The GNU C preprocessor is implemented as a library, cpplib, so it can be easily shared between a stand-alone preprocessor, and a preprocessor integrated with the C, C++ and Objective-C front ends. It is also available for use by other programs, though this is not recommended as its exposed interface has not yet reached a point of reasonable stability.
The library has been written to be re-entrant, so that it can be used to preprocess many files simultaneously if necessary. It has also been written with the preprocessing token as the fundamental unit; the preprocessor in previous versions of GCC would operate on text strings as the fundamental unit.
This brief manual documents the internals of cpplib, and explains some of the tricky issues. It is intended that, along with the comments in the source code, a reasonably competent C programmer should be able to figure out what the code is doing, and why things have been implemented the way they have.
cpplib has two interfaces—one is exposed internally only, and the other is for both internal and external use.
The convention is that functions and types that are exposed to multiple files internally are prefixed with ‘_cpp_’, and are to be found in the file internal.h. Functions and types exposed to external clients are in cpplib.h, and prefixed with ‘cpp_’. For historical reasons this is no longer quite true, but we should strive to stick to it.
We are striving to reduce the information exposed in cpplib.h to the bare minimum necessary, and then to keep it there. This makes clear exactly what external clients are entitled to assume, and allows us to change internals in the future without worrying whether library clients are perhaps relying on some kind of undocumented implementation-specific behavior.
The lexer is contained in the file lex.cc. It is a hand-coded lexer, and not implemented as a state machine. It can understand C, C++ and Objective-C source code, and has been extended to allow reasonably successful preprocessing of assembly language. The lexer does not make an initial pass to strip out trigraphs and escaped newlines, but handles them as they are encountered in a single pass of the input file. It returns preprocessing tokens individually, not a line at a time.
It is mostly transparent to users of the library, since the library’s
interface for obtaining the next token, cpp_get_token
, takes care
of lexing new tokens, handling directives, and expanding macros as
necessary. However, the lexer does expose some functionality so that
clients of the library can easily spell a given token, such as
cpp_spell_token
and cpp_token_len
. These functions are
useful when generating diagnostics, and for emitting the preprocessed
output.
Lexing of an individual token is handled by _cpp_lex_direct
and
its subroutines. In its current form the code is quite complicated,
with read ahead characters and such-like, since it strives to not step
back in the character stream in preparation for handling non-ASCII file
encodings. The current plan is to convert any such files to UTF-8
before processing them. This complexity is therefore unnecessary and
will be removed, so I’ll not discuss it further here.
The job of _cpp_lex_direct
is simply to lex a token. It is not
responsible for issues like directive handling, returning lookahead
tokens directly, multiple-include optimization, or conditional block
skipping. It necessarily has a minor rôle to play in memory
management of lexed lines. I discuss these issues in a separate section
(see Lexing a line).
The lexer places the token it lexes into storage pointed to by the
variable cur_token
, and then increments it. This variable is
important for correct diagnostic positioning. Unless a specific line
and column are passed to the diagnostic routines, they will examine the
line
and col
values of the token just before the location
that cur_token
points to, and use that location to report the
diagnostic.
The lexer does not consider whitespace to be a token in its own right.
If whitespace (other than a new line) precedes a token, it sets the
PREV_WHITE
bit in the token’s flags. Each token has its
line
and col
variables set to the line and column of the
first character of the token. This line number is the line number in
the translation unit, and can be converted to a source (file, line) pair
using the line map code.
The first token on a logical, i.e. unescaped, line has the flag
BOL
set for beginning-of-line. This flag is intended for
internal use, both to distinguish a ‘#’ that begins a directive
from one that doesn’t, and to generate a call-back to clients that want
to be notified about the start of every non-directive line with tokens
on it. Clients cannot reliably determine this for themselves: the first
token might be a macro, and the tokens of a macro expansion do not have
the BOL
flag set. The macro expansion may even be empty, and the
next token on the line certainly won’t have the BOL
flag set.
New lines are treated specially; exactly how the lexer handles them is
context-dependent. The C standard mandates that directives are
terminated by the first unescaped newline character, even if it appears
in the middle of a macro expansion. Therefore, if the state variable
in_directive
is set, the lexer returns a CPP_EOF
token,
which is normally used to indicate end-of-file, to indicate
end-of-directive. In a directive a CPP_EOF
token never means
end-of-file. Conveniently, if the caller was collect_args
, it
already handles CPP_EOF
as if it were end-of-file, and reports an
error about an unterminated macro argument list.
The C standard also specifies that a new line in the middle of the
arguments to a macro is treated as whitespace. This white space is
important in case the macro argument is stringized. The state variable
parsing_args
is nonzero when the preprocessor is collecting the
arguments to a macro call. It is set to 1 when looking for the opening
parenthesis to a function-like macro, and 2 when collecting the actual
arguments up to the closing parenthesis, since these two cases need to
be distinguished sometimes. One such time is here: the lexer sets the
PREV_WHITE
flag of a token if it meets a new line when
parsing_args
is set to 2. It doesn’t set it if it meets a new
line when parsing_args
is 1, since then code like
#define foo() bar foo baz
would be output with an erroneous space before ‘baz’:
foo baz
This is a good example of the subtlety of getting token spacing correct in the preprocessor; there are plenty of tests in the testsuite for corner cases like this.
The lexer is written to treat each of ‘\r’, ‘\n’, ‘\r\n’ and ‘\n\r’ as a single new line indicator. This allows it to transparently preprocess MS-DOS, Macintosh and Unix files without their needing to pass through a special filter beforehand.
We also decided to treat a backslash, either ‘\’ or the trigraph ‘??/’, separated from one of the above newline indicators by non-comment whitespace only, as intending to escape the newline. It tends to be a typing mistake, and cannot reasonably be mistaken for anything else in any of the C-family grammars. Since handling it this way is not strictly conforming to the ISO standard, the library issues a warning wherever it encounters it.
Handling newlines like this is made simpler by doing it in one place
only. The function handle_newline
takes care of all newline
characters, and skip_escaped_newlines
takes care of arbitrarily
long sequences of escaped newlines, deferring to handle_newline
to handle the newlines themselves.
The most painful aspect of lexing ISO-standard C and C++ is handling trigraphs and backlash-escaped newlines. Trigraphs are processed before any interpretation of the meaning of a character is made, and unfortunately there is a trigraph representation for a backslash, so it is possible for the trigraph ‘??/’ to introduce an escaped newline.
Escaped newlines are tedious because theoretically they can occur anywhere—between the ‘+’ and ‘=’ of the ‘+=’ token, within the characters of an identifier, and even between the ‘*’ and ‘/’ that terminates a comment. Moreover, you cannot be sure there is just one—there might be an arbitrarily long sequence of them.
So, for example, the routine that lexes a number, parse_number
,
cannot assume that it can scan forwards until the first non-number
character and be done with it, because this could be the ‘\’
introducing an escaped newline, or the ‘?’ introducing the trigraph
sequence that represents the ‘\’ of an escaped newline. If it
encounters a ‘?’ or ‘\’, it calls skip_escaped_newlines
to skip over any potential escaped newlines before checking whether the
number has been finished.
Similarly code in the main body of _cpp_lex_direct
cannot simply
check for a ‘=’ after a ‘+’ character to determine whether it
has a ‘+=’ token; it needs to be prepared for an escaped newline of
some sort. Such cases use the function get_effective_char
, which
returns the first character after any intervening escaped newlines.
The lexer needs to keep track of the correct column position, including counting tabs as specified by the -ftabstop= option. This should be done even within C-style comments; they can appear in the middle of a line, and we want to report diagnostics in the correct position for text appearing after the end of the comment.
Some identifiers, such as __VA_ARGS__
and poisoned identifiers,
may be invalid and require a diagnostic. However, if they appear in a
macro expansion we don’t want to complain with each use of the macro.
It is therefore best to catch them during the lexing stage, in
parse_identifier
. In both cases, whether a diagnostic is needed
or not is dependent upon the lexer’s state. For example, we don’t want
to issue a diagnostic for re-poisoning a poisoned identifier, or for
using __VA_ARGS__
in the expansion of a variable-argument macro.
Therefore parse_identifier
makes use of state flags to determine
whether a diagnostic is appropriate. Since we change state on a
per-token basis, and don’t lex whole lines at a time, this is not a
problem.
Another place where state flags are used to change behavior is whilst
lexing header names. Normally, a ‘<’ would be lexed as a single
token. After a #include
directive, though, it should be lexed as
a single token as far as the nearest ‘>’ character. Note that we
don’t allow the terminators of header names to be escaped; the first
‘"’ or ‘>’ terminates the header name.
Interpretation of some character sequences depends upon whether we are
lexing C, C++ or Objective-C, and on the revision of the standard in
force. For example, ‘::’ is a single token in C++, but in C it is
two separate ‘:’ tokens and almost certainly a syntax error. Such
cases are handled by _cpp_lex_direct
based upon command-line
flags stored in the cpp_options
structure.
Once a token has been lexed, it leads an independent existence. The
spelling of numbers, identifiers and strings is copied to permanent
storage from the original input buffer, so a token remains valid and
correct even if its source buffer is freed with _cpp_pop_buffer
.
The storage holding the spellings of such tokens remains until the
client program calls cpp_destroy, probably at the end of the translation
unit.
When the preprocessor was changed to return pointers to tokens, one feature I wanted was some sort of guarantee regarding how long a returned pointer remains valid. This is important to the stand-alone preprocessor, the future direction of the C family front ends, and even to cpplib itself internally.
Occasionally the preprocessor wants to be able to peek ahead in the
token stream. For example, after the name of a function-like macro, it
wants to check the next token to see if it is an opening parenthesis.
Another example is that, after reading the first few tokens of a
#pragma
directive and not recognizing it as a registered pragma,
it wants to backtrack and allow the user-defined handler for unknown
pragmas to access the full #pragma
token stream. The stand-alone
preprocessor wants to be able to test the current token with the
previous one to see if a space needs to be inserted to preserve their
separate tokenization upon re-lexing (paste avoidance), so it needs to
be sure the pointer to the previous token is still valid. The
recursive-descent C++ parser wants to be able to perform tentative
parsing arbitrarily far ahead in the token stream, and then to be able
to jump back to a prior position in that stream if necessary.
The rule I chose, which is fairly natural, is to arrange that the
preprocessor lex all tokens on a line consecutively into a token buffer,
which I call a token run, and when meeting an unescaped new line
(newlines within comments do not count either), to start lexing back at
the beginning of the run. Note that we do not lex a line of
tokens at once; if we did that parse_identifier
would not have
state flags available to warn about invalid identifiers (see Invalid identifiers).
In other words, accessing tokens that appeared earlier in the current
line is valid, but since each logical line overwrites the tokens of the
previous line, tokens from prior lines are unavailable. In particular,
since a directive only occupies a single logical line, this means that
the directive handlers like the #pragma
handler can jump around
in the directive’s tokens if necessary.
Two issues remain: what about tokens that arise from macro expansions, and what happens when we have a long line that overflows the token run?
Since we promise clients that we preserve the validity of pointers that we have already returned for tokens that appeared earlier in the line, we cannot reallocate the run. Instead, on overflow it is expanded by chaining a new token run on to the end of the existing one.
The tokens forming a macro’s replacement list are collected by the
#define
handler, and placed in storage that is only freed by
cpp_destroy
. So if a macro is expanded in the line of tokens,
the pointers to the tokens of its expansion that are returned will always
remain valid. However, macros are a little trickier than that, since
they give rise to three sources of fresh tokens. They are the built-in
macros like __LINE__
, and the ‘#’ and ‘##’ operators
for stringizing and token pasting. I handled this by allocating
space for these tokens from the lexer’s token run chain. This means
they automatically receive the same lifetime guarantees as lexed tokens,
and we don’t need to concern ourselves with freeing them.
Lexing into a line of tokens solves some of the token memory management
issues, but not all. The opening parenthesis after a function-like
macro name might lie on a different line, and the front ends definitely
want the ability to look ahead past the end of the current line. So
cpplib only moves back to the start of the token run at the end of a
line if the variable keep_tokens
is zero. Line-buffering is
quite natural for the preprocessor, and as a result the only time cpplib
needs to increment this variable is whilst looking for the opening
parenthesis to, and reading the arguments of, a function-like macro. In
the near future cpplib will export an interface to increment and
decrement this variable, so that clients can share full control over the
lifetime of token pointers too.
The routine _cpp_lex_token
handles moving to new token runs,
calling _cpp_lex_direct
to lex new tokens, or returning
previously-lexed tokens if we stepped back in the token stream. It also
checks each token for the BOL
flag, which might indicate a
directive that needs to be handled, or require a start-of-line call-back
to be made. _cpp_lex_token
also handles skipping over tokens in
failed conditional blocks, and invalidates the control macro of the
multiple-include optimization if a token was successfully lexed outside
a directive. In other words, its callers do not need to concern
themselves with such issues.
When cpplib encounters an “identifier”, it generates a hash code for
it and stores it in the hash table. By “identifier” we mean tokens
with type CPP_NAME
; this includes identifiers in the usual C
sense, as well as keywords, directive names, macro names and so on. For
example, all of pragma
, int
, foo
and
__GNUC__
are identifiers and hashed when lexed.
Each node in the hash table contain various information about the identifier it represents. For example, its length and type. At any one time, each identifier falls into exactly one of three categories:
These have been declared to be macros, either on the command line or
with #define
. A few, such as __TIME__
are built-ins
entered in the hash table during initialization. The hash node for a
normal macro points to a structure with more information about the
macro, such as whether it is function-like, how many arguments it takes,
and its expansion. Built-in macros are flagged as special, and instead
contain an enum indicating which of the various built-in macros it is.
Assertions are in a separate namespace to macros. To enforce this, cpp
actually prepends a #
character before hashing and entering it in
the hash table. An assertion’s node points to a chain of answers to
that assertion.
Everything else falls into this category—an identifier that is not
currently a macro, or a macro that has since been undefined with
#undef
.
When preprocessing C++, this category also includes the named operators,
such as xor
. In expressions these behave like the operators they
represent, but in contexts where the spelling of a token matters they
are spelt differently. This spelling distinction is relevant when they
are operands of the stringizing and pasting macro operators #
and
##
. Named operator hash nodes are flagged, both to catch the
spelling distinction and to prevent them from being defined as macros.
The same identifiers share the same hash node. Since each identifier
token, after lexing, contains a pointer to its hash node, this is used
to provide rapid lookup of various information. For example, when
parsing a #define
statement, CPP flags each argument’s identifier
hash node with the index of that argument. This makes duplicated
argument checking an O(1) operation for each argument. Similarly, for
each identifier in the macro’s expansion, lookup to see if it is an
argument, and which argument it is, is also an O(1) operation. Further,
each directive name, such as endif
, has an associated directive
enum stored in its hash node, so that directive lookup is also O(1).
Macro expansion is a tricky operation, fraught with nasty corner cases and situations that render what you thought was a nifty way to optimize the preprocessor’s expansion algorithm wrong in quite subtle ways.
I strongly recommend you have a good grasp of how the C and C++ standards require macros to be expanded before diving into this section, let alone the code!. If you don’t have a clear mental picture of how things like nested macro expansion, stringizing and token pasting are supposed to work, damage to your sanity can quickly result.
The preprocessor stores macro expansions in tokenized form. This saves repeated lexing passes during expansion, at the cost of a small increase in memory consumption on average. The tokens are stored contiguously in memory, so a pointer to the first one and a token count is all you need to get the replacement list of a macro.
If the macro is a function-like macro the preprocessor also stores its
parameters, in the form of an ordered list of pointers to the hash
table entry of each parameter’s identifier. Further, in the macro’s
stored expansion each occurrence of a parameter is replaced with a
special token of type CPP_MACRO_ARG
. Each such token holds the
index of the parameter it represents in the parameter list, which
allows rapid replacement of parameters with their arguments during
expansion. Despite this optimization it is still necessary to store
the original parameters to the macro, both for dumping with e.g.,
-dD, and to warn about non-trivial macro redefinitions when
the parameter names have changed.
The preprocessor maintains a context stack, implemented as a
linked list of cpp_context
structures, which together represent
the macro expansion state at any one time. The struct
cpp_reader
member variable context
points to the current top
of this stack. The top normally holds the unexpanded replacement list
of the innermost macro under expansion, except when cpplib is about to
pre-expand an argument, in which case it holds that argument’s
unexpanded tokens.
When there are no macros under expansion, cpplib is in base context. All contexts other than the base context contain a contiguous list of tokens delimited by a starting and ending token. When not in base context, cpplib obtains the next token from the list of the top context. If there are no tokens left in the list, it pops that context off the stack, and subsequent ones if necessary, until an unexhausted context is found or it returns to base context. In base context, cpplib reads tokens directly from the lexer.
If it encounters an identifier that is both a macro and enabled for
expansion, cpplib prepares to push a new context for that macro on the
stack by calling the routine enter_macro_context
. When this
routine returns, the new context will contain the unexpanded tokens of
the replacement list of that macro. In the case of function-like
macros, enter_macro_context
also replaces any parameters in the
replacement list, stored as CPP_MACRO_ARG
tokens, with the
appropriate macro argument. If the standard requires that the
parameter be replaced with its expanded argument, the argument will
have been fully macro expanded first.
enter_macro_context
also handles special macros like
__LINE__
. Although these macros expand to a single token which
cannot contain any further macros, for reasons of token spacing
(see Token Spacing) and simplicity of implementation, cpplib
handles these special macros by pushing a context containing just that
one token.
The final thing that enter_macro_context
does before returning
is to mark the macro disabled for expansion (except for special macros
like __TIME__
). The macro is re-enabled when its context is
later popped from the context stack, as described above. This strict
ordering ensures that a macro is disabled whilst its expansion is
being scanned, but that it is not disabled whilst any arguments
to it are being expanded.
The C standard states that, after any parameters have been replaced with their possibly-expanded arguments, the replacement list is scanned for nested macros. Further, any identifiers in the replacement list that are not expanded during this scan are never again eligible for expansion in the future, if the reason they were not expanded is that the macro in question was disabled.
Clearly this latter condition can only apply to tokens resulting from argument pre-expansion. Other tokens never have an opportunity to be re-tested for expansion. It is possible for identifiers that are function-like macros to not expand initially but to expand during a later scan. This occurs when the identifier is the last token of an argument (and therefore originally followed by a comma or a closing parenthesis in its macro’s argument list), and when it replaces its parameter in the macro’s replacement list, the subsequent token happens to be an opening parenthesis (itself possibly the first token of an argument).
It is important to note that when cpplib reads the last token of a given context, that context still remains on the stack. Only when looking for the next token do we pop it off the stack and drop to a lower context. This makes backing up by one token easy, but more importantly ensures that the macro corresponding to the current context is still disabled when we are considering the last token of its replacement list for expansion (or indeed expanding it). As an example, which illustrates many of the points above, consider
#define foo(x) bar x foo(foo) (2)
which fully expands to ‘bar foo (2)’. During pre-expansion of the argument, ‘foo’ does not expand even though the macro is enabled, since it has no following parenthesis [pre-expansion of an argument only uses tokens from that argument; it cannot take tokens from whatever follows the macro invocation]. This still leaves the argument token ‘foo’ eligible for future expansion. Then, when re-scanning after argument replacement, the token ‘foo’ is rejected for expansion, and marked ineligible for future expansion, since the macro is now disabled. It is disabled because the replacement list ‘bar foo’ of the macro is still on the context stack.
If instead the algorithm looked for an opening parenthesis first and then tested whether the macro were disabled it would be subtly wrong. In the example above, the replacement list of ‘foo’ would be popped in the process of finding the parenthesis, re-enabling ‘foo’ and expanding it a second time.
Function-like macros only expand when immediately followed by a parenthesis. To do this cpplib needs to temporarily disable macros and read the next token. Unfortunately, because of spacing issues (see Token Spacing), there can be fake padding tokens in-between, and if the next real token is not a parenthesis cpplib needs to be able to back up that one token as well as retain the information in any intervening padding tokens.
Backing up more than one token when macros are involved is not
permitted by cpplib, because in general it might involve issues like
restoring popped contexts onto the context stack, which are too hard.
Instead, searching for the parenthesis is handled by a special
function, funlike_invocation_p
, which remembers padding
information as it reads tokens. If the next real token is not an
opening parenthesis, it backs up that one token, and then pushes an
extra context just containing the padding information if necessary.
As discussed above, cpplib needs a way of marking tokens as
unexpandable. Since the tokens cpplib handles are read-only once they
have been lexed, it instead makes a copy of the token and adds the
flag NO_EXPAND
to the copy.
For efficiency and to simplify memory management by avoiding having to
remember to free these tokens, they are allocated as temporary tokens
from the lexer’s current token run (see Lexing a line) using the
function _cpp_temp_token
. The tokens are then re-used once the
current line of tokens has been read in.
This might sound unsafe. However, tokens runs are not re-used at the end of a line if it happens to be in the middle of a macro argument list, and cpplib only wants to back-up more than one lexer token in situations where no macro expansion is involved, so the optimization is safe.
First, consider an issue that only concerns the stand-alone preprocessor: there needs to be a guarantee that re-reading its preprocessed output results in an identical token stream. Without taking special measures, this might not be the case because of macro substitution. For example:
#define PLUS + #define EMPTY #define f(x) =x= +PLUS -EMPTY- PLUS+ f(=) → + + - - + + = = = not → ++ -- ++ ===
One solution would be to simply insert a space between all adjacent tokens. However, we would like to keep space insertion to a minimum, both for aesthetic reasons and because it causes problems for people who still try to abuse the preprocessor for things like Fortran source and Makefiles.
For now, just notice that when tokens are added (or removed, as shown by
the EMPTY
example) from the original lexed token stream, we need
to check for accidental token pasting. We call this paste
avoidance. Token addition and removal can only occur because of macro
expansion, but accidental pasting can occur in many places: both before
and after each macro replacement, each argument replacement, and
additionally each token created by the ‘#’ and ‘##’ operators.
Look at how the preprocessor gets whitespace output correct
normally. The cpp_token
structure contains a flags byte, and one
of those flags is PREV_WHITE
. This is flagged by the lexer, and
indicates that the token was preceded by whitespace of some form other
than a new line. The stand-alone preprocessor can use this flag to
decide whether to insert a space between tokens in the output.
Now consider the result of the following macro expansion:
#define add(x, y, z) x + y +z; sum = add (1,2, 3); → sum = 1 + 2 +3;
The interesting thing here is that the tokens ‘1’ and ‘2’ are output with a preceding space, and ‘3’ is output without a preceding space, but when lexed none of these tokens had that property. Careful consideration reveals that ‘1’ gets its preceding whitespace from the space preceding ‘add’ in the macro invocation, not replacement list. ‘2’ gets its whitespace from the space preceding the parameter ‘y’ in the macro replacement list, and ‘3’ has no preceding space because parameter ‘z’ has none in the replacement list.
Once lexed, tokens are effectively fixed and cannot be altered, since pointers to them might be held in many places, in particular by in-progress macro expansions. So instead of modifying the two tokens above, the preprocessor inserts a special token, which I call a padding token, into the token stream to indicate that spacing of the subsequent token is special. The preprocessor inserts padding tokens in front of every macro expansion and expanded macro argument. These point to a source token from which the subsequent real token should inherit its spacing. In the above example, the source tokens are ‘add’ in the macro invocation, and ‘y’ and ‘z’ in the macro replacement list, respectively.
It is quite easy to get multiple padding tokens in a row, for example if a macro’s first replacement token expands straight into another macro.
#define foo bar #define bar baz [foo] → [baz]
Here, two padding tokens are generated with sources the ‘foo’ token between the brackets, and the ‘bar’ token from foo’s replacement list, respectively. Clearly the first padding token is the one to use, so the output code should contain a rule that the first padding token in a sequence is the one that matters.
But what if a macro expansion is left? Adjusting the above example slightly:
#define foo bar #define bar EMPTY baz #define EMPTY [foo] EMPTY; → [ baz] ;
As shown, now there should be a space before ‘baz’ and the semicolon in the output.
The rules we decided above fail for ‘baz’: we generate three padding tokens, one per macro invocation, before the token ‘baz’. We would then have it take its spacing from the first of these, which carries source token ‘foo’ with no leading space.
It is vital that cpplib get spacing correct in these examples since any of these macro expansions could be stringized, where spacing matters.
So, this demonstrates that not just entering macro and argument
expansions, but leaving them requires special handling too. I made
cpplib insert a padding token with a NULL
source token when
leaving macro expansions, as well as after each replaced argument in a
macro’s replacement list. It also inserts appropriate padding tokens on
either side of tokens created by the ‘#’ and ‘##’ operators.
I expanded the rule so that, if we see a padding token with a
NULL
source token, and that source token has no leading
space, then we behave as if we have seen no padding tokens at all. A
quick check shows this rule will then get the above example correct as
well.
Now a relationship with paste avoidance is apparent: we have to be
careful about paste avoidance in exactly the same locations we have
padding tokens in order to get white space correct. This makes
implementation of paste avoidance easy: wherever the stand-alone
preprocessor is fixing up spacing because of padding tokens, and it
turns out that no space is needed, it has to take the extra step to
check that a space is not needed after all to avoid an accidental paste.
The function cpp_avoid_paste
advises whether a space is required
between two consecutive tokens. To avoid excessive spacing, it tries
hard to only require a space if one is likely to be necessary, but for
reasons of efficiency it is slightly conservative and might recommend a
space where one is not strictly needed.
There are three reasonable requirements a cpplib client might have for the line number of a token passed to it:
foo /* A long
comment */ bar \
baz
⇒
foo bar baz
The cpp_token
structure contains line
and col
members. The lexer fills these in with the line and column of the first
character of the token. Consequently, but maybe unexpectedly, a token
from the replacement list of a macro expansion carries the location of
the token within the #define
directive, because cpplib expands a
macro by returning pointers to the tokens in its replacement list. The
current implementation of cpplib assigns tokens created from built-in
macros and the ‘#’ and ‘##’ operators the location of the most
recently lexed token. This is a because they are allocated from the
lexer’s token runs, and because of the way the diagnostic routines infer
the appropriate location to report.
The diagnostic routines in cpplib display the location of the most recently lexed token, unless they are passed a specific line and column to report. For diagnostics regarding tokens that arise from macro expansions, it might also be helpful for the user to see the original location in the macro definition that the token came from. Since that is exactly the information each token carries, such an enhancement could be made relatively easily in future.
The stand-alone preprocessor faces a similar problem when determining the correct line to output the token on: the position attached to a token is fairly useless if the token came from a macro expansion. All tokens on a logical line should be output on its first physical line, so the token’s reported location is also wrong if it is part of a physical line other than the first.
To solve these issues, cpplib provides a callback that is generated
whenever it lexes a preprocessing token that starts a new logical line
other than a directive. It passes this token (which may be a
CPP_EOF
token indicating the end of the translation unit) to the
callback routine, which can then use the line and column of this token
to produce correct output.
As mentioned above, cpplib stores with each token the line number that it was lexed on. In fact, this number is not the number of the line in the source file, but instead bears more resemblance to the number of the line in the translation unit.
The preprocessor maintains a monotonic increasing line count, which is incremented at every new line character (and also at the end of any buffer that does not end in a new line). Since a line number of zero is useful to indicate certain special states and conditions, this variable starts counting from one.
This variable therefore uniquely enumerates each line in the translation unit. With some simple infrastructure, it is straight forward to map from this to the original source file and line number pair, saving space whenever line number information needs to be saved. The code the implements this mapping lies in the files line-map.cc and line-map.h.
Command-line macros and assertions are implemented by pushing a buffer
containing the right hand side of an equivalent #define
or
#assert
directive. Some built-in macros are handled similarly.
Since these are all processed before the first line of the main input
file, it will typically have an assigned line closer to twenty than to
one.
Header files are often of the form
#ifndef FOO #define FOO ... #endif
to prevent the compiler from processing them more than once. The
preprocessor notices such header files, so that if the header file
appears in a subsequent #include
directive and FOO
is
defined, then it is ignored and it doesn’t preprocess or even re-open
the file a second time. This is referred to as the multiple
include optimization.
Under what circumstances is such an optimization valid? If the file were included a second time, it can only be optimized away if that inclusion would result in no tokens to return, and no relevant directives to process. Therefore the current implementation imposes requirements and makes some allowances as follows:
#if
-#endif
pair, but whitespace and comments are permitted.
#ifndef FOO
or
#if !defined FOO [equivalently, #if !defined(FOO)]
#if
expression
must have come directly from the source file—no macro expansion must
have been involved. This is because macro definitions can change, and
tracking whether or not a relevant change has been made is not worth the
implementation cost.
#else
or #elif
directives at the outer
conditional block level, because they would probably contain something
of interest to a subsequent pass.
First, when pushing a new file on the buffer stack,
_stack_include_file
sets the controlling macro mi_cmacro
to
NULL
, and sets mi_valid
to true
. This indicates
that the preprocessor has not yet encountered anything that would
invalidate the multiple-include optimization. As described in the next
few paragraphs, these two variables having these values effectively
indicates top-of-file.
When about to return a token that is not part of a directive,
_cpp_lex_token
sets mi_valid
to false
. This
enforces the constraint that tokens outside the controlling conditional
block invalidate the optimization.
The do_if
, when appropriate, and do_ifndef
directive
handlers pass the controlling macro to the function
push_conditional
. cpplib maintains a stack of nested conditional
blocks, and after processing every opening conditional this function
pushes an if_stack
structure onto the stack. In this structure
it records the controlling macro for the block, provided there is one
and we’re at top-of-file (as described above). If an #elif
or
#else
directive is encountered, the controlling macro for that
block is cleared to NULL
. Otherwise, it survives until the
#endif
closing the block, upon which do_endif
sets
mi_valid
to true and stores the controlling macro in
mi_cmacro
.
_cpp_handle_directive
clears mi_valid
when processing any
directive other than an opening conditional and the null directive.
With this, and requiring top-of-file to record a controlling macro, and
no #else
or #elif
for it to survive and be copied to
mi_cmacro
by do_endif
, we have enforced the absence of
directives outside the main conditional block for the optimization to be
on.
Note that whilst we are inside the conditional block, mi_valid
is
likely to be reset to false
, but this does not matter since
the closing #endif
restores it to true
if appropriate.
Finally, since _cpp_lex_direct
pops the file off the buffer stack
at EOF
without returning a token, if the #endif
directive
was not followed by any tokens, mi_valid
is true
and
_cpp_pop_file_buffer
remembers the controlling macro associated
with the file. Subsequent calls to stack_include_file
result in
no buffer being pushed if the controlling macro is defined, effecting
the optimization.
A quick word on how we handle the
#if !defined FOO
case. _cpp_parse_expr
and parse_defined
take steps to see
whether the three stages ‘!’, ‘defined-expression’ and
‘end-of-directive’ occur in order in a #if
expression. If
so, they return the guard macro to do_if
in the variable
mi_ind_cmacro
, and otherwise set it to NULL
.
enter_macro_context
sets mi_valid
to false, so if a macro
was expanded whilst parsing any part of the expression, then the
top-of-file test in push_conditional
fails and the optimization
is turned off.
Fairly obviously, the file handling code of cpplib resides in the file files.cc. It takes care of the details of file searching, opening, reading and caching, for both the main source file and all the headers it recursively includes.
The basic strategy is to minimize the number of system calls. On many
systems, the basic open ()
and fstat ()
system calls can
be quite expensive. For every #include
-d file, we need to try
all the directories in the search path until we find a match. Some
projects, such as glibc, pass twenty or thirty include paths on the
command line, so this can rapidly become time consuming.
For a header file we have not encountered before we have little choice but to do this. However, it is often the case that the same headers are repeatedly included, and in these cases we try to avoid repeating the filesystem queries whilst searching for the correct file.
For each file we try to open, we store the constructed path in a splay
tree. This path first undergoes simplification by the function
_cpp_simplify_pathname
. For example,
/usr/include/bits/../foo.h is simplified to
/usr/include/foo.h before we enter it in the splay tree and try
to open ()
the file. CPP will then find subsequent uses of
foo.h, even as /usr/include/foo.h, in the splay tree and
save system calls.
Further, it is likely the file contents have also been cached, saving a
read ()
system call. We don’t bother caching the contents of
header files that are re-inclusion protected, and whose re-inclusion
macro is defined when we leave the header file for the first time. If
the host supports it, we try to map suitably large files into memory,
rather than reading them in directly.
The include paths are internally stored on a null-terminated
singly-linked list, starting with the "header.h"
directory search
chain, which then links into the <header.h>
directory chain.
Files included with the <foo.h>
syntax start the lookup directly
in the second half of this chain. However, files included with the
"foo.h"
syntax start at the beginning of the chain, but with one
extra directory prepended. This is the directory of the current file;
the one containing the #include
directive. Prepending this
directory on a per-file basis is handled by the function
search_from
.
Note that a header included with a directory component, such as
#include "mydir/foo.h"
and opened as
/usr/local/include/mydir/foo.h, will have the complete path minus
the basename ‘foo.h’ as the current directory.
Enough information is stored in the splay tree that CPP can immediately
tell whether it can skip the header file because of the multiple include
optimization, whether the file didn’t exist or couldn’t be opened for
some reason, or whether the header was flagged not to be re-used, as it
is with the obsolete #import
directive.
For the benefit of MS-DOS filesystems with an 8.3 filename limitation, CPP offers the ability to treat various include file names as aliases for the real header files with shorter names. The map from one to the other is found in a special file called ‘header.gcc’, stored in the command line (or system) include directories to which the mapping applies. This may be higher up the directory tree than the full path to the file minus the base name.