumType::value = o; } SRSASN_CODE pack(bit_ref& bref) const { return pack_enum(bref, *this); } SRSASN_CODE unpack(bit_ref& bref) { return unpack_enum(*this, bref); } EnumType& operator=(EnumType v) { EnumType::value = v; return *this; } operator typename EnumType::options() const { return EnumType::value; } }; /************************ PER encoding ************************/ /* X.691 - Section 10.5 - Constrained Whole Number */ template SRSASN_CODE pack_constrained_whole_number(bit_ref& bref, IntType n, IntType lb, IntType ub, bool aligned); template SRSASN_CODE unpack_constrained_whole_number(IntType& n, bit_ref& bref, IntType lb, IntType ub, bool aligned); /* X.691 - Section 10.6 - Normally small non-negative whole Number */ template SRSASN_CODE pack_norm_small_non_neg_whole_number(bit_ref& bref, UintType n); template SRSASN_CODE unpack_norm_small_non_neg_whole_number(UintType& n, bit_ref& bref); /* X.691 - Section 10.8 - Unconstrained Whole Number */ template SRSASN_CODE pack_unconstrained_whole_number(bit_ref& bref, IntType n, bool aligned); template SRSASN_CODE unpack_unconstrained_whole_number(IntType& n, bit_ref& bref, bool aligned); /************************ length determinant ************************/ // Pack as whole constrained number template SRSASN_CODE pack_length(bit_ref& bref, IntType n, IntType lb, IntType ub, bool aligned = false); template SRSASN_CODE unpack_length(IntType& n, bit_ref& bref, IntType lb, IntType ub, bool aligned = false); // Pack as a small non-negative whole number SRSASN_CODE pack_length(bit_ref& ref, uint32_t val, bool aligned = false); SRSASN_CODE unpack_length(uint32_t& val, bit_ref& ref, bool aligned = false); /************************ Integer ************************/ template SRSASN_CODE pack_integer(bit_ref& bref, IntType n, IntType lb = std::numeric_limits::min(), IntType ub = std::numeric_limits::max(), bool has_ext = false, bool aligned = false); template SRSASN_CODE unpack_integer(IntType& n, bit_ref& bref, IntType lb = std::numeric_limits::min(), IntType ub = std::numeric_limits::max(), bool has_ext = false, bool aligned = false); // unconstrained case template SRSASN_CODE pack_unconstrained_integer(bit_ref& bref, IntType n, bool has_ext = false, bool aligned = false); template SRSASN_CODE unpack_unconstrained_integer(IntType& n, bit_ref& bref, bool has_ext = false, bool aligned = false); template struct integer_packer { integer_packer(IntType lb_, IntType ub_, bool has_ext_ = false, bool aligned_ = false); SRSASN_CODE pack(bit_ref& bref, IntType n); SRSASN_CODE unpack(IntType& n, bit_ref& bref); IntType lb; IntType ub; bool has_ext; bool aligned; }; template ::min(), IntType UB = std::numeric_limits::max(), bool Ext = false, bool Al = false> class integer { public: static const IntType ub = UB, lb = LB; static const bool has_ext = Ext, is_aligned = Al; IntType value; integer() = default; integer(IntType value_) : value(value_) {} operator IntType() { return value; } SRSASN_CODE pack(bit_ref& bref) const { return pack_integer(bref, value, lb, ub, has_ext, is_aligned); } SRSASN_CODE unpack(bit_ref& bref) { return unpack_integer(value, bref, lb, ub, has_ext, is_aligned); } }; /************************ General Packer/Unpacker ************************/ struct BitPacker { BitPacker(uint32_t nof_bits_) : nof_bits(nof_bits_) {} template SRSASN_CODE pack(bit_ref& bref, const T& topack) { bref.pack(topack, nof_bits); return SRSASN_SUCCESS; } template SRSASN_CODE unpack(T& tounpack, bit_ref& bref) { return bref.unpack(tounpack, nof_bits); } uint32_t nof_bits; }; struct Packer { template SRSASN_CODE pack(bit_ref& bref, const T& topack) { return topack.pack(bref); } template SRSASN_CODE unpack(T& tounpack, bit_ref& bref) { return tounpack.unpack(bref); } }; /********************* common octstring *********************/ // helper functions common to all octstring implementations uint64_t octstring_to_number(const uint8_t* ptr, uint32_t nbytes); void number_to_octstring(uint8_t* ptr, uint64_t number, uint32_t nbytes); std::string octstring_to_string(const uint8_t* ptr, uint32_t N); void string_to_octstring(uint8_t* ptr, const std::string& str); /************************ fixed_octstring ************************/ template class fixed_octstring { public: const uint8_t& operator[](uint32_t idx) const { return octets_[idx]; } uint8_t& operator[](uint32_t idx) { return octets_[idx]; } bool operator==(const fixed_octstring& other) const { return octets_ == other.octets_; } uint8_t* data() { return &octets_[0]; } const uint8_t* data() const { return &octets_[0]; } static uint32_t size() { return N; } std::string to_string() const { return octstring_to_string(&octets_[0], N); } fixed_octstring& from_string(const std::string& hexstr) { if (hexstr.size() != 2 * N) { srsasn_log_print( srslte::LOG_LEVEL_ERROR, "The provided hex string size is not valid (%d!=2*%d).\n", hexstr.size(), N); } else { string_to_octstring(&octets_[0], hexstr); } return *this; } uint64_t to_number() const { return octstring_to_number(&octets_[0], size()); } fixed_octstring& from_number(uint64_t val) { number_to_octstring(&octets_[0], val, size()); return *this; } SRSASN_CODE pack(bit_ref& bref) const; SRSASN_CODE unpack(bit_ref& bref); private: std::array octets_; }; /** * X.691 Section 16 - Encoding the octetstring type * @tparam N - number of items * @tparam ext - aligned variant * @param bref * @return */ template SRSASN_CODE fixed_octstring::pack(bit_ref& bref) const { if (aligned and N > 2) { bref.align_bytes_zero(); } for (uint32_t i = 0; i < size(); ++i) { HANDLE_CODE(bref.pack(octets_[i], 8)); } return SRSASN_SUCCESS; } template SRSASN_CODE fixed_octstring::unpack(bit_ref& bref) { if (aligned and N > 2) { bref.align_bytes_zero(); } for (uint32_t i = 0; i < size(); ++i) { HANDLE_CODE(bref.unpack(octets_[i], 8)); } return SRSASN_SUCCESS; } /************************ dyn_octstring ************************/ template class unbounded_octstring { public: static const bool aligned = Al; unbounded_octstring() = default; explicit unbounded_octstring(uint32_t new_size) : octets_(new_size) {} const uint8_t& operator[](uint32_t idx) const { return octets_[idx]; } uint8_t& operator[](uint32_t idx) { return octets_[idx]; } bool operator==(const unbounded_octstring& other) const { return octets_ == other.octets_; } void resize(uint32_t new_size) { octets_.resize(new_size); } uint32_t size() const { return octets_.size(); } uint8_t* data() { return &octets_[0]; } const uint8_t* data() const { return &octets_[0]; } SRSASN_CODE pack(bit_ref& ie_ref) const; SRSASN_CODE unpack(bit_ref& ie_ref); std::string to_string() const; unbounded_octstring& from_string(const std::string& hexstr); uint64_t to_number() const { return octstring_to_number(&octets_[0], size()); } unbounded_octstring& from_number(uint64_t val) { number_to_octstring(&octets_[0], val, size()); return *this; } private: dyn_array octets_; }; using dyn_octstring = unbounded_octstring; /********************* common bitstring *********************/ // helper functions common to all bitstring implementations uint64_t bitstring_to_number(const uint8_t* ptr, uint32_t nbits); void number_to_bitstring(uint8_t* ptr, uint64_t number, uint32_t nbits); std::string bitstring_to_string(const uint8_t* ptr, uint32_t nbits); inline bool bitstring_get(const uint8_t* ptr, uint32_t idx) { uint32_t byte_idx = idx / 8; uint32_t offset = idx % 8; return (ptr[byte_idx] & (1u << offset)) > 0; } inline void bitstring_set(uint8_t* ptr, uint32_t idx, bool value) { uint32_t byte_idx = idx / 8; uint32_t offset = idx % 8; if (value) { ptr[byte_idx] |= (1u << offset); } else { ptr[byte_idx] &= ((uint16_t)(1u << 8) - 1) - (1 << offset); } } /********************* fixed_bitstring *********************/ // fixed bitstring pack/unpack helpers SRSASN_CODE pack_fixed_bitstring(bit_ref& bref, const uint8_t* buf, uint32_t nbits); SRSASN_CODE pack_fixed_bitstring(bit_ref& bref, const uint8_t* buf, uint32_t nbits, bool ext); SRSASN_CODE unpack_fixed_bitstring(uint8_t* buf, bit_ref& bref, uint32_t nbits); SRSASN_CODE unpack_fixed_bitstring(uint8_t* buf, bool& ext, bit_ref& bref, uint32_t nbits); template class fixed_bitstring { public: using type_t = fixed_bitstring; static const bool has_ext = Ext, is_aligned = Al; fixed_bitstring() { memset(&octets_[0], 0, nof_octets()); } fixed_bitstring(const std::string& s) { if (s.size() != N) { srsasn_log_print( srslte::LOG_LEVEL_ERROR, "The provided string size=%zd does not match the bit string size=%d\n", s.size(), N); } memset(&octets_[0], 0, nof_octets()); for (uint32_t i = 0; i < N; ++i) this->set(N - i - 1, s[i] == '1'); } bool get(uint32_t idx) const { return bitstring_get(&octets_[0], idx); } void set(uint32_t idx, bool value) { bitstring_set(&octets_[0], idx, value); } bool operator==(const type_t& other) const { return octets_ == other.octets_; } bool operator==(const char* other_str) const { return strlen(other_str) == N and (*this) == type_t(other_str); } uint32_t nof_octets() const { return (uint32_t)ceilf(N / 8.0f); } uint32_t length() const { return N; } std::string to_string() const { return bitstring_to_string(&octets_[0], length()); } uint64_t to_number() const { return bitstring_to_number(&octets_[0], length()); } type_t& from_number(uint64_t val) { number_to_bitstring(&octets_[0], val, length()); return *this; } uint8_t* data() { return &octets_[0]; } const uint8_t* data() const { return &octets_[0]; } SRSASN_CODE pack(bit_ref& bref) const { return pack_fixed_bitstring(bref, data(), N); } SRSASN_CODE unpack(bit_ref& bref) { return unpack_fixed_bitstring(data(), bref, N); } private: std::array octets_; // ceil(N/8.0) }; /********************* bounded_bitstring *********************/ namespace bitstring_utils { SRSASN_CODE pack(bit_ref& bref, const uint8_t* data, uint32_t size, uint32_t lb, uint32_t ub, bool has_ext, bool is_aligned); SRSASN_CODE unpack_length_prefix(uint32_t& len, bit_ref& bref, uint32_t lb, uint32_t ub, bool has_ext, bool is_aligned); SRSASN_CODE unpack_bitfield(uint8_t* buf, bit_ref& bref, uint32_t n, uint32_t lb, uint32_t ub, bool is_aligned); SRSASN_CODE unpack_fixed_bitstring(uint8_t* buf, bit_ref& bref, uint32_t nof_bits, bool has_ext = false, bool is_aligned = false); } // namespace bitstring_utils template class base_bitstring { protected: using derived_t = BitStringType; public: bool get(uint32_t idx) const { return bitstring_get(derived()->data(), idx); } void set(uint32_t idx, bool value) { bitstring_set(derived()->data(), idx, value); } uint32_t nof_octets() const { return ceil_frac(derived()->length(), 8u); } std::string to_string() const { return bitstring_to_string(derived()->data(), derived()->length()); } derived_t& from_string(const std::string& s) { if (s.size() < derived_t::lb or s.size() > derived_t::ub) { srsasn_log_print(srslte::LOG_LEVEL_ERROR, "The provided string size=%d is not withing the bounds [%d, %d]\n", s.size(), derived_t::lb, derived_t::ub); } else { derived()->resize(s.size()); for (uint32_t i = 0; i < s.size(); ++i) { set(s.size() - i - 1, s[i] == '1'); } } return *derived(); } uint64_t to_number() const { return bitstring_to_number(derived()->data(), derived()->length()); } derived_t& from_number(uint64_t val) { uint32_t nof_bits = (uint32_t)ceilf(log2(val)); if (nof_bits > derived()->length()) { derived()->resize(nof_bits); } number_to_bitstring(derived()->data(), val, derived()->length()); return *derived(); } bool operator==(const base_bitstring& other) const { return derived()->length() == other.derived()->length() and std::equal(derived()->data(), derived()->data() + derived()->nof_octets(), other.derived()->data()); } bool operator==(const char* other_str) const { return strlen(other_str) == derived()->length() and (*this) == derived_t{}.from_string(other_str); } SRSASN_CODE pack(bit_ref& bref) const { return bitstring_utils::pack(bref, derived()->data(), derived()->length(), derived_t::lb, derived_t::ub, derived_t::has_ext, derived_t::is_aligned); } SRSASN_CODE unpack(bit_ref& bref) { // X.691, subclause 15.11 uint32_t nbits; HANDLE_CODE(bitstring_utils::unpack_length_prefix( nbits, bref, derived_t::lb, derived_t::ub, derived_t::has_ext, derived_t::is_aligned)); derived()->resize(nbits); return bitstring_utils::unpack_bitfield( derived()->data(), bref, nbits, derived_t::lb, derived_t::ub, derived_t::is_aligned); } private: derived_t* derived() { return static_cast(this); } const derived_t* derived() const { return static_cast(this); } }; template class bounded_bitstring : public base_bitstring > { using base_t = base_bitstring >; public: static const uint32_t lb = LB, ub = UB; static const bool has_ext = ext, is_aligned = aligned; explicit bounded_bitstring(uint32_t siz_ = 0) { resize(siz_); } const uint8_t* data() const { return &octets_[0]; } uint8_t* data() { return &octets_[0]; } uint32_t length() const { return nof_bits; } void resize(uint32_t new_size) { nof_bits = new_size; octets_.resize(this->nof_octets()); memset(data(), 0, this->nof_octets()); } private: bounded_array octets_; uint32_t nof_bits = 0; }; /********************* dyn_bitstring *********************/ template class unbounded_bitstring : public base_bitstring > { using base_t = base_bitstring >; public: static const uint32_t lb = 0, ub = std::numeric_limits::max(); static const bool has_ext = Ext, is_aligned = Al; explicit unbounded_bitstring(uint32_t siz_ = 0) { resize(siz_); } const uint8_t* data() const { return &octets_[0]; } uint8_t* data() { return &octets_[0]; } uint32_t length() const { return n_bits; } void resize(uint32_t new_size) { n_bits = new_size; octets_.resize(this->nof_octets()); memset(data(), 0, this->nof_octets()); // resize always resets content } private: dyn_array octets_; uint32_t n_bits; }; using dyn_bitstring = unbounded_bitstring; /********************* fixed sequence of *********************/ // packers/unpackers for fixed_length sequence-of template SRSASN_CODE pack_fixed_seq_of(bit_ref& bref, const T* item_array, uint32_t nof_items, ItemPacker packer) { for (uint32_t i = 0; i < nof_items; ++i) { HANDLE_CODE(packer.pack(bref, item_array[i])); } return SRSASN_SUCCESS; } template SRSASN_CODE pack_fixed_seq_of(bit_ref& bref, const T* item_array, uint32_t nof_items) { for (uint32_t i = 0; i < nof_items; ++i) { HANDLE_CODE(item_array[i].pack(bref)); } return SRSASN_SUCCESS; } template SRSASN_CODE unpack_fixed_seq_of(T* item_array, bit_ref& bref, uint32_t nof_items, ItemUnpacker unpacker) { for (uint32_t i = 0; i < nof_items; ++i) { HANDLE_CODE(unpacker.unpack(item_array[i], bref)); } return SRSASN_SUCCESS; } template SRSASN_CODE unpack_fixed_seq_of(T* item_array, bit_ref& bref, uint32_t nof_items) { for (uint32_t i = 0; i < nof_items; ++i) { HANDLE_CODE(item_array[i].unpack(bref)); } return SRSASN_SUCCESS; } template struct FixedSeqOfPacker { FixedSeqOfPacker(uint32_t nof_items_, ItemPacker packer_) : nof_items(nof_items_), packer(packer_) {} FixedSeqOfPacker(uint32_t nof_items_) : nof_items(nof_items_), packer(Packer()) {} template SRSASN_CODE pack(bit_ref& bref, const T* topack) { return pack_fixed_seq_of(bref, topack, nof_items, packer); } template SRSASN_CODE unpack(T* tounpack, bit_ref& bref) { return unpack_fixed_seq_of(tounpack, bref, nof_items, packer); } uint32_t nof_items; ItemPacker packer; }; /********************* dyn sequence of *********************/ template SRSASN_CODE pack_dyn_seq_of(bit_ref& bref, const ArrayType& seqof, uint32_t lb, uint32_t ub, ItemPacker packer, bool aligned = false) { HANDLE_CODE(pack_length(bref, seqof.size(), lb, ub, aligned)); for (uint32_t i = 0; i < seqof.size(); ++i) { HANDLE_CODE(packer.pack(bref, seqof[i])); } return SRSASN_SUCCESS; } template SRSASN_CODE pack_dyn_seq_of(bit_ref& bref, const ArrayType& seqof, uint32_t lb, uint32_t ub, bool aligned = false) { HANDLE_CODE(pack_length(bref, seqof.size(), lb, ub, aligned)); for (uint32_t i = 0; i < seqof.size(); ++i) { HANDLE_CODE(seqof[i].pack(bref)); } return SRSASN_SUCCESS; } template SRSASN_CODE unpack_dyn_seq_of(ArrayType& seqof, bit_ref& bref, uint32_t lb, uint32_t ub, ItemUnpacker unpacker, bool aligned = false) { uint32_t nof_items; HANDLE_CODE(unpack_length(nof_items, bref, lb, ub, aligned)); seqof.resize(nof_items); for (uint32_t i = 0; i < nof_items; ++i) { HANDLE_CODE(unpacker.unpack(seqof[i], bref)); } return SRSASN_SUCCESS; } template SRSASN_CODE unpack_dyn_seq_of(ArrayType& seqof, bit_ref& bref, uint32_t lb, uint32_t ub, bool aligned = false) { uint32_t nof_items; HANDLE_CODE(unpack_length(nof_items, bref, lb, ub, aligned)); seqof.resize(nof_items); for (uint32_t i = 0; i < nof_items; ++i) { HANDLE_CODE(seqof[i].unpack(bref)); } return SRSASN_SUCCESS; } template struct SeqOfPacker { SeqOfPacker(uint32_t lb_, uint32_t ub_, InnerPacker packer_) : lb(lb_), ub(ub_), packer(packer_) {} template SRSASN_CODE pack(bit_ref& bref, const T& topack) const { return pack_dyn_seq_of(bref, topack, lb, ub, packer); } template SRSASN_CODE unpack(T& tounpack, bit_ref& bref) { return unpack_dyn_seq_of(tounpack, bref, lb, ub, packer); } InnerPacker packer; uint32_t lb; uint32_t ub; }; template struct dyn_seq_of : public dyn_array { dyn_seq_of() = default; dyn_seq_of(const dyn_array& other) : dyn_array(other) {} SRSASN_CODE pack(bit_ref& bref) const { return pack_dyn_seq_of(bref, *this, lb, ub, aligned); } SRSASN_CODE unpack(bit_ref& bref) { return unpack_dyn_seq_of(*this, bref, lb, ub, aligned); } }; /********************* printable string *********************/ /* X.691 - Section 27 - Character Restricted String */ namespace asn_string_utils { SRSASN_CODE pack(bit_ref& bref, const std::string& s, size_t lb, size_t ub, size_t alb, size_t aub, bool ext, bool aligned); SRSASN_CODE unpack(std::string& s, bit_ref& bref, size_t lb, size_t ub, size_t alb, size_t aub, bool ext, bool aligned); } // namespace asn_string_utils template ::max(), bool ext = false, bool aligned = false> class asn_string { public: SRSASN_CODE pack(bit_ref& bref) const { return asn_string_utils::pack(bref, str, LB, UB, ALB, AUB, ext, aligned); } SRSASN_CODE unpack(bit_ref& bref) { return asn_string_utils::unpack(str, bref, LB, UB, ALB, AUB, ext, aligned); } char& operator[](std::size_t idx) { return str[idx]; } const char& operator[](std::size_t idx) const { return str[idx]; } void resize(std::size_t newsize) { str.resize(newsize); } std::size_t size() const { return str.size(); } std::string to_string() const { return str; } void from_string(std::string s) { str = std::move(s); } private: std::string str; }; template ::max(), bool ext = false, bool aligned = false> using printable_string = asn_string<32, 122, ALB, AUB, ext, aligned>; /********************* copy_ptr *********************/ template class copy_ptr { public: explicit copy_ptr(T* ptr_ = nullptr) : ptr(ptr_) {} // it takes hold of the pointer (including destruction). You should use make_copy_ptr() in most cases // instead of this ctor copy_ptr(const copy_ptr& other) { ptr = (other.ptr == nullptr) ? nullptr : new T(*other.ptr); } ~copy_ptr() { destroy_(); } copy_ptr& operator=(const copy_ptr& other) { if (this != &other) { reset((other.ptr == nullptr) ? nullptr : new T(*other.ptr)); } return *this; } bool operator==(const copy_ptr& other) const { return *ptr == *other; } T* operator->() { return ptr; } const T* operator->() const { return ptr; } T& operator*() { return *ptr; } // like pointers, don't call this if ptr==NULL const T& operator*() const { return *ptr; } // like pointers, don't call this if ptr==NULL T* get() { return ptr; } const T* get() const { return ptr; } T* release() { T* ret = ptr; ptr = nullptr; return ret; } void reset(T* ptr_ = nullptr) { destroy_(); ptr = ptr_; } void set_present(bool flag = true) { if (flag) { reset(new T()); } else { reset(); } } bool is_present() const { return get() != nullptr; } private: void destroy_() { if (ptr != NULL) { delete ptr; } } T* ptr; }; template copy_ptr make_copy_ptr(const T& t) { return copy_ptr(new T(t)); } /********************* choice utils *********************/ union alignment_t { char c; float f; uint32_t i; uint64_t i2; double d; long double d2; uint32_t* ptr; }; template struct static_max; template struct static_max { static const std::size_t value = arg; }; template struct static_max { static const std::size_t value = arg1 >= arg2 ? static_max::value : static_max::value; }; template struct choice_buffer_base_t { static const std::size_t data_size = Size; static const std::size_t data_align = Align; using buffer_t = typename std::aligned_storage::type; buffer_t buffer; template T& get() { return *(reinterpret_cast(&buffer)); } template const T& get() const { return *(reinterpret_cast(&buffer)); } template void destroy() { get().~T(); } template void init() { new (&buffer) T(); } template void init(const T& other) { new (&buffer) T(other); } template void set(const T& other) { get() = other; } }; template struct choice_buffer_t : public choice_buffer_base_t::value, static_max::value> { }; using pod_choice_buffer_t = choice_buffer_t<>; /********************* ext group *********************/ class ext_groups_packer_guard { public: bool& operator[](uint32_t idx); SRSASN_CODE pack(bit_ref& bref) const; private: ext_array groups; }; class ext_groups_unpacker_guard { public: explicit ext_groups_unpacker_guard(uint32_t nof_supported_groups_); ~ext_groups_unpacker_guard(); void resize(uint32_t new_size); bool& operator[](uint32_t idx); SRSASN_CODE unpack(bit_ref& bref); private: ext_array groups; const uint32_t nof_supported_groups; uint32_t nof_unpacked_groups = 0; bit_ref* bref_tracker = nullptr; }; /********************* Var Length Field *********************/ class varlength_field_pack_guard { public: explicit varlength_field_pack_guard(bit_ref& bref, bool align_ = false); ~varlength_field_pack_guard(); private: bit_ref brefstart; // bit_ref bref0; bit_ref* bref_tracker; uint8_t buffer[1024]; bool align; }; class varlength_field_unpack_guard { public: explicit varlength_field_unpack_guard(bit_ref& bref, bool align = false); ~varlength_field_unpack_guard(); private: bit_ref bref0; bit_ref* bref_tracker = nullptr; uint32_t len = 0; }; /******************* JsonWriter *******************/ class json_writer { public: json_writer(); void write_fieldname(const std::string& fieldname); void write_str(const std::string& fieldname, const std::string& value); void write_str(const std::string& value); void write_int(const std::string& fieldname, int64_t value); void write_int(int64_t value); void write_bool(const std::string& fieldname, bool value); void write_bool(bool value); void write_null(const std::string& fieldname); void write_null(); void start_obj(const std::string& fieldname = ""); void end_obj(); void start_array(const std::string& fieldname = ""); void end_array(); std::string to_string() const; private: std::stringstream ss; std::string ident; enum separator_t { COMMA, NEWLINE, NONE }; separator_t sep; }; /******************* Test pack/unpack *******************/ template int test_pack_unpack_consistency(const Msg& msg) { uint8_t buf[2048], buf2[2048]; bzero(buf, sizeof(buf)); bzero(buf2, sizeof(buf2)); Msg msg2; asn1::bit_ref bref(&buf[0], sizeof(buf)), bref2(&buf[0], sizeof(buf)), bref3(&buf2[0], sizeof(buf2)); if (msg.pack(bref) != asn1::SRSASN_SUCCESS) { log_error_code(SRSASN_ERROR_ENCODE_FAIL, __FILE__, __LINE__); return -1; } if (msg2.unpack(bref2) != asn1::SRSASN_SUCCESS) { log_error_code(SRSASN_ERROR_DECODE_FAIL, __FILE__, __LINE__); return -1; } if (msg2.pack(bref3) != asn1::SRSASN_SUCCESS) { log_error_code(SRSASN_ERROR_ENCODE_FAIL, __FILE__, __LINE__); return -1; } // unpack and last pack done for the same number of bits if (bref3.distance() != bref2.distance()) { srsasn_log_print(LOG_LEVEL_ERROR, "[%s][%d] .\n", __FILE__, __LINE__); return -1; } // ensure packed messages are the same if (bref3.distance() != bref.distance()) { srsasn_log_print(LOG_LEVEL_ERROR, "[%s][%d] .\n", __FILE__, __LINE__); return -1; } if (memcmp(buf, buf2, bref.distance_bytes()) != 0) { srsasn_log_print(LOG_LEVEL_ERROR, "[%s][%d] .\n", __FILE__, __LINE__); return -1; } return SRSASN_SUCCESS; } } // namespace asn1 #endif // SRSASN_COMMON_UTILS_H