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// statements.cc -- Go frontend statements.
// Copyright 2009 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
#include "go-system.h"
#include "go-c.h"
#include "go-diagnostics.h"
#include "types.h"
#include "expressions.h"
#include "gogo.h"
#include "export.h"
#include "import.h"
#include "runtime.h"
#include "backend.h"
#include "statements.h"
#include "ast-dump.h"
// Class Statement.
Statement::Statement(Statement_classification classification,
Location location)
: classification_(classification), location_(location)
{
}
Statement::~Statement()
{
}
// Traverse the tree. The work of walking the components is handled
// by the subclasses.
int
Statement::traverse(Block* block, size_t* pindex, Traverse* traverse)
{
if (this->classification_ == STATEMENT_ERROR)
return TRAVERSE_CONTINUE;
unsigned int traverse_mask = traverse->traverse_mask();
if ((traverse_mask & Traverse::traverse_statements) != 0)
{
int t = traverse->statement(block, pindex, this);
if (t == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
else if (t == TRAVERSE_SKIP_COMPONENTS)
return TRAVERSE_CONTINUE;
}
// No point in checking traverse_mask here--a statement may contain
// other blocks or statements, and if we got here we always want to
// walk them.
return this->do_traverse(traverse);
}
// Traverse the contents of a statement.
int
Statement::traverse_contents(Traverse* traverse)
{
return this->do_traverse(traverse);
}
// Traverse assignments.
bool
Statement::traverse_assignments(Traverse_assignments* tassign)
{
if (this->classification_ == STATEMENT_ERROR)
return false;
return this->do_traverse_assignments(tassign);
}
// Traverse an expression in a statement. This is a helper function
// for child classes.
int
Statement::traverse_expression(Traverse* traverse, Expression** expr)
{
if ((traverse->traverse_mask()
& (Traverse::traverse_types | Traverse::traverse_expressions)) == 0)
return TRAVERSE_CONTINUE;
return Expression::traverse(expr, traverse);
}
// Traverse an expression list in a statement. This is a helper
// function for child classes.
int
Statement::traverse_expression_list(Traverse* traverse,
Expression_list* expr_list)
{
if (expr_list == NULL)
return TRAVERSE_CONTINUE;
if ((traverse->traverse_mask()
& (Traverse::traverse_types | Traverse::traverse_expressions)) == 0)
return TRAVERSE_CONTINUE;
return expr_list->traverse(traverse);
}
// Traverse a type in a statement. This is a helper function for
// child classes.
int
Statement::traverse_type(Traverse* traverse, Type* type)
{
if ((traverse->traverse_mask()
& (Traverse::traverse_types | Traverse::traverse_expressions)) == 0)
return TRAVERSE_CONTINUE;
return Type::traverse(type, traverse);
}
// Set type information for unnamed constants. This is really done by
// the child class.
void
Statement::determine_types()
{
this->do_determine_types();
}
// Read a statement from export data.
Statement*
Statement::import_statement(Import_function_body* ifb, Location loc)
{
if (ifb->match_c_string("{"))
{
bool is_lowered_for_statement;
Block* block = Block_statement::do_import(ifb, loc,
&is_lowered_for_statement);
if (block == NULL)
return Statement::make_error_statement(loc);
Block_statement* s = Statement::make_block_statement(block, loc);
if (is_lowered_for_statement)
s->set_is_lowered_for_statement();
return s;
}
else if (ifb->match_c_string("return"))
{
// After lowering return statements have no expressions. The
// return expressions are assigned to result parameters.
ifb->advance(6);
return Statement::make_return_statement(NULL, loc);
}
else if (ifb->match_c_string("var $t"))
return Temporary_statement::do_import(ifb, loc);
else if (ifb->match_c_string("var "))
return Variable_declaration_statement::do_import(ifb, loc);
else if (ifb->match_c_string("if "))
return If_statement::do_import(ifb, loc);
else if (ifb->match_c_string(":"))
return Label_statement::do_import(ifb, loc);
else if (ifb->match_c_string("goto "))
return Goto_statement::do_import(ifb, loc);
Expression* lhs = Expression::import_expression(ifb, loc);
if (ifb->match_c_string(" //"))
return Statement::make_statement(lhs, true);
ifb->require_c_string(" = ");
Expression* rhs = Expression::import_expression(ifb, loc);
return Statement::make_assignment(lhs, rhs, loc);
}
// If this is a thunk statement, return it.
Thunk_statement*
Statement::thunk_statement()
{
Thunk_statement* ret = this->convert<Thunk_statement, STATEMENT_GO>();
if (ret == NULL)
ret = this->convert<Thunk_statement, STATEMENT_DEFER>();
return ret;
}
// Convert a Statement to the backend representation. This is really
// done by the child class.
Bstatement*
Statement::get_backend(Translate_context* context)
{
if (this->classification_ == STATEMENT_ERROR)
return context->backend()->error_statement();
return this->do_get_backend(context);
}
// Dump AST representation for a statement to a dump context.
void
Statement::dump_statement(Ast_dump_context* ast_dump_context) const
{
this->do_dump_statement(ast_dump_context);
}
// Note that this statement is erroneous. This is called by children
// when they discover an error.
void
Statement::set_is_error()
{
this->classification_ = STATEMENT_ERROR;
}
// For children to call to report an error conveniently.
void
Statement::report_error(const char* msg)
{
go_error_at(this->location_, "%s", msg);
this->set_is_error();
}
// An error statement, used to avoid crashing after we report an
// error.
class Error_statement : public Statement
{
public:
Error_statement(Location location)
: Statement(STATEMENT_ERROR, location)
{ }
protected:
int
do_traverse(Traverse*)
{ return TRAVERSE_CONTINUE; }
Bstatement*
do_get_backend(Translate_context*)
{ go_unreachable(); }
void
do_dump_statement(Ast_dump_context*) const;
};
//
// Helper to tack on available source position information
// at the end of a statement.
//
static std::string
dsuffix(Location location)
{
std::string lstr = Linemap::location_to_string(location);
if (lstr == "")
return lstr;
std::string rval(" // ");
rval += lstr;
return rval;
}
// Dump the AST representation for an error statement.
void
Error_statement::do_dump_statement(Ast_dump_context* ast_dump_context) const
{
ast_dump_context->print_indent();
ast_dump_context->ostream() << "Error statement" << std::endl;
}
// Make an error statement.
Statement*
Statement::make_error_statement(Location location)
{
return new Error_statement(location);
}
// Class Variable_declaration_statement.
Variable_declaration_statement::Variable_declaration_statement(
Named_object* var)
: Statement(STATEMENT_VARIABLE_DECLARATION, var->var_value()->location()),
var_(var)
{
}
// We don't actually traverse the variable here; it was traversed
// while traversing the Block.
int
Variable_declaration_statement::do_traverse(Traverse*)
{
return TRAVERSE_CONTINUE;
}
// Traverse the assignments in a variable declaration. Note that this
// traversal is different from the usual traversal.
bool
Variable_declaration_statement::do_traverse_assignments(
Traverse_assignments* tassign)
{
tassign->initialize_variable(this->var_);
return true;
}
// Lower the variable's initialization expression.
Statement*
Variable_declaration_statement::do_lower(Gogo* gogo, Named_object* function,
Block*, Statement_inserter* inserter)
{
this->var_->var_value()->lower_init_expression(gogo, function, inserter);
return this;
}
// Flatten the variable's initialization expression.
Statement*
Variable_declaration_statement::do_flatten(Gogo* gogo, Named_object* function,
Block*, Statement_inserter* inserter)
{
Variable* var = this->var_->var_value();
if (var->type()->is_error_type()
|| (var->init() != NULL
&& var->init()->is_error_expression()))
{
go_assert(saw_errors());
return Statement::make_error_statement(this->location());
}
this->var_->var_value()->flatten_init_expression(gogo, function, inserter);
return this;
}
// Add explicit type conversions.
void
Variable_declaration_statement::do_add_conversions()
{
Variable* var = this->var_->var_value();
Expression* init = var->init();
if (init == NULL)
return;
Type* lt = var->type();
Type* rt = init->type();
if (!Type::are_identical(lt, rt, 0, NULL)
&& lt->interface_type() != NULL)
var->set_init(Expression::make_cast(lt, init, this->location()));
}
// Convert a variable declaration to the backend representation.
Bstatement*
Variable_declaration_statement::do_get_backend(Translate_context* context)
{
Bfunction* bfunction = context->function()->func_value()->get_decl();
Variable* var = this->var_->var_value();
Bvariable* bvar = this->var_->get_backend_variable(context->gogo(),
context->function());
Bexpression* binit = var->get_init(context->gogo(), context->function());
if (!var->is_in_heap())
{
go_assert(binit != NULL);
return context->backend()->init_statement(bfunction, bvar, binit);
}
// Something takes the address of this variable, so the value is
// stored in the heap. Initialize it to newly allocated memory
// space, and assign the initial value to the new space.
Location loc = this->location();
Named_object* newfn = context->gogo()->lookup_global("new");
go_assert(newfn != NULL && newfn->is_function_declaration());
Expression* func = Expression::make_func_reference(newfn, NULL, loc);
Expression_list* params = new Expression_list();
params->push_back(Expression::make_type(var->type(), loc));
Expression* call = Expression::make_call(func, params, false, loc);
context->gogo()->lower_expression(context->function(), NULL, &call);
Temporary_statement* temp = Statement::make_temporary(NULL, call, loc);
Bstatement* btemp = temp->get_backend(context);
Bstatement* set = NULL;
if (binit != NULL)
{
Expression* e = Expression::make_temporary_reference(temp, loc);
e = Expression::make_dereference(e, Expression::NIL_CHECK_NOT_NEEDED,
loc);
Bexpression* be = e->get_backend(context);
set = context->backend()->assignment_statement(bfunction, be, binit, loc);
}
Expression* ref = Expression::make_temporary_reference(temp, loc);
Bexpression* bref = ref->get_backend(context);
Bstatement* sinit = context->backend()->init_statement(bfunction, bvar, bref);
std::vector<Bstatement*> stats;
stats.reserve(3);
stats.push_back(btemp);
if (set != NULL)
stats.push_back(set);
stats.push_back(sinit);
return context->backend()->statement_list(stats);
}
// Dump the AST representation for a variable declaration.
void
Variable_declaration_statement::do_dump_statement(
Ast_dump_context* ast_dump_context) const
{
ast_dump_context->print_indent();
go_assert(var_->is_variable());
ast_dump_context->ostream() << "var " << this->var_->name() << " ";
Variable* var = this->var_->var_value();
if (var->has_type())
{
ast_dump_context->dump_type(var->type());
ast_dump_context->ostream() << " ";
}
if (var->init() != NULL)
{
ast_dump_context->ostream() << "= ";
ast_dump_context->dump_expression(var->init());
}
ast_dump_context->ostream() << dsuffix(location()) << std::endl;
}
// Make a variable declaration.
Statement*
Statement::make_variable_declaration(Named_object* var)
{
return new Variable_declaration_statement(var);
}
// Export a variable declaration.
void
Variable_declaration_statement::do_export_statement(Export_function_body* efb)
{
efb->write_c_string("var ");
efb->write_string(Gogo::unpack_hidden_name(this->var_->name()));
efb->write_c_string(" ");
Variable* var = this->var_->var_value();
Type* type = var->type();
efb->write_type(type);
Expression* init = var->init();
if (init != NULL)
{
efb->write_c_string(" = ");
go_assert(efb->type_context() == NULL);
efb->set_type_context(type);
init->export_expression(efb);
efb->set_type_context(NULL);
}
}
// Import a variable declaration.
Statement*
Variable_declaration_statement::do_import(Import_function_body* ifb,
Location loc)
{
ifb->require_c_string("var ");
std::string id = ifb->read_identifier();
ifb->require_c_string(" ");
Type* type = ifb->read_type();
Expression* init = NULL;
if (ifb->match_c_string(" = "))
{
ifb->advance(3);
init = Expression::import_expression(ifb, loc);
}
Variable* var = new Variable(type, init, false, false, false, loc);
var->set_is_used();
// FIXME: The package we are importing does not yet exist, so we
// can't pass the correct package here. It probably doesn't matter.
Named_object* no = ifb->block()->bindings()->add_variable(id, NULL, var);
return Statement::make_variable_declaration(no);
}
// Class Temporary_statement.
// Return the type of the temporary variable.
Type*
Temporary_statement::type() const
{
Type* type = this->type_ != NULL ? this->type_ : this->init_->type();
// Temporary variables cannot have a void type.
if (type->is_void_type())
{
go_assert(saw_errors());
return Type::make_error_type();
}
return type;
}
// Traversal.
int
Temporary_statement::do_traverse(Traverse* traverse)
{
if (this->type_ != NULL
&& this->traverse_type(traverse, this->type_) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
if (this->init_ == NULL)
return TRAVERSE_CONTINUE;
else
return this->traverse_expression(traverse, &this->init_);
}
// Traverse assignments.
bool
Temporary_statement::do_traverse_assignments(Traverse_assignments* tassign)
{
if (this->init_ == NULL)
return false;
tassign->value(&this->init_, true, true);
return true;
}
// Determine types.
void
Temporary_statement::do_determine_types()
{
if (this->type_ != NULL && this->type_->is_abstract())
this->type_ = this->type_->make_non_abstract_type();
if (this->init_ != NULL)
{
if (this->type_ == NULL)
this->init_->determine_type_no_context();
else
{
Type_context context(this->type_, false);
this->init_->determine_type(&context);
}
}
if (this->type_ == NULL)
{
this->type_ = this->init_->type();
go_assert(!this->type_->is_abstract());
}
}
// Check types.
void
Temporary_statement::do_check_types(Gogo*)
{
if (this->type_ != NULL && this->init_ != NULL)
{
std::string reason;
if (!Type::are_assignable(this->type_, this->init_->type(), &reason))
{
if (reason.empty())
go_error_at(this->location(), "incompatible types in assignment");
else
go_error_at(this->location(), "incompatible types in assignment (%s)",
reason.c_str());
this->set_is_error();
}
}
}
// Flatten a temporary statement: add another temporary when it might
// be needed for interface conversion.
Statement*
Temporary_statement::do_flatten(Gogo*, Named_object*, Block*,
Statement_inserter* inserter)
{
if (this->type()->is_error_type()
|| (this->init_ != NULL
&& this->init_->is_error_expression()))
{
go_assert(saw_errors());
return Statement::make_error_statement(this->location());
}
if (this->type_ != NULL
&& this->init_ != NULL
&& !Type::are_identical(this->type_, this->init_->type(),
Type::COMPARE_ERRORS | Type::COMPARE_TAGS,
NULL)
&& this->init_->type()->interface_type() != NULL
&& !this->init_->is_variable())
{
Temporary_statement *temp =
Statement::make_temporary(NULL, this->init_, this->location());
inserter->insert(temp);
this->init_ = Expression::make_temporary_reference(temp,
this->location());
}
return this;
}
// Add explicit type conversions.
void
Temporary_statement::do_add_conversions()
{
if (this->init_ == NULL)
return;
Type* lt = this->type();
Type* rt = this->init_->type();
if (!Type::are_identical(lt, rt, 0, NULL)
&& lt->interface_type() != NULL)
this->init_ = Expression::make_cast(lt, this->init_, this->location());
}
// Convert to backend representation.
Bstatement*
Temporary_statement::do_get_backend(Translate_context* context)
{
go_assert(this->bvariable_ == NULL);
Named_object* function = context->function();
go_assert(function != NULL);
Bfunction* bfunction = function->func_value()->get_decl();
Btype* btype = this->type()->get_backend(context->gogo());
Bexpression* binit;
if (this->init_ == NULL)
binit = NULL;
else if (this->type_ == NULL)
binit = this->init_->get_backend(context);
else
{
Expression* init = Expression::convert_for_assignment(context->gogo(),
this->type_,
this->init_,
this->location());
binit = init->get_backend(context);
}
if (binit != NULL)
binit = context->backend()->convert_expression(btype, binit,
this->location());
Bstatement* statement;
this->bvariable_ =
context->backend()->temporary_variable(bfunction, context->bblock(),
btype, binit,
this->is_address_taken_,
this->location(), &statement);
return statement;
}
// Return the backend variable.
Bvariable*
Temporary_statement::get_backend_variable(Translate_context* context) const
{
if (this->bvariable_ == NULL)
{
go_assert(saw_errors());
return context->backend()->error_variable();
}
return this->bvariable_;
}
// Dump the AST represemtation for a temporary statement
void
Temporary_statement::do_dump_statement(Ast_dump_context* ast_dump_context) const
{
ast_dump_context->print_indent();
ast_dump_context->dump_temp_variable_name(this);
if (this->type_ != NULL)
{
ast_dump_context->ostream() << " ";
ast_dump_context->dump_type(this->type_);
}
if (this->init_ != NULL)
{
ast_dump_context->ostream() << " = ";
ast_dump_context->dump_expression(this->init_);
}
ast_dump_context->ostream() << dsuffix(location()) << std::endl;
}
// Make and initialize a temporary variable in BLOCK.
Temporary_statement*
Statement::make_temporary(Type* type, Expression* init,
Location location)
{
return new Temporary_statement(type, init, location);
}
// Export a temporary statement.
void
Temporary_statement::do_export_statement(Export_function_body* efb)
{
unsigned int idx = efb->record_temporary(this);
char buf[100];
snprintf(buf, sizeof buf, "var $t%u", idx);
efb->write_c_string(buf);
if (this->type_ != NULL)
{
efb->write_c_string(" ");
efb->write_type(this->type_);
}
if (this->init_ != NULL)
{
efb->write_c_string(" = ");
go_assert(efb->type_context() == NULL);
efb->set_type_context(this->type_);
this->init_->export_expression(efb);
efb->set_type_context(NULL);
}
}
// Import a temporary statement.
Statement*
Temporary_statement::do_import(Import_function_body* ifb, Location loc)
{
ifb->require_c_string("var ");
std::string id = ifb->read_identifier();
go_assert(id[0] == '$' && id[1] == 't');
const char *p = id.c_str();
char *end;
long idx = strtol(p + 2, &end, 10);
if (*end != '\0' || idx > 0x7fffffff)
{
if (!ifb->saw_error())
go_error_at(loc,
("invalid export data for %qs: "
"bad temporary statement index at %lu"),
ifb->name().c_str(),
static_cast<unsigned long>(ifb->off()));
ifb->set_saw_error();
return Statement::make_error_statement(loc);
}
Type* type = NULL;
if (!ifb->match_c_string(" = "))
{
ifb->require_c_string(" ");
type = ifb->read_type();
}
Expression* init = NULL;
if (ifb->match_c_string(" = "))
{
ifb->advance(3);
init = Expression::import_expression(ifb, loc);
}
if (type == NULL && init == NULL)
{
if (!ifb->saw_error())
go_error_at(loc,
("invalid export data for %qs: "
"temporary statement has neither type nor init at %lu"),
ifb->name().c_str(),
static_cast<unsigned long>(ifb->off()));
ifb->set_saw_error();
return Statement::make_error_statement(loc);
}
Temporary_statement* temp = Statement::make_temporary(type, init, loc);
ifb->record_temporary(temp, static_cast<unsigned int>(idx));
return temp;
}
// The Move_subexpressions class is used to move all top-level
// subexpressions of an expression. This is used for things like
// index expressions in which we must evaluate the index value before
// it can be changed by a multiple assignment.
class Move_subexpressions : public Traverse
{
public:
Move_subexpressions(int skip, Block* block)
: Traverse(traverse_expressions),
skip_(skip), block_(block)
{ }
protected:
int
expression(Expression**);
private:
// The number of subexpressions to skip moving. This is used to
// avoid moving the array itself, as we only need to move the index.
int skip_;
// The block where new temporary variables should be added.
Block* block_;
};
int
Move_subexpressions::expression(Expression** pexpr)
{
if (this->skip_ > 0)
--this->skip_;
else if ((*pexpr)->temporary_reference_expression() == NULL
&& !(*pexpr)->is_nil_expression()
&& !(*pexpr)->is_constant())
{
Location loc = (*pexpr)->location();
Temporary_statement* temp = Statement::make_temporary(NULL, *pexpr, loc);
this->block_->add_statement(temp);
*pexpr = Expression::make_temporary_reference(temp, loc);
}
// We only need to move top-level subexpressions.
return TRAVERSE_SKIP_COMPONENTS;
}
// The Move_ordered_evals class is used to find any subexpressions of
// an expression that have an evaluation order dependency. It creates
// temporary variables to hold them.
class Move_ordered_evals : public Traverse
{
public:
Move_ordered_evals(Block* block)
: Traverse(traverse_expressions),
block_(block)
{ }
protected:
int
expression(Expression**);
private:
// The block where new temporary variables should be added.
Block* block_;
};
int
Move_ordered_evals::expression(Expression** pexpr)
{
// We have to look at subexpressions first.
if ((*pexpr)->traverse_subexpressions(this) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
int i;
if ((*pexpr)->must_eval_subexpressions_in_order(&i))
{
Move_subexpressions ms(i, this->block_);
if ((*pexpr)->traverse_subexpressions(&ms) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
}
if ((*pexpr)->must_eval_in_order())
{
Call_expression* call = (*pexpr)->call_expression();
if (call != NULL && call->is_multi_value_arg())
{
// A call expression which returns multiple results as an argument
// to another call must be handled specially. We can't create a
// temporary because there is no type to give it. Instead, group
// the caller and this multi-valued call argument and use a temporary
// variable to hold them.
return TRAVERSE_SKIP_COMPONENTS;
}
Location loc = (*pexpr)->location();
Temporary_statement* temp = Statement::make_temporary(NULL, *pexpr, loc);
this->block_->add_statement(temp);
*pexpr = Expression::make_temporary_reference(temp, loc);
}
return TRAVERSE_SKIP_COMPONENTS;
}
// Class Assignment_statement.
// Traversal.
int
Assignment_statement::do_traverse(Traverse* traverse)
{
if (this->traverse_expression(traverse, &this->lhs_) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
return this->traverse_expression(traverse, &this->rhs_);
}
bool
Assignment_statement::do_traverse_assignments(Traverse_assignments* tassign)
{
tassign->assignment(&this->lhs_, &this->rhs_);
return true;
}
// Lower an assignment to a map index expression to a runtime function
// call. Mark some slice assignments as not requiring a write barrier.
Statement*
Assignment_statement::do_lower(Gogo* gogo, Named_object*, Block* enclosing,
Statement_inserter*)
{
Map_index_expression* mie = this->lhs_->map_index_expression();
if (mie != NULL)
{
Location loc = this->location();
Expression* map = mie->map();
Map_type* mt = map->type()->map_type();
if (mt == NULL)
{
go_assert(saw_errors());
return Statement::make_error_statement(loc);
}
Block* b = new Block(enclosing, loc);
// Move out any subexpressions on the left hand side to make
// sure that functions are called in the required order.
Move_ordered_evals moe(b);
mie->traverse_subexpressions(&moe);
// Copy the key into a temporary so that we can take its address
// without pushing the value onto the heap.
// var key_temp KEY_TYPE = MAP_INDEX
Temporary_statement* key_temp = Statement::make_temporary(mt->key_type(),
mie->index(),
loc);
b->add_statement(key_temp);
// Copy the value into a temporary to ensure that it is
// evaluated before we add the key to the map. This may matter
// if the value is itself a reference to the map.
// var val_temp VAL_TYPE = RHS
Temporary_statement* val_temp = Statement::make_temporary(mt->val_type(),
this->rhs_,
loc);
b->add_statement(val_temp);
// *mapassign(TYPE, MAP, &key_temp) = RHS
Expression* a1 = Expression::make_type_descriptor(mt, loc);
Expression* a2 = mie->map();
Temporary_reference_expression* ref =
Expression::make_temporary_reference(key_temp, loc);
Expression* a3 = Expression::make_unary(OPERATOR_AND, ref, loc);
Runtime::Function code;
Map_type::Map_alg alg = mt->algorithm(gogo);
switch (alg)
{
case Map_type::MAP_ALG_FAST32:
{
code = Runtime::MAPASSIGN_FAST32;
Type* uint32_type = Type::lookup_integer_type("uint32");
Type* uint32_ptr_type = Type::make_pointer_type(uint32_type);
a3 = Expression::make_unsafe_cast(uint32_ptr_type, a3,
loc);
a3 = Expression::make_dereference(a3,
Expression::NIL_CHECK_NOT_NEEDED,
loc);
break;
}
case Map_type::MAP_ALG_FAST64:
{
code = Runtime::MAPASSIGN_FAST64;
Type* uint64_type = Type::lookup_integer_type("uint64");
Type* uint64_ptr_type = Type::make_pointer_type(uint64_type);
a3 = Expression::make_unsafe_cast(uint64_ptr_type, a3,
loc);
a3 = Expression::make_dereference(a3,
Expression::NIL_CHECK_NOT_NEEDED,
loc);
break;
}
case Map_type::MAP_ALG_FAST32PTR:
case Map_type::MAP_ALG_FAST64PTR:
{
code = (alg == Map_type::MAP_ALG_FAST32PTR
? Runtime::MAPASSIGN_FAST32PTR
: Runtime::MAPASSIGN_FAST64PTR);
Type* ptr_type =
Type::make_pointer_type(Type::make_void_type());
Type* ptr_ptr_type = Type::make_pointer_type(ptr_type);
a3 = Expression::make_unsafe_cast(ptr_ptr_type, a3,
loc);
a3 = Expression::make_dereference(a3,
Expression::NIL_CHECK_NOT_NEEDED,
loc);
break;
}
case Map_type::MAP_ALG_FASTSTR:
code = Runtime::MAPASSIGN_FASTSTR;
a3 = ref;
break;
default:
code = Runtime::MAPASSIGN;
break;
}
Expression* call = Runtime::make_call(code, loc, 3,
a1, a2, a3);
Type* ptrval_type = Type::make_pointer_type(mt->val_type());
call = Expression::make_cast(ptrval_type, call, loc);
Expression* indir =
Expression::make_dereference(call, Expression::NIL_CHECK_NOT_NEEDED,
loc);
ref = Expression::make_temporary_reference(val_temp, loc);
b->add_statement(Statement::make_assignment(indir, ref, loc));
return Statement::make_block_statement(b, loc);
}
// An assignment of the form s = s[:n] does not require a write
// barrier, because the pointer value will not change.
Array_index_expression* aie = this->rhs_->array_index_expression();
if (aie != NULL
&& aie->end() != NULL
&& Expression::is_same_variable(this->lhs_, aie->array()))
{
Numeric_constant nc;
unsigned long ival;
if (aie->start()->numeric_constant_value(&nc)
&& nc.to_unsigned_long(&ival) == Numeric_constant::NC_UL_VALID
&& ival == 0)
this->omit_write_barrier_ = true;
}
String_index_expression* sie = this->rhs_->string_index_expression();
if (sie != NULL
&& sie->end() != NULL
&& Expression::is_same_variable(this->lhs_, sie->string()))
{
Numeric_constant nc;
unsigned long ival;
if (sie->start()->numeric_constant_value(&nc)
&& nc.to_unsigned_long(&ival) == Numeric_constant::NC_UL_VALID
&& ival == 0)
this->omit_write_barrier_ = true;
}
return this;
}
// Set types for the assignment.
void
Assignment_statement::do_determine_types()
{
this->lhs_->determine_type_no_context();
Type* rhs_context_type = this->lhs_->type();
if (rhs_context_type->is_sink_type())
rhs_context_type = NULL;
Type_context context(rhs_context_type, false);
this->rhs_->determine_type(&context);
}
// Check types for an assignment.
void
Assignment_statement::do_check_types(Gogo*)
{
// The left hand side must be either addressable, a map index
// expression, or the blank identifier.
if (!this->lhs_->is_addressable()
&& this->lhs_->map_index_expression() == NULL
&& !this->lhs_->is_sink_expression())
{
if (!this->lhs_->type()->is_error())
this->report_error(_("invalid left hand side of assignment"));
return;
}
Type* lhs_type = this->lhs_->type();
Type* rhs_type = this->rhs_->type();
// Invalid assignment of nil to the blank identifier.
if (lhs_type->is_sink_type()
&& rhs_type->is_nil_type())
{
this->report_error(_("use of untyped nil"));
return;
}
std::string reason;
if (!Type::are_assignable(lhs_type, rhs_type, &reason))
{
if (reason.empty())
go_error_at(this->location(), "incompatible types in assignment");
else
go_error_at(this->location(), "incompatible types in assignment (%s)",
reason.c_str());
this->set_is_error();
}
if (lhs_type->is_error() || rhs_type->is_error())
this->set_is_error();
}
void
Assignment_statement::do_export_statement(Export_function_body* efb)
{
this->lhs_->export_expression(efb);
efb->write_c_string(" = ");
this->rhs_->export_expression(efb);
}
// Flatten an assignment statement. We may need a temporary for
// interface conversion.
Statement*
Assignment_statement::do_flatten(Gogo*, Named_object*, Block*,
Statement_inserter* inserter)
{
if (this->lhs_->is_error_expression()
|| this->lhs_->type()->is_error_type()
|| this->rhs_->is_error_expression()
|| this->rhs_->type()->is_error_type())
{
go_assert(saw_errors());
return Statement::make_error_statement(this->location());
}
if (!this->lhs_->is_sink_expression()
&& !Type::are_identical(this->lhs_->type(), this->rhs_->type(),
Type::COMPARE_ERRORS | Type::COMPARE_TAGS,
NULL)
&& this->rhs_->type()->interface_type() != NULL
&& !this->rhs_->is_variable())
{
Temporary_statement* temp =
Statement::make_temporary(NULL, this->rhs_, this->location());
inserter->insert(temp);
this->rhs_ = Expression::make_temporary_reference(temp,
this->location());
}
return this;
}
// Add explicit type conversions.
void
Assignment_statement::do_add_conversions()
{
Type* lt = this->lhs_->type();
Type* rt = this->rhs_->type();
if (!Type::are_identical(lt, rt, 0, NULL)
&& lt->interface_type() != NULL)
this->rhs_ = Expression::make_cast(lt, this->rhs_, this->location());
}
// Convert an assignment statement to the backend representation.
Bstatement*
Assignment_statement::do_get_backend(Translate_context* context)
{
if (this->lhs_->is_sink_expression())
{
Bexpression* rhs = this->rhs_->get_backend(context);
Bfunction* bfunction = context->function()->func_value()->get_decl();
return context->backend()->expression_statement(bfunction, rhs);
}
Bexpression* lhs = this->lhs_->get_backend(context);
Expression* conv =
Expression::convert_for_assignment(context->gogo(), this->lhs_->type(),
this->rhs_, this->location());
Bexpression* rhs = conv->get_backend(context);
Bfunction* bfunction = context->function()->func_value()->get_decl();
return context->backend()->assignment_statement(bfunction, lhs, rhs,
this->location());
}
// Dump the AST representation for an assignment statement.
void
Assignment_statement::do_dump_statement(Ast_dump_context* ast_dump_context)
const
{
ast_dump_context->print_indent();
ast_dump_context->dump_expression(this->lhs_);
ast_dump_context->ostream() << " = " ;
ast_dump_context->dump_expression(this->rhs_);
ast_dump_context->ostream() << dsuffix(location()) << std::endl;
}
// Make an assignment statement.
Assignment_statement*
Statement::make_assignment(Expression* lhs, Expression* rhs,
Location location)
{
Temporary_reference_expression* tre = lhs->temporary_reference_expression();
if (tre != NULL)
tre->statement()->set_assigned();
return new Assignment_statement(lhs, rhs, location);
}
// An assignment operation statement.
class Assignment_operation_statement : public Statement
{
public:
Assignment_operation_statement(Operator op, Expression* lhs, Expression* rhs,
Location location)
: Statement(STATEMENT_ASSIGNMENT_OPERATION, location),
op_(op), lhs_(lhs), rhs_(rhs)
{ }
protected:
int
do_traverse(Traverse*);
bool
do_traverse_assignments(Traverse_assignments*)
{ go_unreachable(); }
Statement*
do_lower(Gogo*, Named_object*, Block*, Statement_inserter*);
Bstatement*
do_get_backend(Translate_context*)
{ go_unreachable(); }
void
do_dump_statement(Ast_dump_context*) const;
private:
// The operator (OPERATOR_PLUSEQ, etc.).
Operator op_;
// Left hand side.
Expression* lhs_;
// Right hand side.
Expression* rhs_;
};
// Traversal.
int
Assignment_operation_statement::do_traverse(Traverse* traverse)
{
if (this->traverse_expression(traverse, &this->lhs_) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
return this->traverse_expression(traverse, &this->rhs_);
}
// Lower an assignment operation statement to a regular assignment
// statement.
Statement*
Assignment_operation_statement::do_lower(Gogo*, Named_object*,
Block* enclosing, Statement_inserter*)
{
Location loc = this->location();
// We have to evaluate the left hand side expression only once. We
// do this by moving out any expression with side effects.
Block* b = new Block(enclosing, loc);
Move_ordered_evals moe(b);
this->lhs_->traverse_subexpressions(&moe);
Expression* lval = this->lhs_->copy();
Operator op;
switch (this->op_)
{
case OPERATOR_PLUSEQ:
op = OPERATOR_PLUS;
break;
case OPERATOR_MINUSEQ:
op = OPERATOR_MINUS;
break;
case OPERATOR_OREQ:
op = OPERATOR_OR;
break;
case OPERATOR_XOREQ:
op = OPERATOR_XOR;
break;
case OPERATOR_MULTEQ:
op = OPERATOR_MULT;
break;
case OPERATOR_DIVEQ:
op = OPERATOR_DIV;
break;
case OPERATOR_MODEQ:
op = OPERATOR_MOD;
break;
case OPERATOR_LSHIFTEQ:
op = OPERATOR_LSHIFT;
break;
case OPERATOR_RSHIFTEQ:
op = OPERATOR_RSHIFT;
break;
case OPERATOR_ANDEQ:
op = OPERATOR_AND;
break;
case OPERATOR_BITCLEAREQ:
op = OPERATOR_BITCLEAR;
break;
default:
go_unreachable();
}
Expression* binop = Expression::make_binary(op, lval, this->rhs_, loc);
Statement* s = Statement::make_assignment(this->lhs_, binop, loc);
if (b->statements()->empty())
{
delete b;
return s;
}
else
{
b->add_statement(s);
return Statement::make_block_statement(b, loc);
}
}
// Dump the AST representation for an assignment operation statement
void
Assignment_operation_statement::do_dump_statement(
Ast_dump_context* ast_dump_context) const
{
ast_dump_context->print_indent();
ast_dump_context->dump_expression(this->lhs_);
ast_dump_context->dump_operator(this->op_);
ast_dump_context->dump_expression(this->rhs_);
ast_dump_context->ostream() << dsuffix(location()) << std::endl;
}
// Make an assignment operation statement.
Statement*
Statement::make_assignment_operation(Operator op, Expression* lhs,
Expression* rhs, Location location)
{
return new Assignment_operation_statement(op, lhs, rhs, location);
}
// A tuple assignment statement. This differs from an assignment
// statement in that the right-hand-side expressions are evaluated in
// parallel.
class Tuple_assignment_statement : public Statement
{
public:
Tuple_assignment_statement(Expression_list* lhs, Expression_list* rhs,
Location location)
: Statement(STATEMENT_TUPLE_ASSIGNMENT, location),
lhs_(lhs), rhs_(rhs)
{ }
protected:
int
do_traverse(Traverse* traverse);
bool
do_traverse_assignments(Traverse_assignments*)
{ go_unreachable(); }
Statement*
do_lower(Gogo*, Named_object*, Block*, Statement_inserter*);
Bstatement*
do_get_backend(Translate_context*)
{ go_unreachable(); }
void
do_dump_statement(Ast_dump_context*) const;
private:
// Left hand side--a list of lvalues.
Expression_list* lhs_;
// Right hand side--a list of rvalues.
Expression_list* rhs_;
};
// Traversal.
int
Tuple_assignment_statement::do_traverse(Traverse* traverse)
{
if (this->traverse_expression_list(traverse, this->lhs_) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
return this->traverse_expression_list(traverse, this->rhs_);
}
// Lower a tuple assignment. We use temporary variables to split it
// up into a set of single assignments.
Statement*
Tuple_assignment_statement::do_lower(Gogo*, Named_object*, Block* enclosing,
Statement_inserter*)
{
Location loc = this->location();
Block* b = new Block(enclosing, loc);
// First move out any subexpressions on the left hand side. The
// right hand side will be evaluated in the required order anyhow.
Move_ordered_evals moe(b);
for (Expression_list::iterator plhs = this->lhs_->begin();
plhs != this->lhs_->end();
++plhs)
Expression::traverse(&*plhs, &moe);
std::vector<Temporary_statement*> temps;
temps.reserve(this->lhs_->size());
Expression_list::const_iterator prhs = this->rhs_->begin();
for (Expression_list::const_iterator plhs = this->lhs_->begin();
plhs != this->lhs_->end();
++plhs, ++prhs)
{
go_assert(prhs != this->rhs_->end());
if ((*plhs)->is_error_expression()
|| (*plhs)->type()->is_error()
|| (*prhs)->is_error_expression()
|| (*prhs)->type()->is_error())
continue;
if ((*plhs)->is_sink_expression())
{
if ((*prhs)->type()->is_nil_type())
this->report_error(_("use of untyped nil"));
else
b->add_statement(Statement::make_statement(*prhs, true));
continue;
}
Temporary_statement* temp = Statement::make_temporary((*plhs)->type(),
*prhs, loc);
b->add_statement(temp);
temps.push_back(temp);
}
go_assert(prhs == this->rhs_->end());
prhs = this->rhs_->begin();
std::vector<Temporary_statement*>::const_iterator ptemp = temps.begin();
for (Expression_list::const_iterator plhs = this->lhs_->begin();
plhs != this->lhs_->end();
++plhs, ++prhs)
{
if ((*plhs)->is_error_expression()
|| (*plhs)->type()->is_error()
|| (*prhs)->is_error_expression()
|| (*prhs)->type()->is_error())
continue;
if ((*plhs)->is_sink_expression())
continue;
Expression* ref = Expression::make_temporary_reference(*ptemp, loc);
b->add_statement(Statement::make_assignment(*plhs, ref, loc));
++ptemp;
}
go_assert(ptemp == temps.end() || saw_errors());
return Statement::make_block_statement(b, loc);
}
// Dump the AST representation for a tuple assignment statement.
void
Tuple_assignment_statement::do_dump_statement(
Ast_dump_context* ast_dump_context) const
{
ast_dump_context->print_indent();
ast_dump_context->dump_expression_list(this->lhs_);
ast_dump_context->ostream() << " = ";
ast_dump_context->dump_expression_list(this->rhs_);
ast_dump_context->ostream() << dsuffix(location()) << std::endl;
}
// Make a tuple assignment statement.
Statement*
Statement::make_tuple_assignment(Expression_list* lhs, Expression_list* rhs,
Location location)
{
return new Tuple_assignment_statement(lhs, rhs, location);
}
// A tuple assignment from a map index expression.
// v, ok = m[k]
class Tuple_map_assignment_statement : public Statement
{
public:
Tuple_map_assignment_statement(Expression* val, Expression* present,
Expression* map_index,
Location location)
: Statement(STATEMENT_TUPLE_MAP_ASSIGNMENT, location),
val_(val), present_(present), map_index_(map_index)
{ }
protected:
int
do_traverse(Traverse* traverse);
bool
do_traverse_assignments(Traverse_assignments*)
{ go_unreachable(); }
Statement*
do_lower(Gogo*, Named_object*, Block*, Statement_inserter*);
Bstatement*
do_get_backend(Translate_context*)
{ go_unreachable(); }
void
do_dump_statement(Ast_dump_context*) const;
private:
// Lvalue which receives the value from the map.
Expression* val_;
// Lvalue which receives whether the key value was present.
Expression* present_;
// The map index expression.
Expression* map_index_;
};
// Traversal.
int
Tuple_map_assignment_statement::do_traverse(Traverse* traverse)
{
if (this->traverse_expression(traverse, &this->val_) == TRAVERSE_EXIT
|| this->traverse_expression(traverse, &this->present_) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
return this->traverse_expression(traverse, &this->map_index_);
}
// Lower a tuple map assignment.
Statement*
Tuple_map_assignment_statement::do_lower(Gogo* gogo, Named_object*,
Block* enclosing, Statement_inserter*)
{
Location loc = this->location();
Map_index_expression* map_index = this->map_index_->map_index_expression();
if (map_index == NULL)
{
this->report_error(_("expected map index on right hand side"));
return Statement::make_error_statement(loc);
}
Map_type* map_type = map_index->get_map_type();
if (map_type == NULL)
return Statement::make_error_statement(loc);
// Avoid copy for string([]byte) conversions used in map keys.
// mapaccess doesn't keep the reference, so this is safe.
Type_conversion_expression* ce = map_index->index()->conversion_expression();
if (ce != NULL && ce->type()->is_string_type()
&& ce->expr()->type()->is_slice_type())
ce->set_no_copy(true);
Block* b = new Block(enclosing, loc);
// Move out any subexpressions to make sure that functions are
// called in the required order.
Move_ordered_evals moe(b);
this->val_->traverse_subexpressions(&moe);
this->present_->traverse_subexpressions(&moe);
// Copy the key value into a temporary so that we can take its
// address without pushing the value onto the heap.
// var key_temp KEY_TYPE = MAP_INDEX
Temporary_statement* key_temp =
Statement::make_temporary(map_type->key_type(), map_index->index(), loc);
b->add_statement(key_temp);
// var val_ptr_temp *VAL_TYPE
Type* val_ptr_type = Type::make_pointer_type(map_type->val_type());
Temporary_statement* val_ptr_temp = Statement::make_temporary(val_ptr_type,
NULL, loc);
b->add_statement(val_ptr_temp);
// var present_temp bool
Temporary_statement* present_temp =
Statement::make_temporary((this->present_->type()->is_sink_type())
? Type::make_boolean_type()
: this->present_->type(),
NULL, loc);
b->add_statement(present_temp);
// val_ptr_temp, present_temp = mapaccess2(DESCRIPTOR, MAP, &key_temp)
Expression* a1 = Expression::make_type_descriptor(map_type, loc);
Expression* a2 = map_index->map();
Temporary_reference_expression* ref =
Expression::make_temporary_reference(key_temp, loc);
Expression* a3 = Expression::make_unary(OPERATOR_AND, ref, loc);
Expression* a4 = map_type->fat_zero_value(gogo);
Call_expression* call;
if (a4 == NULL)
{
Runtime::Function code;
Map_type::Map_alg alg = map_type->algorithm(gogo);
switch (alg)
{
case Map_type::MAP_ALG_FAST32:
case Map_type::MAP_ALG_FAST32PTR:
{
code = Runtime::MAPACCESS2_FAST32;
Type* uint32_type = Type::lookup_integer_type("uint32");
Type* uint32_ptr_type = Type::make_pointer_type(uint32_type);
a3 = Expression::make_unsafe_cast(uint32_ptr_type, a3,
loc);
a3 = Expression::make_dereference(a3,
Expression::NIL_CHECK_NOT_NEEDED,
loc);
break;
}
case Map_type::MAP_ALG_FAST64:
case Map_type::MAP_ALG_FAST64PTR:
{
code = Runtime::MAPACCESS2_FAST64;
Type* uint64_type = Type::lookup_integer_type("uint64");
Type* uint64_ptr_type = Type::make_pointer_type(uint64_type);
a3 = Expression::make_unsafe_cast(uint64_ptr_type, a3,
loc);
a3 = Expression::make_dereference(a3,
Expression::NIL_CHECK_NOT_NEEDED,
loc);
break;
}
case Map_type::MAP_ALG_FASTSTR:
code = Runtime::MAPACCESS2_FASTSTR;
a3 = ref;
break;
default:
code = Runtime::MAPACCESS2;
break;
}
call = Runtime::make_call(code, loc, 3, a1, a2, a3);
}
else
call = Runtime::make_call(Runtime::MAPACCESS2_FAT, loc, 4, a1, a2, a3, a4);
ref = Expression::make_temporary_reference(val_ptr_temp, loc);
ref->set_is_lvalue();
Expression* res = Expression::make_call_result(call, 0);
res = Expression::make_unsafe_cast(val_ptr_type, res, loc);
Statement* s = Statement::make_assignment(ref, res, loc);
b->add_statement(s);
ref = Expression::make_temporary_reference(present_temp, loc);
ref->set_is_lvalue();
res = Expression::make_call_result(call, 1);
s = Statement::make_assignment(ref, res, loc);
b->add_statement(s);
// val = *val__ptr_temp
ref = Expression::make_temporary_reference(val_ptr_temp, loc);
Expression* ind =
Expression::make_dereference(ref, Expression::NIL_CHECK_NOT_NEEDED, loc);
s = Statement::make_assignment(this->val_, ind, loc);
b->add_statement(s);
// present = present_temp
ref = Expression::make_temporary_reference(present_temp, loc);
s = Statement::make_assignment(this->present_, ref, loc);
b->add_statement(s);
return Statement::make_block_statement(b, loc);
}
// Dump the AST representation for a tuple map assignment statement.
void
Tuple_map_assignment_statement::do_dump_statement(
Ast_dump_context* ast_dump_context) const
{
ast_dump_context->print_indent();
ast_dump_context->dump_expression(this->val_);
ast_dump_context->ostream() << ", ";
ast_dump_context->dump_expression(this->present_);
ast_dump_context->ostream() << " = ";
ast_dump_context->dump_expression(this->map_index_);
ast_dump_context->ostream() << dsuffix(location()) << std::endl;
}
// Make a map assignment statement which returns a pair of values.
Statement*
Statement::make_tuple_map_assignment(Expression* val, Expression* present,
Expression* map_index,
Location location)
{
return new Tuple_map_assignment_statement(val, present, map_index, location);
}
// A tuple assignment from a receive statement.
class Tuple_receive_assignment_statement : public Statement
{
public:
Tuple_receive_assignment_statement(Expression* val, Expression* closed,
Expression* channel, Location location)
: Statement(STATEMENT_TUPLE_RECEIVE_ASSIGNMENT, location),
val_(val), closed_(closed), channel_(channel)
{ }
protected:
int
do_traverse(Traverse* traverse);
bool
do_traverse_assignments(Traverse_assignments*)
{ go_unreachable(); }
Statement*
do_lower(Gogo*, Named_object*, Block*, Statement_inserter*);
Bstatement*
do_get_backend(Translate_context*)
{ go_unreachable(); }
void
do_dump_statement(Ast_dump_context*) const;
private:
// Lvalue which receives the value from the channel.
Expression* val_;
// Lvalue which receives whether the channel is closed.
Expression* closed_;
// The channel on which we receive the value.
Expression* channel_;
};
// Traversal.
int
Tuple_receive_assignment_statement::do_traverse(Traverse* traverse)
{
if (this->traverse_expression(traverse, &this->val_) == TRAVERSE_EXIT
|| this->traverse_expression(traverse, &this->closed_) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
return this->traverse_expression(traverse, &this->channel_);
}
// Lower to a function call.
Statement*
Tuple_receive_assignment_statement::do_lower(Gogo*, Named_object*,
Block* enclosing,
Statement_inserter*)
{
Location loc = this->location();
Channel_type* channel_type = this->channel_->type()->channel_type();
if (channel_type == NULL)
{
this->report_error(_("expected channel"));
return Statement::make_error_statement(loc);
}
if (!channel_type->may_receive())
{
this->report_error(_("invalid receive on send-only channel"));
return Statement::make_error_statement(loc);
}
Block* b = new Block(enclosing, loc);
// Make sure that any subexpressions on the left hand side are
// evaluated in the right order.
Move_ordered_evals moe(b);
this->val_->traverse_subexpressions(&moe);
this->closed_->traverse_subexpressions(&moe);
// var val_temp ELEMENT_TYPE
Temporary_statement* val_temp =
Statement::make_temporary(channel_type->element_type(), NULL, loc);
b->add_statement(val_temp);
// var closed_temp bool
Temporary_statement* closed_temp =
Statement::make_temporary((this->closed_->type()->is_sink_type())
? Type::make_boolean_type()
: this->closed_->type(),
NULL, loc);
b->add_statement(closed_temp);
// closed_temp = chanrecv2(channel, &val_temp)
Temporary_reference_expression* ref =
Expression::make_temporary_reference(val_temp, loc);
Expression* p2 = Expression::make_unary(OPERATOR_AND, ref, loc);
Expression* call = Runtime::make_call(Runtime::CHANRECV2,
loc, 2, this->channel_, p2);
ref = Expression::make_temporary_reference(closed_temp, loc);
ref->set_is_lvalue();
Statement* s = Statement::make_assignment(ref, call, loc);
b->add_statement(s);
// val = val_temp
ref = Expression::make_temporary_reference(val_temp, loc);
s = Statement::make_assignment(this->val_, ref, loc);
b->add_statement(s);
// closed = closed_temp
ref = Expression::make_temporary_reference(closed_temp, loc);
s = Statement::make_assignment(this->closed_, ref, loc);
b->add_statement(s);
return Statement::make_block_statement(b, loc);
}
// Dump the AST representation for a tuple receive statement.
void
Tuple_receive_assignment_statement::do_dump_statement(
Ast_dump_context* ast_dump_context) const
{
ast_dump_context->print_indent();
ast_dump_context->dump_expression(this->val_);
ast_dump_context->ostream() << ", ";
ast_dump_context->dump_expression(this->closed_);
ast_dump_context->ostream() << " <- ";
ast_dump_context->dump_expression(this->channel_);
ast_dump_context->ostream() << dsuffix(location()) << std::endl;
}
// Make a nonblocking receive statement.
Statement*
Statement::make_tuple_receive_assignment(Expression* val, Expression* closed,
Expression* channel,
Location location)
{
return new Tuple_receive_assignment_statement(val, closed, channel,
location);
}
// An assignment to a pair of values from a type guard. This is a
// conditional type guard. v, ok = i.(type).
class Tuple_type_guard_assignment_statement : public Statement
{
public:
Tuple_type_guard_assignment_statement(Expression* val, Expression* ok,
Expression* expr, Type* type,
Location location)
: Statement(STATEMENT_TUPLE_TYPE_GUARD_ASSIGNMENT, location),
val_(val), ok_(ok), expr_(expr), type_(type)
{ }
protected:
int
do_traverse(Traverse*);
bool
do_traverse_assignments(Traverse_assignments*)
{ go_unreachable(); }
Statement*
do_lower(Gogo*, Named_object*, Block*, Statement_inserter*);
Bstatement*
do_get_backend(Translate_context*)
{ go_unreachable(); }
void
do_dump_statement(Ast_dump_context*) const;
private:
Call_expression*
lower_to_type(Runtime::Function);
void
lower_to_object_type(Block*, Runtime::Function);
// The variable which recieves the converted value.
Expression* val_;
// The variable which receives the indication of success.
Expression* ok_;
// The expression being converted.
Expression* expr_;
// The type to which the expression is being converted.
Type* type_;
};
// Traverse a type guard tuple assignment.
int
Tuple_type_guard_assignment_statement::do_traverse(Traverse* traverse)
{
if (this->traverse_expression(traverse, &this->val_) == TRAVERSE_EXIT
|| this->traverse_expression(traverse, &this->ok_) == TRAVERSE_EXIT
|| this->traverse_type(traverse, this->type_) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
return this->traverse_expression(traverse, &this->expr_);
}
// Lower to a function call.
Statement*
Tuple_type_guard_assignment_statement::do_lower(Gogo*, Named_object*,
Block* enclosing,
Statement_inserter*)
{
Location loc = this->location();
Type* expr_type = this->expr_->type();
if (expr_type->interface_type() == NULL)
{
if (!expr_type->is_error() && !this->type_->is_error())
this->report_error(_("type assertion only valid for interface types"));
return Statement::make_error_statement(loc);
}
Block* b = new Block(enclosing, loc);
// Make sure that any subexpressions on the left hand side are
// evaluated in the right order.
Move_ordered_evals moe(b);
this->val_->traverse_subexpressions(&moe);
this->ok_->traverse_subexpressions(&moe);
bool expr_is_empty = expr_type->interface_type()->is_empty();
Call_expression* call;
if (this->type_->interface_type() != NULL)
{
if (this->type_->interface_type()->is_empty())
call = Runtime::make_call((expr_is_empty
? Runtime::IFACEE2E2
: Runtime::IFACEI2E2),
loc, 1, this->expr_);
else
call = this->lower_to_type(expr_is_empty
? Runtime::IFACEE2I2
: Runtime::IFACEI2I2);
}
else if (this->type_->points_to() != NULL)
call = this->lower_to_type(expr_is_empty
? Runtime::IFACEE2T2P
: Runtime::IFACEI2T2P);
else
{
this->lower_to_object_type(b,
(expr_is_empty
? Runtime::IFACEE2T2
: Runtime::IFACEI2T2));
call = NULL;
}
if (call != NULL)
{
Expression* res = Expression::make_call_result(call, 0);
res = Expression::make_unsafe_cast(this->type_, res, loc);
Statement* s = Statement::make_assignment(this->val_, res, loc);
b->add_statement(s);
res = Expression::make_call_result(call, 1);
s = Statement::make_assignment(this->ok_, res, loc);
b->add_statement(s);
}
return Statement::make_block_statement(b, loc);
}
// Lower a conversion to a non-empty interface type or a pointer type.
Call_expression*
Tuple_type_guard_assignment_statement::lower_to_type(Runtime::Function code)
{
Location loc = this->location();
return Runtime::make_call(code, loc, 2,
Expression::make_type_descriptor(this->type_, loc),
this->expr_);
}
// Lower a conversion to a non-interface non-pointer type.
void
Tuple_type_guard_assignment_statement::lower_to_object_type(
Block* b,
Runtime::Function code)
{
Location loc = this->location();
// var val_temp TYPE
Temporary_statement* val_temp = Statement::make_temporary(this->type_,
NULL, loc);
b->add_statement(val_temp);
// ok = CODE(type_descriptor, expr, &val_temp)
Expression* p1 = Expression::make_type_descriptor(this->type_, loc);
Expression* ref = Expression::make_temporary_reference(val_temp, loc);
Expression* p3 = Expression::make_unary(OPERATOR_AND, ref, loc);
Expression* call = Runtime::make_call(code, loc, 3, p1, this->expr_, p3);
Statement* s = Statement::make_assignment(this->ok_, call, loc);
b->add_statement(s);
// val = val_temp
ref = Expression::make_temporary_reference(val_temp, loc);
s = Statement::make_assignment(this->val_, ref, loc);
b->add_statement(s);
}
// Dump the AST representation for a tuple type guard statement.
void
Tuple_type_guard_assignment_statement::do_dump_statement(
Ast_dump_context* ast_dump_context) const
{
ast_dump_context->print_indent();
ast_dump_context->dump_expression(this->val_);
ast_dump_context->ostream() << ", ";
ast_dump_context->dump_expression(this->ok_);
ast_dump_context->ostream() << " = ";
ast_dump_context->dump_expression(this->expr_);
ast_dump_context->ostream() << " . ";
ast_dump_context->dump_type(this->type_);
ast_dump_context->ostream() << dsuffix(location()) << std::endl;
}
// Make an assignment from a type guard to a pair of variables.
Statement*
Statement::make_tuple_type_guard_assignment(Expression* val, Expression* ok,
Expression* expr, Type* type,
Location location)
{
return new Tuple_type_guard_assignment_statement(val, ok, expr, type,
location);
}
// Class Expression_statement.
// Constructor.
Expression_statement::Expression_statement(Expression* expr, bool is_ignored)
: Statement(STATEMENT_EXPRESSION, expr->location()),
expr_(expr), is_ignored_(is_ignored)
{
}
// Determine types.
void
Expression_statement::do_determine_types()
{
this->expr_->determine_type_no_context();
}
// Check the types of an expression statement. The only check we do
// is to possibly give an error about discarding the value of the
// expression.
void
Expression_statement::do_check_types(Gogo*)
{
if (!this->is_ignored_)
this->expr_->discarding_value();
}
// An expression statement is only a terminating statement if it is
// a call to panic.
bool
Expression_statement::do_may_fall_through() const
{
const Call_expression* call = this->expr_->call_expression();
if (call != NULL)
{
const Expression* fn = call->fn();
// panic is still an unknown named object.
const Unknown_expression* ue = fn->unknown_expression();
if (ue != NULL)
{
Named_object* no = ue->named_object();
if (no->is_unknown())
no = no->unknown_value()->real_named_object();
if (no != NULL)
{
Function_type* fntype;
if (no->is_function())
fntype = no->func_value()->type();
else if (no->is_function_declaration())
fntype = no->func_declaration_value()->type();
else
fntype = NULL;
// The builtin function panic does not return.
if (fntype != NULL && fntype->is_builtin() && no->name() == "panic")
return false;
}
}
}
return true;
}
// Export an expression statement.
void
Expression_statement::do_export_statement(Export_function_body* efb)
{
this->expr_->export_expression(efb);
}
// Convert to backend representation.
Bstatement*
Expression_statement::do_get_backend(Translate_context* context)
{
Bexpression* bexpr = this->expr_->get_backend(context);
Bfunction* bfunction = context->function()->func_value()->get_decl();
return context->backend()->expression_statement(bfunction, bexpr);
}
// Dump the AST representation for an expression statement
void
Expression_statement::do_dump_statement(Ast_dump_context* ast_dump_context)
const
{
ast_dump_context->print_indent();
ast_dump_context->dump_expression(expr_);
ast_dump_context->ostream() << dsuffix(location()) << std::endl;
}
// Make an expression statement from an Expression.
Statement*
Statement::make_statement(Expression* expr, bool is_ignored)
{
return new Expression_statement(expr, is_ignored);
}
// Export data for a block.
void
Block_statement::do_export_statement(Export_function_body* efb)
{
Block_statement::export_block(efb, this->block_,
this->is_lowered_for_statement_);
}
void
Block_statement::export_block(Export_function_body* efb, Block* block,
bool is_lowered_for_statement)
{
// We are already indented to the right position.
char buf[50];
efb->write_c_string("{");
if (is_lowered_for_statement)
efb->write_c_string(" /*for*/");
snprintf(buf, sizeof buf, " //%d\n",
Linemap::location_to_line(block->start_location()));
efb->write_c_string(buf);
block->export_block(efb);
// The indentation is correct for the statements in the block, so
// subtract one for the closing curly brace.
efb->decrement_indent();
efb->indent();
efb->write_c_string("}");
// Increment back to the value the caller thinks it has.
efb->increment_indent();
}
// Import a block statement, returning the block.
Block*
Block_statement::do_import(Import_function_body* ifb, Location loc,
bool* is_lowered_for_statement)
{
go_assert(ifb->match_c_string("{"));
*is_lowered_for_statement = false;
if (ifb->match_c_string(" /*for*/"))
{
ifb->advance(8);
*is_lowered_for_statement = true;
}
size_t nl = ifb->body().find('\n', ifb->off());
if (nl == std::string::npos)
{
if (!ifb->saw_error())
go_error_at(ifb->location(),
"import error: no newline after %<{%> at %lu",
static_cast<unsigned long>(ifb->off()));
ifb->set_saw_error();
return NULL;
}
ifb->set_off(nl + 1);
ifb->increment_indent();
Block* block = new Block(ifb->block(), loc);
ifb->begin_block(block);
bool ok = Block::import_block(block, ifb, loc);
ifb->finish_block();
ifb->decrement_indent();
if (!ok)
return NULL;
return block;
}
// Convert a block to the backend representation of a statement.
Bstatement*
Block_statement::do_get_backend(Translate_context* context)
{
Bblock* bblock = this->block_->get_backend(context);
return context->backend()->block_statement(bblock);
}
// Dump the AST for a block statement
void
Block_statement::do_dump_statement(Ast_dump_context*) const
{
// block statement braces are dumped when traversing.
}
// Make a block statement.
Block_statement*
Statement::make_block_statement(Block* block, Location location)
{
return new Block_statement(block, location);
}
// An increment or decrement statement.
class Inc_dec_statement : public Statement
{
public:
Inc_dec_statement(bool is_inc, Expression* expr)
: Statement(STATEMENT_INCDEC, expr->location()),
expr_(expr), is_inc_(is_inc)
{ }
protected:
int
do_traverse(Traverse* traverse)
{ return this->traverse_expression(traverse, &this->expr_); }
bool
do_traverse_assignments(Traverse_assignments*)
{ go_unreachable(); }
Statement*
do_lower(Gogo*, Named_object*, Block*, Statement_inserter*);
Bstatement*
do_get_backend(Translate_context*)
{ go_unreachable(); }
void
do_dump_statement(Ast_dump_context*) const;
private:
// The l-value to increment or decrement.
Expression* expr_;
// Whether to increment or decrement.
bool is_inc_;
};
// Lower to += or -=.
Statement*
Inc_dec_statement::do_lower(Gogo*, Named_object*, Block*, Statement_inserter*)
{
Location loc = this->location();
if (!this->expr_->type()->is_numeric_type())
{
this->report_error("increment or decrement of non-numeric type");
return Statement::make_error_statement(loc);
}
Expression* oexpr = Expression::make_integer_ul(1, this->expr_->type(), loc);
Operator op = this->is_inc_ ? OPERATOR_PLUSEQ : OPERATOR_MINUSEQ;
return Statement::make_assignment_operation(op, this->expr_, oexpr, loc);
}
// Dump the AST representation for a inc/dec statement.
void
Inc_dec_statement::do_dump_statement(Ast_dump_context* ast_dump_context) const
{
ast_dump_context->print_indent();
ast_dump_context->dump_expression(expr_);
ast_dump_context->ostream() << (is_inc_? "++": "--") << dsuffix(location()) << std::endl;
}
// Make an increment statement.
Statement*
Statement::make_inc_statement(Expression* expr)
{
return new Inc_dec_statement(true, expr);
}
// Make a decrement statement.
Statement*
Statement::make_dec_statement(Expression* expr)
{
return new Inc_dec_statement(false, expr);
}
// Class Thunk_statement. This is the base class for go and defer
// statements.
// Constructor.
Thunk_statement::Thunk_statement(Statement_classification classification,
Call_expression* call,
Location location)
: Statement(classification, location),
call_(call), struct_type_(NULL)
{
}
// Return whether this is a simple statement which does not require a
// thunk.
bool
Thunk_statement::is_simple(Function_type* fntype) const
{
// We need a thunk to call a method, or to pass a variable number of
// arguments.
if (fntype->is_method() || fntype->is_varargs())
return false;
// A defer statement requires a thunk to set up for whether the
// function can call recover.
if (this->classification() == STATEMENT_DEFER)
return false;
// We can only permit a single parameter of pointer type.
const Typed_identifier_list* parameters = fntype->parameters();
if (parameters != NULL
&& (parameters->size() > 1
|| (parameters->size() == 1
&& parameters->begin()->type()->points_to() == NULL)))
return false;
// If the function returns multiple values, or returns a type other
// than integer, floating point, or pointer, then it may get a
// hidden first parameter, in which case we need the more
// complicated approach. This is true even though we are going to
// ignore the return value.
const Typed_identifier_list* results = fntype->results();
if (results != NULL
&& (results->size() > 1
|| (results->size() == 1
&& !results->begin()->type()->is_basic_type()
&& results->begin()->type()->points_to() == NULL)))
return false;
// If this calls something that is not a simple function, then we
// need a thunk.
Expression* fn = this->call_->call_expression()->fn();
if (fn->func_expression() == NULL)
return false;
// If the function uses a closure, then we need a thunk. FIXME: We
// could accept a zero argument function with a closure.
if (fn->func_expression()->closure() != NULL)
return false;
return true;
}
// Traverse a thunk statement.
int
Thunk_statement::do_traverse(Traverse* traverse)
{
return this->traverse_expression(traverse, &this->call_);
}
// We implement traverse_assignment for a thunk statement because it
// effectively copies the function call.
bool
Thunk_statement::do_traverse_assignments(Traverse_assignments* tassign)
{
Expression* fn = this->call_->call_expression()->fn();
Expression* fn2 = fn;
tassign->value(&fn2, true, false);
return true;
}
// Determine types in a thunk statement.
void
Thunk_statement::do_determine_types()
{
this->call_->determine_type_no_context();
// Now that we know the types of the call, build the struct used to
// pass parameters.
Call_expression* ce = this->call_->call_expression();
if (ce == NULL)
return;
Function_type* fntype = ce->get_function_type();
if (fntype != NULL && !this->is_simple(fntype))
this->struct_type_ = this->build_struct(fntype);
}
// Check types in a thunk statement.
void
Thunk_statement::do_check_types(Gogo*)
{
if (!this->call_->discarding_value())
return;
Call_expression* ce = this->call_->call_expression();
if (ce == NULL)
{
if (!this->call_->is_error_expression())
this->report_error("expected call expression");
return;
}
}
// The Traverse class used to find and simplify thunk statements.
class Simplify_thunk_traverse : public Traverse
{
public:
Simplify_thunk_traverse(Gogo* gogo)
: Traverse(traverse_functions | traverse_blocks),
gogo_(gogo), function_(NULL)
{ }
int
function(Named_object*);
int
block(Block*);
private:
// General IR.
Gogo* gogo_;
// The function we are traversing.
Named_object* function_;
};
// Keep track of the current function while looking for thunks.
int
Simplify_thunk_traverse::function(Named_object* no)
{
go_assert(this->function_ == NULL);
this->function_ = no;
int t = no->func_value()->traverse(this);
this->function_ = NULL;
if (t == TRAVERSE_EXIT)
return t;
return TRAVERSE_SKIP_COMPONENTS;
}
// Look for thunks in a block.
int
Simplify_thunk_traverse::block(Block* b)
{
// The parser ensures that thunk statements always appear at the end
// of a block.
if (b->statements()->size() < 1)
return TRAVERSE_CONTINUE;
Thunk_statement* stat = b->statements()->back()->thunk_statement();
if (stat == NULL)
return TRAVERSE_CONTINUE;
if (stat->simplify_statement(this->gogo_, this->function_, b))
return TRAVERSE_SKIP_COMPONENTS;
return TRAVERSE_CONTINUE;
}
// Simplify all thunk statements.
void
Gogo::simplify_thunk_statements()
{
Simplify_thunk_traverse thunk_traverse(this);
this->traverse(&thunk_traverse);
}
// Return true if the thunk function is a constant, which means that
// it does not need to be passed to the thunk routine.
bool
Thunk_statement::is_constant_function() const
{
Call_expression* ce = this->call_->call_expression();
Function_type* fntype = ce->get_function_type();
if (fntype == NULL)
{
go_assert(saw_errors());
return false;
}
if (fntype->is_builtin())
return true;
Expression* fn = ce->fn();
if (fn->func_expression() != NULL)
return fn->func_expression()->closure() == NULL;
if (fn->interface_field_reference_expression() != NULL)
return true;
return false;
}
// Simplify complex thunk statements into simple ones. A complicated
// thunk statement is one which takes anything other than zero
// parameters or a single pointer parameter. We rewrite it into code
// which allocates a struct, stores the parameter values into the
// struct, and does a simple go or defer statement which passes the
// struct to a thunk. The thunk does the real call.
bool
Thunk_statement::simplify_statement(Gogo* gogo, Named_object* function,
Block* block)
{
if (this->classification() == STATEMENT_ERROR)
return false;
if (this->call_->is_error_expression())
return false;
if (this->classification() == STATEMENT_DEFER)
{
// Make sure that the defer stack exists for the function. We
// will use when converting this statement to the backend
// representation, but we want it to exist when we start
// converting the function.
function->func_value()->defer_stack(this->location());
}
Call_expression* ce = this->call_->call_expression();
Function_type* fntype = ce->get_function_type();
if (fntype == NULL)
{
go_assert(saw_errors());
this->set_is_error();
return false;
}
if (this->is_simple(fntype))
return false;
Expression* fn = ce->fn();
Interface_field_reference_expression* interface_method =
fn->interface_field_reference_expression();
Location location = this->location();
bool is_constant_function = this->is_constant_function();
Temporary_statement* fn_temp = NULL;
if (!is_constant_function)
{
fn_temp = Statement::make_temporary(NULL, fn, location);
block->insert_statement_before(block->statements()->size() - 1, fn_temp);
fn = Expression::make_temporary_reference(fn_temp, location);
}
std::string thunk_name = gogo->thunk_name();
// Build the thunk.
this->build_thunk(gogo, thunk_name);
// Generate code to call the thunk.
// Get the values to store into the struct which is the single
// argument to the thunk.
Expression_list* vals = new Expression_list();
if (!is_constant_function)
vals->push_back(fn);
if (interface_method != NULL)
vals->push_back(interface_method->expr());
if (ce->args() != NULL)
{
for (Expression_list::const_iterator p = ce->args()->begin();
p != ce->args()->end();
++p)
{
if ((*p)->is_constant())
continue;
vals->push_back(*p);
}
}
// Build the struct.
Expression* constructor =
Expression::make_struct_composite_literal(this->struct_type_, vals,
location);
// Allocate the initialized struct on the heap.
constructor = Expression::make_heap_expression(constructor, location);
if ((Node::make_node(this)->encoding() & ESCAPE_MASK) == Node::ESCAPE_NONE)
constructor->heap_expression()->set_allocate_on_stack();
// Throw an error if the function is nil. This is so that for `go
// nil` we get a backtrace from the go statement, rather than a
// useless backtrace from the brand new goroutine.
Expression* param = constructor;
if (!is_constant_function)
{
fn = Expression::make_temporary_reference(fn_temp, location);
Expression* nil = Expression::make_nil(location);
Expression* isnil = Expression::make_binary(OPERATOR_EQEQ, fn, nil,
location);
Expression* crash = gogo->runtime_error(RUNTIME_ERROR_GO_NIL, location);
crash = Expression::make_conditional(isnil, crash,
Expression::make_nil(location),
location);
param = Expression::make_compound(crash, constructor, location);
}
// Look up the thunk.
Named_object* named_thunk = gogo->lookup(thunk_name, NULL);
go_assert(named_thunk != NULL && named_thunk->is_function());
// Build the call.
Expression* func = Expression::make_func_reference(named_thunk, NULL,
location);
Expression_list* params = new Expression_list();
params->push_back(param);
Call_expression* call = Expression::make_call(func, params, false, location);
// Build the simple go or defer statement.
Statement* s;
if (this->classification() == STATEMENT_GO)
s = Statement::make_go_statement(call, location);
else if (this->classification() == STATEMENT_DEFER)
{
s = Statement::make_defer_statement(call, location);
if ((Node::make_node(this)->encoding() & ESCAPE_MASK) == Node::ESCAPE_NONE)
s->defer_statement()->set_on_stack();
}
else
go_unreachable();
// The current block should end with the go statement.
go_assert(block->statements()->size() >= 1);
go_assert(block->statements()->back() == this);
block->replace_statement(block->statements()->size() - 1, s);
// We already ran the determine_types pass, so we need to run it now
// for the new statement.
s->determine_types();
// Sanity check.
gogo->check_types_in_block(block);
// Return true to tell the block not to keep looking at statements.
return true;
}
// Set the name to use for thunk parameter N.
void
Thunk_statement::thunk_field_param(int n, char* buf, size_t buflen)
{
snprintf(buf, buflen, "a%d", n);
}
// Build a new struct type to hold the parameters for a complicated
// thunk statement. FNTYPE is the type of the function call.
Struct_type*
Thunk_statement::build_struct(Function_type* fntype)
{
Location location = this->location();
Struct_field_list* fields = new Struct_field_list();
Call_expression* ce = this->call_->call_expression();
Expression* fn = ce->fn();
if (!this->is_constant_function())
{
// The function to call.
fields->push_back(Struct_field(Typed_identifier("fn", fntype,
location)));
}
// If this thunk statement calls a method on an interface, we pass
// the interface object to the thunk.
Interface_field_reference_expression* interface_method =
fn->interface_field_reference_expression();
if (interface_method != NULL)
{
Typed_identifier tid("object", interface_method->expr()->type(),
location);
fields->push_back(Struct_field(tid));
}
// The predeclared recover function has no argument. However, we
// add an argument when building recover thunks. Handle that here.
if (ce->is_recover_call())
{
fields->push_back(Struct_field(Typed_identifier("can_recover",
Type::lookup_bool_type(),
location)));
}
const Expression_list* args = ce->args();
if (args != NULL)
{
int i = 0;
for (Expression_list::const_iterator p = args->begin();
p != args->end();
++p, ++i)
{
if ((*p)->is_constant())
continue;
char buf[50];
this->thunk_field_param(i, buf, sizeof buf);
fields->push_back(Struct_field(Typed_identifier(buf, (*p)->type(),
location)));
}
}
Struct_type *st = Type::make_struct_type(fields, location);
st->set_is_struct_incomparable();
return st;
}
// Build the thunk we are going to call. This is a brand new, albeit
// artificial, function.
void
Thunk_statement::build_thunk(Gogo* gogo, const std::string& thunk_name)
{
Location location = this->location();
Call_expression* ce = this->call_->call_expression();
bool may_call_recover = false;
if (this->classification() == STATEMENT_DEFER)
{
Func_expression* fn = ce->fn()->func_expression();
if (fn == NULL)
may_call_recover = true;
else
{
const Named_object* no = fn->named_object();
if (!no->is_function())
may_call_recover = true;
else
may_call_recover = no->func_value()->calls_recover();