class
super SeparateCompilerVisitor
redef fun compile_callsite(callsite, arguments)
do
var res = super
if callsite.erasure_cast and not self.compiler.as(SeparateErasureCompiler).modelbuilder.toolcontext.opt_no_check_erasure_cast.value then
assert res != null
var mtype = callsite.msignature.return_mtype
assert mtype != null
self.add("/* Erasure cast for return {res} isa {mtype} */")
var cond = self.type_test(res, mtype, "erasure")
self.add("if (!{cond}) \{")
#var x = self.class_name_string(res)
#var y = self.class_name_string(arguments.first)
#self.add("PRINT_ERROR(\"Erasure cast: expected {mtype} (self is %s), got %s for {res}\\n\", {y}, {x});")
self.add_abort("Cast failed")
self.add("\}")
end
return res
end
redef fun init_instance(mtype)
do
self.require_declaration("NEW_{mtype.mclass.c_name}")
return self.new_expr("NEW_{mtype.mclass.c_name}()", mtype)
end
redef fun type_test(value, mtype, tag)
do
self.add("/* type test for {value.inspect} isa {mtype} */")
var res = self.new_var(bool_type)
var cltype = self.get_name("cltype")
self.add_decl("int {cltype};")
var idtype = self.get_name("idtype")
self.add_decl("int {idtype};")
var maybe_null = self.maybe_null(value)
var accept_null = "0"
if mtype isa MNullableType then
mtype = mtype.mtype
accept_null = "1"
end
if mtype isa MParameterType then
# Here we get the bound of the the formal type (eh, erasure...)
mtype = mtype.resolve_for(self.frame..mclassdef.bound_mtype, self.frame..mclassdef.bound_mtype, self.frame..mclassdef.mmodule, false)
if mtype isa MNullableType then
mtype = mtype.mtype
accept_null = "1"
end
end
if value.mcasttype.is_subtype(self.frame..mclassdef.mmodule, self.frame..mclassdef.bound_mtype, mtype) then
self.add("{res} = 1; /* easy {value.inspect} isa {mtype}*/")
if compiler.modelbuilder.toolcontext.opt_typing_test_metrics.value then
self.compiler.count_type_test_skipped[tag] += 1
self.add("count_type_test_skipped_{tag}++;")
end
return res
end
var class_ptr
if not value.mtype.is_c_primitive then
class_ptr = "{value}->class->"
else
var mclass = value.mtype.as(MClassType).mclass
self.require_declaration("class_{mclass.c_name}")
class_ptr = "class_{mclass.c_name}."
end
if mtype isa MClassType then
self.require_declaration("class_{mtype.mclass.c_name}")
self.add("{cltype} = class_{mtype.mclass.c_name}.color;")
self.add("{idtype} = class_{mtype.mclass.c_name}.id;")
if compiler.modelbuilder.toolcontext.opt_typing_test_metrics.value then
self.compiler.count_type_test_resolved[tag] += 1
self.add("count_type_test_resolved_{tag}++;")
end
else if mtype isa MVirtualType then
var recv = self.frame..first
var recv_ptr
if not recv.mtype.is_c_primitive then
recv_ptr = "{recv}->class->"
else
var mclass = recv.mtype.as(MClassType).mclass
self.require_declaration("class_{mclass.c_name}")
recv_ptr = "class_{mclass.c_name}."
end
var entry = self.get_name("entry")
self.add("struct vts_entry {entry};")
self.require_declaration(mtype.mproperty.const_color)
self.add("{entry} = {recv_ptr}vts_table->vts[{mtype.mproperty.const_color}];")
self.add("{cltype} = {entry}.class->color;")
self.add("{idtype} = {entry}.class->id;")
if maybe_null and accept_null == "0" then
var is_nullable = self.get_name("is_nullable")
self.add_decl("short int {is_nullable};")
self.add("{is_nullable} = {entry}.is_nullable;")
accept_null = is_nullable.to_s
end
if compiler.modelbuilder.toolcontext.opt_typing_test_metrics.value then
self.compiler.count_type_test_unresolved[tag] += 1
self.add("count_type_test_unresolved_{tag}++;")
end
else
self.debug("type_test({value.inspect}, {mtype})")
abort
end
# check color is in table
if maybe_null then
self.add("if({value} == NULL) \{")
self.add("{res} = {accept_null};")
self.add("\} else \{")
end
self.add("if({cltype} >= {class_ptr}type_table->size) \{")
self.add("{res} = 0;")
self.add("\} else \{")
self.add("{res} = {class_ptr}type_table->table[{cltype}] == {idtype};")
self.add("\}")
if maybe_null then
self.add("\}")
end
return res
end
redef fun unbox_extern(value, mtype)
do
if mtype isa MClassType and mtype.mclass.kind == extern_kind and
mtype.mclass.name != "CString" then
var pointer_type = compiler.mainmodule.pointer_type
var res = self.new_var_extern(mtype)
self.add "{res} = ((struct instance_{pointer_type.c_name}*){value})->value; /* unboxing {value.mtype} */"
return res
else
return value
end
end
redef fun box_extern(value, mtype)
do
if mtype isa MClassType and mtype.mclass.kind == extern_kind and
mtype.mclass.name != "CString" then
var valtype = compiler.mainmodule.pointer_type
var res = self.new_var(mtype)
if compiler.runtime_type_analysis != null and not compiler.runtime_type_analysis..has(value.mtype.as(MClassType)) then
self.add("/*no boxing of {value.mtype}: {value.mtype} is not live! */")
self.add("PRINT_ERROR(\"Dead code executed!\\n\"); fatal_exit(1);")
return res
end
self.require_declaration("BOX_{valtype.c_name}")
self.add("{res} = BOX_{valtype.c_name}({value}); /* boxing {value.mtype} */")
self.require_declaration("class_{mtype.c_name}")
self.add("{res}->class = &class_{mtype.c_name};")
return res
else
return value
end
end
redef fun class_name_string(value)
do
var res = self.get_name("var_class_name")
self.add_decl("const char* {res};")
if not value.mtype.is_c_primitive then
self.add "{res} = {value} == NULL ? \"null\" : {value}->class->name;"
else
self.require_declaration("class_{value.mtype.c_name}")
self.add "{res} = class_{value.mtype.c_name}.name;"
end
return res
end
redef fun native_array_instance(elttype, length)
do
var nclass = mmodule.native_array_class
var mtype = nclass.get_mtype([elttype])
var res = self.new_var(mtype)
res.is_exact = true
self.require_declaration("NEW_{nclass.c_name}")
length = autobox(length, compiler.mainmodule.int_type)
self.add("{res} = NEW_{nclass.c_name}({length});")
return res
end
redef fun routine_ref_instance(routine_type, recv, callsite)
do
var mmethoddef = callsite.mpropdef
#debug "ENTER ref_instance"
var = mmethoddef.mproperty
# routine_mclass is the specialized one, e.g: FunRef1, ProcRef2, etc..
var routine_mclass = routine_type.mclass
var nclasses = mmodule.model.get_mclasses_by_name("RoutineRef").as(not null)
var base_routine_mclass = nclasses.first
# All routine classes use the same `NEW` constructor.
# However, they have different declared `class` and `type` value.
self.require_declaration("NEW_{base_routine_mclass.c_name}")
var = recv.mcasttype.as(MClassType).mclass.c_name
var my_recv = recv
if recv.mtype.is_c_primitive then
my_recv = autobox(recv, mmodule.object_type)
end
var my_recv_mclass_type = my_recv.mtype.as(MClassType)
# The class of the concrete Routine must exist (e.g ProcRef0, FunRef0, etc.)
self.require_declaration("class_{routine_mclass.c_name}")
self.require_declaration(mmethoddef.c_name)
var thunk_function = mmethoddef.callref_thunk(my_recv_mclass_type)
var runtime_function = mmethoddef.virtual_runtime_function
var is_c_equiv = runtime_function.msignature.c_equiv(thunk_function.msignature)
var c_ref = thunk_function.c_ref
if is_c_equiv then
var const_color = mmethoddef.mproperty.const_color
c_ref = "{class_info(my_recv)}->vft[{const_color}]"
self.require_declaration(const_color)
else
self.require_declaration(thunk_function.c_name)
compiler.thunk_todo(thunk_function)
end
compiler.thunk_todo(thunk_function)
# Each RoutineRef points to a receiver AND a callref_thunk
var res = self.new_expr("NEW_{base_routine_mclass.c_name}({my_recv}, (nitmethod_t){c_ref}, &class_{routine_mclass.c_name})", routine_type)
#debug "LEAVING ref_instance"
return res
end
end
src/compiler/separate_erasure_compiler.nit:535,1--773,3