1 # This file is part of NIT ( http://www.nitlanguage.org ).
3 # Licensed under the Apache License, Version 2.0 (the "License");
4 # you may not use this file except in compliance with the License.
5 # You may obtain a copy of the License at
7 # http://www.apache.org/licenses/LICENSE-2.0
9 # Unless required by applicable law or agreed to in writing, software
10 # distributed under the License is distributed on an "AS IS" BASIS,
11 # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
12 # See the License for the specific language governing permissions and
13 # limitations under the License.
15 # Separate compilation of a Nit program
16 module separate_compiler
18 import abstract_compiler
20 import rapid_type_analysis
22 # Add separate compiler specific options
23 redef class ToolContext
25 var opt_separate
= new OptionBool("Use separate compilation", "--separate")
27 var opt_no_inline_intern
= new OptionBool("Do not inline call to intern methods", "--no-inline-intern")
28 # --no-union-attribute
29 var opt_no_union_attribute
= new OptionBool("Put primitive attributes in a box instead of an union", "--no-union-attribute")
30 # --no-shortcut-equate
31 var opt_no_shortcut_equate
= new OptionBool("Always call == in a polymorphic way", "--no-shortcut-equal")
33 var opt_no_tag_primitives
= new OptionBool("Use only boxes for primitive types", "--no-tag-primitives")
35 # --colors-are-symbols
36 var opt_colors_are_symbols
= new OptionBool("Store colors as symbols instead of static data (link-boost)", "--colors-are-symbols")
38 var opt_trampoline_call
= new OptionBool("Use an indirection when calling", "--trampoline-call")
40 var opt_guard_call
= new OptionBool("Guard VFT calls with a direct call", "--guard-call")
41 # --substitute-monomorph
42 var opt_substitute_monomorph
= new OptionBool("Replace monomorphic trampolines with direct calls (link-boost)", "--substitute-monomorph")
44 var opt_link_boost
= new OptionBool("Enable all link-boost optimizations", "--link-boost")
46 # --inline-coloring-numbers
47 var opt_inline_coloring_numbers
= new OptionBool("Inline colors and ids (semi-global)", "--inline-coloring-numbers")
48 # --inline-some-methods
49 var opt_inline_some_methods
= new OptionBool("Allow the separate compiler to inline some methods (semi-global)", "--inline-some-methods")
50 # --direct-call-monomorph
51 var opt_direct_call_monomorph
= new OptionBool("Allow the separate compiler to direct call monomorphic sites (semi-global)", "--direct-call-monomorph")
52 # --direct-call-monomorph0
53 var opt_direct_call_monomorph0
= new OptionBool("Allow the separate compiler to direct call monomorphic sites (semi-global)", "--direct-call-monomorph0")
55 var opt_skip_dead_methods
= new OptionBool("Do not compile dead methods (semi-global)", "--skip-dead-methods")
57 var opt_semi_global
= new OptionBool("Enable all semi-global optimizations", "--semi-global")
58 # --no-colo-dead-methods
59 var opt_colo_dead_methods
= new OptionBool("Force colorization of dead methods", "--colo-dead-methods")
61 var opt_tables_metrics
= new OptionBool("Enable static size measuring of tables used for vft, typing and resolution", "--tables-metrics")
63 var opt_type_poset
= new OptionBool("Build a poset of types to create more condensed tables", "--type-poset")
68 self.option_context
.add_option
(self.opt_separate
)
69 self.option_context
.add_option
(self.opt_no_inline_intern
)
70 self.option_context
.add_option
(self.opt_no_union_attribute
)
71 self.option_context
.add_option
(self.opt_no_shortcut_equate
)
72 self.option_context
.add_option
(self.opt_no_tag_primitives
)
73 self.option_context
.add_option
(opt_colors_are_symbols
, opt_trampoline_call
, opt_guard_call
, opt_direct_call_monomorph0
, opt_substitute_monomorph
, opt_link_boost
)
74 self.option_context
.add_option
(self.opt_inline_coloring_numbers
, opt_inline_some_methods
, opt_direct_call_monomorph
, opt_skip_dead_methods
, opt_semi_global
)
75 self.option_context
.add_option
(self.opt_colo_dead_methods
)
76 self.option_context
.add_option
(self.opt_tables_metrics
)
77 self.option_context
.add_option
(self.opt_type_poset
)
80 redef fun process_options
(args
)
85 if tc
.opt_semi_global
.value
then
86 tc
.opt_inline_coloring_numbers
.value
= true
87 tc
.opt_inline_some_methods
.value
= true
88 tc
.opt_direct_call_monomorph
.value
= true
89 tc
.opt_skip_dead_methods
.value
= true
91 if tc
.opt_link_boost
.value
then
92 tc
.opt_colors_are_symbols
.value
= true
93 tc
.opt_substitute_monomorph
.value
= true
95 if tc
.opt_substitute_monomorph
.value
then
96 tc
.opt_trampoline_call
.value
= true
100 var separate_compiler_phase
= new SeparateCompilerPhase(self, null)
103 class SeparateCompilerPhase
105 redef fun process_mainmodule
(mainmodule
, given_mmodules
) do
106 if not toolcontext
.opt_separate
.value
then return
108 var modelbuilder
= toolcontext
.modelbuilder
109 var analysis
= modelbuilder
.do_rapid_type_analysis
(mainmodule
)
110 modelbuilder
.run_separate_compiler
(mainmodule
, analysis
)
114 redef class ModelBuilder
115 fun run_separate_compiler
(mainmodule
: MModule, runtime_type_analysis
: nullable RapidTypeAnalysis)
118 self.toolcontext
.info
("*** GENERATING C ***", 1)
120 var compiler
= new SeparateCompiler(mainmodule
, self, runtime_type_analysis
)
121 compiler
.do_compilation
122 compiler
.display_stats
125 self.toolcontext
.info
("*** END GENERATING C: {time1-time0} ***", 2)
126 write_and_make
(compiler
)
129 # Count number of invocations by VFT
130 private var nb_invok_by_tables
= 0
131 # Count number of invocations by direct call
132 private var nb_invok_by_direct
= 0
133 # Count number of invocations by inlining
134 private var nb_invok_by_inline
= 0
137 # Singleton that store the knowledge about the separate compilation process
138 class SeparateCompiler
139 super AbstractCompiler
141 redef type VISITOR: SeparateCompilerVisitor
143 # The result of the RTA (used to know live types and methods)
144 var runtime_type_analysis
: nullable RapidTypeAnalysis
146 private var undead_types
: Set[MType] = new HashSet[MType]
147 private var live_unresolved_types
: Map[MClassDef, Set[MType]] = new HashMap[MClassDef, HashSet[MType]]
149 private var type_ids
: Map[MType, Int] is noinit
150 private var type_colors
: Map[MType, Int] is noinit
151 private var opentype_colors
: Map[MType, Int] is noinit
154 var file
= new_file
("nit.common")
155 self.header
= new CodeWriter(file
)
156 self.compile_box_kinds
159 redef fun do_compilation
162 compiler
.compile_header
164 var c_name
= mainmodule
.c_name
166 # compile class structures
167 modelbuilder
.toolcontext
.info
("Property coloring", 2)
168 compiler
.new_file
("{c_name}.classes")
169 compiler
.do_property_coloring
170 compiler
.compile_class_infos
171 for m
in mainmodule
.in_importation
.greaters
do
172 for mclass
in m
.intro_mclasses
do
173 #if mclass.kind == abstract_kind or mclass.kind == interface_kind then continue
174 compiler
.compile_class_to_c
(mclass
)
178 # The main function of the C
179 compiler
.new_file
("{c_name}.main")
180 compiler
.compile_nitni_global_ref_functions
181 compiler
.compile_main_function
182 compiler
.compile_finalizer_function
183 compiler
.link_mmethods
186 for m
in mainmodule
.in_importation
.greaters
do
187 modelbuilder
.toolcontext
.info
("Generate C for module {m.full_name}", 2)
188 compiler
.new_file
("{m.c_name}.sep")
189 compiler
.compile_module_to_c
(m
)
192 # compile live & cast type structures
193 modelbuilder
.toolcontext
.info
("Type coloring", 2)
194 compiler
.new_file
("{c_name}.types")
195 compiler
.compile_types
198 # Color and compile type structures and cast information
203 var mtypes
= compiler
.do_type_coloring
205 compiler
.compile_type_to_c
(t
)
207 # compile remaining types structures (useless but needed for the symbol resolution at link-time)
208 for t
in compiler
.undead_types
do
209 if mtypes
.has
(t
) then continue
210 compiler
.compile_type_to_c
(t
)
215 redef fun compile_header_structs
do
216 self.header
.add_decl
("typedef void(*nitmethod_t)(void); /* general C type representing a Nit method. */")
217 self.compile_header_attribute_structs
218 self.header
.add_decl
("struct class \{ int box_kind; nitmethod_t vft[]; \}; /* general C type representing a Nit class. */")
220 # With resolution_table_table, all live type resolution are stored in a big table: resolution_table
221 self.header
.add_decl
("struct type \{ int id; const char *name; int color; short int is_nullable; const struct types *resolution_table; int table_size; int type_table[]; \}; /* general C type representing a Nit type. */")
222 self.header
.add_decl
("struct instance \{ const struct type *type; const struct class *class; nitattribute_t attrs[]; \}; /* general C type representing a Nit instance. */")
223 self.header
.add_decl
("struct types \{ int dummy; const struct type *types[]; \}; /* a list types (used for vts, fts and unresolved lists). */")
224 self.header
.add_decl
("typedef struct instance val; /* general C type representing a Nit instance. */")
226 if not modelbuilder
.toolcontext
.opt_no_tag_primitives
.value
then
227 self.header
.add_decl
("extern const struct class *class_info[];")
228 self.header
.add_decl
("extern const struct type *type_info[];")
232 fun compile_header_attribute_structs
234 if modelbuilder
.toolcontext
.opt_no_union_attribute
.value
then
235 self.header
.add_decl
("typedef void* nitattribute_t; /* general C type representing a Nit attribute. */")
237 self.header
.add_decl
("typedef union \{")
238 self.header
.add_decl
("void* val;")
239 for c
, v
in self.box_kinds
do
240 var t
= c
.mclass_type
242 # `Pointer` reuse the `val` field
243 if t
.mclass
.name
== "Pointer" then continue
245 self.header
.add_decl
("{t.ctype_extern} {t.ctypename};")
247 self.header
.add_decl
("\} nitattribute_t; /* general C type representing a Nit attribute. */")
251 fun compile_box_kinds
253 # Collect all bas box class
254 # FIXME: this is not completely fine with a separate compilation scheme
255 for classname
in ["Int", "Bool", "Byte", "Char", "Float", "CString",
256 "Pointer", "Int8", "Int16", "UInt16", "Int32", "UInt32"] do
257 var classes
= self.mainmodule
.model
.get_mclasses_by_name
(classname
)
258 if classes
== null then continue
259 assert classes
.length
== 1 else print_error classes
.join
(", ")
260 self.box_kinds
[classes
.first
] = self.box_kinds
.length
+ 1
264 var box_kinds
= new HashMap[MClass, Int]
266 fun box_kind_of
(mclass
: MClass): Int
268 #var pointer_type = self.mainmodule.pointer_type
269 #if mclass.mclass_type.ctype == "val*" or mclass.mclass_type.is_subtype(self.mainmodule, mclass.mclass_type pointer_type) then
270 if mclass
.mclass_type
.ctype_extern
== "val*" then
272 else if mclass
.kind
== extern_kind
and mclass
.name
!= "CString" then
273 return self.box_kinds
[self.mainmodule
.pointer_type
.mclass
]
275 return self.box_kinds
[mclass
]
280 fun compile_color_consts
(colors
: Map[Object, Int]) do
282 for m
, c
in colors
do
283 compile_color_const
(v
, m
, c
)
287 fun compile_color_const
(v
: SeparateCompilerVisitor, m
: Object, color
: Int) do
288 if color_consts_done
.has
(m
) then return
289 if m
isa MEntity then
290 if modelbuilder
.toolcontext
.opt_inline_coloring_numbers
.value
then
291 self.provide_declaration
(m
.const_color
, "#define {m.const_color} {color}")
292 else if not modelbuilder
.toolcontext
.opt_colors_are_symbols
.value
or not v
.compiler
.target_platform
.supports_linker_script
then
293 self.provide_declaration
(m
.const_color
, "extern const int {m.const_color};")
294 v
.add
("const int {m.const_color} = {color};")
296 # The color 'C' is the ``address'' of a false static variable 'XC'
297 self.provide_declaration
(m
.const_color
, "#define {m.const_color} ((long)&X{m.const_color})\nextern const void X{m.const_color};")
298 if color
== -1 then color
= 0 # Symbols cannot be negative, so just use 0 for dead things
299 # Teach the linker that the address of 'XC' is `color`.
300 linker_script
.add
("X{m.const_color} = {color};")
305 color_consts_done
.add
(m
)
308 private var color_consts_done
= new HashSet[Object]
310 # The conflict graph of classes used for coloration
311 var class_conflict_graph
: POSetConflictGraph[MClass] is noinit
313 # colorize classe properties
314 fun do_property_coloring
do
316 var rta
= runtime_type_analysis
319 var mclasses
= mainmodule
.flatten_mclass_hierarchy
320 class_conflict_graph
= mclasses
.to_conflict_graph
322 # Prepare to collect elements to color and build layout with
323 var mmethods
= new HashMap[MClass, Set[PropertyLayoutElement]]
324 var mattributes
= new HashMap[MClass, Set[MAttribute]]
326 # The dead methods and super-call, still need to provide a dead color symbol
327 var dead_methods
= new Array[PropertyLayoutElement]
329 for mclass
in mclasses
do
330 mmethods
[mclass
] = new HashSet[PropertyLayoutElement]
331 mattributes
[mclass
] = new HashSet[MAttribute]
334 # Pre-collect known live things
336 for m
in rta
.live_methods
do
337 mmethods
[m
.intro_mclassdef
.mclass
].add m
339 for m
in rta
.live_super_sends
do
340 var mclass
= m
.mclassdef
.mclass
341 mmethods
[mclass
].add m
345 for m
in mainmodule
.in_importation
.greaters
do for cd
in m
.mclassdefs
do
346 var mclass
= cd
.mclass
347 # Collect methods and attributes
348 for p
in cd
.intro_mproperties
do
349 if p
isa MMethod then
351 mmethods
[mclass
].add p
352 else if not rta
.live_methods
.has
(p
) then
355 else if p
isa MAttribute then
356 mattributes
[mclass
].add p
360 # Collect all super calls (dead or not)
361 for mpropdef
in cd
.mpropdefs
do
362 if not mpropdef
isa MMethodDef then continue
363 if mpropdef
.has_supercall
then
365 mmethods
[mclass
].add mpropdef
366 else if not rta
.live_super_sends
.has
(mpropdef
) then
367 dead_methods
.add mpropdef
374 var meth_colorer
= new POSetGroupColorer[MClass, PropertyLayoutElement](class_conflict_graph
, mmethods
)
375 var method_colors
= meth_colorer
.colors
376 compile_color_consts
(method_colors
)
378 # give null color to dead methods and supercalls
379 for mproperty
in dead_methods
do compile_color_const
(new_visitor
, mproperty
, -1)
381 # attribute coloration
382 var attr_colorer
= new POSetGroupColorer[MClass, MAttribute](class_conflict_graph
, mattributes
)
383 var attr_colors
= attr_colorer
.colors
#ize(poset, mattributes)
384 compile_color_consts
(attr_colors
)
386 # Build method and attribute tables
387 method_tables
= new HashMap[MClass, Array[nullable MPropDef]]
388 attr_tables
= new HashMap[MClass, Array[nullable MProperty]]
389 for mclass
in mclasses
do
390 if not mclass
.has_new_factory
and (mclass
.kind
== abstract_kind
or mclass
.kind
== interface_kind
) then continue
391 if rta
!= null and not rta
.live_classes
.has
(mclass
) then continue
393 var mtype
= mclass
.intro
.bound_mtype
395 # Resolve elements in the layout to get the final table
396 var meth_layout
= meth_colorer
.build_layout
(mclass
)
397 var meth_table
= new Array[nullable MPropDef].with_capacity
(meth_layout
.length
)
398 method_tables
[mclass
] = meth_table
399 for e
in meth_layout
do
402 else if e
isa MMethod then
403 # Standard method call of `e`
404 meth_table
.add e
.lookup_first_definition
(mainmodule
, mtype
)
405 else if e
isa MMethodDef then
406 # Super-call in the methoddef `e`
407 meth_table
.add e
.lookup_next_definition
(mainmodule
, mtype
)
413 # Do not need to resolve attributes as only the position is used
414 attr_tables
[mclass
] = attr_colorer
.build_layout
(mclass
)
420 # colorize live types of the program
421 private fun do_type_coloring
: Collection[MType] do
422 # Collect types to colorize
423 var live_types
= runtime_type_analysis
.live_types
424 var live_cast_types
= runtime_type_analysis
.live_cast_types
426 var res
= new HashSet[MType]
427 res
.add_all live_types
428 res
.add_all live_cast_types
430 if modelbuilder
.toolcontext
.opt_type_poset
.value
then
431 # Compute colors with a type poset
432 var poset
= poset_from_mtypes
(live_types
, live_cast_types
)
433 var colorer
= new POSetColorer[MType]
434 colorer
.colorize
(poset
)
435 type_ids
= colorer
.ids
436 type_colors
= colorer
.colors
437 type_tables
= build_type_tables
(poset
)
439 # Compute colors using the class poset
440 # Faster to compute but the number of holes can degenerate
441 compute_type_test_layouts
(live_types
, live_cast_types
)
443 type_ids
= new HashMap[MType, Int]
444 for x
in res
do type_ids
[x
] = type_ids
.length
+ 1
447 # VT and FT are stored with other unresolved types in the big resolution_tables
448 self.compute_resolution_tables
(live_types
)
453 private fun poset_from_mtypes
(mtypes
, cast_types
: Set[MType]): POSet[MType] do
454 var poset
= new POSet[MType]
456 # Instead of doing the full matrix mtypes X cast_types,
457 # a grouping is done by the base classes of the type so
458 # that we compare only types whose base classes are in inheritance.
460 var mtypes_by_class
= new MultiHashMap[MClass, MType]
462 var c
= e
.undecorate
.as(MClassType).mclass
463 mtypes_by_class
[c
].add
(e
)
467 var casttypes_by_class
= new MultiHashMap[MClass, MType]
468 for e
in cast_types
do
469 var c
= e
.undecorate
.as(MClassType).mclass
470 casttypes_by_class
[c
].add
(e
)
474 for c1
, ts1
in mtypes_by_class
do
475 for c2
in c1
.in_hierarchy
(mainmodule
).greaters
do
476 var ts2
= casttypes_by_class
[c2
]
479 if e
== o
then continue
480 if e
.is_subtype
(mainmodule
, null, o
) then
491 fun build_type_tables
(mtypes
: POSet[MType]): Map[MType, Array[nullable MType]] do
492 var tables
= new HashMap[MType, Array[nullable MType]]
493 for mtype
in mtypes
do
494 var table
= new Array[nullable MType]
495 for sup
in mtypes
[mtype
].greaters
do
496 var color
= type_colors
[sup
]
497 if table
.length
<= color
then
498 for i
in [table
.length
.. color
[ do
504 tables
[mtype
] = table
510 private fun compute_type_test_layouts
(mtypes
: Set[MClassType], cast_types
: Set[MType]) do
511 # Group cast_type by their classes
512 var bucklets
= new HashMap[MClass, Set[MType]]
513 for e
in cast_types
do
514 var c
= e
.undecorate
.as(MClassType).mclass
515 if not bucklets
.has_key
(c
) then
516 bucklets
[c
] = new HashSet[MType]
521 # Colorize cast_types from the class hierarchy
522 var colorer
= new POSetGroupColorer[MClass, MType](class_conflict_graph
, bucklets
)
523 type_colors
= colorer
.colors
525 var layouts
= new HashMap[MClass, Array[nullable MType]]
526 for c
in runtime_type_analysis
.live_classes
do
527 layouts
[c
] = colorer
.build_layout
(c
)
530 # Build the table for each live type
532 # A live type use the layout of its class
534 var layout
= layouts
[c
]
535 var table
= new Array[nullable MType].with_capacity
(layout
.length
)
536 type_tables
[t
] = table
538 # For each potential super-type in the layout
542 else if t
.is_subtype
(mainmodule
, null, sup
) then
551 # resolution_tables is used to perform a type resolution at runtime in O(1)
552 private fun compute_resolution_tables
(mtypes
: Set[MType]) do
553 # During the visit of the body of classes, live_unresolved_types are collected
555 # Collect all live_unresolved_types (visited in the body of classes)
557 # Determinate fo each livetype what are its possible requested anchored types
558 var mtype2unresolved
= new HashMap[MClass, Set[MType]]
559 for mtype
in self.runtime_type_analysis
.live_types
do
560 var mclass
= mtype
.mclass
561 var set
= mtype2unresolved
.get_or_null
(mclass
)
563 set
= new HashSet[MType]
564 mtype2unresolved
[mclass
] = set
566 for cd
in mtype
.collect_mclassdefs
(self.mainmodule
) do
567 if self.live_unresolved_types
.has_key
(cd
) then
568 set
.add_all
(self.live_unresolved_types
[cd
])
573 # Compute the table layout with the prefered method
574 var colorer
= new BucketsColorer[MClass, MType]
576 opentype_colors
= colorer
.colorize
(mtype2unresolved
)
577 resolution_tables
= self.build_resolution_tables
(self.runtime_type_analysis
.live_types
, mtype2unresolved
)
579 # Compile a C constant for each collected unresolved type.
580 # Either to a color, or to -1 if the unresolved type is dead (no live receiver can require it)
581 var all_unresolved
= new HashSet[MType]
582 for t
in self.live_unresolved_types
.values
do
583 all_unresolved
.add_all
(t
)
585 var all_unresolved_types_colors
= new HashMap[MType, Int]
586 for t
in all_unresolved
do
587 if opentype_colors
.has_key
(t
) then
588 all_unresolved_types_colors
[t
] = opentype_colors
[t
]
590 all_unresolved_types_colors
[t
] = -1
593 self.compile_color_consts
(all_unresolved_types_colors
)
596 #for k, v in unresolved_types_tables.as(not null) do
597 # print "{k}: {v.join(", ")}"
602 fun build_resolution_tables
(elements
: Set[MClassType], map
: Map[MClass, Set[MType]]): Map[MClassType, Array[nullable MType]] do
603 var tables
= new HashMap[MClassType, Array[nullable MType]]
604 for mclasstype
in elements
do
605 var mtypes
= map
[mclasstype
.mclass
]
606 var table
= new Array[nullable MType]
607 for mtype
in mtypes
do
608 var color
= opentype_colors
[mtype
]
609 if table
.length
<= color
then
610 for i
in [table
.length
.. color
[ do
616 tables
[mclasstype
] = table
621 # Separately compile all the method definitions of the module
622 fun compile_module_to_c
(mmodule
: MModule)
624 var old_module
= self.mainmodule
625 self.mainmodule
= mmodule
626 for cd
in mmodule
.mclassdefs
do
627 for pd
in cd
.mpropdefs
do
628 if not pd
isa MMethodDef then continue
629 if pd
.mproperty
.is_broken
or pd
.is_broken
or pd
.msignature
== null then continue # Skip broken method
630 var rta
= runtime_type_analysis
631 if modelbuilder
.toolcontext
.opt_skip_dead_methods
.value
and rta
!= null and not rta
.live_methoddefs
.has
(pd
) then continue
632 #print "compile {pd} @ {cd} @ {mmodule}"
633 var r
= pd
.separate_runtime_function
635 var r2
= pd
.virtual_runtime_function
636 if r2
!= r
then r2
.compile_to_c
(self)
638 # Generate trampolines
639 if modelbuilder
.toolcontext
.opt_trampoline_call
.value
then
640 r2
.compile_trampolines
(self)
644 self.mainmodule
= old_module
647 # Process all introduced methods and compile some linking information (if needed)
650 if not modelbuilder
.toolcontext
.opt_substitute_monomorph
.value
and not modelbuilder
.toolcontext
.opt_guard_call
.value
then return
652 for mmodule
in mainmodule
.in_importation
.greaters
do
653 for cd
in mmodule
.mclassdefs
do
654 for m
in cd
.intro_mproperties
do
655 if not m
isa MMethod then continue
662 # Compile some linking information (if needed)
663 fun link_mmethod
(m
: MMethod)
665 var n2
= "CALL_" + m
.const_color
667 # Replace monomorphic call by a direct call to the virtual implementation
668 var md
= is_monomorphic
(m
)
670 linker_script
.add
("{n2} = {md.virtual_runtime_function.c_name};")
673 # If opt_substitute_monomorph then a trampoline is used, else a weak symbol is used
674 if modelbuilder
.toolcontext
.opt_guard_call
.value
then
675 var r
= m
.intro
.virtual_runtime_function
676 provide_declaration
(n2
, "{r.c_ret} {n2}{r.c_sig} __attribute__((weak));")
680 # The single mmethodef called in case of monomorphism.
681 # Returns nul if dead or polymorphic.
682 fun is_monomorphic
(m
: MMethod): nullable MMethodDef
684 var rta
= runtime_type_analysis
686 # Without RTA, monomorphic means alone (uniq name)
687 if m
.mpropdefs
.length
== 1 then
688 return m
.mpropdefs
.first
693 # With RTA, monomorphic means only live methoddef
694 var res
: nullable MMethodDef = null
695 for md
in m
.mpropdefs
do
696 if rta
.live_methoddefs
.has
(md
) then
697 if res
!= null then return null
705 # Globaly compile the type structure of a live type
706 fun compile_type_to_c
(mtype
: MType)
708 assert not mtype
.need_anchor
709 var is_live
= mtype
isa MClassType and runtime_type_analysis
.live_types
.has
(mtype
)
710 var is_cast_live
= runtime_type_analysis
.live_cast_types
.has
(mtype
)
711 var c_name
= mtype
.c_name
712 var v
= new SeparateCompilerVisitor(self)
713 v
.add_decl
("/* runtime type {mtype} */")
715 # extern const struct type_X
716 self.provide_declaration
("type_{c_name}", "extern const struct type type_{c_name};")
718 # const struct type_X
719 v
.add_decl
("const struct type type_{c_name} = \{")
721 # type id (for cast target)
723 v
.add_decl
("{type_ids[mtype]},")
725 v
.add_decl
("-1, /*CAST DEAD*/")
729 v
.add_decl
("\"{mtype}\
", /* class_name_string */")
731 # type color (for cast target)
733 v
.add_decl
("{type_colors[mtype]},")
735 v
.add_decl
("-1, /*CAST DEAD*/")
739 if mtype
isa MNullableType then
745 # resolution table (for receiver)
747 var mclass_type
= mtype
.undecorate
748 assert mclass_type
isa MClassType
749 if resolution_tables
[mclass_type
].is_empty
then
750 v
.add_decl
("NULL, /*NO RESOLUTIONS*/")
752 compile_type_resolution_table
(mtype
)
753 v
.require_declaration
("resolution_table_{c_name}")
754 v
.add_decl
("&resolution_table_{c_name},")
757 v
.add_decl
("NULL, /*DEAD*/")
760 # cast table (for receiver)
762 v
.add_decl
("{self.type_tables[mtype].length},")
764 for stype
in self.type_tables
[mtype
] do
765 if stype
== null then
766 v
.add_decl
("-1, /* empty */")
768 v
.add_decl
("{type_ids[stype]}, /* {stype} */")
773 # Use -1 to indicate dead type, the info is used by --hardening
774 v
.add_decl
("-1, \{\}, /*DEAD TYPE*/")
779 fun compile_type_resolution_table
(mtype
: MType) do
781 var mclass_type
= mtype
.undecorate
.as(MClassType)
783 # extern const struct resolution_table_X resolution_table_X
784 self.provide_declaration
("resolution_table_{mtype.c_name}", "extern const struct types resolution_table_{mtype.c_name};")
786 # const struct fts_table_X fts_table_X
788 v
.add_decl
("const struct types resolution_table_{mtype.c_name} = \{")
789 v
.add_decl
("0, /* dummy */")
791 for t
in self.resolution_tables
[mclass_type
] do
793 v
.add_decl
("NULL, /* empty */")
795 # The table stores the result of the type resolution
796 # Therefore, for a receiver `mclass_type`, and a unresolved type `t`
797 # the value stored is tv.
798 var tv
= t
.resolve_for
(mclass_type
, mclass_type
, self.mainmodule
, true)
799 # FIXME: What typeids means here? How can a tv not be live?
800 if type_ids
.has_key
(tv
) then
801 v
.require_declaration
("type_{tv.c_name}")
802 v
.add_decl
("&type_{tv.c_name}, /* {t}: {tv} */")
804 v
.add_decl
("NULL, /* empty ({t}: {tv} not a live type) */")
812 # Globally compile the table of the class mclass
813 # In a link-time optimisation compiler, tables are globally computed
814 # In a true separate compiler (a with dynamic loading) you cannot do this unfortnally
815 fun compile_class_to_c
(mclass
: MClass)
817 if mclass
.is_broken
then return
819 var mtype
= mclass
.intro
.bound_mtype
820 var c_name
= mclass
.c_name
824 var rta
= runtime_type_analysis
825 var is_dead
= rta
!= null and not rta
.live_classes
.has
(mclass
)
826 # While the class may be dead, some part of separately compiled code may use symbols associated to the class, so
827 # in order to compile and link correctly the C code, these symbols should be declared and defined.
828 var need_corpse
= is_dead
and mtype
.is_c_primitive
or mclass
.kind
== extern_kind
or mclass
.kind
== enum_kind
830 v
.add_decl
("/* runtime class {c_name}: {mclass.full_name} (dead={is_dead}; need_corpse={need_corpse})*/")
833 if not is_dead
or need_corpse
then
834 self.provide_declaration
("class_{c_name}", "extern const struct class class_{c_name};")
835 v
.add_decl
("const struct class class_{c_name} = \{")
836 v
.add_decl
("{self.box_kind_of(mclass)}, /* box_kind */")
838 var vft
= self.method_tables
.get_or_null
(mclass
)
839 if vft
!= null then for i
in [0 .. vft
.length
[ do
840 var mpropdef
= vft
[i
]
841 if mpropdef
== null then
842 v
.add_decl
("NULL, /* empty */")
844 assert mpropdef
isa MMethodDef
845 if rta
!= null and not rta
.live_methoddefs
.has
(mpropdef
) then
846 v
.add_decl
("NULL, /* DEAD {mclass.intro_mmodule}:{mclass}:{mpropdef} */")
848 else if mpropdef
.is_broken
or mpropdef
.msignature
== null or mpropdef
.mproperty
.is_broken
then
849 v
.add_decl
("NULL, /* DEAD (BROKEN) {mclass.intro_mmodule}:{mclass}:{mpropdef} */")
852 var rf
= mpropdef
.virtual_runtime_function
853 v
.require_declaration
(rf
.c_name
)
854 v
.add_decl
("(nitmethod_t){rf.c_name}, /* pointer to {mclass.intro_mmodule}:{mclass}:{mpropdef} */")
861 if mtype
.is_c_primitive
or mtype
.mclass
.name
== "Pointer" then
862 # Is a primitive type or the Pointer class, not any other extern class
864 if mtype
.is_tagged
then return
866 #Build instance struct
867 self.header
.add_decl
("struct instance_{c_name} \{")
868 self.header
.add_decl
("const struct type *type;")
869 self.header
.add_decl
("const struct class *class;")
870 self.header
.add_decl
("{mtype.ctype_extern} value;")
871 self.header
.add_decl
("\};")
873 # Pointer is needed by extern types, live or not
874 if is_dead
and mtype
.mclass
.name
!= "Pointer" then return
877 self.provide_declaration
("BOX_{c_name}", "val* BOX_{c_name}({mtype.ctype_extern});")
878 v
.add_decl
("/* allocate {mtype} */")
879 v
.add_decl
("val* BOX_{mtype.c_name}({mtype.ctype_extern} value) \{")
880 var alloc
= v
.nit_alloc
("sizeof(struct instance_{c_name})", mclass
.full_name
)
881 v
.add
("struct instance_{c_name}*res = {alloc};")
882 v
.compiler
.undead_types
.add
(mtype
)
883 v
.require_declaration
("type_{c_name}")
884 v
.add
("res->type = &type_{c_name};")
885 v
.require_declaration
("class_{c_name}")
886 v
.add
("res->class = &class_{c_name};")
887 v
.add
("res->value = value;")
888 v
.add
("return (val*)res;")
891 # A Pointer class also need its constructor
892 if mtype
.mclass
.name
!= "Pointer" then return
895 self.provide_declaration
("NEW_{c_name}", "{mtype.ctype} NEW_{c_name}(const struct type* type);")
896 v
.add_decl
("/* allocate {mtype} */")
897 v
.add_decl
("{mtype.ctype} NEW_{c_name}(const struct type* type) \{")
899 v
.add_abort
("{mclass} is DEAD")
901 var res
= v
.new_named_var
(mtype
, "self")
903 alloc
= v
.nit_alloc
("sizeof(struct instance_{mtype.c_name})", mclass
.full_name
)
904 v
.add
("{res} = {alloc};")
905 v
.add
("{res}->type = type;")
906 hardening_live_type
(v
, "type")
907 v
.require_declaration
("class_{c_name}")
908 v
.add
("{res}->class = &class_{c_name};")
909 v
.add
("((struct instance_{mtype.c_name}*){res})->value = NULL;")
910 v
.add
("return {res};")
914 else if mclass
.name
== "NativeArray" then
915 #Build instance struct
916 self.header
.add_decl
("struct instance_{c_name} \{")
917 self.header
.add_decl
("const struct type *type;")
918 self.header
.add_decl
("const struct class *class;")
919 # NativeArrays are just a instance header followed by a length and an array of values
920 self.header
.add_decl
("int length;")
921 self.header
.add_decl
("val* values[0];")
922 self.header
.add_decl
("\};")
925 self.provide_declaration
("NEW_{c_name}", "{mtype.ctype} NEW_{c_name}(int length, const struct type* type);")
926 v
.add_decl
("/* allocate {mtype} */")
927 v
.add_decl
("{mtype.ctype} NEW_{c_name}(int length, const struct type* type) \{")
928 var res
= v
.get_name
("self")
929 v
.add_decl
("struct instance_{c_name} *{res};")
930 var mtype_elt
= mtype
.arguments
.first
931 var alloc
= v
.nit_alloc
("sizeof(struct instance_{c_name}) + length*sizeof({mtype_elt.ctype})", mclass
.full_name
)
932 v
.add
("{res} = {alloc};")
933 v
.add
("{res}->type = type;")
934 hardening_live_type
(v
, "type")
935 v
.require_declaration
("class_{c_name}")
936 v
.add
("{res}->class = &class_{c_name};")
937 v
.add
("{res}->length = length;")
938 v
.add
("return (val*){res};")
941 else if mtype
.mclass
.kind
== extern_kind
and mtype
.mclass
.name
!= "CString" then
942 # Is an extern class (other than Pointer and CString)
943 # Pointer is caught in a previous `if`, and CString is internal
945 var pointer_type
= mainmodule
.pointer_type
947 self.provide_declaration
("NEW_{c_name}", "{mtype.ctype} NEW_{c_name}(const struct type* type);")
948 v
.add_decl
("/* allocate extern {mtype} */")
949 v
.add_decl
("{mtype.ctype} NEW_{c_name}(const struct type* type) \{")
951 v
.add_abort
("{mclass} is DEAD")
953 var res
= v
.new_named_var
(mtype
, "self")
955 var alloc
= v
.nit_alloc
("sizeof(struct instance_{pointer_type.c_name})", mclass
.full_name
)
956 v
.add
("{res} = {alloc};")
957 v
.add
("{res}->type = type;")
958 hardening_live_type
(v
, "type")
959 v
.require_declaration
("class_{c_name}")
960 v
.add
("{res}->class = &class_{c_name};")
961 v
.add
("((struct instance_{pointer_type.c_name}*){res})->value = NULL;")
962 v
.add
("return {res};")
969 self.provide_declaration
("NEW_{c_name}", "{mtype.ctype} NEW_{c_name}(const struct type* type);")
970 v
.add_decl
("/* allocate {mtype} */")
971 v
.add_decl
("{mtype.ctype} NEW_{c_name}(const struct type* type) \{")
973 v
.add_abort
("{mclass} is DEAD")
975 var res
= v
.new_named_var
(mtype
, "self")
977 var attrs
= self.attr_tables
.get_or_null
(mclass
)
978 if attrs
== null then
979 var alloc
= v
.nit_alloc
("sizeof(struct instance)", mclass
.full_name
)
980 v
.add
("{res} = {alloc};")
982 var alloc
= v
.nit_alloc
("sizeof(struct instance) + {attrs.length}*sizeof(nitattribute_t)", mclass
.full_name
)
983 v
.add
("{res} = {alloc};")
985 if modelbuilder
.toolcontext
.opt_trace
.value
then
986 v
.add
("tracepoint(Nit_Compiler, Object_Instance,\"{mtype}\
", (uintptr_t)self);")
987 v
.add
("GC_register_finalizer(self, object_destroy_callback, NULL, NULL, NULL);")
989 v
.add
("{res}->type = type;")
990 hardening_live_type
(v
, "type")
991 v
.require_declaration
("class_{c_name}")
992 v
.add
("{res}->class = &class_{c_name};")
993 if attrs
!= null then
994 self.generate_init_attr
(v
, res
, mtype
)
997 v
.add
("return {res};")
1002 # Compile structures used to map tagged primitive values to their classes and types.
1003 # This method also determines which class will be tagged.
1004 fun compile_class_infos
1006 if modelbuilder
.toolcontext
.opt_no_tag_primitives
.value
then return
1008 # Note: if you change the tagging scheme, do not forget to update
1009 # `autobox` and `extract_tag`
1010 var class_info
= new Array[nullable MClass].filled_with
(null, 4)
1011 for t
in box_kinds
.keys
do
1012 # Note: a same class can be associated to multiple slots if one want to
1013 # use some Huffman coding.
1014 if t
.name
== "Int" then
1016 t
.mclass_type
.tag_value
= 1
1017 else if t
.name
== "Char" then
1019 t
.mclass_type
.tag_value
= 2
1020 else if t
.name
== "Bool" then
1022 t
.mclass_type
.tag_value
= 3
1026 t
.mclass_type
.is_tagged
= true
1029 # Compile the table for classes. The tag is used as an index
1030 var v
= self.new_visitor
1031 v
.add_decl
"const struct class *class_info[4] = \{"
1032 for t
in class_info
do
1036 var s
= "class_{t.c_name}"
1037 v
.require_declaration
(s
)
1043 # Compile the table for types. The tag is used as an index
1044 v
.add_decl
"const struct type *type_info[4] = \{"
1045 for t
in class_info
do
1049 var s
= "type_{t.c_name}"
1050 undead_types
.add
(t
.mclass_type
)
1051 v
.require_declaration
(s
)
1058 # Add a dynamic test to ensure that the type referenced by `t` is a live type
1059 fun hardening_live_type
(v
: VISITOR, t
: String)
1061 if not v
.compiler
.modelbuilder
.toolcontext
.opt_hardening
.value
then return
1062 v
.add
("if({t} == NULL) \{")
1063 v
.add_abort
("type null")
1065 v
.add
("if({t}->table_size < 0) \{")
1066 v
.add
("PRINT_ERROR(\"Instantiation of a dead
type: %s\\n\
", {t}->name);")
1067 v
.add_abort
("type dead")
1071 redef fun new_visitor
do return new SeparateCompilerVisitor(self)
1075 private var type_tables
: Map[MType, Array[nullable MType]] = new HashMap[MType, Array[nullable MType]]
1076 private var resolution_tables
: Map[MClassType, Array[nullable MType]] = new HashMap[MClassType, Array[nullable MType]]
1077 protected var method_tables
: Map[MClass, Array[nullable MPropDef]] = new HashMap[MClass, Array[nullable MPropDef]]
1078 protected var attr_tables
: Map[MClass, Array[nullable MProperty]] = new HashMap[MClass, Array[nullable MProperty]]
1080 redef fun display_stats
1083 if self.modelbuilder
.toolcontext
.opt_tables_metrics
.value
then
1086 if self.modelbuilder
.toolcontext
.opt_isset_checks_metrics
.value
then
1087 display_isset_checks
1089 var tc
= self.modelbuilder
.toolcontext
1090 tc
.info
("# implementation of method invocation",2)
1091 var nb_invok_total
= modelbuilder
.nb_invok_by_tables
+ modelbuilder
.nb_invok_by_direct
+ modelbuilder
.nb_invok_by_inline
1092 tc
.info
("total number of invocations: {nb_invok_total}",2)
1093 tc
.info
("invocations by VFT send: {modelbuilder.nb_invok_by_tables} ({div(modelbuilder.nb_invok_by_tables,nb_invok_total)}%)",2)
1094 tc
.info
("invocations by direct call: {modelbuilder.nb_invok_by_direct} ({div(modelbuilder.nb_invok_by_direct,nb_invok_total)}%)",2)
1095 tc
.info
("invocations by inlining: {modelbuilder.nb_invok_by_inline} ({div(modelbuilder.nb_invok_by_inline,nb_invok_total)}%)",2)
1100 print
"# size of subtyping tables"
1101 print
"\ttotal \tholes"
1104 for t
, table
in type_tables
do
1105 total
+= table
.length
1106 for e
in table
do if e
== null then holes
+= 1
1108 print
"\t{total}\t{holes}"
1110 print
"# size of resolution tables"
1111 print
"\ttotal \tholes"
1114 for t
, table
in resolution_tables
do
1115 total
+= table
.length
1116 for e
in table
do if e
== null then holes
+= 1
1118 print
"\t{total}\t{holes}"
1120 print
"# size of methods tables"
1121 print
"\ttotal \tholes"
1124 for t
, table
in method_tables
do
1125 total
+= table
.length
1126 for e
in table
do if e
== null then holes
+= 1
1128 print
"\t{total}\t{holes}"
1130 print
"# size of attributes tables"
1131 print
"\ttotal \tholes"
1134 for t
, table
in attr_tables
do
1135 total
+= table
.length
1136 for e
in table
do if e
== null then holes
+= 1
1138 print
"\t{total}\t{holes}"
1141 protected var isset_checks_count
= 0
1142 protected var attr_read_count
= 0
1144 fun display_isset_checks
do
1145 print
"# total number of compiled attribute reads"
1146 print
"\t{attr_read_count}"
1147 print
"# total number of compiled isset-checks"
1148 print
"\t{isset_checks_count}"
1151 redef fun compile_nitni_structs
1153 self.header
.add_decl
"""
1154 struct nitni_instance \{
1155 struct nitni_instance *next,
1156 *prev; /* adjacent global references in global list */
1157 int count; /* number of time this global reference has been marked */
1158 struct instance *value;
1164 redef fun finalize_ffi_for_module
(mmodule
)
1166 var old_module
= self.mainmodule
1167 self.mainmodule
= mmodule
1169 self.mainmodule
= old_module
1173 # A visitor on the AST of property definition that generate the C code of a separate compilation process.
1174 class SeparateCompilerVisitor
1175 super AbstractCompilerVisitor
1177 redef type COMPILER: SeparateCompiler
1179 redef fun adapt_signature
(m
, args
)
1181 var msignature
= m
.msignature
.resolve_for
(m
.mclassdef
.bound_mtype
, m
.mclassdef
.bound_mtype
, m
.mclassdef
.mmodule
, true)
1182 var recv
= args
.first
1183 if recv
.mtype
.ctype
!= m
.mclassdef
.mclass
.mclass_type
.ctype
then
1184 args
.first
= self.autobox
(args
.first
, m
.mclassdef
.mclass
.mclass_type
)
1186 for i
in [0..msignature
.arity
[ do
1187 var mp
= msignature
.mparameters
[i
]
1189 if mp
.is_vararg
then
1192 args
[i
+1] = self.autobox
(args
[i
+1], t
)
1196 redef fun unbox_signature_extern
(m
, args
)
1198 var msignature
= m
.msignature
.resolve_for
(m
.mclassdef
.bound_mtype
, m
.mclassdef
.bound_mtype
, m
.mclassdef
.mmodule
, true)
1199 if not m
.mproperty
.is_init
and m
.is_extern
then
1200 args
.first
= self.unbox_extern
(args
.first
, m
.mclassdef
.mclass
.mclass_type
)
1202 for i
in [0..msignature
.arity
[ do
1203 var mp
= msignature
.mparameters
[i
]
1205 if mp
.is_vararg
then
1208 if m
.is_extern
then args
[i
+1] = self.unbox_extern
(args
[i
+1], t
)
1212 redef fun autobox
(value
, mtype
)
1214 if value
.mtype
== mtype
then
1216 else if not value
.mtype
.is_c_primitive
and not mtype
.is_c_primitive
then
1218 else if not value
.mtype
.is_c_primitive
then
1219 if mtype
.is_tagged
then
1220 if mtype
.name
== "Int" then
1221 return self.new_expr
("(long)({value})>>2", mtype
)
1222 else if mtype
.name
== "Char" then
1223 return self.new_expr
("(uint32_t)((long)({value})>>2)", mtype
)
1224 else if mtype
.name
== "Bool" then
1225 return self.new_expr
("(short int)((long)({value})>>2)", mtype
)
1230 return self.new_expr
("((struct instance_{mtype.c_name}*){value})->value; /* autounbox from {value.mtype} to {mtype} */", mtype
)
1231 else if not mtype
.is_c_primitive
then
1232 assert value
.mtype
== value
.mcasttype
1233 if value
.mtype
.is_tagged
then
1235 if value
.mtype
.name
== "Int" then
1236 res
= self.new_expr
("(val*)({value}<<2|1)", mtype
)
1237 else if value
.mtype
.name
== "Char" then
1238 res
= self.new_expr
("(val*)((long)({value})<<2|2)", mtype
)
1239 else if value
.mtype
.name
== "Bool" then
1240 res
= self.new_expr
("(val*)((long)({value})<<2|3)", mtype
)
1244 # Do not loose type info
1245 res
.mcasttype
= value
.mcasttype
1248 var valtype
= value
.mtype
.as(MClassType)
1249 if mtype
isa MClassType and mtype
.mclass
.kind
== extern_kind
and mtype
.mclass
.name
!= "CString" then
1250 valtype
= compiler
.mainmodule
.pointer_type
1252 var res
= self.new_var
(mtype
)
1253 # Do not loose type info
1254 res
.mcasttype
= value
.mcasttype
1255 self.require_declaration
("BOX_{valtype.c_name}")
1256 self.add
("{res} = BOX_{valtype.c_name}({value}); /* autobox from {value.mtype} to {mtype} */")
1258 else if (value
.mtype
.ctype
== "void*" and mtype
.ctype
== "void*") or
1259 (value
.mtype
.ctype
== "char*" and mtype
.ctype
== "void*") or
1260 (value
.mtype
.ctype
== "void*" and mtype
.ctype
== "char*") then
1263 # Bad things will appen!
1264 var res
= self.new_var
(mtype
)
1265 self.add
("/* {res} left unintialized (cannot convert {value.mtype} to {mtype}) */")
1266 self.add
("PRINT_ERROR(\"Cast error
: Cannot cast
%s to
%s
.\\n\
", \"{value.mtype}\
", \"{mtype}\
"); fatal_exit(1);")
1271 redef fun unbox_extern
(value
, mtype
)
1273 if mtype
isa MClassType and mtype
.mclass
.kind
== extern_kind
and
1274 mtype
.mclass
.name
!= "CString" then
1275 var pointer_type
= compiler
.mainmodule
.pointer_type
1276 var res
= self.new_var_extern
(mtype
)
1277 self.add
"{res} = ((struct instance_{pointer_type.c_name}*){value})->value; /* unboxing {value.mtype} */"
1284 redef fun box_extern
(value
, mtype
)
1286 if mtype
isa MClassType and mtype
.mclass
.kind
== extern_kind
and
1287 mtype
.mclass
.name
!= "CString" then
1288 var valtype
= compiler
.mainmodule
.pointer_type
1289 var res
= self.new_var
(mtype
)
1290 compiler
.undead_types
.add
(mtype
)
1291 self.require_declaration
("BOX_{valtype.c_name}")
1292 self.add
("{res} = BOX_{valtype.c_name}({value}); /* boxing {value.mtype} */")
1293 self.require_declaration
("type_{mtype.c_name}")
1294 self.add
("{res}->type = &type_{mtype.c_name};")
1295 self.require_declaration
("class_{mtype.c_name}")
1296 self.add
("{res}->class = &class_{mtype.c_name};")
1303 # Returns a C expression containing the tag of the value as a long.
1305 # If the C expression is evaluated to 0, it means there is no tag.
1306 # Thus the expression can be used as a condition.
1307 fun extract_tag
(value
: RuntimeVariable): String
1309 assert not value
.mtype
.is_c_primitive
1310 return "((long){value}&3)" # Get the two low bits
1313 # Returns a C expression of the runtime class structure of the value.
1314 # The point of the method is to work also with primitive types.
1315 fun class_info
(value
: RuntimeVariable): String
1317 if not value
.mtype
.is_c_primitive
then
1318 if can_be_primitive
(value
) and not compiler
.modelbuilder
.toolcontext
.opt_no_tag_primitives
.value
then
1319 var tag
= extract_tag
(value
)
1320 return "({tag}?class_info[{tag}]:{value}->class)"
1322 return "{value}->class"
1324 compiler
.undead_types
.add
(value
.mtype
)
1325 self.require_declaration
("class_{value.mtype.c_name}")
1326 return "(&class_{value.mtype.c_name})"
1330 # Returns a C expression of the runtime type structure of the value.
1331 # The point of the method is to work also with primitive types.
1332 fun type_info
(value
: RuntimeVariable): String
1334 if not value
.mtype
.is_c_primitive
then
1335 if can_be_primitive
(value
) and not compiler
.modelbuilder
.toolcontext
.opt_no_tag_primitives
.value
then
1336 var tag
= extract_tag
(value
)
1337 return "({tag}?type_info[{tag}]:{value}->type)"
1339 return "{value}->type"
1341 compiler
.undead_types
.add
(value
.mtype
)
1342 self.require_declaration
("type_{value.mtype.c_name}")
1343 return "(&type_{value.mtype.c_name})"
1347 redef fun compile_callsite
(callsite
, args
)
1349 var rta
= compiler
.runtime_type_analysis
1350 # TODO: Inlining of new-style constructors with initializers
1351 if compiler
.modelbuilder
.toolcontext
.opt_direct_call_monomorph
.value
and rta
!= null and callsite
.mpropdef
.initializers
.is_empty
then
1352 var tgs
= rta
.live_targets
(callsite
)
1353 if tgs
.length
== 1 then
1354 return direct_call
(tgs
.first
, args
)
1357 # Shortcut intern methods as they are not usually redefinable
1358 if callsite
.mpropdef
.is_intern
and callsite
.mproperty
.name
!= "object_id" then
1359 # `object_id` is the only redefined intern method, so it can not be directly called.
1360 # TODO find a less ugly approach?
1361 return direct_call
(callsite
.mpropdef
, args
)
1366 # Fully and directly call a mpropdef
1368 # This method is used by `compile_callsite`
1369 private fun direct_call
(mpropdef
: MMethodDef, args
: Array[RuntimeVariable]): nullable RuntimeVariable
1371 var res0
= before_send
(mpropdef
.mproperty
, args
)
1372 var res
= call
(mpropdef
, mpropdef
.mclassdef
.bound_mtype
, args
)
1373 if res0
!= null then
1375 self.assign
(res0
, res
)
1378 add
("\}") # close the before_send
1381 redef fun send
(mmethod
, arguments
)
1383 if arguments
.first
.mcasttype
.is_c_primitive
then
1384 # In order to shortcut the primitive, we need to find the most specific method
1385 # Howverr, because of performance (no flattening), we always work on the realmainmodule
1386 var m
= self.compiler
.mainmodule
1387 self.compiler
.mainmodule
= self.compiler
.realmainmodule
1388 var res
= self.monomorphic_send
(mmethod
, arguments
.first
.mcasttype
, arguments
)
1389 self.compiler
.mainmodule
= m
1393 return table_send
(mmethod
, arguments
, mmethod
)
1396 # Handle common special cases before doing the effective method invocation
1397 # This methods handle the `==` and `!=` methods and the case of the null receiver.
1398 # Note: a { is open in the generated C, that enclose and protect the effective method invocation.
1399 # Client must not forget to close the } after them.
1401 # The value returned is the result of the common special cases.
1402 # If not null, client must compile it with the result of their own effective method invocation.
1404 # If `before_send` can shortcut the whole message sending, a dummy `if(0){`
1405 # is generated to cancel the effective method invocation that will follow
1406 # TODO: find a better approach
1407 private fun before_send
(mmethod
: MMethod, arguments
: Array[RuntimeVariable]): nullable RuntimeVariable
1409 var res
: nullable RuntimeVariable = null
1410 var recv
= arguments
.first
1411 var consider_null
= not self.compiler
.modelbuilder
.toolcontext
.opt_no_check_null
.value
or mmethod
.name
== "==" or mmethod
.name
== "!="
1412 if maybe_null
(recv
) and consider_null
then
1413 self.add
("if ({recv} == NULL) \{")
1414 if mmethod
.name
== "==" or mmethod
.name
== "is_same_instance" then
1415 res
= self.new_var
(bool_type
)
1416 var arg
= arguments
[1]
1417 if arg
.mcasttype
isa MNullableType then
1418 self.add
("{res} = ({arg} == NULL);")
1419 else if arg
.mcasttype
isa MNullType then
1420 self.add
("{res} = 1; /* is null */")
1422 self.add
("{res} = 0; /* {arg.inspect} cannot be null */")
1424 else if mmethod
.name
== "!=" then
1425 res
= self.new_var
(bool_type
)
1426 var arg
= arguments
[1]
1427 if arg
.mcasttype
isa MNullableType then
1428 self.add
("{res} = ({arg} != NULL);")
1429 else if arg
.mcasttype
isa MNullType then
1430 self.add
("{res} = 0; /* is null */")
1432 self.add
("{res} = 1; /* {arg.inspect} cannot be null */")
1435 self.add_abort
("Receiver is null")
1437 self.add
("\} else \{")
1441 if not self.compiler
.modelbuilder
.toolcontext
.opt_no_shortcut_equate
.value
and (mmethod
.name
== "==" or mmethod
.name
== "!=" or mmethod
.name
== "is_same_instance") then
1442 # Recv is not null, thus if arg is, it is easy to conclude (and respect the invariants)
1443 var arg
= arguments
[1]
1444 if arg
.mcasttype
isa MNullType then
1445 if res
== null then res
= self.new_var
(bool_type
)
1446 if mmethod
.name
== "!=" then
1447 self.add
("{res} = 1; /* arg is null and recv is not */")
1448 else # `==` and `is_same_instance`
1449 self.add
("{res} = 0; /* arg is null but recv is not */")
1451 self.add
("\}") # closes the null case
1452 self.add
("if (0) \{") # what follow is useless, CC will drop it
1458 private fun table_send
(mmethod
: MMethod, arguments
: Array[RuntimeVariable], mentity
: MEntity): nullable RuntimeVariable
1460 compiler
.modelbuilder
.nb_invok_by_tables
+= 1
1461 if compiler
.modelbuilder
.toolcontext
.opt_invocation_metrics
.value
then add
("count_invoke_by_tables++;")
1463 assert arguments
.length
== mmethod
.intro
.msignature
.arity
+ 1 else debug
("Invalid arity for {mmethod}. {arguments.length} arguments given.")
1465 var res0
= before_send
(mmethod
, arguments
)
1467 var runtime_function
= mmethod
.intro
.virtual_runtime_function
1468 var msignature
= runtime_function
.called_signature
1470 adapt_signature
(mmethod
.intro
, arguments
)
1472 var res
: nullable RuntimeVariable
1473 var ret
= msignature
.return_mtype
1477 res
= self.new_var
(ret
)
1480 var ss
= arguments
.join
(", ")
1482 var const_color
= mentity
.const_color
1489 if mentity
isa MMethod and compiler
.modelbuilder
.toolcontext
.opt_direct_call_monomorph0
.value
then
1490 # opt_direct_call_monomorph0 is used to compare the efficiency of the alternative lookup implementation, ceteris paribus.
1491 # The difference with the non-zero option is that the monomorphism is looked-at on the mmethod level and not at the callsite level.
1492 # TODO: remove this mess and use per callsite service to detect monomorphism in a single place.
1493 var md
= compiler
.is_monomorphic
(mentity
)
1495 var callsym
= md
.virtual_runtime_function
.c_name
1496 self.require_declaration
(callsym
)
1497 self.add
"{ress}{callsym}({ss}); /* {mmethod} on {arguments.first.inspect}*/"
1499 self.require_declaration
(const_color
)
1500 self.add
"{ress}(({runtime_function.c_funptrtype})({class_info(arguments.first)}->vft[{const_color}]))({ss}); /* {mmethod} on {arguments.first.inspect}*/"
1502 else if mentity
isa MMethod and compiler
.modelbuilder
.toolcontext
.opt_guard_call
.value
then
1503 var callsym
= "CALL_" + const_color
1504 self.require_declaration
(callsym
)
1505 self.add
"if (!{callsym}) \{"
1506 self.require_declaration
(const_color
)
1507 self.add
"{ress}(({runtime_function.c_funptrtype})({class_info(arguments.first)}->vft[{const_color}]))({ss}); /* {mmethod} on {arguments.first.inspect}*/"
1508 self.add
"\} else \{"
1509 self.add
"{ress}{callsym}({ss}); /* {mmethod} on {arguments.first.inspect}*/"
1511 else if mentity
isa MMethod and compiler
.modelbuilder
.toolcontext
.opt_trampoline_call
.value
then
1512 var callsym
= "CALL_" + const_color
1513 self.require_declaration
(callsym
)
1514 self.add
"{ress}{callsym}({ss}); /* {mmethod} on {arguments.first.inspect}*/"
1516 self.require_declaration
(const_color
)
1517 self.add
"{ress}(({runtime_function.c_funptrtype})({class_info(arguments.first)}->vft[{const_color}]))({ss}); /* {mmethod} on {arguments.first.inspect}*/"
1520 if res0
!= null then
1526 self.add
("\}") # closes the null case
1531 redef fun call
(mmethoddef
, recvtype
, arguments
)
1533 assert arguments
.length
== mmethoddef
.msignature
.arity
+ 1 else debug
("Invalid arity for {mmethoddef}. {arguments.length} arguments given.")
1535 var res
: nullable RuntimeVariable
1536 var ret
= mmethoddef
.msignature
.return_mtype
1540 ret
= ret
.resolve_for
(mmethoddef
.mclassdef
.bound_mtype
, mmethoddef
.mclassdef
.bound_mtype
, mmethoddef
.mclassdef
.mmodule
, true)
1541 res
= self.new_var
(ret
)
1544 if (mmethoddef
.is_intern
and not compiler
.modelbuilder
.toolcontext
.opt_no_inline_intern
.value
) or
1545 (compiler
.modelbuilder
.toolcontext
.opt_inline_some_methods
.value
and mmethoddef
.can_inline
(self)) then
1546 compiler
.modelbuilder
.nb_invok_by_inline
+= 1
1547 if compiler
.modelbuilder
.toolcontext
.opt_invocation_metrics
.value
then add
("count_invoke_by_inline++;")
1548 var frame
= new StaticFrame(self, mmethoddef
, recvtype
, arguments
)
1549 frame
.returnlabel
= self.get_name
("RET_LABEL")
1550 frame
.returnvar
= res
1551 var old_frame
= self.frame
1553 self.add
("\{ /* Inline {mmethoddef} ({arguments.join(",")}) on {arguments.first.inspect} */")
1554 mmethoddef
.compile_inside_to_c
(self, arguments
)
1555 self.add
("{frame.returnlabel.as(not null)}:(void)0;")
1557 self.frame
= old_frame
1560 compiler
.modelbuilder
.nb_invok_by_direct
+= 1
1561 if compiler
.modelbuilder
.toolcontext
.opt_invocation_metrics
.value
then add
("count_invoke_by_direct++;")
1564 self.adapt_signature
(mmethoddef
, arguments
)
1566 self.require_declaration
(mmethoddef
.c_name
)
1568 self.add
("{mmethoddef.c_name}({arguments.join(", ")}); /* Direct call {mmethoddef} on {arguments.first.inspect}*/")
1571 self.add
("{res} = {mmethoddef.c_name}({arguments.join(", ")});")
1577 redef fun supercall
(m
: MMethodDef, recvtype
: MClassType, arguments
: Array[RuntimeVariable]): nullable RuntimeVariable
1579 if arguments
.first
.mcasttype
.is_c_primitive
then
1580 # In order to shortcut the primitive, we need to find the most specific method
1581 # However, because of performance (no flattening), we always work on the realmainmodule
1582 var main
= self.compiler
.mainmodule
1583 self.compiler
.mainmodule
= self.compiler
.realmainmodule
1584 var res
= self.monomorphic_super_send
(m
, recvtype
, arguments
)
1585 self.compiler
.mainmodule
= main
1588 return table_send
(m
.mproperty
, arguments
, m
)
1591 redef fun vararg_instance
(mpropdef
, recv
, varargs
, elttype
)
1593 # A vararg must be stored into an new array
1594 # The trick is that the dymaic type of the array may depends on the receiver
1595 # of the method (ie recv) if the static type is unresolved
1596 # This is more complex than usual because the unresolved type must not be resolved
1597 # with the current receiver (ie self).
1598 # Therefore to isolate the resolution from self, a local StaticFrame is created.
1599 # One can see this implementation as an inlined method of the receiver whose only
1600 # job is to allocate the array
1601 var old_frame
= self.frame
1602 var frame
= new StaticFrame(self, mpropdef
, mpropdef
.mclassdef
.bound_mtype
, [recv
])
1604 #print "required Array[{elttype}] for recv {recv.inspect}. bound=Array[{self.resolve_for(elttype, recv)}]. selfvar={frame.arguments.first.inspect}"
1605 var res
= self.array_instance
(varargs
, elttype
)
1606 self.frame
= old_frame
1610 redef fun isset_attribute
(a
, recv
)
1612 self.check_recv_notnull
(recv
)
1613 var res
= self.new_var
(bool_type
)
1615 # What is the declared type of the attribute?
1616 var mtype
= a
.intro
.static_mtype
.as(not null)
1617 var intromclassdef
= a
.intro
.mclassdef
1618 mtype
= mtype
.resolve_for
(intromclassdef
.bound_mtype
, intromclassdef
.bound_mtype
, intromclassdef
.mmodule
, true)
1620 if mtype
isa MNullableType then
1621 self.add
("{res} = 1; /* easy isset: {a} on {recv.inspect} */")
1625 self.require_declaration
(a
.const_color
)
1626 if self.compiler
.modelbuilder
.toolcontext
.opt_no_union_attribute
.value
then
1627 self.add
("{res} = {recv}->attrs[{a.const_color}] != NULL; /* {a} on {recv.inspect}*/")
1630 if not mtype
.is_c_primitive
and not mtype
.is_tagged
then
1631 self.add
("{res} = {recv}->attrs[{a.const_color}].val != NULL; /* {a} on {recv.inspect} */")
1633 self.add
("{res} = 1; /* NOT YET IMPLEMENTED: isset of primitives: {a} on {recv.inspect} */")
1639 redef fun read_attribute
(a
, recv
)
1641 self.check_recv_notnull
(recv
)
1643 # What is the declared type of the attribute?
1644 var ret
= a
.intro
.static_mtype
.as(not null)
1645 var intromclassdef
= a
.intro
.mclassdef
1646 ret
= ret
.resolve_for
(intromclassdef
.bound_mtype
, intromclassdef
.bound_mtype
, intromclassdef
.mmodule
, true)
1648 if self.compiler
.modelbuilder
.toolcontext
.opt_isset_checks_metrics
.value
then
1649 self.compiler
.attr_read_count
+= 1
1650 self.add
("count_attr_reads++;")
1653 self.require_declaration
(a
.const_color
)
1654 if self.compiler
.modelbuilder
.toolcontext
.opt_no_union_attribute
.value
then
1655 # Get the attribute or a box (ie. always a val*)
1656 var cret
= self.object_type
.as_nullable
1657 var res
= self.new_var
(cret
)
1660 self.add
("{res} = {recv}->attrs[{a.const_color}]; /* {a} on {recv.inspect} */")
1662 # Check for Uninitialized attribute
1663 if not ret
isa MNullableType and not self.compiler
.modelbuilder
.toolcontext
.opt_no_check_attr_isset
.value
then
1664 self.add
("if (unlikely({res} == NULL)) \{")
1665 self.add_abort
("Uninitialized attribute {a.name}")
1668 if self.compiler
.modelbuilder
.toolcontext
.opt_isset_checks_metrics
.value
then
1669 self.compiler
.isset_checks_count
+= 1
1670 self.add
("count_isset_checks++;")
1674 # Return the attribute or its unboxed version
1675 # Note: it is mandatory since we reuse the box on write, we do not whant that the box escapes
1676 return self.autobox
(res
, ret
)
1678 var res
= self.new_var
(ret
)
1679 self.add
("{res} = {recv}->attrs[{a.const_color}].{ret.ctypename}; /* {a} on {recv.inspect} */")
1681 # Check for Uninitialized attribute
1682 if not ret
.is_c_primitive
and not ret
isa MNullableType and not self.compiler
.modelbuilder
.toolcontext
.opt_no_check_attr_isset
.value
then
1683 self.add
("if (unlikely({res} == NULL)) \{")
1684 self.add_abort
("Uninitialized attribute {a.name}")
1686 if self.compiler
.modelbuilder
.toolcontext
.opt_isset_checks_metrics
.value
then
1687 self.compiler
.isset_checks_count
+= 1
1688 self.add
("count_isset_checks++;")
1696 redef fun write_attribute
(a
, recv
, value
)
1698 self.check_recv_notnull
(recv
)
1700 # What is the declared type of the attribute?
1701 var mtype
= a
.intro
.static_mtype
.as(not null)
1702 var intromclassdef
= a
.intro
.mclassdef
1703 mtype
= mtype
.resolve_for
(intromclassdef
.bound_mtype
, intromclassdef
.bound_mtype
, intromclassdef
.mmodule
, true)
1705 # Adapt the value to the declared type
1706 value
= self.autobox
(value
, mtype
)
1708 self.require_declaration
(a
.const_color
)
1709 if self.compiler
.modelbuilder
.toolcontext
.opt_no_union_attribute
.value
then
1710 var attr
= "{recv}->attrs[{a.const_color}]"
1711 if mtype
.is_tagged
then
1712 # The attribute is not primitive, thus store it as tagged
1713 var tv
= autobox
(value
, compiler
.mainmodule
.object_type
)
1714 self.add
("{attr} = {tv}; /* {a} on {recv.inspect} */")
1715 else if mtype
.is_c_primitive
then
1716 assert mtype
isa MClassType
1717 # The attribute is primitive, thus we store it in a box
1718 # The trick is to create the box the first time then resuse the box
1719 self.add
("if ({attr} != NULL) \{")
1720 self.add
("((struct instance_{mtype.c_name}*){attr})->value = {value}; /* {a} on {recv.inspect} */")
1721 self.add
("\} else \{")
1722 value
= self.autobox
(value
, self.object_type
.as_nullable
)
1723 self.add
("{attr} = {value}; /* {a} on {recv.inspect} */")
1726 # The attribute is not primitive, thus store it direclty
1727 self.add
("{attr} = {value}; /* {a} on {recv.inspect} */")
1730 self.add
("{recv}->attrs[{a.const_color}].{mtype.ctypename} = {value}; /* {a} on {recv.inspect} */")
1734 # Check that mtype is a live open type
1735 fun hardening_live_open_type
(mtype
: MType)
1737 if not compiler
.modelbuilder
.toolcontext
.opt_hardening
.value
then return
1738 self.require_declaration
(mtype
.const_color
)
1739 var col
= mtype
.const_color
1740 self.add
("if({col} == -1) \{")
1741 self.add
("PRINT_ERROR(\"Resolution of a dead open
type: %s\\n\
", \"{mtype.to_s.escape_to_c}\
");")
1742 self.add_abort
("open type dead")
1746 # Check that mtype it a pointer to a live cast type
1747 fun hardening_cast_type
(t
: String)
1749 if not compiler
.modelbuilder
.toolcontext
.opt_hardening
.value
then return
1750 add
("if({t} == NULL) \{")
1751 add_abort
("cast type null")
1753 add
("if({t}->id == -1 || {t}->color == -1) \{")
1754 add
("PRINT_ERROR(\"Try to cast on a dead cast
type: %s\\n\
", {t}->name);")
1755 add_abort
("cast type dead")
1759 redef fun init_instance
(mtype
)
1761 self.require_declaration
("NEW_{mtype.mclass.c_name}")
1762 var compiler
= self.compiler
1763 if mtype
isa MGenericType and mtype
.need_anchor
then
1764 hardening_live_open_type
(mtype
)
1765 link_unresolved_type
(self.frame
.mpropdef
.mclassdef
, mtype
)
1766 var recv
= self.frame
.arguments
.first
1767 var recv_type_info
= self.type_info
(recv
)
1768 self.require_declaration
(mtype
.const_color
)
1769 return self.new_expr
("NEW_{mtype.mclass.c_name}({recv_type_info}->resolution_table->types[{mtype.const_color}])", mtype
)
1771 compiler
.undead_types
.add
(mtype
)
1772 self.require_declaration
("type_{mtype.c_name}")
1773 return self.new_expr
("NEW_{mtype.mclass.c_name}(&type_{mtype.c_name})", mtype
)
1776 redef fun type_test
(value
, mtype
, tag
)
1778 self.add
("/* {value.inspect} isa {mtype} */")
1779 var compiler
= self.compiler
1781 var recv
= self.frame
.arguments
.first
1782 var recv_type_info
= self.type_info
(recv
)
1784 var res
= self.new_var
(bool_type
)
1786 var cltype
= self.get_name
("cltype")
1787 self.add_decl
("int {cltype};")
1788 var idtype
= self.get_name
("idtype")
1789 self.add_decl
("int {idtype};")
1791 var maybe_null
= self.maybe_null
(value
)
1792 var accept_null
= "0"
1794 if ntype
isa MNullableType then
1799 if value
.mcasttype
.is_subtype
(self.frame
.mpropdef
.mclassdef
.mmodule
, self.frame
.mpropdef
.mclassdef
.bound_mtype
, mtype
) then
1800 self.add
("{res} = 1; /* easy {value.inspect} isa {mtype}*/")
1801 if compiler
.modelbuilder
.toolcontext
.opt_typing_test_metrics
.value
then
1802 self.compiler
.count_type_test_skipped
[tag
] += 1
1803 self.add
("count_type_test_skipped_{tag}++;")
1808 if ntype
.need_anchor
then
1809 var type_struct
= self.get_name
("type_struct")
1810 self.add_decl
("const struct type* {type_struct};")
1812 # Either with resolution_table with a direct resolution
1813 hardening_live_open_type
(mtype
)
1814 link_unresolved_type
(self.frame
.mpropdef
.mclassdef
, mtype
)
1815 self.require_declaration
(mtype
.const_color
)
1816 self.add
("{type_struct} = {recv_type_info}->resolution_table->types[{mtype.const_color}];")
1817 if compiler
.modelbuilder
.toolcontext
.opt_typing_test_metrics
.value
then
1818 self.compiler
.count_type_test_unresolved
[tag
] += 1
1819 self.add
("count_type_test_unresolved_{tag}++;")
1821 hardening_cast_type
(type_struct
)
1822 self.add
("{cltype} = {type_struct}->color;")
1823 self.add
("{idtype} = {type_struct}->id;")
1824 if maybe_null
and accept_null
== "0" then
1825 var is_nullable
= self.get_name
("is_nullable")
1826 self.add_decl
("short int {is_nullable};")
1827 self.add
("{is_nullable} = {type_struct}->is_nullable;")
1828 accept_null
= is_nullable
.to_s
1830 else if ntype
isa MClassType then
1831 compiler
.undead_types
.add
(mtype
)
1832 self.require_declaration
("type_{mtype.c_name}")
1833 hardening_cast_type
("(&type_{mtype.c_name})")
1834 self.add
("{cltype} = type_{mtype.c_name}.color;")
1835 self.add
("{idtype} = type_{mtype.c_name}.id;")
1836 if compiler
.modelbuilder
.toolcontext
.opt_typing_test_metrics
.value
then
1837 self.compiler
.count_type_test_resolved
[tag
] += 1
1838 self.add
("count_type_test_resolved_{tag}++;")
1841 self.add
("PRINT_ERROR(\"NOT YET IMPLEMENTED: type_test
(%s
, {mtype}).\\n\
", \"{value.inspect}\
"); fatal_exit(1);")
1844 # check color is in table
1846 self.add
("if({value} == NULL) \{")
1847 self.add
("{res} = {accept_null};")
1848 self.add
("\} else \{")
1850 var value_type_info
= self.type_info
(value
)
1851 self.add
("if({cltype} >= {value_type_info}->table_size) \{")
1852 self.add
("{res} = 0;")
1853 self.add
("\} else \{")
1854 self.add
("{res} = {value_type_info}->type_table[{cltype}] == {idtype};")
1863 redef fun is_same_type_test
(value1
, value2
)
1865 var res
= self.new_var
(bool_type
)
1866 # Swap values to be symetric
1867 if value2
.mtype
.is_c_primitive
and not value1
.mtype
.is_c_primitive
then
1872 if value1
.mtype
.is_c_primitive
then
1873 if value2
.mtype
== value1
.mtype
then
1874 self.add
("{res} = 1; /* is_same_type_test: compatible types {value1.mtype} vs. {value2.mtype} */")
1875 else if value2
.mtype
.is_c_primitive
then
1876 self.add
("{res} = 0; /* is_same_type_test: incompatible types {value1.mtype} vs. {value2.mtype}*/")
1878 var mtype1
= value1
.mtype
.as(MClassType)
1879 self.require_declaration
("class_{mtype1.c_name}")
1880 self.add
("{res} = ({value2} != NULL) && ({class_info(value2)} == &class_{mtype1.c_name}); /* is_same_type_test */")
1883 self.add
("{res} = ({value1} == {value2}) || ({value1} != NULL && {value2} != NULL && {class_info(value1)} == {class_info(value2)}); /* is_same_type_test */")
1888 redef fun class_name_string
(value
)
1890 var res
= self.get_name
("var_class_name")
1891 self.add_decl
("const char* {res};")
1892 if not value
.mtype
.is_c_primitive
then
1893 self.add
"{res} = {value} == NULL ? \"null\
" : {type_info(value)}->name;"
1894 else if value
.mtype
isa MClassType and value
.mtype
.as(MClassType).mclass
.kind
== extern_kind
and
1895 value
.mtype
.as(MClassType).name
!= "CString" then
1896 self.add
"{res} = \"{value.mtype.as(MClassType).mclass}\
";"
1898 self.require_declaration
("type_{value.mtype.c_name}")
1899 self.add
"{res} = type_{value.mtype.c_name}.name;"
1904 redef fun equal_test
(value1
, value2
)
1906 var res
= self.new_var
(bool_type
)
1907 if value2
.mtype
.is_c_primitive
and not value1
.mtype
.is_c_primitive
then
1912 if value1
.mtype
.is_c_primitive
then
1913 var t1
= value1
.mtype
1914 assert t1
== value1
.mcasttype
1916 # Fast case: same C type.
1917 if value2
.mtype
== t1
then
1918 # Same exact C primitive representation.
1919 self.add
("{res} = {value1} == {value2};")
1923 # Complex case: value2 has a different representation
1924 # Thus, it should be checked if `value2` is type-compatible with `value1`
1925 # This compatibility is done statically if possible and dynamically else
1927 # Conjunction (ands) of dynamic tests according to the static knowledge
1928 var tests
= new Array[String]
1930 var t2
= value2
.mcasttype
1931 if t2
isa MNullableType then
1932 # The destination type cannot be null
1933 tests
.add
("({value2} != NULL)")
1935 else if t2
isa MNullType then
1936 # `value2` is known to be null, thus incompatible with a primitive
1937 self.add
("{res} = 0; /* incompatible types {t1} vs. {t2}*/")
1942 # Same type but different representation.
1943 else if t2
.is_c_primitive
then
1944 # Type of `value2` is a different primitive type, thus incompatible
1945 self.add
("{res} = 0; /* incompatible types {t1} vs. {t2}*/")
1947 else if t1
.is_tagged
then
1948 # To be equal, `value2` should also be correctly tagged
1949 tests
.add
("({extract_tag(value2)} == {t1.tag_value})")
1951 # To be equal, `value2` should also be boxed with the same class
1952 self.require_declaration
("class_{t1.c_name}")
1953 tests
.add
"({class_info(value2)} == &class_{t1.c_name})"
1956 # Compare the unboxed `value2` with `value1`
1957 if tests
.not_empty
then
1958 self.add
"if ({tests.join(" && ")}) \{"
1960 self.add
"{res} = {self.autobox(value2, t1)} == {value1};"
1961 if tests
.not_empty
then
1962 self.add
"\} else {res} = 0;"
1967 var maybe_null
= true
1968 var test
= new Array[String]
1969 var t1
= value1
.mcasttype
1970 if t1
isa MNullableType then
1971 test
.add
("{value1} != NULL")
1976 var t2
= value2
.mcasttype
1977 if t2
isa MNullableType then
1978 test
.add
("{value2} != NULL")
1984 var incompatible
= false
1986 if t1
.is_c_primitive
then
1989 # No need to compare class
1990 else if t2
.is_c_primitive
then
1992 else if can_be_primitive
(value2
) then
1993 if t1
.is_tagged
then
1994 self.add
("{res} = {value1} == {value2};")
1997 if not compiler
.modelbuilder
.toolcontext
.opt_no_tag_primitives
.value
then
1998 test
.add
("(!{extract_tag(value2)})")
2000 test
.add
("{value1}->class == {value2}->class")
2004 else if t2
.is_c_primitive
then
2006 if can_be_primitive
(value1
) then
2007 if t2
.is_tagged
then
2008 self.add
("{res} = {value1} == {value2};")
2011 if not compiler
.modelbuilder
.toolcontext
.opt_no_tag_primitives
.value
then
2012 test
.add
("(!{extract_tag(value1)})")
2014 test
.add
("{value1}->class == {value2}->class")
2022 if incompatible
then
2024 self.add
("{res} = {value1} == {value2}; /* incompatible types {t1} vs. {t2}; but may be NULL*/")
2027 self.add
("{res} = 0; /* incompatible types {t1} vs. {t2}; cannot be NULL */")
2031 if primitive
!= null then
2032 if primitive
.is_tagged
then
2033 self.add
("{res} = {value1} == {value2};")
2036 test
.add
("((struct instance_{primitive.c_name}*){value1})->value == ((struct instance_{primitive.c_name}*){value2})->value")
2037 else if can_be_primitive
(value1
) and can_be_primitive
(value2
) then
2038 if not compiler
.modelbuilder
.toolcontext
.opt_no_tag_primitives
.value
then
2039 test
.add
("(!{extract_tag(value1)}) && (!{extract_tag(value2)})")
2041 test
.add
("{value1}->class == {value2}->class")
2042 var s
= new Array[String]
2043 for t
, v
in self.compiler
.box_kinds
do
2044 if t
.mclass_type
.is_tagged
then continue
2045 s
.add
"({value1}->class->box_kind == {v} && ((struct instance_{t.c_name}*){value1})->value == ((struct instance_{t.c_name}*){value2})->value)"
2048 self.add
("{res} = {value1} == {value2};")
2051 test
.add
("({s.join(" || ")})")
2053 self.add
("{res} = {value1} == {value2};")
2056 self.add
("{res} = {value1} == {value2} || ({test.join(" && ")});")
2060 fun can_be_primitive
(value
: RuntimeVariable): Bool
2062 var t
= value
.mcasttype
.undecorate
2063 if not t
isa MClassType then return false
2064 var k
= t
.mclass
.kind
2065 return k
== interface_kind
or t
.is_c_primitive
2068 redef fun array_instance
(array
, elttype
)
2070 var nclass
= mmodule
.native_array_class
2071 var arrayclass
= mmodule
.array_class
2072 var arraytype
= arrayclass
.get_mtype
([elttype
])
2073 var res
= self.init_instance
(arraytype
)
2074 self.add
("\{ /* {res} = array_instance Array[{elttype}] */")
2075 var length
= self.int_instance
(array
.length
)
2076 var nat
= native_array_instance
(elttype
, length
)
2077 for i
in [0..array
.length
[ do
2078 var r
= self.autobox
(array
[i
], self.object_type
)
2079 self.add
("((struct instance_{nclass.c_name}*){nat})->values[{i}] = (val*) {r};")
2081 self.send
(self.get_property
("with_native", arrayclass
.intro
.bound_mtype
), [res
, nat
, length
])
2086 redef fun native_array_instance
(elttype
, length
)
2088 var mtype
= mmodule
.native_array_type
(elttype
)
2089 self.require_declaration
("NEW_{mtype.mclass.c_name}")
2090 assert mtype
isa MGenericType
2091 var compiler
= self.compiler
2092 length
= autobox
(length
, compiler
.mainmodule
.int_type
)
2093 if mtype
.need_anchor
then
2094 hardening_live_open_type
(mtype
)
2095 link_unresolved_type
(self.frame
.mpropdef
.mclassdef
, mtype
)
2096 var recv
= self.frame
.arguments
.first
2097 var recv_type_info
= self.type_info
(recv
)
2098 self.require_declaration
(mtype
.const_color
)
2099 return self.new_expr
("NEW_{mtype.mclass.c_name}((int){length}, {recv_type_info}->resolution_table->types[{mtype.const_color}])", mtype
)
2101 compiler
.undead_types
.add
(mtype
)
2102 self.require_declaration
("type_{mtype.c_name}")
2103 return self.new_expr
("NEW_{mtype.mclass.c_name}((int){length}, &type_{mtype.c_name})", mtype
)
2106 redef fun native_array_def
(pname
, ret_type
, arguments
)
2108 var elttype
= arguments
.first
.mtype
2109 var nclass
= mmodule
.native_array_class
2110 var recv
= "((struct instance_{nclass.c_name}*){arguments[0]})->values"
2111 if pname
== "[]" then
2112 # Because the objects are boxed, return the box to avoid unnecessary (or broken) unboxing/reboxing
2113 var res
= self.new_expr
("{recv}[{arguments[1]}]", compiler
.mainmodule
.object_type
)
2114 res
.mcasttype
= ret_type
.as(not null)
2117 else if pname
== "[]=" then
2118 self.add
("{recv}[{arguments[1]}]={arguments[2]};")
2120 else if pname
== "length" then
2121 self.ret
(self.new_expr
("((struct instance_{nclass.c_name}*){arguments[0]})->length", ret_type
.as(not null)))
2123 else if pname
== "copy_to" then
2124 var recv1
= "((struct instance_{nclass.c_name}*){arguments[1]})->values"
2125 self.add
("memmove({recv1}, {recv}, {arguments[2]}*sizeof({elttype.ctype}));")
2127 else if pname
== "memmove" then
2128 # fun memmove(start: Int, length: Int, dest: NativeArray[E], dest_start: Int) is intern do
2129 var recv1
= "((struct instance_{nclass.c_name}*){arguments[3]})->values"
2130 self.add
("memmove({recv1}+{arguments[4]}, {recv}+{arguments[1]}, {arguments[2]}*sizeof({elttype.ctype}));")
2136 redef fun native_array_get
(nat
, i
)
2138 var nclass
= mmodule
.native_array_class
2139 var recv
= "((struct instance_{nclass.c_name}*){nat})->values"
2140 # Because the objects are boxed, return the box to avoid unnecessary (or broken) unboxing/reboxing
2141 var res
= self.new_expr
("{recv}[{i}]", compiler
.mainmodule
.object_type
)
2145 redef fun native_array_set
(nat
, i
, val
)
2147 var nclass
= mmodule
.native_array_class
2148 var recv
= "((struct instance_{nclass.c_name}*){nat})->values"
2149 self.add
("{recv}[{i}]={val};")
2152 fun link_unresolved_type
(mclassdef
: MClassDef, mtype
: MType) do
2153 assert mtype
.need_anchor
2154 var compiler
= self.compiler
2155 if not compiler
.live_unresolved_types
.has_key
(self.frame
.mpropdef
.mclassdef
) then
2156 compiler
.live_unresolved_types
[self.frame
.mpropdef
.mclassdef
] = new HashSet[MType]
2158 compiler
.live_unresolved_types
[self.frame
.mpropdef
.mclassdef
].add
(mtype
)
2162 redef class MMethodDef
2163 # The C function associated to a mmethoddef
2164 fun separate_runtime_function
: SeparateRuntimeFunction
2166 var res
= self.separate_runtime_function_cache
2168 var recv
= mclassdef
.bound_mtype
2169 var msignature
= msignature
.resolve_for
(recv
, recv
, mclassdef
.mmodule
, true)
2170 res
= new SeparateRuntimeFunction(self, recv
, msignature
, c_name
)
2171 self.separate_runtime_function_cache
= res
2175 private var separate_runtime_function_cache
: nullable SeparateRuntimeFunction
2177 # The C function associated to a mmethoddef, that can be stored into a VFT of a class
2178 # The first parameter (the reciever) is always typed by val* in order to accept an object value
2179 # The C-signature is always compatible with the intro
2180 fun virtual_runtime_function
: SeparateRuntimeFunction
2182 var res
= self.virtual_runtime_function_cache
2184 # Because the function is virtual, the signature must match the one of the original class
2185 var intromclassdef
= mproperty
.intro
.mclassdef
2186 var recv
= intromclassdef
.bound_mtype
2188 res
= separate_runtime_function
2189 if res
.called_recv
== recv
then
2190 self.virtual_runtime_function_cache
= res
2194 var msignature
= mproperty
.intro
.msignature
.resolve_for
(recv
, recv
, intromclassdef
.mmodule
, true)
2196 if recv
.ctype
== res
.called_recv
.ctype
and msignature
.c_equiv
(res
.called_signature
) then
2197 self.virtual_runtime_function_cache
= res
2201 res
= new SeparateRuntimeFunction(self, recv
, msignature
, "VIRTUAL_{c_name}")
2202 self.virtual_runtime_function_cache
= res
2207 private var virtual_runtime_function_cache
: nullable SeparateRuntimeFunction
2210 redef class MSignature
2211 # Does the C-version of `self` the same than the C-version of `other`?
2212 fun c_equiv
(other
: MSignature): Bool
2214 if self == other
then return true
2215 if arity
!= other
.arity
then return false
2216 for i
in [0..arity
[ do
2217 if mparameters
[i
].mtype
.ctype
!= other
.mparameters
[i
].mtype
.ctype
then return false
2219 if return_mtype
!= other
.return_mtype
then
2220 if return_mtype
== null or other
.return_mtype
== null then return false
2221 if return_mtype
.ctype
!= other
.return_mtype
.ctype
then return false
2227 # The C function associated to a methoddef separately compiled
2228 class SeparateRuntimeFunction
2229 super AbstractRuntimeFunction
2231 # The call-side static receiver
2232 var called_recv
: MType
2234 # The call-side static signature
2235 var called_signature
: MSignature
2237 # The name on the compiled method
2238 redef var build_c_name
: String
2240 # Statically call the original body instead
2241 var is_thunk
= false
2243 redef fun to_s
do return self.mmethoddef
.to_s
2245 # The C return type (something or `void`)
2246 var c_ret
: String is lazy
do
2247 var ret
= called_signature
.return_mtype
2255 # The C signature (only the parmeter part)
2256 var c_sig
: String is lazy
do
2257 var sig
= new FlatBuffer
2258 sig
.append
("({called_recv.ctype} self")
2259 for i
in [0..called_signature
.arity
[ do
2260 var mp
= called_signature
.mparameters
[i
]
2261 var mtype
= mp
.mtype
2262 if mp
.is_vararg
then
2263 mtype
= mmethoddef
.mclassdef
.mmodule
.array_type
(mtype
)
2265 sig
.append
(", {mtype.ctype} p{i}")
2271 # The C type for the function pointer.
2272 var c_funptrtype
: String is lazy
do return "{c_ret}(*){c_sig}"
2274 redef fun compile_to_c
(compiler
)
2276 var mmethoddef
= self.mmethoddef
2278 var sig
= "{c_ret} {c_name}{c_sig}"
2279 compiler
.provide_declaration
(self.c_name
, "{sig};")
2281 var rta
= compiler
.as(SeparateCompiler).runtime_type_analysis
2283 var recv
= self.mmethoddef
.mclassdef
.bound_mtype
2284 var v
= compiler
.new_visitor
2285 var selfvar
= new RuntimeVariable("self", called_recv
, recv
)
2286 var arguments
= new Array[RuntimeVariable]
2287 var frame
= new StaticFrame(v
, mmethoddef
, recv
, arguments
)
2290 var msignature
= called_signature
2291 var ret
= called_signature
.return_mtype
2293 var comment
= new FlatBuffer
2294 comment
.append
("({selfvar}: {selfvar.mtype}")
2295 arguments
.add
(selfvar
)
2296 for i
in [0..msignature
.arity
[ do
2297 var mp
= msignature
.mparameters
[i
]
2298 var mtype
= mp
.mtype
2299 if mp
.is_vararg
then
2300 mtype
= v
.mmodule
.array_type
(mtype
)
2302 comment
.append
(", {mtype}")
2303 var argvar
= new RuntimeVariable("p{i}", mtype
, mtype
)
2304 arguments
.add
(argvar
)
2308 comment
.append
(": {ret}")
2311 v
.add_decl
("/* method {self} for {comment} */")
2312 v
.add_decl
("{sig} \{")
2314 frame
.returnvar
= v
.new_var
(ret
)
2316 frame
.returnlabel
= v
.get_name
("RET_LABEL")
2319 var subret
= v
.call
(mmethoddef
, recv
, arguments
)
2321 assert subret
!= null
2322 v
.assign
(frame
.returnvar
.as(not null), subret
)
2324 else if rta
!= null and not rta
.live_mmodules
.has
(mmethoddef
.mclassdef
.mmodule
) then
2325 v
.add_abort
("FATAL: Dead method executed.")
2327 mmethoddef
.compile_inside_to_c
(v
, arguments
)
2330 v
.add
("{frame.returnlabel.as(not null)}:;")
2332 v
.add
("return {frame.returnvar.as(not null)};")
2335 compiler
.names
[self.c_name
] = "{mmethoddef.full_name} ({mmethoddef.location.file.filename}:{mmethoddef.location.line_start})"
2338 # Compile the trampolines used to implement late-binding.
2340 # See `opt_trampoline_call`.
2341 fun compile_trampolines
(compiler
: SeparateCompiler)
2343 var recv
= self.mmethoddef
.mclassdef
.bound_mtype
2344 var selfvar
= new RuntimeVariable("self", called_recv
, recv
)
2345 var ret
= called_signature
.return_mtype
2346 var arguments
= ["self"]
2347 for i
in [0..called_signature
.arity
[ do arguments
.add
"p{i}"
2349 if mmethoddef
.is_intro
and not recv
.is_c_primitive
then
2350 var m
= mmethoddef
.mproperty
2351 var n2
= "CALL_" + m
.const_color
2352 compiler
.provide_declaration
(n2
, "{c_ret} {n2}{c_sig};")
2353 var v2
= compiler
.new_visitor
2354 v2
.add
"{c_ret} {n2}{c_sig} \{"
2355 v2
.require_declaration
(m
.const_color
)
2356 var call
= "(({c_funptrtype})({v2.class_info(selfvar)}->vft[{m.const_color}]))({arguments.join(", ")});"
2358 v2
.add
"return {call}"
2366 if mmethoddef
.has_supercall
and not recv
.is_c_primitive
then
2368 var n2
= "CALL_" + m
.const_color
2369 compiler
.provide_declaration
(n2
, "{c_ret} {n2}{c_sig};")
2370 var v2
= compiler
.new_visitor
2371 v2
.add
"{c_ret} {n2}{c_sig} \{"
2372 v2
.require_declaration
(m
.const_color
)
2373 var call
= "(({c_funptrtype})({v2.class_info(selfvar)}->vft[{m.const_color}]))({arguments.join(", ")});"
2375 v2
.add
"return {call}"
2386 # Are values of `self` tagged?
2387 # If false, it means that the type is not primitive, or is boxed.
2388 var is_tagged
= false
2390 # The tag value of the type
2392 # ENSURE `is_tagged == (tag_value > 0)`
2393 # ENSURE `not is_tagged == (tag_value == 0)`
2398 var const_color
: String is lazy
do return "COLOR_{c_name}"
2401 interface PropertyLayoutElement end
2403 redef class MProperty
2404 super PropertyLayoutElement
2407 redef class MPropDef
2408 super PropertyLayoutElement
2411 redef class AMethPropdef
2412 # The semi-global compilation does not support inlining calls to extern news
2413 redef fun can_inline
2416 if m
!= null and m
.mproperty
.is_init
and m
.is_extern
then return false
2421 redef class AAttrPropdef
2422 redef fun init_expr
(v
, recv
)
2425 if is_lazy
and v
.compiler
.modelbuilder
.toolcontext
.opt_no_union_attribute
.value
then
2426 var guard
= self.mlazypropdef
.mproperty
2427 v
.write_attribute
(guard
, recv
, v
.bool_instance
(false))