public override void EmitStatement(EmitContext ec)
{
var stmt = new If(condition, new StatementExpression(invoke), new StatementExpression(assign), loc);
using (ec.With(BuilderContext.Options.OmitDebugInfo, true)) {
stmt.Emit(ec);
}
}
public override void Emit(EmitContext ec)
{
stmt.EmitPrologue(ec);
using (ec.With(BuilderContext.Options.OmitDebugInfo, true)) {
stmt.Emit(ec);
}
}
protected override void DoEmit(EmitContext ec)
{
//
// Restore redirection for any captured variables
//
ec.CurrentAnonymousMethod = iterator;
using (ec.With(BuilderContext.Options.OmitDebugInfo, !ec.HasMethodSymbolBuilder)) {
block.EmitFinallyBody(ec);
}
}
public override EmitContext CreateEmitContext(ILGenerator ig, SourceMethodBuilder sourceMethod)
{
EmitContext ec = new EmitContext(this, ig, MemberType, sourceMethod);
ec.CurrentAnonymousMethod = expr;
if (expr is AsyncInitializer)
{
ec.With(BuilderContext.Options.AsyncBody, true);
}
return(ec);
}
public override void EmitStatement (EmitContext ec)
{
var stmt = new If (condition, new StatementExpression (invoke), new StatementExpression (assign), loc);
using (ec.With (BuilderContext.Options.OmitDebugInfo, true)) {
stmt.Emit (ec);
}
}
protected void EmitCall (EmitContext ec, Expression binder, Arguments arguments, bool isStatement)
{
//
// This method generates all internal infrastructure for a dynamic call. The
// reason why it's quite complicated is the mixture of dynamic and anonymous
// methods. Dynamic itself requires a temporary class (ContainerX) and anonymous
// methods can generate temporary storey as well (AnonStorey). Handling MVAR
// type parameters rewrite is non-trivial in such case as there are various
// combinations possible therefore the mutator is not straightforward. Secondly
// we need to keep both MVAR(possibly VAR for anon storey) and type VAR to emit
// correct Site field type and its access from EmitContext.
//
int dyn_args_count = arguments == null ? 0 : arguments.Count;
int default_args = isStatement ? 1 : 2;
var module = ec.Module;
bool has_ref_out_argument = false;
var targs = new TypeExpression[dyn_args_count + default_args];
targs[0] = new TypeExpression (module.PredefinedTypes.CallSite.TypeSpec, loc);
TypeExpression[] targs_for_instance = null;
TypeParameterMutator mutator;
var site_container = ec.CreateDynamicSite ();
if (context_mvars != null) {
TypeParameters tparam;
TypeContainer sc = site_container;
do {
tparam = sc.CurrentTypeParameters;
sc = sc.Parent;
} while (tparam == null);
mutator = new TypeParameterMutator (context_mvars, tparam);
if (!ec.IsAnonymousStoreyMutateRequired) {
targs_for_instance = new TypeExpression[targs.Length];
targs_for_instance[0] = targs[0];
}
} else {
mutator = null;
}
for (int i = 0; i < dyn_args_count; ++i) {
Argument a = arguments[i];
if (a.ArgType == Argument.AType.Out || a.ArgType == Argument.AType.Ref)
has_ref_out_argument = true;
var t = a.Type;
// Convert any internal type like dynamic or null to object
if (t.Kind == MemberKind.InternalCompilerType)
t = ec.BuiltinTypes.Object;
if (targs_for_instance != null)
targs_for_instance[i + 1] = new TypeExpression (t, loc);
if (mutator != null)
t = t.Mutate (mutator);
targs[i + 1] = new TypeExpression (t, loc);
}
TypeExpr del_type = null;
TypeExpr del_type_instance_access = null;
if (!has_ref_out_argument) {
string d_name = isStatement ? "Action" : "Func";
TypeExpr te = null;
Namespace type_ns = module.GlobalRootNamespace.GetNamespace ("System", true);
if (type_ns != null) {
te = type_ns.LookupType (module, d_name, dyn_args_count + default_args, LookupMode.Normal, loc);
}
if (te != null) {
if (!isStatement) {
var t = type;
if (t.Kind == MemberKind.InternalCompilerType)
t = ec.BuiltinTypes.Object;
if (targs_for_instance != null)
targs_for_instance[targs_for_instance.Length - 1] = new TypeExpression (t, loc);
if (mutator != null)
t = t.Mutate (mutator);
targs[targs.Length - 1] = new TypeExpression (t, loc);
}
del_type = new GenericTypeExpr (te.Type, new TypeArguments (targs), loc);
if (targs_for_instance != null)
del_type_instance_access = new GenericTypeExpr (te.Type, new TypeArguments (targs_for_instance), loc);
else
del_type_instance_access = del_type;
}
}
//
// Create custom delegate when no appropriate predefined delegate has been found
//
Delegate d;
if (del_type == null) {
TypeSpec rt = isStatement ? ec.BuiltinTypes.Void : type;
Parameter[] p = new Parameter[dyn_args_count + 1];
p[0] = new Parameter (targs[0], "p0", Parameter.Modifier.NONE, null, loc);
var site = ec.CreateDynamicSite ();
int index = site.Containers == null ? 0 : site.Containers.Count;
if (mutator != null)
rt = mutator.Mutate (rt);
for (int i = 1; i < dyn_args_count + 1; ++i) {
p[i] = new Parameter (targs[i], "p" + i.ToString ("X"), arguments[i - 1].Modifier, null, loc);
}
d = new Delegate (site, new TypeExpression (rt, loc),
Modifiers.INTERNAL | Modifiers.COMPILER_GENERATED,
new MemberName ("Container" + index.ToString ("X")),
new ParametersCompiled (p), null);
d.CreateContainer ();
d.DefineContainer ();
d.Define ();
site.AddTypeContainer (d);
del_type = new TypeExpression (d.CurrentType, loc);
if (targs_for_instance != null) {
del_type_instance_access = null;
} else {
del_type_instance_access = del_type;
}
} else {
d = null;
}
var site_type_decl = new GenericTypeExpr (module.PredefinedTypes.CallSiteGeneric.TypeSpec, new TypeArguments (del_type), loc);
var field = site_container.CreateCallSiteField (site_type_decl, loc);
if (field == null)
return;
if (del_type_instance_access == null) {
var dt = d.CurrentType.DeclaringType.MakeGenericType (module, context_mvars.Types);
del_type_instance_access = new TypeExpression (MemberCache.GetMember (dt, d.CurrentType), loc);
}
var instanceAccessExprType = new GenericTypeExpr (module.PredefinedTypes.CallSiteGeneric.TypeSpec,
new TypeArguments (del_type_instance_access), loc);
if (instanceAccessExprType.ResolveAsType (ec.MemberContext) == null)
return;
bool inflate_using_mvar = context_mvars != null && ec.IsAnonymousStoreyMutateRequired;
TypeSpec gt;
if (inflate_using_mvar || context_mvars == null) {
gt = site_container.CurrentType;
} else {
gt = site_container.CurrentType.MakeGenericType (module, context_mvars.Types);
}
// When site container already exists the inflated version has to be
// updated manually to contain newly created field
if (gt is InflatedTypeSpec && site_container.AnonymousMethodsCounter > 1) {
var tparams = gt.MemberDefinition.TypeParametersCount > 0 ? gt.MemberDefinition.TypeParameters : TypeParameterSpec.EmptyTypes;
var inflator = new TypeParameterInflator (module, gt, tparams, gt.TypeArguments);
gt.MemberCache.AddMember (field.InflateMember (inflator));
}
FieldExpr site_field_expr = new FieldExpr (MemberCache.GetMember (gt, field), loc);
BlockContext bc = new BlockContext (ec.MemberContext, null, ec.BuiltinTypes.Void);
Arguments args = new Arguments (1);
args.Add (new Argument (binder));
StatementExpression s = new StatementExpression (new SimpleAssign (site_field_expr, new Invocation (new MemberAccess (instanceAccessExprType, "Create"), args)));
using (ec.With (BuilderContext.Options.OmitDebugInfo, true)) {
if (s.Resolve (bc)) {
Statement init = new If (new Binary (Binary.Operator.Equality, site_field_expr, new NullLiteral (loc)), s, loc);
init.Emit (ec);
}
args = new Arguments (1 + dyn_args_count);
args.Add (new Argument (site_field_expr));
if (arguments != null) {
int arg_pos = 1;
foreach (Argument a in arguments) {
if (a is NamedArgument) {
// Name is not valid in this context
args.Add (new Argument (a.Expr, a.ArgType));
} else {
args.Add (a);
}
if (inflate_using_mvar && a.Type != targs[arg_pos].Type)
a.Expr.Type = targs[arg_pos].Type;
++arg_pos;
}
}
Expression target = new DelegateInvocation (new MemberAccess (site_field_expr, "Target", loc).Resolve (bc), args, loc).Resolve (bc);
if (target != null)
target.Emit (ec);
}
}
protected void EmitCall(EmitContext ec, Expression binder, Arguments arguments, bool isStatement)
{
//
// This method generates all internal infrastructure for a dynamic call. The
// reason why it's quite complicated is the mixture of dynamic and anonymous
// methods. Dynamic itself requires a temporary class (ContainerX) and anonymous
// methods can generate temporary storey as well (AnonStorey). Handling MVAR
// type parameters rewrite is non-trivial in such case as there are various
// combinations possible therefore the mutator is not straightforward. Secondly
// we need to keep both MVAR(possibly VAR for anon storey) and type VAR to emit
// correct Site field type and its access from EmitContext.
//
int dyn_args_count = arguments == null ? 0 : arguments.Count;
int default_args = isStatement ? 1 : 2;
var module = ec.Module;
bool has_ref_out_argument = false;
var targs = new TypeExpression[dyn_args_count + default_args];
targs[0] = new TypeExpression(module.PredefinedTypes.CallSite.TypeSpec, loc);
TypeExpression[] targs_for_instance = null;
TypeParameterMutator mutator;
var site_container = ec.CreateDynamicSite();
if (context_mvars != null)
{
TypeParameters tparam;
TypeContainer sc = site_container;
do
{
tparam = sc.CurrentTypeParameters;
sc = sc.Parent;
} while (tparam == null);
mutator = new TypeParameterMutator(context_mvars, tparam);
if (!ec.IsAnonymousStoreyMutateRequired)
{
targs_for_instance = new TypeExpression[targs.Length];
targs_for_instance[0] = targs[0];
}
}
else
{
mutator = null;
}
for (int i = 0; i < dyn_args_count; ++i)
{
Argument a = arguments[i];
if (a.ArgType == Argument.AType.Out || a.ArgType == Argument.AType.Ref)
{
has_ref_out_argument = true;
}
var t = a.Type;
// Convert any internal type like dynamic or null to object
if (t.Kind == MemberKind.InternalCompilerType)
{
t = ec.BuiltinTypes.Object;
}
if (targs_for_instance != null)
{
targs_for_instance[i + 1] = new TypeExpression(t, loc);
}
if (mutator != null)
{
t = t.Mutate(mutator);
}
targs[i + 1] = new TypeExpression(t, loc);
}
TypeExpr del_type = null;
TypeExpr del_type_instance_access = null;
if (!has_ref_out_argument)
{
string d_name = isStatement ? "Action" : "Func";
TypeExpr te = null;
Namespace type_ns = module.GlobalRootNamespace.GetNamespace("System", true);
if (type_ns != null)
{
te = type_ns.LookupType(module, d_name, dyn_args_count + default_args, LookupMode.Normal, loc);
}
if (te != null)
{
if (!isStatement)
{
var t = type;
if (t.Kind == MemberKind.InternalCompilerType)
{
t = ec.BuiltinTypes.Object;
}
if (targs_for_instance != null)
{
targs_for_instance[targs_for_instance.Length - 1] = new TypeExpression(t, loc);
}
if (mutator != null)
{
t = t.Mutate(mutator);
}
targs[targs.Length - 1] = new TypeExpression(t, loc);
}
del_type = new GenericTypeExpr(te.Type, new TypeArguments(targs), loc);
if (targs_for_instance != null)
{
del_type_instance_access = new GenericTypeExpr(te.Type, new TypeArguments(targs_for_instance), loc);
}
else
{
del_type_instance_access = del_type;
}
}
}
//
// Create custom delegate when no appropriate predefined delegate has been found
//
Delegate d;
if (del_type == null)
{
TypeSpec rt = isStatement ? ec.BuiltinTypes.Void : type;
Parameter[] p = new Parameter[dyn_args_count + 1];
p[0] = new Parameter(targs[0], "p0", Parameter.Modifier.NONE, null, loc);
var site = ec.CreateDynamicSite();
int index = site.Containers == null ? 0 : site.Containers.Count;
if (mutator != null)
{
rt = mutator.Mutate(rt);
}
for (int i = 1; i < dyn_args_count + 1; ++i)
{
p[i] = new Parameter(targs[i], "p" + i.ToString("X"), arguments[i - 1].Modifier, null, loc);
}
d = new Delegate(site, new TypeExpression(rt, loc),
Modifiers.INTERNAL | Modifiers.COMPILER_GENERATED,
new MemberName("Container" + index.ToString("X")),
new ParametersCompiled(p), null);
d.CreateContainer();
d.DefineContainer();
d.Define();
site.AddTypeContainer(d);
del_type = new TypeExpression(d.CurrentType, loc);
if (targs_for_instance != null)
{
del_type_instance_access = null;
}
else
{
del_type_instance_access = del_type;
}
}
else
{
d = null;
}
var site_type_decl = new GenericTypeExpr(module.PredefinedTypes.CallSiteGeneric.TypeSpec, new TypeArguments(del_type), loc);
var field = site_container.CreateCallSiteField(site_type_decl, loc);
if (field == null)
{
return;
}
if (del_type_instance_access == null)
{
var dt = d.CurrentType.DeclaringType.MakeGenericType(module, context_mvars.Types);
del_type_instance_access = new TypeExpression(MemberCache.GetMember(dt, d.CurrentType), loc);
}
var instanceAccessExprType = new GenericTypeExpr(module.PredefinedTypes.CallSiteGeneric.TypeSpec,
new TypeArguments(del_type_instance_access), loc);
if (instanceAccessExprType.ResolveAsType(ec.MemberContext) == null)
{
return;
}
bool inflate_using_mvar = context_mvars != null && ec.IsAnonymousStoreyMutateRequired;
TypeSpec gt;
if (inflate_using_mvar || context_mvars == null)
{
gt = site_container.CurrentType;
}
else
{
gt = site_container.CurrentType.MakeGenericType(module, context_mvars.Types);
}
// When site container already exists the inflated version has to be
// updated manually to contain newly created field
if (gt is InflatedTypeSpec && site_container.AnonymousMethodsCounter > 1)
{
var tparams = gt.MemberDefinition.TypeParametersCount > 0 ? gt.MemberDefinition.TypeParameters : TypeParameterSpec.EmptyTypes;
var inflator = new TypeParameterInflator(module, gt, tparams, gt.TypeArguments);
gt.MemberCache.AddMember(field.InflateMember(inflator));
}
FieldExpr site_field_expr = new FieldExpr(MemberCache.GetMember(gt, field), loc);
BlockContext bc = new BlockContext(ec.MemberContext, null, ec.BuiltinTypes.Void);
Arguments args = new Arguments(1);
args.Add(new Argument(binder));
StatementExpression s = new StatementExpression(new SimpleAssign(site_field_expr, new Invocation(new MemberAccess(instanceAccessExprType, "Create"), args)));
using (ec.With(BuilderContext.Options.OmitDebugInfo, true)) {
if (s.Resolve(bc))
{
Statement init = new If(new Binary(Binary.Operator.Equality, site_field_expr, new NullLiteral(loc)), s, loc);
init.Emit(ec);
}
args = new Arguments(1 + dyn_args_count);
args.Add(new Argument(site_field_expr));
if (arguments != null)
{
int arg_pos = 1;
foreach (Argument a in arguments)
{
if (a is NamedArgument)
{
// Name is not valid in this context
args.Add(new Argument(a.Expr, a.ArgType));
}
else
{
args.Add(a);
}
if (inflate_using_mvar && a.Type != targs[arg_pos].Type)
{
a.Expr.Type = targs[arg_pos].Type;
}
++arg_pos;
}
}
Expression target = new DelegateInvocation(new MemberAccess(site_field_expr, "Target", loc).Resolve(bc), args, loc).Resolve(bc);
if (target != null)
{
target.Emit(ec);
}
}
}
public override void EmitStatement (EmitContext ec)
{
if (resolved == null)
return;
//
// Emit sequence symbol info even if we are in compiler generated
// block to allow debugging field initializers when constructor is
// compiler generated
//
if (ec.HasSet (BuilderContext.Options.OmitDebugInfo) && ec.HasMethodSymbolBuilder) {
using (ec.With (BuilderContext.Options.OmitDebugInfo, false)) {
ec.Mark (loc);
}
}
if (resolved != this)
resolved.EmitStatement (ec);
else
base.EmitStatement (ec);
}
//
// Emits the code
//
public override void Emit ()
{
if (Parent.PartialContainer.IsComImport) {
if (!IsDefault ()) {
Report.Error (669, Location, "`{0}': A class with the ComImport attribute cannot have a user-defined constructor",
Parent.GetSignatureForError ());
}
// Set as internal implementation and reset block data
// to ensure no IL is generated
ConstructorBuilder.SetImplementationFlags (MethodImplAttributes.InternalCall);
block = null;
}
if ((ModFlags & Modifiers.DEBUGGER_HIDDEN) != 0)
Module.PredefinedAttributes.DebuggerHidden.EmitAttribute (ConstructorBuilder);
if (OptAttributes != null)
OptAttributes.Emit ();
base.Emit ();
parameters.ApplyAttributes (this, ConstructorBuilder);
BlockContext bc = new BlockContext (this, block, Compiler.BuiltinTypes.Void);
bc.Set (ResolveContext.Options.ConstructorScope);
if (block != null) {
//
// If we use a "this (...)" constructor initializer, then
// do not emit field initializers, they are initialized in the other constructor
//
if (!(Initializer is ConstructorThisInitializer))
Parent.PartialContainer.ResolveFieldInitializers (bc);
if (!IsStatic) {
if (Initializer == null) {
if (Parent.PartialContainer.Kind == MemberKind.Struct) {
//
// If this is a non-static `struct' constructor and doesn't have any
// initializer, it must initialize all of the struct's fields.
//
block.AddThisVariable (bc);
} else if (Parent.PartialContainer.Kind == MemberKind.Class) {
Initializer = new GeneratedBaseInitializer (Location);
}
}
if (Initializer != null) {
//
// mdb format does not support reqions. Try to workaround this by emitting the
// sequence point at initializer. Any breakpoint at constructor header should
// be adjusted to this sequence point as it's the next one which follows.
//
block.AddScopeStatement (new StatementExpression (Initializer));
}
}
if (block.Resolve (null, bc, this)) {
debug_builder = Parent.CreateMethodSymbolEntry ();
EmitContext ec = new EmitContext (this, ConstructorBuilder.GetILGenerator (), bc.ReturnType, debug_builder);
ec.With (EmitContext.Options.ConstructorScope, true);
block.Emit (ec);
}
}
if (declarative_security != null) {
foreach (var de in declarative_security) {
#if STATIC
ConstructorBuilder.__AddDeclarativeSecurity (de);
#else
ConstructorBuilder.AddDeclarativeSecurity (de.Key, de.Value);
#endif
}
}
block = null;
}
public void EmitPrologue(EmitContext ec)
{
awaiter = ((AsyncTaskStorey)machine_initializer.Storey).AddAwaiter(expr.Type, loc);
var fe_awaiter = new FieldExpr(awaiter, loc);
fe_awaiter.InstanceExpression = new CompilerGeneratedThis(ec.CurrentType, loc);
//
// awaiter = expr.GetAwaiter ();
//
using (ec.With(BuilderContext.Options.OmitDebugInfo, true)) {
fe_awaiter.EmitAssign(ec, expr, false, false);
}
Label skip_continuation = ec.DefineLabel();
Expression completed_expr;
if (IsDynamic)
{
var rc = new ResolveContext(ec.MemberContext);
Arguments dargs = new Arguments(1);
dargs.Add(new Argument(fe_awaiter));
completed_expr = new DynamicMemberBinder("IsCompleted", dargs, loc).Resolve(rc);
dargs = new Arguments(1);
dargs.Add(new Argument(completed_expr));
completed_expr = new DynamicConversion(ec.Module.Compiler.BuiltinTypes.Bool, 0, dargs, loc).Resolve(rc);
}
else
{
var pe = PropertyExpr.CreatePredefined(awaiter_definition.IsCompleted, loc);
pe.InstanceExpression = fe_awaiter;
completed_expr = pe;
}
completed_expr.EmitBranchable(ec, skip_continuation, true);
base.DoEmit(ec);
//
// The stack has to be empty before calling await continuation. We handle this
// by lifting values which would be left on stack into class fields. The process
// is quite complicated and quite hard to test because any expression can possibly
// leave a value on the stack.
//
// Following assert fails when some of expression called before is missing EmitToField
// or parent expression fails to find await in children expressions
//
ec.AssertEmptyStack();
var storey = (AsyncTaskStorey)machine_initializer.Storey;
if (IsDynamic)
{
storey.EmitAwaitOnCompletedDynamic(ec, fe_awaiter);
}
else
{
storey.EmitAwaitOnCompleted(ec, fe_awaiter);
}
// Return ok
machine_initializer.EmitLeave(ec, unwind_protect);
ec.MarkLabel(resume_point);
ec.MarkLabel(skip_continuation);
}
