# A single C file regroups many compiled rumtime functions
# Note that we do not try to be clever an a small change in a Nit source file may change the content of all the generated .c files
var time0 = get_time
+ self.toolcontext.info("*** WRITING C ***", 1)
".nit_compile".mkdir
var outname = self.toolcontext.opt_output.value
if outname == null then
- outname = "{mainmodule.name}.bin"
+ outname = "{mainmodule.name}"
end
var hfilename = compiler.header.file.name + ".h"
#p = "..".join_path(p)
cc_includes += " -I \"" + p + "\""
end
- makefile.write("CC = ccache cc\nCFLAGS = -g -O2{cc_includes}\nLDFLAGS ?= \nLDLIBS ?= -lm -lgc\n\n")
+ makefile.write("CC = ccache cc\nCFLAGS = -g -O2\nCINCL = {cc_includes}\nLDFLAGS ?= \nLDLIBS ?= -lm -lgc\n\n")
makefile.write("all: {outname}\n\n")
var ofiles = new Array[String]
# Compile each generated file
for f in cfiles do
var o = f.strip_extension(".c") + ".o"
- makefile.write("{o}: {f}\n\t$(CC) $(CFLAGS) -D NONITCNI -c -o {o} {f}\n\n")
+ makefile.write("{o}: {f}\n\t$(CC) $(CFLAGS) $(CINCL) -D NONITCNI -c -o {o} {f}\n\n")
ofiles.add(o)
end
+
+ # Add gc_choser.h to aditionnal bodies
+ var gc_chooser = new ExternCFile("{cc_paths.first}/gc_chooser.c", "-DWITH_LIBGC")
+ compiler.extern_bodies.add(gc_chooser)
+
# Compile each required extern body into a specific .o
for f in compiler.extern_bodies do
var basename = f.filename.basename(".c")
self.toolcontext.info("Generated makefile: {makename}", 2)
var time1 = get_time
- self.toolcontext.info("*** END COMPILING TO C: {time1-time0} ***", 2)
+ self.toolcontext.info("*** END WRITING C: {time1-time0} ***", 2)
# Execute the Makefile
abstract class AbstractCompiler
type VISITOR: AbstractCompilerVisitor
- # The main module of the program
- var mainmodule: MModule protected writable
+ # The main module of the program currently compiled
+ # Is assigned during the separate compilation
+ var mainmodule: MModule writable
+
+ # The real main module of the program
+ var realmainmodule: MModule
# The modeulbuilder used to know the model and the AST
var modelbuilder: ModelBuilder protected writable
init(mainmodule: MModule, modelbuilder: ModelBuilder)
do
self.mainmodule = mainmodule
+ self.realmainmodule = mainmodule
self.modelbuilder = modelbuilder
end
self.header.add_decl("#include <stdlib.h>")
self.header.add_decl("#include <stdio.h>")
self.header.add_decl("#include <string.h>")
- self.header.add_decl("#ifndef NOBOEHM")
- self.header.add_decl("#include <gc/gc.h>")
- self.header.add_decl("#ifdef NOBOEHM_ATOMIC")
- self.header.add_decl("#undef GC_MALLOC_ATOMIC")
- self.header.add_decl("#define GC_MALLOC_ATOMIC(x) GC_MALLOC(x)")
- self.header.add_decl("#endif /*NOBOEHM_ATOMIC*/")
- self.header.add_decl("#else /*NOBOEHM*/")
- self.header.add_decl("#define GC_MALLOC(x) calloc(1, (x))")
- self.header.add_decl("#define GC_MALLOC_ATOMIC(x) calloc(1, (x))")
- self.header.add_decl("#endif /*NOBOEHM*/")
+ self.header.add_decl("#include <gc_chooser.h>")
compile_header_structs
end
v.add_decl("int main(int argc, char** argv) \{")
v.add("glob_argc = argc; glob_argv = argv;")
+ v.add("initialize_gc_option();")
var main_type = mainmodule.sys_type
if main_type != null then
var mainmodule = v.compiler.mainmodule
var glob_sys = v.init_instance(main_type)
v.add("glob_sys = {glob_sys};")
- var main_init = mainmodule.try_get_primitive_method("init", main_type)
+ var main_init = mainmodule.try_get_primitive_method("init", main_type.mclass)
if main_init != null then
v.send(main_init, [glob_sys])
end
- var main_method = mainmodule.try_get_primitive_method("main", main_type)
+ var main_method = mainmodule.try_get_primitive_method("main", main_type.mclass)
if main_method != null then
v.send(main_method, [glob_sys])
end
# Force to get the primitive property named `name' in the instance `recv' or abort
fun get_property(name: String, recv: MType): MMethod
do
- return self.compiler.modelbuilder.force_get_primitive_method(self.current_node.as(not null), name, recv, self.compiler.mainmodule)
+ assert recv isa MClassType
+ return self.compiler.modelbuilder.force_get_primitive_method(self.current_node.as(not null), name, recv.mclass, self.compiler.mainmodule)
end
fun compile_callsite(callsite: CallSite, args: Array[RuntimeVariable]): nullable RuntimeVariable
v.ret(v.new_expr("glob_sys", ret.as(not null)))
return
else if pname == "calloc_string" then
- v.ret(v.new_expr("(char*)GC_MALLOC_ATOMIC({arguments[1]})", ret.as(not null)))
+ v.ret(v.new_expr("(char*)nit_alloc({arguments[1]})", ret.as(not null)))
return
else if pname == "calloc_array" then
v.calloc_array(ret.as(not null), arguments)
v.ret(v.new_expr("(char*){nat}", ret.as(not null)))
return
else if pname == "force_garbage_collection" then
- v.add("GC_gcollect();")
+ v.add("nit_gcollect();")
+ return
+ else if pname == "native_argc" then
+ v.ret(v.new_expr("glob_argc", ret.as(not null)))
+ return
+ else if pname == "native_argv" then
+ v.ret(v.new_expr("glob_argv[{arguments[1]}]", ret.as(not null)))
return
end
v.add("printf(\"NOT YET IMPLEMENTED {class_name}:{mpropdef} at {location.to_s}\\n\");")
do
for e in self.n_expr do v.stmt(e)
end
+ redef fun expr(v)
+ do
+ var last = self.n_expr.last
+ for e in self.n_expr do
+ if e == last then break
+ v.stmt(e)
+ end
+ return v.expr(last, null)
+ end
end
redef class AVardeclExpr
# Utils
-redef class HashSet[E]
- init from(elements: Collection[E]) do
- init
- self.add_all(elements)
- end
-end
-
redef class Array[E]
- init from(elements: Collection[E]) do
- init
- self.add_all(elements)
- end
-
# Return a new Array with the elements only contened in 'self' and not in 'o'
fun -(o: Array[E]): Array[E] do
var res = new Array[E]
end
redef class MModule
-
- # Return a linearization of a set of mtypes
- fun linearize_mtypes(mtypes: Set[MType]): Array[MType] do
- var lin = new Array[MType].from(mtypes)
- var sorter = new TypeSorter(self)
- sorter.sort(lin)
- return lin
- end
-
- # Return a reverse linearization of a set of mtypes
- fun reverse_linearize_mtypes(mtypes: Set[MType]): Array[MType] do
- var lin = new Array[MType].from(mtypes)
- var sorter = new ReverseTypeSorter(self)
- sorter.sort(lin)
- return lin
- end
-
- # Return super types of a `mtype` in `self`
- fun super_mtypes(mtype: MType, mtypes: Set[MType]): Set[MType] do
- if not self.super_mtypes_cache.has_key(mtype) then
- var supers = new HashSet[MType]
- for otype in mtypes do
- if otype == mtype then continue
- if mtype.is_subtype(self, null, otype) then
- supers.add(otype)
- end
- end
- self.super_mtypes_cache[mtype] = supers
- end
- return self.super_mtypes_cache[mtype]
- end
-
- private var super_mtypes_cache: Map[MType, Set[MType]] = new HashMap[MType, Set[MType]]
-
- # Return all sub mtypes (directs and indirects) of a `mtype` in `self`
- fun sub_mtypes(mtype: MType, mtypes: Set[MType]): Set[MType] do
- if not self.sub_mtypes_cache.has_key(mtype) then
- var subs = new HashSet[MType]
- for otype in mtypes do
- if otype == mtype then continue
- if otype.is_subtype(self, null, mtype) then
- subs.add(otype)
- end
- end
- self.sub_mtypes_cache[mtype] = subs
- end
- return self.sub_mtypes_cache[mtype]
- end
-
- private var sub_mtypes_cache: Map[MType, Set[MType]] = new HashMap[MType, Set[MType]]
-
- # Return a linearization of a set of mclasses
- fun linearize_mclasses_2(mclasses: Set[MClass]): Array[MClass] do
- var lin = new Array[MClass].from(mclasses)
- var sorter = new ClassSorter(self)
- sorter.sort(lin)
- return lin
- end
-
- # Return a reverse linearization of a set of mtypes
- fun reverse_linearize_mclasses(mclasses: Set[MClass]): Array[MClass] do
- var lin = new Array[MClass].from(mclasses)
- var sorter = new ReverseClassSorter(self)
- sorter.sort(lin)
- return lin
- end
-
- # Return all super mclasses (directs and indirects) of a `mclass` in `self`
- fun super_mclasses(mclass: MClass): Set[MClass] do
- if not self.super_mclasses_cache.has_key(mclass) then
- var supers = new HashSet[MClass]
- if self.flatten_mclass_hierarchy.has(mclass) then
- for sup in self.flatten_mclass_hierarchy[mclass].greaters do
- if sup == mclass then continue
- supers.add(sup)
- end
- end
- self.super_mclasses_cache[mclass] = supers
- end
- return self.super_mclasses_cache[mclass]
- end
-
- private var super_mclasses_cache: Map[MClass, Set[MClass]] = new HashMap[MClass, Set[MClass]]
-
- # Return all parents of a `mclass` in `self`
- fun parent_mclasses(mclass: MClass): Set[MClass] do
- if not self.parent_mclasses_cache.has_key(mclass) then
- var parents = new HashSet[MClass]
- if self.flatten_mclass_hierarchy.has(mclass) then
- for sup in self.flatten_mclass_hierarchy[mclass].direct_greaters do
- if sup == mclass then continue
- parents.add(sup)
- end
- end
- self.parent_mclasses_cache[mclass] = parents
- end
- return self.parent_mclasses_cache[mclass]
- end
-
- private var parent_mclasses_cache: Map[MClass, Set[MClass]] = new HashMap[MClass, Set[MClass]]
-
- # Return all sub mclasses (directs and indirects) of a `mclass` in `self`
- fun sub_mclasses(mclass: MClass): Set[MClass] do
- if not self.sub_mclasses_cache.has_key(mclass) then
- var subs = new HashSet[MClass]
- if self.flatten_mclass_hierarchy.has(mclass) then
- for sub in self.flatten_mclass_hierarchy[mclass].smallers do
- if sub == mclass then continue
- subs.add(sub)
- end
- end
- self.sub_mclasses_cache[mclass] = subs
- end
- return self.sub_mclasses_cache[mclass]
- end
-
- private var sub_mclasses_cache: Map[MClass, Set[MClass]] = new HashMap[MClass, Set[MClass]]
-
# All 'mproperties' associated to all 'mclassdefs' of `mclass`
fun properties(mclass: MClass): Set[MProperty] do
if not self.properties_cache.has_key(mclass) then
var properties = new HashSet[MProperty]
- var parents = self.super_mclasses(mclass)
+ var parents = new Array[MClass]
+ if self.flatten_mclass_hierarchy.has(mclass) then
+ parents.add_all(mclass.in_hierarchy(self).direct_greaters)
+ end
for parent in parents do
properties.add_all(self.properties(parent))
end
-
for mclassdef in mclass.mclassdefs do
- for mpropdef in mclassdef.mpropdefs do
- properties.add(mpropdef.mproperty)
+ for mprop in mclassdef.intro_mproperties do
+ properties.add(mprop)
end
end
self.properties_cache[mclass] = properties
end
return properties_cache[mclass]
end
-
private var properties_cache: Map[MClass, Set[MProperty]] = new HashMap[MClass, Set[MProperty]]
end
-
-# A sorter for linearize list of types
-private class TypeSorter
- super AbstractSorter[MType]
-
- private var mmodule: MModule
-
- init(mmodule: MModule) do self.mmodule = mmodule
-
- redef fun compare(a, b) do
- if a == b then
- return 0
- else if a.is_subtype(self.mmodule, null, b) then
- return -1
- end
- return 1
- end
-end
-
-# A sorter for reverse linearization
-private class ReverseTypeSorter
- super TypeSorter
-
- init(mmodule: MModule) do end
-
- redef fun compare(a, b) do
- if a == b then
- return 0
- else if a.is_subtype(self.mmodule, null, b) then
- return 1
- end
- return -1
- end
-end
-
-# A sorter for linearize list of classes
-private class ClassSorter
- super AbstractSorter[MClass]
-
- var mmodule: MModule
-
- redef fun compare(a, b) do
- if a == b then
- return 0
- else if self.mmodule.flatten_mclass_hierarchy.has(a) and self.mmodule.flatten_mclass_hierarchy[a].greaters.has(b) then
- return -1
- end
- return 1
- end
-end
-
-# A sorter for reverse linearization
-private class ReverseClassSorter
- super AbstractSorter[MClass]
-
- var mmodule: MModule
-
- redef fun compare(a, b) do
- if a == b then
- return 0
- else if self.mmodule.flatten_mclass_hierarchy.has(a) and self.mmodule.flatten_mclass_hierarchy[a].greaters.has(b) then
- return 1
- end
- return -1
- end
-end