/** * PANDA 3D SOFTWARE * Copyright (c) Carnegie Mellon University. All rights reserved. * * All use of this software is subject to the terms of the revised BSD * license. You should have received a copy of this license along * with this source code in a file named "LICENSE." * * @file dcPacker.I * @author drose * @date 2004-06-15 */ /** * Empties the data in the pack buffer and unpack buffer. This should be * called between calls to begin_pack(), unless you want to concatenate all of * the pack results together. */ INLINE void DCPacker:: clear_data() { _pack_data.clear(); if (_owns_unpack_data) { delete[] _unpack_data; _owns_unpack_data = false; } _unpack_data = nullptr; } /** * Returns true if the current field has any nested fields (and thus expects a * push() .. pop() interface), or false otherwise. If this returns true, * get_num_nested_fields() may be called to determine how many nested fields * are expected. */ INLINE bool DCPacker:: has_nested_fields() const { if (_current_field == nullptr) { return false; } else { return _current_field->has_nested_fields(); } } /** * Returns the number of nested fields associated with the current field, if * has_nested_fields() returned true. * * The return value may be -1 to indicate that a variable number of nested * fields are accepted by this field type (e.g. a variable-length array). * * Note that this method is unreliable to determine how many fields you must * traverse before you can call pop(), since particularly in the presence of a * DCSwitch, it may change during traversal. Use more_nested_fields() * instead. */ INLINE int DCPacker:: get_num_nested_fields() const { return _num_nested_fields; } /** * Returns true if there are more nested fields to pack or unpack in the * current push sequence, false if it is time to call pop(). */ INLINE bool DCPacker:: more_nested_fields() const { return (_current_field != nullptr && !_pack_error); } /** * Returns the field that we left in our last call to push(): the owner of the * current level of fields. This may be NULL at the beginning of the pack * operation. */ INLINE const DCPackerInterface *DCPacker:: get_current_parent() const { return _current_parent; } /** * Returns the field that will be referenced by the next call to pack_*() or * unpack_*(). This will be NULL if we have unpacked (or packed) all fields, * or if it is time to call pop(). */ INLINE const DCPackerInterface *DCPacker:: get_current_field() const { return _current_field; } /** * Returns a pointer to the last DCSwitch instance that we have passed by and * selected one case of during the pack/unpack process. Each time we * encounter a new DCSwitch and select a case, this will change state. * * This may be used to detect when a DCSwitch has been selected. At the * moment this changes state, get_current_parent() will contain the particular * SwitchCase that was selected by the switch. */ INLINE const DCSwitchParameter *DCPacker:: get_last_switch() const { return _last_switch; } /** * Returns the type of value expected by the current field. See the * enumerated type definition at the top of DCPackerInterface.h. If this * returns one of PT_double, PT_int, PT_int64, or PT_string, then you should * call the corresponding pack_double(), pack_int() function (or * unpack_double(), unpack_int(), etc.) to transfer data. Otherwise, you * should call push() and begin packing or unpacking the nested fields. */ INLINE DCPackType DCPacker:: get_pack_type() const { if (_current_field == nullptr) { return PT_invalid; } else { return _current_field->get_pack_type(); } } /** * Returns the name of the current field, if it has a name, or the empty * string if the field does not have a name or there is no current field. */ INLINE std::string DCPacker:: get_current_field_name() const { if (_current_field == nullptr) { return std::string(); } else { return _current_field->get_name(); } } /** * Packs the indicated numeric or string value into the stream. */ INLINE void DCPacker:: pack_double(double value) { nassertv(_mode == M_pack || _mode == M_repack); if (_current_field == nullptr) { _pack_error = true; } else { _current_field->pack_double(_pack_data, value, _pack_error, _range_error); advance(); } } /** * Packs the indicated numeric or string value into the stream. */ INLINE void DCPacker:: pack_int(int value) { nassertv(_mode == M_pack || _mode == M_repack); if (_current_field == nullptr) { _pack_error = true; } else { _current_field->pack_int(_pack_data, value, _pack_error, _range_error); advance(); } } /** * Packs the indicated numeric or string value into the stream. */ INLINE void DCPacker:: pack_uint(unsigned int value) { nassertv(_mode == M_pack || _mode == M_repack); if (_current_field == nullptr) { _pack_error = true; } else { _current_field->pack_uint(_pack_data, value, _pack_error, _range_error); advance(); } } /** * Packs the indicated numeric or string value into the stream. */ INLINE void DCPacker:: pack_int64(int64_t value) { nassertv(_mode == M_pack || _mode == M_repack); if (_current_field == nullptr) { _pack_error = true; } else { _current_field->pack_int64(_pack_data, value, _pack_error, _range_error); advance(); } } /** * Packs the indicated numeric or string value into the stream. */ INLINE void DCPacker:: pack_uint64(uint64_t value) { nassertv(_mode == M_pack || _mode == M_repack); if (_current_field == nullptr) { _pack_error = true; } else { _current_field->pack_uint64(_pack_data, value, _pack_error, _range_error); advance(); } } /** * Packs the indicated numeric or string value into the stream. */ INLINE void DCPacker:: pack_string(const std::string &value) { nassertv(_mode == M_pack || _mode == M_repack); if (_current_field == nullptr) { _pack_error = true; } else { _current_field->pack_string(_pack_data, value, _pack_error, _range_error); advance(); } } /** * Packs the indicated numeric or string value into the stream. */ INLINE void DCPacker:: pack_blob(const vector_uchar &value) { nassertv(_mode == M_pack || _mode == M_repack); if (_current_field == nullptr) { _pack_error = true; } else { _current_field->pack_blob(_pack_data, value, _pack_error, _range_error); advance(); } } /** * Adds the indicated string value into the stream, representing a single pre- * packed field element, or a whole group of field elements at once. */ INLINE void DCPacker:: pack_literal_value(const vector_uchar &value) { nassertv(_mode == M_pack || _mode == M_repack); if (_current_field == nullptr) { _pack_error = true; } else { _pack_data.append_data((const char *)value.data(), value.size()); advance(); } } /** * Unpacks the current numeric or string value from the stream. */ INLINE double DCPacker:: unpack_double() { double value = 0.0; nassertr(_mode == M_unpack, value); if (_current_field == nullptr) { _pack_error = true; } else { _current_field->unpack_double(_unpack_data, _unpack_length, _unpack_p, value, _pack_error, _range_error); advance(); } return value; } /** * Unpacks the current numeric or string value from the stream. */ INLINE int DCPacker:: unpack_int() { int value = 0; nassertr(_mode == M_unpack, value); if (_current_field == nullptr) { _pack_error = true; } else { _current_field->unpack_int(_unpack_data, _unpack_length, _unpack_p, value, _pack_error, _range_error); advance(); } return value; } /** * Unpacks the current numeric or string value from the stream. */ INLINE unsigned int DCPacker:: unpack_uint() { unsigned int value = 0; nassertr(_mode == M_unpack, value); if (_current_field == nullptr) { _pack_error = true; } else { _current_field->unpack_uint(_unpack_data, _unpack_length, _unpack_p, value, _pack_error, _range_error); advance(); } return value; } /** * Unpacks the current numeric or string value from the stream. */ INLINE int64_t DCPacker:: unpack_int64() { int64_t value = 0; nassertr(_mode == M_unpack, value); if (_current_field == nullptr) { _pack_error = true; } else { _current_field->unpack_int64(_unpack_data, _unpack_length, _unpack_p, value, _pack_error, _range_error); advance(); } return value; } /** * Unpacks the current numeric or string value from the stream. */ INLINE uint64_t DCPacker:: unpack_uint64() { uint64_t value = 0; nassertr(_mode == M_unpack, value); if (_current_field == nullptr) { _pack_error = true; } else { _current_field->unpack_uint64(_unpack_data, _unpack_length, _unpack_p, value, _pack_error, _range_error); advance(); } return value; } /** * Unpacks the current numeric or string value from the stream. */ INLINE std::string DCPacker:: unpack_string() { std::string value; nassertr(_mode == M_unpack, value); if (_current_field == nullptr) { _pack_error = true; } else { _current_field->unpack_string(_unpack_data, _unpack_length, _unpack_p, value, _pack_error, _range_error); advance(); } return value; } /** * Unpacks the current binary data value from the stream. */ INLINE vector_uchar DCPacker:: unpack_blob() { vector_uchar value; nassertr(_mode == M_unpack, value); if (_current_field == nullptr) { _pack_error = true; } else { _current_field->unpack_blob(_unpack_data, _unpack_length, _unpack_p, value, _pack_error, _range_error); advance(); } return value; } /** * Returns the literal string that represents the packed value of the current * field, and advances the field pointer. */ INLINE vector_uchar DCPacker:: unpack_literal_value() { size_t start = _unpack_p; unpack_skip(); nassertr(_unpack_p >= start, vector_uchar()); return vector_uchar((const unsigned char *)_unpack_data + start, (const unsigned char *)_unpack_data + _unpack_p); } /** * Unpacks the current numeric or string value from the stream. */ INLINE void DCPacker:: unpack_double(double &value) { nassertv(_mode == M_unpack); if (_current_field == nullptr) { _pack_error = true; } else { _current_field->unpack_double(_unpack_data, _unpack_length, _unpack_p, value, _pack_error, _range_error); advance(); } } /** * Unpacks the current numeric or string value from the stream. */ INLINE void DCPacker:: unpack_int(int &value) { nassertv(_mode == M_unpack); if (_current_field == nullptr) { _pack_error = true; } else { _current_field->unpack_int(_unpack_data, _unpack_length, _unpack_p, value, _pack_error, _range_error); advance(); } } /** * Unpacks the current numeric or string value from the stream. */ INLINE void DCPacker:: unpack_uint(unsigned int &value) { nassertv(_mode == M_unpack); if (_current_field == nullptr) { _pack_error = true; } else { _current_field->unpack_uint(_unpack_data, _unpack_length, _unpack_p, value, _pack_error, _range_error); advance(); } } /** * Unpacks the current numeric or string value from the stream. */ INLINE void DCPacker:: unpack_int64(int64_t &value) { nassertv(_mode == M_unpack); if (_current_field == nullptr) { _pack_error = true; } else { _current_field->unpack_int64(_unpack_data, _unpack_length, _unpack_p, value, _pack_error, _range_error); advance(); } } /** * Unpacks the current numeric or string value from the stream. */ INLINE void DCPacker:: unpack_uint64(uint64_t &value) { nassertv(_mode == M_unpack); if (_current_field == nullptr) { _pack_error = true; } else { _current_field->unpack_uint64(_unpack_data, _unpack_length, _unpack_p, value, _pack_error, _range_error); advance(); } } /** * Unpacks the current numeric or string value from the stream. */ INLINE void DCPacker:: unpack_string(std::string &value) { nassertv(_mode == M_unpack); if (_current_field == nullptr) { _pack_error = true; } else { _current_field->unpack_string(_unpack_data, _unpack_length, _unpack_p, value, _pack_error, _range_error); advance(); } } /** * Unpacks the current numeric or string value from the stream. */ INLINE void DCPacker:: unpack_blob(vector_uchar &value) { nassertv(_mode == M_unpack); if (_current_field == nullptr) { _pack_error = true; } else { _current_field->unpack_blob(_unpack_data, _unpack_length, _unpack_p, value, _pack_error, _range_error); advance(); } } /** * Returns the literal string that represents the packed value of the current * field, and advances the field pointer. */ INLINE void DCPacker:: unpack_literal_value(vector_uchar &value) { size_t start = _unpack_p; unpack_skip(); nassertv(_unpack_p >= start); value = vector_uchar((const unsigned char *)_unpack_data + start, (const unsigned char *)_unpack_data + _unpack_p); } /** * Returns true if there has been an parse error since the most recent call to * begin(); this can only happen if you call parse_and_pack(). */ INLINE bool DCPacker:: had_parse_error() const { return _parse_error; } /** * Returns true if there has been an packing error since the most recent call * to begin(); in particular, this may be called after end() has returned * false to determine the nature of the failure. * * A return value of true indicates there was a push/pop mismatch, or the * push/pop structure did not match the data structure, or there were the * wrong number of elements in a nested push/pop structure, or on unpack that * the data stream was truncated. */ INLINE bool DCPacker:: had_pack_error() const { return _pack_error; } /** * Returns true if there has been an range validation error since the most * recent call to begin(); in particular, this may be called after end() has * returned false to determine the nature of the failure. * * A return value of true indicates a value that was packed or unpacked did * not fit within the specified legal range for a parameter, or within the * limits of the field size. */ INLINE bool DCPacker:: had_range_error() const { return _range_error; } /** * Returns true if there has been any error (either a pack error or a range * error) since the most recent call to begin(). If this returns true, then * the matching call to end() will indicate an error (false). */ INLINE bool DCPacker:: had_error() const { return _range_error || _pack_error || _parse_error; } /** * Returns the number of bytes that have been unpacked so far, or after * unpack_end(), the total number of bytes that were unpacked at all. This * can be used to validate that all of the bytes in the buffer were actually * unpacked (which is not otherwise considered an error). */ INLINE size_t DCPacker:: get_num_unpacked_bytes() const { return _unpack_p; } /** * Returns the current length of the buffer. This is the number of useful * bytes stored in the buffer, not the amount of memory it takes up. */ INLINE size_t DCPacker:: get_length() const { return _pack_data.get_length(); } /** * Returns the packed data buffer as a string. Also see get_data(). */ INLINE std::string DCPacker:: get_string() const { return _pack_data.get_string(); } /** * Returns the packed data buffer as a bytes object. Also see get_data(). */ INLINE vector_uchar DCPacker:: get_bytes() const { const unsigned char *p = (const unsigned char *)_pack_data.get_data(); return vector_uchar(p, p + _pack_data.get_length()); } /** * Returns the total number of bytes in the unpack data buffer. This is the * buffer used when unpacking; it is separate from the pack data returned by * get_length(), which is filled during packing. */ INLINE size_t DCPacker:: get_unpack_length() const { return _unpack_length; } /** * Returns the unpack data buffer, as a string. This is the buffer used when * unpacking; it is separate from the pack data returned by get_string(), * which is filled during packing. Also see get_unpack_data(). */ INLINE std::string DCPacker:: get_unpack_string() const { return std::string(_unpack_data, _unpack_length); } /** * Copies the packed data into the indicated string. Also see get_data(). */ INLINE void DCPacker:: get_string(std::string &data) const { data.assign(_pack_data.get_data(), _pack_data.get_length()); } /** * Returns the beginning of the data buffer. The buffer is not null- * terminated, but see also get_string(). * * This may be used in conjunction with get_length() to copy all of the bytes * out of the buffer. Also see take_data() to get the packed data without a * copy operation. */ INLINE const char *DCPacker:: get_data() const { return _pack_data.get_data(); } /** * Returns the pointer to the beginning of the data buffer, and transfers * ownership of the buffer to the caller. The caller is now responsible for * ultimately freeing the returned pointer with delete[], if it is non-NULL. * This may (or may not) return NULL if the buffer is empty. * * This also empties the DCPackData structure, and sets its length to zero (so * you should call get_length() before calling this method). */ INLINE char *DCPacker:: take_data() { return _pack_data.take_data(); } /** * Adds the indicated bytes to the end of the data. This may only be called * between packing sessions. */ INLINE void DCPacker:: append_data(const unsigned char *buffer, size_t size) { nassertv(_mode == M_idle); _pack_data.append_data((const char *)buffer, size); } /** * Adds the indicated number of bytes to the end of the data without * initializing them, and returns a pointer to the beginning of the new data. * This may only be called between packing sessions. */ INLINE char *DCPacker:: get_write_pointer(size_t size) { nassertr(_mode == M_idle, nullptr); return _pack_data.get_write_pointer(size); } /** * Returns a read pointer to the unpack data buffer. This is the buffer used * when unpacking; it is separate from the pack data returned by get_data(), * which is filled during packing. */ INLINE const char *DCPacker:: get_unpack_data() const { return _unpack_data; } /** * Returns the number of DCPacker::StackElement pointers ever simultaneously * allocated; these are now either in active use or have been recycled into * the deleted DCPacker::StackElement pool to be used again. */ INLINE int DCPacker:: get_num_stack_elements_ever_allocated() { return StackElement::_num_ever_allocated; } /** * Packs the data into the buffer between packing sessions. */ INLINE void DCPacker:: raw_pack_int8(int value) { nassertv(_mode == M_idle); DCPackerInterface::do_pack_int8(_pack_data.get_write_pointer(1), value); } /** * Packs the data into the buffer between packing sessions. */ INLINE void DCPacker:: raw_pack_int16(int value) { nassertv(_mode == M_idle); DCPackerInterface::do_pack_int16(_pack_data.get_write_pointer(2), value); } /** * Packs the data into the buffer between packing sessions. */ INLINE void DCPacker:: raw_pack_int32(int value) { nassertv(_mode == M_idle); DCPackerInterface::do_pack_int32(_pack_data.get_write_pointer(4), value); } /** * Packs the data into the buffer between packing sessions. */ INLINE void DCPacker:: raw_pack_int64(int64_t value) { nassertv(_mode == M_idle); DCPackerInterface::do_pack_int64(_pack_data.get_write_pointer(8), value); } /** * Packs the data into the buffer between packing sessions. */ INLINE void DCPacker:: raw_pack_uint8(unsigned int value) { nassertv(_mode == M_idle); DCPackerInterface::do_pack_uint8(_pack_data.get_write_pointer(1), value); } /** * Packs the data into the buffer between packing sessions. */ INLINE void DCPacker:: raw_pack_uint16(unsigned int value) { nassertv(_mode == M_idle); DCPackerInterface::do_pack_uint16(_pack_data.get_write_pointer(2), value); } /** * Packs the data into the buffer between packing sessions. */ INLINE void DCPacker:: raw_pack_uint32(unsigned int value) { nassertv(_mode == M_idle); DCPackerInterface::do_pack_uint32(_pack_data.get_write_pointer(4), value); } /** * Packs the data into the buffer between packing sessions. */ INLINE void DCPacker:: raw_pack_uint64(uint64_t value) { nassertv(_mode == M_idle); DCPackerInterface::do_pack_uint64(_pack_data.get_write_pointer(8), value); } /** * Packs the data into the buffer between packing sessions. */ INLINE void DCPacker:: raw_pack_float64(double value) { nassertv(_mode == M_idle); DCPackerInterface::do_pack_float64(_pack_data.get_write_pointer(8), value); } /** * Packs the data into the buffer between packing sessions. */ INLINE void DCPacker:: raw_pack_string(const std::string &value) { nassertv(_mode == M_idle); DCPackerInterface::do_pack_uint16(_pack_data.get_write_pointer(2), value.length()); _pack_data.append_data(value.data(), value.length()); } /** * Packs the data into the buffer between packing sessions. */ INLINE void DCPacker:: raw_pack_blob(const vector_uchar &value) { nassertv(_mode == M_idle); DCPackerInterface::do_pack_uint16(_pack_data.get_write_pointer(2), value.size()); _pack_data.append_data((const char *)value.data(), value.size()); } /** * Unpacks the data from the buffer between unpacking sessions. */ INLINE int DCPacker:: raw_unpack_int8() { int value = 0; raw_unpack_int8(value); return value; } /** * Unpacks the data from the buffer between unpacking sessions. */ INLINE int DCPacker:: raw_unpack_int16() { int value = 0; raw_unpack_int16(value); return value; } /** * Unpacks the data from the buffer between unpacking sessions. */ INLINE int DCPacker:: raw_unpack_int32() { int value = 0; raw_unpack_int32(value); return value; } /** * Unpacks the data from the buffer between unpacking sessions. */ INLINE int64_t DCPacker:: raw_unpack_int64() { int64_t value = 0; raw_unpack_int64(value); return value; } /** * Unpacks the data from the buffer between unpacking sessions. */ INLINE void DCPacker:: raw_unpack_int8(int &value) { nassertv(_mode == M_idle && _unpack_data != nullptr); if (_unpack_p + 1 > _unpack_length) { _pack_error = true; return; } value = DCPackerInterface::do_unpack_int8(_unpack_data + _unpack_p); _unpack_p++; } /** * Unpacks the data from the buffer between unpacking sessions. */ INLINE void DCPacker:: raw_unpack_int16(int &value) { nassertv(_mode == M_idle && _unpack_data != nullptr); if (_unpack_p + 2 > _unpack_length) { _pack_error = true; return; } value = DCPackerInterface::do_unpack_int16(_unpack_data + _unpack_p); _unpack_p += 2; } /** * Unpacks the data from the buffer between unpacking sessions. */ INLINE void DCPacker:: raw_unpack_int32(int &value) { nassertv(_mode == M_idle && _unpack_data != nullptr); if (_unpack_p + 4 > _unpack_length) { _pack_error = true; return; } value = DCPackerInterface::do_unpack_int32(_unpack_data + _unpack_p); _unpack_p += 4; } /** * Unpacks the data from the buffer between unpacking sessions. */ INLINE unsigned int DCPacker:: raw_unpack_uint8() { unsigned int value = 0; raw_unpack_uint8(value); return value; } /** * Unpacks the data from the buffer between unpacking sessions. */ INLINE unsigned int DCPacker:: raw_unpack_uint16() { unsigned int value = 0; raw_unpack_uint16(value); return value; } /** * Unpacks the data from the buffer between unpacking sessions. */ INLINE unsigned int DCPacker:: raw_unpack_uint32() { unsigned int value = 0; raw_unpack_uint32(value); return value; } /** * Unpacks the data from the buffer between unpacking sessions. */ INLINE uint64_t DCPacker:: raw_unpack_uint64() { uint64_t value = 0; raw_unpack_uint64(value); return value; } /** * Unpacks the data from the buffer between unpacking sessions. */ INLINE double DCPacker:: raw_unpack_float64() { double value = 0; raw_unpack_float64(value); return value; } /** * Unpacks the data from the buffer between unpacking sessions. */ INLINE std::string DCPacker:: raw_unpack_string() { std::string value; raw_unpack_string(value); return value; } /** * Unpacks the data from the buffer between unpacking sessions. */ INLINE vector_uchar DCPacker:: raw_unpack_blob() { vector_uchar value; raw_unpack_blob(value); return value; } /** * Unpacks the data from the buffer between unpacking sessions. */ INLINE void DCPacker:: raw_unpack_int64(int64_t &value) { nassertv(_mode == M_idle && _unpack_data != nullptr); if (_unpack_p + 8 > _unpack_length) { _pack_error = true; return; } value = DCPackerInterface::do_unpack_int64(_unpack_data + _unpack_p); _unpack_p += 8; } /** * Unpacks the data from the buffer between unpacking sessions. */ INLINE void DCPacker:: raw_unpack_uint8(unsigned int &value) { nassertv(_mode == M_idle && _unpack_data != nullptr); if (_unpack_p + 1 > _unpack_length) { _pack_error = true; return; } value = DCPackerInterface::do_unpack_uint8(_unpack_data + _unpack_p); _unpack_p++; } /** * Unpacks the data from the buffer between unpacking sessions. */ INLINE void DCPacker:: raw_unpack_uint16(unsigned int &value) { nassertv(_mode == M_idle && _unpack_data != nullptr); if (_unpack_p + 2 > _unpack_length) { _pack_error = true; return; } value = DCPackerInterface::do_unpack_uint16(_unpack_data + _unpack_p); _unpack_p += 2; } /** * Unpacks the data from the buffer between unpacking sessions. */ INLINE void DCPacker:: raw_unpack_uint32(unsigned int &value) { nassertv(_mode == M_idle && _unpack_data != nullptr); if (_unpack_p + 4 > _unpack_length) { _pack_error = true; return; } value = DCPackerInterface::do_unpack_uint32(_unpack_data + _unpack_p); _unpack_p += 4; } /** * Unpacks the data from the buffer between unpacking sessions. */ INLINE void DCPacker:: raw_unpack_uint64(uint64_t &value) { nassertv(_mode == M_idle && _unpack_data != nullptr); if (_unpack_p + 8 > _unpack_length) { _pack_error = true; return; } value = DCPackerInterface::do_unpack_uint64(_unpack_data + _unpack_p); _unpack_p += 8; } /** * Unpacks the data from the buffer between unpacking sessions. */ INLINE void DCPacker:: raw_unpack_float64(double &value) { nassertv(_mode == M_idle && _unpack_data != nullptr); if (_unpack_p + 8 > _unpack_length) { _pack_error = true; return; } value = DCPackerInterface::do_unpack_float64(_unpack_data + _unpack_p); _unpack_p += 8; } /** * Unpacks the data from the buffer between unpacking sessions. */ INLINE void DCPacker:: raw_unpack_string(std::string &value) { nassertv(_mode == M_idle && _unpack_data != nullptr); unsigned int string_length = raw_unpack_uint16(); if (_unpack_p + string_length > _unpack_length) { _pack_error = true; return; } value.assign(_unpack_data + _unpack_p, string_length); _unpack_p += string_length; } /** * Unpacks the data from the buffer between unpacking sessions. */ INLINE void DCPacker:: raw_unpack_blob(vector_uchar &value) { nassertv(_mode == M_idle && _unpack_data != nullptr); unsigned int blob_size = raw_unpack_uint16(); if (_unpack_p + blob_size > _unpack_length) { _pack_error = true; return; } const unsigned char *p = (const unsigned char *)_unpack_data + _unpack_p; value = vector_uchar(p, p + blob_size); _unpack_p += blob_size; } /** * Advances to the next field after a call to pack_value() or pop(). */ INLINE void DCPacker:: advance() { _current_field_index++; if (_num_nested_fields >= 0 && _current_field_index >= _num_nested_fields) { // Done with all the fields on this parent. The caller must now call // pop(). _current_field = nullptr; // But if the parent is a switch record, we make a special case so we can // get the alternate fields. if (_current_parent != nullptr) { const DCSwitchParameter *switch_parameter = ((DCPackerInterface *)_current_parent)->as_switch_parameter(); if (switch_parameter != nullptr) { handle_switch(switch_parameter); } } } else if (_pop_marker != 0 && _unpack_p >= _pop_marker) { // Done with all the fields on this parent. The caller must now call // pop(). _current_field = nullptr; } else { // We have another field to advance to. _current_field = _current_parent->get_nested_field(_current_field_index); } } /** * Allocates the memory for a new DCPacker::StackElement. This is specialized * here to provide for fast allocation of these things. */ INLINE void *DCPacker::StackElement:: operator new(size_t size) { if (_deleted_chain != nullptr) { StackElement *obj = _deleted_chain; _deleted_chain = _deleted_chain->_next; return obj; } #ifndef NDEBUG _num_ever_allocated++; #endif // NDEBUG return ::operator new(size); } /** * Frees the memory for a deleted DCPacker::StackElement. This is specialized * here to provide for fast allocation of these things. */ INLINE void DCPacker::StackElement:: operator delete(void *ptr) { StackElement *obj = (StackElement *)ptr; obj->_next = _deleted_chain; _deleted_chain = obj; }