4 // Fraunhofer Institute for Open Communication Systems (FOKUS)
5 // Competence Center NETwork research (NET), St. Augustin, GERMANY
6 // Stefan Bund <g0dil@berlios.de>
8 // This program is free software; you can redistribute it and/or modify
9 // it under the terms of the GNU General Public License as published by
10 // the Free Software Foundation; either version 2 of the License, or
11 // (at your option) any later version.
13 // This program is distributed in the hope that it will be useful,
14 // but WITHOUT ANY WARRANTY; without even the implied warranty of
15 // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
16 // GNU General Public License for more details.
18 // You should have received a copy of the GNU General Public License
19 // along with this program; if not, write to the
20 // Free Software Foundation, Inc.,
21 // 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
24 \brief ParseHelpers public header */
26 #ifndef HH_SENF_Packets_ParseHelpers_
27 #define HH_SENF_Packets_ParseHelpers_ 1
29 #ifndef HH_SENF_Packets_Packets_
30 #error "Don't include 'ParseHelpers.hh' directly, include 'Packets.hh'"
35 //#include "ParseHelpers.mpp"
36 #include "ParseHelpers.ih"
37 ///////////////////////////////hh.p////////////////////////////////////////
39 /** \defgroup packetparsermacros Helper macros for defining new packet parsers
41 To simplify the definition of simple packet parsers, several macros are provided. Before
42 using these macros you should familiarize yourself with the packet parser interface as
43 described in senf::PacketParserBase.
45 These macros simplify providing the above defined interface. A typical packet declaration
46 using these macros has the following form (This is a concrete example from the definition of
47 the ethernet packet in <tt>DefaultBundle/EthernetPacket.hh</tt>)
50 struct EthVLanPacketParser : public PacketParserBase
52 # include SENF_FIXED_PARSER()
54 SENF_PARSER_BITFIELD( priority, 3, unsigned );
55 SENF_PARSER_BITFIELD( cfi, 1, bool );
56 SENF_PARSER_BITFIELD( vlanId, 12, unsigned );
58 SENF_PARSER_FIELD( type, UInt16Parser );
60 SENF_PARSER_FINALIZE(EthVLanPacketParser);
64 The macros take care of the following:
65 \li They define the accessor functions returning parsers of the given type.
66 \li They automatically calculate the offset of the fields from the preceding fields.
67 \li The macros provide a definition for \c init()
68 \li The macros define the \c bytes(), \c fixed_bytes and \c init_bytes members as needed.
70 You may define either a fixed or a dynamically sized parser. Fixed size parsers are defined by
71 starting the packet with <tt>\#include SENF_FIXED_PARSER()</tt>, dynamically sized parsers start
72 with <tt>\#include SENF_PARSER()</tt>. The different members are implemented such that:
74 \li The needed parser constructor is defined
75 \li \c init() calls \c defaultInit(). \c defaultInit() is defined to call \c init() on each
77 \li \c bytes() (on dynamically sized parser) respectively \c fixed_bytes (on fixed size
78 parsers) is defined to return the sum of the sizes of all fields.
79 \li On dynamically sized parsers, \c init_bytes is defined to return the sum of the
80 \c init_byte's of all fields
82 \section parserlanguage The Parser Macro micro-language
84 The macros provided to help implement composite parsers implement a very small declarative
85 language. This way of to think of the macros simplifies understanding, how the macros work.
87 Central to this language is the concept of <em>current offset</em>. The current offset is the
88 place (in bytes) from the beginning of the parser at which the next field will be added. Adding
89 fields to the parser will advance this offset by the size of the field added. Additional
90 commands allow to arbitrarily manipulate the current offset manually.
92 For fixed size parsers, the current offset is a single constant integral value, the number of
93 bytes from the parsers start. For dynamically sized parsers, the current offset really consists
94 of two values: One is the number of bytes from the parsers start, which however needs not be a
95 constant expression, the other value is the \c init_bytes value at this point, which is an
98 To demonstrate this functionality, here a more complex example (taken from \c MPEGDVBBundle and
99 then simplified by removing some fields)
101 struct Parse_DSMCCSection : public PacketParserBase
103 # include SENF_FIXED_PARSER()
105 SENF_PARSER_FIELD ( table_id , UInt8Parser );
107 SENF_PARSER_BITFIELD ( ssi , 1 , bool );
108 SENF_PARSER_BITFIELD ( private_indicator , 1 , bool );
109 SENF_PARSER_SKIP_BITS( 2 );
110 SENF_PARSER_BITFIELD ( sec_length , 12 , unsigned );
112 SENF_PARSER_FIELD ( table_id_extension , UInt16Parser );
114 SENF_PARSER_FINALIZE( Parse_DSMCCSection );
117 struct Parse_DatagramSection : public Parse_DSMCCSection
119 # include SENF_FIXED_PARSER()
121 SENF_PARSER_INHERIT( Parse_DSMCCSection );
123 SENF_PARSER_FIELD ( mac_addr_4 , UInt8Parser );
124 SENF_PARSER_FIELD ( mac_addr_3 , UInt8Parser );
126 SENF_PARSER_FINALIZE( Parse_DatagramSection );
128 // Parse table_id_extension as two bytes
129 SENF_PARSER_GOTO( table_id_extension );
130 SENF_PARSER_FIELD ( mac_addr_6 , UInt8Parser );
131 SENF_PARSER_FIELD ( mac_addr_5 , UInt8Parser );
135 This code defines two parsers, the second of which is based on the first. Both are fixed size
136 parsers. The definition of \c Parse_DSMCCSection is straight forward (more on bit fields
139 The derived parser is a little bit more complex. It starts out the same defining itself as a
140 fixed size parser. Then the base class is imported. Among other things, this call sets the
141 current offset to the first byte after the base parser (the base parser need not be implemented
142 using the packet parser macros, it just needs to be a valid parser). The additional fields \c
143 mac_addr_4 and \c mac_addr_3 are defined. Then we finalize the parser declaration.
145 <em>After</em> \ref SENF_PARSER_FINALIZE we add two more fields but not at the end of the
146 parser. \ref SENF_PARSER_GOTO jumps back to a previously defined label or field. Since the base
147 parser \c Parse_DSMCCSection is defined using the packet parser macros, we can even jump to
148 labels or fields defined in the base parser. Here, we jump to the beginning of the \c
149 table_id_extension field. \c mac_addr_6 and \c mac_addr_5 are therefore defined starting at that
150 offset and therefore overlay the \c table_id_extension field.
152 \section parsermacroinit Parser initialization
155 \ref SENF_FIXED_PARSER(), \ref SENF_PARSER(), \ref SENF_PARSER_INHERIT(), \ref
156 SENF_PARSER_INIT(), \ref SENF_PARSER_FINALIZE()
158 Every parser using the parser macros starts either with <tt>\#include SENF_PARSER()</tt> or with
159 <tt>\#include SENF_FIXED_PARSER()</tt>. This command sets the current offset to zero and defines
160 the type of parser to define.
162 A following optional \ref SENF_PARSER_INHERIT(\e base_class) is necessary if the parser does not
163 derive from senf::PacketParserBase. This call sets the base class and advances the current
164 offset to the end of the base parser.
166 \ref SENF_PARSER_INIT() is used to define the parser initialization code (the \c init()
169 \ref SENF_PARSER_FINALIZE(\e class_name) is called to define the parsers constructor, the \c
170 init() member and to set the parsers size (\c fixed_bytes for fixed size parsers or \c bytes()
171 and \c init_bytes for dynamically sized parsers). It is valid to define further fields \e after
172 \ref SENF_PARSER_FINALIZE() has been called, however
173 \li Fields defined after \ref SENF_PARSER_FINALIZE() will \e not be initialized by \c
174 defaultInit() (and therefore not by the default provided \c init() member). This can be very
175 helpful when defining overlaying fields to avoid initializing some bytes multiple times.
176 \li The size of the parser is given by the current offset at the time of the \ref
177 SENF_PARSER_FINALIZE() call.
179 \section parsermacrofields Defining fields
182 \ref SENF_PARSER_FIELD(), \ref SENF_PARSER_FIELD_RO(), \ref SENF_PARSER_PRIVATE_FIELD(),
183 \ref SENF_PARSER_CUSTOM_FIELD()
185 There are quite a few commands available to define fields. All these macros do the same thing:
186 they define a field accessor plus some auxiliary symbols. The accessor will use the parser type
187 passed to the macro to parse the field. The current offset is adjusted according to the size of
188 that parser. Normally, the parser will return an instance of the given parser type.
190 There are some properties the field defining macros might have. These properties are parts
193 \par \c RO: Read only fields
194 Macros with \c RO in their name define read only fields. This is only possible, if the
195 field's parser is a value parser (that is, it must have a \c value_type typedef member and
196 must provide the \c value() accessor member function). In this case, the value returned from
197 the \e name() accessor member is not the parser but the parsers value and therefore it does
198 not allow assignment to the field.
200 \par \c PRIVATE: Fields private to the parser class
201 A private field will not be accessible from the outside (it is made \c private to the parser
202 class). This is very handy when providing other accessor members to access a field in a
203 manner more suitable for the specific field, when combining several fields into a single
206 The field defining macros come in groups which members only differ in their properties:
208 <dl><dt><em>Standard fields:</em><dt><dd>\ref SENF_PARSER_FIELD(), \ref SENF_PARSER_FIELD_RO(),
209 \ref SENF_PARSER_PRIVATE_FIELD() define standard fields.</dd>
211 <dt><em>Arbitrary custom field:</em><dt><dd>\ref SENF_PARSER_CUSTOM_FIELD()</dd></dl>
213 See the documentation of each of these macros for a detailed description of the macro arguments
214 and usage. Bit-fields are handled in the following section.
216 There also some supplementary macros for defining fields of more complex composite types
217 (e.g. vectors). See the list of 'Defines' further down this page.
219 \subsection parsermacrosbitfields Bit-fields
222 \ref SENF_PARSER_BITFIELD(), \ref SENF_PARSER_BITFIELD_RO(), \ref
223 SENF_PARSER_PRIVATE_BITFIELD()\n
225 Bit-fields play a special role. They are quite frequent in packet definitions but don't fit into
226 the byte offset based parsing infrastructure defined so far. Since defining the correctly
227 parameterized senf::IntFieldParser, senf::UIntFieldParser and senf::FlagParser typedefs is quite
228 tedious, these helper macros are provided.
230 It is important to recognize, that the current offset does \e not include the current bit
231 position. The current offset after defining a bit-field will be the first complete byte after
232 that bit-field. Only the bit-field macros additionally take care of the current bit position
233 which is reset automatically by any intervening non-bitfield command.
235 So bit-field commands will come in groups. Any group of consecutive bitfield commands defines a
236 set of consecutive bits. The group as a whole will always be considered to cover a fixed number
237 of complete bytes. If the group does not cover those bytes completely (there are some bit's left
238 at the end), those bit's will be skipped.
240 Since consecutive bit-field commands are aggregated into a single bit-field group, the offset of
241 all these bit-fields will be the offset of the \e beginning of the group irrespective of the
242 number of bits parsed so far. Changing the offset to some bitfield using \ref SENF_PARSER_GOTO()
243 will therefore always go to the position at the beginning of this bitfield group. And since the
244 current offset does not include the bit position, the bit position will be 0, the first bit. You
245 may however break a bit-field group into two groups (at a byte boundary) by placing a \ref
246 SENF_PARSER_LABEL() command between the two groups.
248 The additional command \ref SENF_PARSER_SKIP_BITS() can be used to skip bit's between two
251 \section parsermacrooffset Manipulating the current offset
254 \ref SENF_PARSER_SKIP(), \ref SENF_PARSER_SKIP_BITS(), \ref SENF_PARSER_GOTO(), \ref
255 SENF_PARSER_GOTO_OFFSET(), \ref SENF_PARSER_LABEL()
257 To define more complex parsers, there are some macro commands which change the current offset.
259 \ref SENF_PARSER_SKIP(\e bytes) will skip the given number of bytes. \ref
260 SENF_PARSER_SKIP_BITS(\e bits) will work within bitfield definition to skip that number of bits.
262 \ref SENF_PARSER_GOTO(\e label_or_field) will change the offset to the given field or label. The
263 following fields will therefore start at that offset and overlay any fields already defined.
265 \ref SENF_PARSER_GOTO_OFFSET(\e offset) will jump to the given byte offset from the start of the
268 \ref SENF_PARSER_LABEL(\e name) will define \e name as a label for the current offset which can
269 then later be referenced using \ref SENF_PARSER_GOTO(). This also defines
270 <em>name</em><tt>_offset</tt> as a constant or member (for fixed respectively dynamically sized
273 It is very important to recognize, that the size of the parser is defined by the current offset
274 <em>at the time \ref SENF_PARSER_FINALIZE() is called</em>. This allows to arbitrarily
275 manipulate the size of the parser by changing the current offset accordingly. For dynamically
276 sized parsers, the offset can even be any expression involving member function calls. See the
277 documentation of the respective macros for more details.
279 \ingroup packetparser
281 ///\addtogroup packetparsermacros
284 ///\name Control information
287 /** \brief Define fixed size parser
289 This macro must be called using \c \#include at the beginning of every fixed size parser using
290 the packet parser helper macros:
293 struct SomeParser : public senf::PacketParserBase
295 # include SENF_FIXED_PARSER()
298 The parser must directly or indirectly inherit from senf::PacketParserBase
302 #define SENF_FIXED_PARSER() SENF_ABSOLUTE_INCLUDE_PATH(Packets/parse_fixed_setup.hh)
304 /** \brief Define dynamically sized parser
306 This macro must be called using \c \#include at the beginning of every dynamically sized parser
307 using the packet parser helper macros:
310 struct SomeParser : public senf::PacketParserBase
312 # include SENF_PARSER()
315 The parser must directly or indirectly inherit from senf::PacketParserBase
319 #define SENF_PARSER() SENF_ABSOLUTE_INCLUDE_PATH(Packets/parse_setup.hh)
321 /** \brief Define parser initialization routine
323 This macro allows to replace the default initialization code. The default \c init()
324 implementation will call \c defaultInit() which in turn will call \c init() of every field
325 defined before \ref SENF_PARSER_FINALIZE().
327 \ref SENF_PARSER_INIT() allows to replace \c init() with custom code:
334 Defining the initialization code manually skips the automatic call of defaultInit(), which may
335 be performed manually. Should the initialization code be more complex, it should be placed into
336 a non-inline private member which is called from \ref SENF_PARSER_INIT()
340 #define SENF_PARSER_INIT() void init(int) const
344 /** \brief Define parser inheritance
346 If the a parser does not directly inherit senf::PacketParserBase, \ref SENF_PARSER_INHERIT()
347 must be called to define the parser's base-class. This call will additionally move the current
348 offset to the end of the inherited parser so additional fields can be added.
350 struct MyParser : public BaseParser
352 # include SENF_FIXED_PARSER() // or SENF_PARSER()
354 SENF_PARSER_INHERIT(BaseParser)
357 If you want to define collection fields which reference auxiliary fields in the base parser,
358 <em>you must define the base parser as a variable parser not a fixed parser</em>.
360 \param[in] base name of base class
363 #define SENF_PARSER_INHERIT(base)
365 /** \brief Generate parser control members
367 \ref SENF_PARSER_FINALIZE() will generate the necessary parser control members (default
368 constructor, parser size, parser initialization). \ref SENF_PARSER_FINALIZE() needs not be the
369 last macro command within the parser though it will often be the last command since \ref
370 SENF_PARSER_FINALIZE() does not account for fields defined later.
372 \ref SENF_PARSER_FINALIZE() uses the information from \ref SENF_PARSER_INHERIT() to construct
373 the parsers base class (which must be a valid parser class).
375 \c defaultInit() is defined to initialize all fields <em>defined before the call to \ref
376 SENF_PARSER_FINALIZE()</em>. Fields defined later will \e not be initialized. If \ref
377 SENF_PARSER_INIT() is not used, \c init() is defined to call \c defaultInit().
379 The parsers size (either \c fixed_bytes for fixed size parsers or \c bytes() and \c init_bytes
380 for dynamically sized parsers) is set to the current offset. By manipulating the current offset
381 before calling \ref SENF_PARSER_FINALIZE(), the parser size can therefore be arbitrarily
382 manipulated. E.g., using \ref SENF_PARSER_GOTO_OFFSET() allows to set the size to an arbitrary
385 \param[in] name name of the parser class currently being defined
387 #define SENF_PARSER_FINALIZE(name)
391 ///\name Parser fields
394 /** \brief Define normal parser field
396 The family of \ref SENF_PARSER_FIELD() macros is used to define standard fields of a composite
397 parser. Every field is accessed by an accessor method named after the \a name parameter. The
398 field will be parsed using the \a type parser which must be a valid packet parser. If the
399 current parser is defined as a fixed size parser, all sub parsers must also be fixed size,
400 otherwise dynamically sized parser (e.g. collection parsers) are Ok.
402 Defining a field will always define several members:
404 <dl><dt><em>return_type</em> <em>name</em><tt>()</tt> <tt>const</tt></dt><dd>The accessor member
405 will return the parsed value when called. For normal fields, <em>return_type</em> equals
406 <em>type</em>, the type of the sub parser. This allows to change the value via the returned
407 sub-parser. If the field is marked read-only (\ref SENF_PARSER_FIELD_RO()), the return type
408 will be <em>type</em>::<tt>value_type</tt>.</dd>
410 <dt><tt>typedef</tt> <em>type</em> <em>name</em><tt>_t</tt></dt><dd>This typedef symbol is an
411 alias for the fields type.</dd>
413 <dt><tt>size_type</tt> <tt>const</tt> <em>name</em><tt>_offset</tt></dt><dd>Defined only for
414 fixed size parsers, this gives the fixed starting offset of the field from the beginning of
417 <dt><tt>size_type</tt> <em>name</em><tt>_offset() const</tt></dt><dd>Defined only for
418 dynamically sized parsers, this member function will return the dynamic offset of the field
419 from the beginning of the parser.</dd></dl>
421 \param[in] name field name
422 \param[in] type parser type
424 \see \ref SENF_PARSER_FIELD_RO(), \ref SENF_PARSER_PRIVATE_FIELD()
427 #define SENF_PARSER_FIELD(name, type)
429 /** \brief Define parser field (read-only)
431 Define read-only parser field. Read-only fields may only be defined for \a type's which are
432 value parsers: The parser \a type must have a \c value_type typedef member and a \c value()
433 member, which returns the current value of the field.
435 Defining such a field really defines \e two accessors: A read/write \e private field and a
436 read-only \e public accessor. The name of the private read/write field is given by adding a
437 trailing '_' to \a name. The read-only public accessor is called \a name.
439 \see SENF_PARSER_FIELD()
442 #define SENF_PARSER_FIELD_RO(name, type)
444 /** \brief Define parser field (private)
446 Define a parser field which is marked as \c private and may only be accessed from the parser
449 \see SENF_PARSER_FIELD()
452 #define SENF_PARSER_PRIVATE_FIELD(name, type)
454 /** \brief Define custom field accessor
456 This macro is used to define a field using a custom access method:
458 // The following is the same as SENF_PARSER_FIELD( xyz, senf::UInt16Parser )
459 // in a fixed size parser.
461 SENF_PARSER_CUSTOM_FIELD(xyz, senf::UInt16Parser, xyz_t::fixed_bytes) {
462 return parse<xyz_t>( xyz_offset );
466 The macro defines the same auxiliary symbols defined by \ref SENF_PARSER_FIELD(\a name, \a
467 type), the accessor method however is provided by the user.
469 \a size depends on the type of parser being defined:
471 \li If defining a fixed parser, \a size is a single value \a bytes which must be a constant
472 integral expression giving the fixed size of the field.
473 \li If defining a dynamically sized parser, \a size is given by two parameters \a bytes and \a
474 init_bytes. \a bytes is an arbitrary (not necessarily constant) expression giving the
475 dynamic size of the field whereas \a init_bytes is the constant initial size assigned to the
478 \param[in] name name of the field to define
479 \param[in] type return type of the accessor function
480 \param[in] size size of the field, either a single value \a bytes for fixed size parsers or two
481 separate arguments \a bytes and \a init_bytes for dynamically sized parsers
483 #define SENF_PARSER_CUSTOM_FIELD(name, type, size)
490 /** \brief Define bit-field
492 Bit fields are supported by a special family of parser macros. These macros simplify defining
493 fields using the senf::IntFieldParser, senf::UIntFieldParser and senf::FlagParser parsers by
494 keeping track of the current bit position and automatically creating the correct template
497 The \a type parameter specifies the type of bitfield to define. This value is one of
498 \li \c signed, for signed bit fields (senf::IntFieldParser)
499 \li \c unsigned, for unsigned bit fields (senf::UIntFieldParser) or
500 \li \c bool, for single-bit flags (senf::FlagParser).
502 The \a bits parameter specifies the number of bits the field covers. For \c signed or \c
503 unsigned fields, this value may be any numeric value from 1 to 32, for \c bool fields, this
506 For more information see \ref parsermacrosbitfields
508 \param[in] name name of the bit field
509 \param[in] bits number of bits
510 \param[in] type bit field type, one of \c signed, \c unsigned or \c bool
512 \see \ref SENF_PARSER_BITFIELD_RO(), \ref SENF_PARSER_PRIVATE_BITFIELD()
515 #define SENF_PARSER_BITFIELD(name, bits, type)
517 /** \brief Define bit-field (read-only)
519 Define read-only bit field. This is for bit-fields what \ref SENF_PARSER_FIELD_RO is for ordinary fields.
521 \see \ref SENF_PARSER_BITFIELD() \n \ref SENF_PARSER_FIELD_RO()
524 #define SENF_PARSER_BITFIELD_RO(name, bits, type)
526 /** \brief Define bit-field (private)
528 Define a bit field which is marked as \c private and may only be accessed from the parser class
531 \see \ref SENF_PARSER_BITFIELD()
534 #define SENF_PARSER_PRIVATE_BITFIELD(name, bits, type)
538 ///\name Current offset
541 /** \brief Skip bytes
543 Moves the offset by the given distance (which may be negative). \a skip depends on the type of
544 parser being defined and is either \a bytes or \a bytes, \a init_bytes.
546 \li If defining a fixed parser, \a bytes must be a constant integral expression which will be
547 added to the current offset
548 \li If defining a dynamically sized parser, the macro really takes two arguments, \a bytes and
549 \a init_bytes. \a bytes will adjust the current field offset whereas \a init_bytes will
550 adjust the parsers \c init_bytes value. \a bytes is allowed to be any integral expression,
551 and need \e not be constant. The second argument \a init_bytes on the other hand needs to be
552 a constant integral expression.
554 \param[in] bytes number of bytes to skip
555 \param[in] init_bytes only for dynamically sized parsers, value to adjust the \c init_bytes value
560 #define SENF_PARSER_SKIP(skip)
562 /** \brief Skip bits within bitfield group
564 This command will skip the given number of bits within a bitfield group. This command does \e
565 only affect bitfield commands. Therefore, a SENF_PARSER_SKIP_BITS command which is not followed
566 by a bitfield command will be ignored.
570 #define SENF_PARSER_SKIP_BITS(bits)
572 /** \brief Change current offset
574 This command will change the current offset to the field or label \a name. Fields defined after
575 this command will start at that position and will therefore overlay any fields defined earlier
576 for these byte positions.
578 \ref SENF_PARSER_GOTO() does \e not take into account the current bit position within bit
579 fields. When passed the name of a field within a bit field group, this command will always jump
580 to the beginning of the \e complete group (\e not the field within the bit field), even if the
581 group covers multiple bytes before the bit field \a name.
583 \param[in] name field or label to jump to
586 #define SENF_PARSER_GOTO(name)
588 /** \brief Change current offset to explicit value
590 \ref SENF_PARSER_GOTO_OFFSET() allows to change the current offset manually to an arbitrary
591 value. The \a offset parameter depends on the type of field currently being defined.
593 \li If defining a <em>fixed size parser</em>, the \a offset argument is a single \a bytes value
594 which is an integral constant expression to which the offset will be set.
595 \li If defining a <em>dynamically sized parser</em>, the \a offset argument is given by two
596 parameters \a bytes and \a init_bytes. \a bytes can be any integral expression (not
597 necessarily constant) giving the new byte position. \a init_bytes must be a constant
598 integral expression and will set the current initial size of the packet to this value.
600 \param[in] offset Depending on the parser type, either single \a bytes value or two arguments \a
601 bytes and \a init_size.
604 #define SENF_PARSER_GOTO_OFFSET(offset)
606 /** \brief Define offset label
608 This command defines \a name as a label for the current offset. The member
609 <em>name</em><tt>_offset</tt> is defined (either as a constant for fixed size parsers or as a
610 member function for dynamically sized parsers) to return the position at the point of label
613 \ref SENF_PARSER_GOTO() can later be used to jump to a position which has previously been
614 labeled with \ref SENF_PARSER_LABEL()
616 \param[in] name label name
619 #define SENF_PARSER_LABEL(name)
621 /** \brief Get field offset
623 This macro will return the offset of the given field or label. This macro may only be used
624 while defining the parser, normally while defining inline functions.
626 This macro will return the correct value when defining fixed or dynamically sized parsers.
628 \param[in] name field or label name
629 \returns offset of the field from parsers start
632 #define SENF_PARSER_OFFSET(name)
634 /** \brief Get fixed field offset, if possible
636 This macro will return the fixed offset to the field \a name, a compile-time constant
637 expression. This is identical to \ref SENF_PARSER_OFFSET() when defining a fixed size parser.
639 Even in dynamically sized parsers this macro will work, if the field \a name is preceded by
640 fixed size fields only. This macro does \e not validate this condition, it will return an
641 arbitrary incorrect value otherwise.
643 \pre Field \a name preceded by fixed size fields only
644 \param[in] name field or label name
645 \returns compile-time constant offset of the field from parsers start
648 #define SENF_PARSER_FIXED_OFFSET(name)
650 /** \brief Get current fixed offset, if possible
652 This macro will return the current fixed offset, a compile-time constant expression. This is
653 always possible when defining a fixed size parser.
655 Even in dynamically sized parsers this macro will work, if all parser defined \e before the
656 current position are fixed-size parsers. This macro does \e not validate this condition, it will
657 return an arbitrary incorrect value otherwise.
659 \pre Current position preceded by fixed-size parsers only
660 \returns compile-time constant offset from parsers start
663 #define SENF_PARSER_CURRENT_FIXED_OFFSET()
669 #define SENF_PARSER_INHERIT BOOST_PP_CAT( SENF_PARSER_INHERIT_, SENF_PARSER_TYPE )
671 #define SENF_PARSER_FIELD BOOST_PP_CAT( SENF_PARSER_FIELD_, SENF_PARSER_TYPE )
672 #define SENF_PARSER_FIELD_RO BOOST_PP_CAT( SENF_PARSER_FIELD_RO_, SENF_PARSER_TYPE )
673 #define SENF_PARSER_BITFIELD BOOST_PP_CAT( SENF_PARSER_BITFIELD_, SENF_PARSER_TYPE )
674 #define SENF_PARSER_BITFIELD_RO BOOST_PP_CAT( SENF_PARSER_BITFIELD_RO_, SENF_PARSER_TYPE )
675 #define SENF_PARSER_CUSTOM_FIELD BOOST_PP_CAT( SENF_PARSER_CUSTOM_FIELD_, SENF_PARSER_TYPE )
677 #define SENF_PARSER_PRIVATE_FIELD BOOST_PP_CAT( SENF_PARSER_P_FIELD_, SENF_PARSER_TYPE )
678 #define SENF_PARSER_PRIVATE_BITFIELD BOOST_PP_CAT( SENF_PARSER_P_BITFIELD_, SENF_PARSER_TYPE )
680 #define SENF_PARSER_SKIP BOOST_PP_CAT( SENF_PARSER_SKIP_, SENF_PARSER_TYPE )
681 #define SENF_PARSER_SKIP_BITS BOOST_PP_CAT( SENF_PARSER_SKIP_BITS_, SENF_PARSER_TYPE )
682 #define SENF_PARSER_GOTO BOOST_PP_CAT( SENF_PARSER_GOTO_, SENF_PARSER_TYPE )
683 #define SENF_PARSER_GOTO_OFFSET BOOST_PP_CAT( SENF_PARSER_GOTO_OFFSET_, SENF_PARSER_TYPE )
684 #define SENF_PARSER_LABEL BOOST_PP_CAT( SENF_PARSER_LABEL_, SENF_PARSER_TYPE )
686 #define SENF_PARSER_OFFSET BOOST_PP_CAT( SENF_PARSER_OFFSET_, SENF_PARSER_TYPE )
687 #define SENF_PARSER_FIXED_OFFSET BOOST_PP_CAT( SENF_PARSER_FIXED_OFFSET_, SENF_PARSER_TYPE )
688 #define SENF_PARSER_CURRENT_FIXED_OFFSET BOOST_PP_CAT( SENF_PARSER_CURRENT_FIXED_OFFSET_, SENF_PARSER_TYPE )
690 #define SENF_PARSER_FINALIZE BOOST_PP_CAT( SENF_PARSER_FINALIZE_, SENF_PARSER_TYPE )
696 ///////////////////////////////hh.e////////////////////////////////////////
698 #if !defined(HH_SENF_Packets_Packets__decls_) && !defined(HH_SENF_Packets_ParseHelpers_i_)
699 #define HH_SENF_Packets_ParseHelpers_i_
700 //#include "ParseHelpers.cci"
701 //#include "ParseHelpers.ct"
702 //#include "ParseHelpers.cti"
709 // comment-column: 40
710 // c-file-style: "senf"
711 // indent-tabs-mode: nil
712 // ispell-local-dictionary: "american"
713 // compile-command: "scons -u test"