NAME
XS::Parse::Infix
- XS functions to assist in parsing infix operators
DESCRIPTION
This module provides some XS functions to assist in writing syntax modules that provide new infix operators as perl syntax, primarily for authors of syntax plugins. It is unlikely to be of much use to anyone else; and highly unlikely to be of any use when writing perl code using these. Unless you are writing a syntax plugin using XS, this module is not for you.
This module is also currently experimental, and the design is still evolving and subject to change. Later versions may break ABI compatibility, requiring changes or at least a rebuild of any module that depends on it.
In addition, the places this functionality can be used are relatively small. Support for custom infix operators as added in Perl development release v5.37.7
, and is therefore present in Perl v5.38.0
.
In addition, the various XPK_INFIX_*
token types of XS::Parse::Keyword support querying on this module, so some syntax provided by other modules may be able to make use of these new infix operators.
CONSTANTS
HAVE_PL_INFIX_PLUGIN
if( XS::Parse::Infix::HAVE_PL_INFIX_PLUGIN ) { ... }
This constant is true if built on a perl that supports the PL_infix_plugin
extension mechanism, meaning that custom infix operators registered with this module will actually be recognised by the perl parser.
No actual production releases of perl yet support this feature, but see above for details of development versions which do.
XS FUNCTIONS
boot_xs_parse_infix
void boot_xs_parse_infix(double ver);
Call this function from your BOOT
section in order to initialise the module and parsing hooks.
ver should either be 0 or a decimal number for the module version requirement; e.g.
boot_xs_parse_infix(0.14);
parse_infix
bool parse_infix(enum XSParseInfixSelection select, struct XSParseInfixInfo **infop);
Since version 0.27.
This function attempts to parse syntax for an infix operator from the current parser position. If it is successful, it fills in the variable pointed to by infop with a pointer to the actual information structure and returns true
. If no suitable operator is found, returns false
.
xs_parse_infix_new_op
OP *xs_parse_infix_new_op(const struct XSParseInfixInfo *info, U32 flags,
OP *lhs, OP *rhs);
This function constructs a new optree fragment to represent invoking the infix operator with the given operands. It should be used much the same as core perl's newBINOP
function.
The info
structure pointer would be obtained from the infix
field of the result of invoking the various XPK_INFIX_*
token types from XS::Parse::Keyword
, or by calling "parse_infix" directly.
register_xs_parse_infix
void register_xs_parse_infix(const char *opname,
const struct XSParseInfixHooks *hooks, void *hookdata);
This function installs a set of parsing hooks to be associated with the given operator name. This new operator will then be available via XS::Parse::Keyword by the various XPK_INFIX_*
token types, "parse_infix", or to core perl's PL_infix_plugin
if available.
These tokens will all yield an info structure, with the following fields:
struct XSParseInfixInfo {
const char *opname;
OPCODE opcode; /* for built-in operators, or OP_CUSTOM for
custom-registered ones */
struct XSParseInfixHooks *hooks;
void *hookdata;
enum XSParseInfixClassification cls; /* since version 0.28 */
};
If the operator name contains any non-ASCII characters they are presumed to be in UTF-8 encoding. This will matter for deparse purposes.
PARSE HOOKS
The XSParseInfixHooks
structure provides the following fields which are used at various stages of parsing.
struct XSParseInfixHooks {
U16 flags;
U8 lhs_flags;
U8 rhs_flags;
enum XSParseInfixClassification cls;
const char *wrapper_func_name;
const char *permit_hintkey;
bool (*permit)(pTHX_ void *hookdata);
OP *(*new_op)(pTHX_ U32 flags, OP *lhs, OP *rhs, SV **parsedata, void *hookdata);
OP *(*ppaddr)(pTHX);
/* optional */
void (*parse)(pTHX_ U32 flags, SV **parsedata, void *hookdata);
};
Flags
The flags
field gives details on how to handle the operator overall. It should be a bitmask of the following constants, or left as zero:
- XPI_FLAG_LISTASSOC
-
Since version 0.40.
If set, the operator supports n-way list-associative syntax; written in the form
OPERAND op OPERAND op OPERAND op ...
In this case, the custom operator will be a LISTOP rather than a BINOP, and every operand of the entire chain will be stored as a child op of it. The op function will need to know how many operands it is working on. There are two ways this may be indicated, depending on whether it was known at compile-time.
If the number operands is known at compile-time, the
OPf_STACKED
flag is not set, and theop_private
field indicates the number of operand expressions that were present.If the number is not known (for example, the operator is being used as the body of a generated wrapper function), the
OPf_STACKED
flag is set. The number of arguments will be passed as the UV of an extra SV which is pushed last to the stack. The op function should pop this first to find out.It is typical to begin a list-associative op function with code such as:
int n = (PL_op->op_flags & OPf_STACKED) ? POPu : PL_op->op_private;
If the operator is list-associative, then
lhs_flags
andrhs_flags
must be equal.
The lhs_flags
and rhs_flags
fields give details on how to handle the left- and right-hand side operands, respectively.
It should be set to one of the following constants, or left as zero:
- XPI_OPERAND_TERM_LIST
-
The operand will be foced into list context, preserving the
OP_PUSHMARK
at the beginning. This means that the ppfunc for this infix operator will have toPOPMARK
to find that. - XPI_OPERAND_LIST
-
The same as above.
Older versions used to provide constants named XPI_OPERAND_ARITH
and XPI_OPERAND_TERM
but they related to an older version of the core perl branch. These names are now aliases for zero, and can be removed from new code.
In addition the following extra bitflags are defined:
- XPI_OPERAND_ONLY_LOOK
-
If set, the operator function promises that it will not mutate any of its passed values, nor allow leaking of direct alias pointers to them via return value or other locations.
This flag is optional; omitting it when applicable will not change any observed behaviour. Setting it may enable certain optimisations to be performed.
Currently, this flag simply enables an optimisation in the call-checker for infix operator wrapper functions that take list-shaped operands. This optimisation discards an
OP_ANONLIST
operation which would create a temporary anonymous array reference for its operand values, allowing a slight saving of memory use and CPU time. This optimisation is only safe to perform if the operator does not mutate or retain aliases of any of the arguments, as otherwise the caller might see unexpected modifications or value references to the values passed.
The Selection Stage
The cls
field gives a "classification" of the operator, suggesting what sort of operation it provides. This is used as a filter by the various XS::Parse::Keyword
selection macros.
The classification should be one of the XPI_CLS_*
constants found and described further in the main XSParseInfix.h file.
The permit
Stage
As a shortcut for the common case, the permit_hintkey
may point to a string to look up from the hints hash. If the given key name is not found in the hints hash then the keyword is not permitted. If the key is present then the permit
function is invoked as normal.
If not rejected by a hint key that was not found in the hints hash, the function part of the stage is called next and should inspect whether the keyword is permitted at this time perhaps by inspecting other lexical clues, and return true only if the keyword is permitted.
Both the string and the function are optional. Either or both may be present. If neither is present then the keyword is always permitted - which is likely not what you wanted to do.
The parse
Stage
If the optional parse
hook function is present, it is called immediately after the parser has recognised the presence of the named operator itself but before it attempts to consume the right-hand side term. This hook function can attempt further parsing, in order to implement more complex syntax such as hyper-operators.
When invoked, it is passed a pointer to an SV *
-typed storage variable. It is free to use this variable it desires to store a result, which will then later be made available to the new_op
function.
The Op Generation Stage
If the infix operator is going to be used, then one of the new_op
or the ppaddr
fields explain how to create a new optree fragment.
If new_op
is defined then it will be used, and is expected to return an optree fragment that consumes the LHS and RHS arguments to implement the semantics of the operator. If the optional parse
stage had been present earlier, the SV **
pointer passed here will point to the same storage that parse
had previously had access to, so it can retrieve the results.
If new_op
is not present, then the ppaddr
will be used instead to construct a new BINOP or LISTOP of the OP_CUSTOM
type. If an earlier parse
stage had stored additional results into the SV *
variable these will be lost here.
The Wrapper Function
Additionally, if the wrapper_func_name
field is set to a string, this gives the (fully-qualified) name for a function to be generated as part of registering the operator. This newly-generated function will act as a wrapper for the operator.
For operators whose RHS is a scalar, the wrapper function is assumed to take two simple scalar arguments. The result of invoking the function on those arguments will be determined by using the operator code.
$result = $lhs OP $rhs;
$result = WRAPPERFUNC( $lhs, $rhs );
For operators whose RHS is a list, the wrapper function takes at least one argument, possibly more. The first argument is the scalar on the LHS, and the remaining arguments, however many there are, form the RHS:
$result = $lhs OP @rhs;
$result = WRAPPERFUNC( $lhs, @rhs );
For operators whose LHS and RHS is a list, the wrapper function takes two arguments which must be array references containing the lists.
$result = @lhs OP @rhs;
$result = WRAPPERFUNC( \@lhs, \@rhs );
This creates a convenience for accessing the operator from perls that do not support PL_infix_plugin
.
In the case of scalar infix operators, the wrapper function also includes a call-checker which attempts to inline the operator directly into the callsite. Thus, in simple cases where the function is called directly on exactly two scalar arguments (such as in the following), no ENTERSUB
overhead will be incurred and the generated optree will be identical to that which would have been generated by using infix operator syntax directly:
WRAPPERFUNC( $lhs, $rhs );
WRAPPERFUNC( $lhs, CONSTANT );
WRAPPERFUNC( $args[0], $args[1] );
WRAPPERFUNC( $lhs, scalar otherfunc() );
The checker is very pessimistic and will only rewrite callsites where it determines this can be done safely. It will not rewrite any of the following forms:
WRAPPERFUNC( $onearg ); # not enough args
WRAPPERFUNC( $x, $y, $z ); # too many args
WRAPPERFUNC( @args[0,1] ); # not a scalar
WRAPPERFUNC( $lhs, otherfunc() ); # not a scalar
The wrapper function for infix operators which take lists on both sides also has a call-checker which will attempt to inline the operator in similar circumstances. In addition to the optimisations described above for scalar operators, this checker will also inline an array-reference operator and omit the resulting dereference behaviour. Thus, the two following lines emit the same optree, without an OP_SREFGEN
or OP_RV2AV
:
@lhs OP @rhs;
WRAPPERFUNC( \@lhs, \@rhs );
Note that technically, this optimisation isn't strictly transparent in the odd cornercase that one of the referenced arrays is also the backing store for a blessed object reference, and that object class has a @{}
overload.
my @arr;
package SomeClass {
use overload '@{}' => sub { return ["values", "go", "here"]; };
}
bless \@arr, "SomeClass";
# this will not actually invoke the overload operator
WRAPPERFUNC( \@arr, [4, 5, 6] );
As this cornercase relates to taking duplicate references to the same blessed object's backing store variable, it should not matter to any real code; regular objects that are passed by reference into the wrapper function will run their overload methods as normal.
The callchecker for list operands can optionally also discard an op of the OP_ANONLIST
type, which is used by anonymous array-ref construction:
($u, $v, $w) OP ($x, $y, $z);
WRAPPERFUNC( [$u, $v, $w], [$x, $y, $z] );
This optimisation is only performed if the operator declared it safe to do so, via the XPI_OPERAND_ONLY_LOOK
flag.
If a function of the given name already exists at registration time it will be left undisturbed and no new wrapper will be created. This permits the same infix operator to have multiple spellings of its name; for example to allow both a real Unicode and a fallback ASCII transliteration of the same operator. The first registration will create the wrapper function; the subsequent one will skip it because it would otherwise be identical.
Note that when generating an optree for a wrapper function call, the new_op
hook function will be invoked with a NULL
pointer for the SV *
-typed parse data storage, as there won't be an opporunity for the parse
hook to run in this case.
DEPARSE
This module operates with B::Deparse in order to automatically provide deparse support for infix operators. Every infix operator that is implemented as a custom op (and thus has the ppaddr
hook field set) will have deparse logic added. This will allow it to deparse to either the named wrapper function, or to the infix operator syntax if on a PL_infix_plugin
-enabled perl and the appropriate lexical hint is enabled at the callsite.
In order for this to work, it is important that your custom operator is not registered as a custom op using the Perl_register_custom_op()
function. This registration will be performed by XS::Parse::Infix
itself at the time the infix operator is registered.
TODO
Have the entersub checker for list/list operators unwrap arrayref or anon-array argument forms (
WRAPPERFUNC( \@lhs, \@rhs )
orWRAPPERFUNC( [LHS], [RHS] )
).Further thoughts about how infix operators with
parse
hooks will work with automatic deparse, and also how to integrate them with XS::Parse::Keyword's grammar piece.
AUTHOR
Paul Evans <leonerd@leonerd.org.uk>