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// expressions.cc -- Go frontend expression handling.
// 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 <gmp.h>
#ifndef ENABLE_BUILD_WITH_CXX
extern "C"
{
#endif
#include "toplev.h"
#include "intl.h"
#include "tree.h"
#include "gimple.h"
#include "tree-iterator.h"
#include "convert.h"
#include "real.h"
#include "realmpfr.h"
#ifndef ENABLE_BUILD_WITH_CXX
}
#endif
#include "go-c.h"
#include "gogo.h"
#include "types.h"
#include "export.h"
#include "import.h"
#include "statements.h"
#include "lex.h"
#include "expressions.h"
// Class Expression.
Expression::Expression(Expression_classification classification,
source_location location)
: classification_(classification), location_(location)
{
}
Expression::~Expression()
{
}
// If this expression has a constant integer value, return it.
bool
Expression::integer_constant_value(bool iota_is_constant, mpz_t val,
Type** ptype) const
{
*ptype = NULL;
return this->do_integer_constant_value(iota_is_constant, val, ptype);
}
// If this expression has a constant floating point value, return it.
bool
Expression::float_constant_value(mpfr_t val, Type** ptype) const
{
*ptype = NULL;
if (this->do_float_constant_value(val, ptype))
return true;
mpz_t ival;
mpz_init(ival);
Type* t;
bool ret;
if (!this->do_integer_constant_value(false, ival, &t))
ret = false;
else
{
mpfr_set_z(val, ival, GMP_RNDN);
ret = true;
}
mpz_clear(ival);
return ret;
}
// If this expression has a constant complex value, return it.
bool
Expression::complex_constant_value(mpfr_t real, mpfr_t imag,
Type** ptype) const
{
*ptype = NULL;
if (this->do_complex_constant_value(real, imag, ptype))
return true;
Type *t;
if (this->float_constant_value(real, &t))
{
mpfr_set_ui(imag, 0, GMP_RNDN);
return true;
}
return false;
}
// Traverse the expressions.
int
Expression::traverse(Expression** pexpr, Traverse* traverse)
{
Expression* expr = *pexpr;
if ((traverse->traverse_mask() & Traverse::traverse_expressions) != 0)
{
int t = traverse->expression(pexpr);
if (t == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
else if (t == TRAVERSE_SKIP_COMPONENTS)
return TRAVERSE_CONTINUE;
}
return expr->do_traverse(traverse);
}
// Traverse subexpressions of this expression.
int
Expression::traverse_subexpressions(Traverse* traverse)
{
return this->do_traverse(traverse);
}
// Default implementation for do_traverse for child classes.
int
Expression::do_traverse(Traverse*)
{
return TRAVERSE_CONTINUE;
}
// This virtual function is called by the parser if the value of this
// expression is being discarded. By default, we warn. Expressions
// with side effects override.
void
Expression::do_discarding_value()
{
this->warn_about_unused_value();
}
// This virtual function is called to export expressions. This will
// only be used by expressions which may be constant.
void
Expression::do_export(Export*) const
{
gcc_unreachable();
}
// Warn that the value of the expression is not used.
void
Expression::warn_about_unused_value()
{
warning_at(this->location(), OPT_Wunused_value, "value computed is not used");
}
// Note that this expression is an error. This is called by children
// when they discover an error.
void
Expression::set_is_error()
{
this->classification_ = EXPRESSION_ERROR;
}
// For children to call to report an error conveniently.
void
Expression::report_error(const char* msg)
{
error_at(this->location_, "%s", msg);
this->set_is_error();
}
// Set types of variables and constants. This is implemented by the
// child class.
void
Expression::determine_type(const Type_context* context)
{
this->do_determine_type(context);
}
// Set types when there is no context.
void
Expression::determine_type_no_context()
{
Type_context context;
this->do_determine_type(&context);
}
// Return a tree handling any conversions which must be done during
// assignment.
tree
Expression::convert_for_assignment(Translate_context* context, Type* lhs_type,
Type* rhs_type, tree rhs_tree,
source_location location)
{
if (lhs_type == rhs_type)
return rhs_tree;
if (lhs_type->is_error_type() || rhs_type->is_error_type())
return error_mark_node;
if (lhs_type->is_undefined() || rhs_type->is_undefined())
{
// Make sure we report the error.
lhs_type->base();
rhs_type->base();
return error_mark_node;
}
if (rhs_tree == error_mark_node || TREE_TYPE(rhs_tree) == error_mark_node)
return error_mark_node;
Gogo* gogo = context->gogo();
tree lhs_type_tree = lhs_type->get_tree(gogo);
if (lhs_type_tree == error_mark_node)
return error_mark_node;
if (lhs_type->interface_type() != NULL)
{
if (rhs_type->interface_type() == NULL)
return Expression::convert_type_to_interface(context, lhs_type,
rhs_type, rhs_tree,
location);
else
return Expression::convert_interface_to_interface(context, lhs_type,
rhs_type, rhs_tree,
false, location);
}
else if (rhs_type->interface_type() != NULL)
return Expression::convert_interface_to_type(context, lhs_type, rhs_type,
rhs_tree, location);
else if (lhs_type->is_open_array_type()
&& rhs_type->is_nil_type())
{
// Assigning nil to an open array.
gcc_assert(TREE_CODE(lhs_type_tree) == RECORD_TYPE);
VEC(constructor_elt,gc)* init = VEC_alloc(constructor_elt, gc, 3);
constructor_elt* elt = VEC_quick_push(constructor_elt, init, NULL);
tree field = TYPE_FIELDS(lhs_type_tree);
gcc_assert(strcmp(IDENTIFIER_POINTER(DECL_NAME(field)),
"__values") == 0);
elt->index = field;
elt->value = fold_convert(TREE_TYPE(field), null_pointer_node);
elt = VEC_quick_push(constructor_elt, init, NULL);
field = DECL_CHAIN(field);
gcc_assert(strcmp(IDENTIFIER_POINTER(DECL_NAME(field)),
"__count") == 0);
elt->index = field;
elt->value = fold_convert(TREE_TYPE(field), integer_zero_node);
elt = VEC_quick_push(constructor_elt, init, NULL);
field = DECL_CHAIN(field);
gcc_assert(strcmp(IDENTIFIER_POINTER(DECL_NAME(field)),
"__capacity") == 0);
elt->index = field;
elt->value = fold_convert(TREE_TYPE(field), integer_zero_node);
tree val = build_constructor(lhs_type_tree, init);
TREE_CONSTANT(val) = 1;
return val;
}
else if (rhs_type->is_nil_type())
{
// The left hand side should be a pointer type at the tree
// level.
gcc_assert(POINTER_TYPE_P(lhs_type_tree));
return fold_convert(lhs_type_tree, null_pointer_node);
}
else if (lhs_type_tree == TREE_TYPE(rhs_tree))
{
// No conversion is needed.
return rhs_tree;
}
else if (POINTER_TYPE_P(lhs_type_tree)
|| INTEGRAL_TYPE_P(lhs_type_tree)
|| SCALAR_FLOAT_TYPE_P(lhs_type_tree)
|| COMPLEX_FLOAT_TYPE_P(lhs_type_tree))
return fold_convert_loc(location, lhs_type_tree, rhs_tree);
else if (TREE_CODE(lhs_type_tree) == RECORD_TYPE
&& TREE_CODE(TREE_TYPE(rhs_tree)) == RECORD_TYPE)
{
// This conversion must be permitted by Go, or we wouldn't have
// gotten here.
gcc_assert(int_size_in_bytes(lhs_type_tree)
== int_size_in_bytes(TREE_TYPE(rhs_tree)));
return fold_build1_loc(location, VIEW_CONVERT_EXPR, lhs_type_tree,
rhs_tree);
}
else
{
gcc_assert(useless_type_conversion_p(lhs_type_tree, TREE_TYPE(rhs_tree)));
return rhs_tree;
}
}
// Return a tree for a conversion from a non-interface type to an
// interface type.
tree
Expression::convert_type_to_interface(Translate_context* context,
Type* lhs_type, Type* rhs_type,
tree rhs_tree, source_location location)
{
Gogo* gogo = context->gogo();
Interface_type* lhs_interface_type = lhs_type->interface_type();
bool lhs_is_empty = lhs_interface_type->is_empty();
// Since RHS_TYPE is a static type, we can create the interface
// method table at compile time.
// When setting an interface to nil, we just set both fields to
// NULL.
if (rhs_type->is_nil_type())
return lhs_type->get_init_tree(gogo, false);
// This should have been checked already.
gcc_assert(lhs_interface_type->implements_interface(rhs_type, NULL));
tree lhs_type_tree = lhs_type->get_tree(gogo);
if (lhs_type_tree == error_mark_node)
return error_mark_node;
// An interface is a tuple. If LHS_TYPE is an empty interface type,
// then the first field is the type descriptor for RHS_TYPE.
// Otherwise it is the interface method table for RHS_TYPE.
tree first_field_value;
if (lhs_is_empty)
first_field_value = rhs_type->type_descriptor_pointer(gogo);
else
{
// Build the interface method table for this interface and this
// object type: a list of function pointers for each interface
// method.
Named_type* rhs_named_type = rhs_type->named_type();
bool is_pointer = false;
if (rhs_named_type == NULL)
{
rhs_named_type = rhs_type->deref()->named_type();
is_pointer = true;
}
tree method_table;
if (rhs_named_type == NULL)
method_table = null_pointer_node;
else
method_table =
rhs_named_type->interface_method_table(gogo, lhs_interface_type,
is_pointer);
first_field_value = fold_convert_loc(location, const_ptr_type_node,
method_table);
}
// Start building a constructor for the value we will return.
VEC(constructor_elt,gc)* init = VEC_alloc(constructor_elt, gc, 2);
constructor_elt* elt = VEC_quick_push(constructor_elt, init, NULL);
tree field = TYPE_FIELDS(lhs_type_tree);
gcc_assert(strcmp(IDENTIFIER_POINTER(DECL_NAME(field)),
(lhs_is_empty ? "__type_descriptor" : "__methods")) == 0);
elt->index = field;
elt->value = fold_convert_loc(location, TREE_TYPE(field), first_field_value);
elt = VEC_quick_push(constructor_elt, init, NULL);
field = DECL_CHAIN(field);
gcc_assert(strcmp(IDENTIFIER_POINTER(DECL_NAME(field)), "__object") == 0);
elt->index = field;
if (rhs_type->points_to() != NULL)
{
// We are assigning a pointer to the interface; the interface
// holds the pointer itself.
elt->value = rhs_tree;
return build_constructor(lhs_type_tree, init);
}
// We are assigning a non-pointer value to the interface; the
// interface gets a copy of the value in the heap.
tree object_size = TYPE_SIZE_UNIT(TREE_TYPE(rhs_tree));
tree space = gogo->allocate_memory(rhs_type, object_size, location);
space = fold_convert_loc(location, build_pointer_type(TREE_TYPE(rhs_tree)),
space);
space = save_expr(space);
tree ref = build_fold_indirect_ref_loc(location, space);
TREE_THIS_NOTRAP(ref) = 1;
tree set = fold_build2_loc(location, MODIFY_EXPR, void_type_node,
ref, rhs_tree);
elt->value = fold_convert_loc(location, TREE_TYPE(field), space);
return build2(COMPOUND_EXPR, lhs_type_tree, set,
build_constructor(lhs_type_tree, init));
}
// Return a tree for the type descriptor of RHS_TREE, which has
// interface type RHS_TYPE. If RHS_TREE is nil the result will be
// NULL.
tree
Expression::get_interface_type_descriptor(Translate_context*,
Type* rhs_type, tree rhs_tree,
source_location location)
{
tree rhs_type_tree = TREE_TYPE(rhs_tree);
gcc_assert(TREE_CODE(rhs_type_tree) == RECORD_TYPE);
tree rhs_field = TYPE_FIELDS(rhs_type_tree);
tree v = build3(COMPONENT_REF, TREE_TYPE(rhs_field), rhs_tree, rhs_field,
NULL_TREE);
if (rhs_type->interface_type()->is_empty())
{
gcc_assert(strcmp(IDENTIFIER_POINTER(DECL_NAME(rhs_field)),
"__type_descriptor") == 0);
return v;
}
gcc_assert(strcmp(IDENTIFIER_POINTER(DECL_NAME(rhs_field)), "__methods")
== 0);
gcc_assert(POINTER_TYPE_P(TREE_TYPE(v)));
v = save_expr(v);
tree v1 = build_fold_indirect_ref_loc(location, v);
gcc_assert(TREE_CODE(TREE_TYPE(v1)) == RECORD_TYPE);
tree f = TYPE_FIELDS(TREE_TYPE(v1));
gcc_assert(strcmp(IDENTIFIER_POINTER(DECL_NAME(f)), "__type_descriptor")
== 0);
v1 = build3(COMPONENT_REF, TREE_TYPE(f), v1, f, NULL_TREE);
tree eq = fold_build2_loc(location, EQ_EXPR, boolean_type_node, v,
fold_convert_loc(location, TREE_TYPE(v),
null_pointer_node));
tree n = fold_convert_loc(location, TREE_TYPE(v1), null_pointer_node);
return fold_build3_loc(location, COND_EXPR, TREE_TYPE(v1),
eq, n, v1);
}
// Return a tree for the conversion of an interface type to an
// interface type.
tree
Expression::convert_interface_to_interface(Translate_context* context,
Type *lhs_type, Type *rhs_type,
tree rhs_tree, bool for_type_guard,
source_location location)
{
Gogo* gogo = context->gogo();
Interface_type* lhs_interface_type = lhs_type->interface_type();
bool lhs_is_empty = lhs_interface_type->is_empty();
tree lhs_type_tree = lhs_type->get_tree(gogo);
if (lhs_type_tree == error_mark_node)
return error_mark_node;
// In the general case this requires runtime examination of the type
// method table to match it up with the interface methods.
// FIXME: If all of the methods in the right hand side interface
// also appear in the left hand side interface, then we don't need
// to do a runtime check, although we still need to build a new
// method table.
// Get the type descriptor for the right hand side. This will be
// NULL for a nil interface.
if (!DECL_P(rhs_tree))
rhs_tree = save_expr(rhs_tree);
tree rhs_type_descriptor =
Expression::get_interface_type_descriptor(context, rhs_type, rhs_tree,
location);
// The result is going to be a two element constructor.
VEC(constructor_elt,gc)* init = VEC_alloc(constructor_elt, gc, 2);
constructor_elt* elt = VEC_quick_push(constructor_elt, init, NULL);
tree field = TYPE_FIELDS(lhs_type_tree);
elt->index = field;
if (for_type_guard)
{
// A type assertion fails when converting a nil interface.
tree lhs_type_descriptor = lhs_type->type_descriptor_pointer(gogo);
static tree assert_interface_decl;
tree call = Gogo::call_builtin(&assert_interface_decl,
location,
"__go_assert_interface",
2,
ptr_type_node,
TREE_TYPE(lhs_type_descriptor),
lhs_type_descriptor,
TREE_TYPE(rhs_type_descriptor),
rhs_type_descriptor);
if (call == error_mark_node)
return error_mark_node;
// This will panic if the interface conversion fails.
TREE_NOTHROW(assert_interface_decl) = 0;
elt->value = fold_convert_loc(location, TREE_TYPE(field), call);
}
else if (lhs_is_empty)
{
// A convertion to an empty interface always succeeds, and the
// first field is just the type descriptor of the object.
gcc_assert(strcmp(IDENTIFIER_POINTER(DECL_NAME(field)),
"__type_descriptor") == 0);
gcc_assert(TREE_TYPE(field) == TREE_TYPE(rhs_type_descriptor));
elt->value = rhs_type_descriptor;
}
else
{
// A conversion to a non-empty interface may fail, but unlike a
// type assertion converting nil will always succeed.
gcc_assert(strcmp(IDENTIFIER_POINTER(DECL_NAME(field)), "__methods")
== 0);
tree lhs_type_descriptor = lhs_type->type_descriptor_pointer(gogo);
static tree convert_interface_decl;
tree call = Gogo::call_builtin(&convert_interface_decl,
location,
"__go_convert_interface",
2,
ptr_type_node,
TREE_TYPE(lhs_type_descriptor),
lhs_type_descriptor,
TREE_TYPE(rhs_type_descriptor),
rhs_type_descriptor);
if (call == error_mark_node)
return error_mark_node;
// This will panic if the interface conversion fails.
TREE_NOTHROW(convert_interface_decl) = 0;
elt->value = fold_convert_loc(location, TREE_TYPE(field), call);
}
// The second field is simply the object pointer.
elt = VEC_quick_push(constructor_elt, init, NULL);
field = DECL_CHAIN(field);
gcc_assert(strcmp(IDENTIFIER_POINTER(DECL_NAME(field)), "__object") == 0);
elt->index = field;
tree rhs_type_tree = TREE_TYPE(rhs_tree);
gcc_assert(TREE_CODE(rhs_type_tree) == RECORD_TYPE);
tree rhs_field = DECL_CHAIN(TYPE_FIELDS(rhs_type_tree));
gcc_assert(strcmp(IDENTIFIER_POINTER(DECL_NAME(rhs_field)), "__object") == 0);
elt->value = build3(COMPONENT_REF, TREE_TYPE(rhs_field), rhs_tree, rhs_field,
NULL_TREE);
return build_constructor(lhs_type_tree, init);
}
// Return a tree for the conversion of an interface type to a
// non-interface type.
tree
Expression::convert_interface_to_type(Translate_context* context,
Type *lhs_type, Type* rhs_type,
tree rhs_tree, source_location location)
{
Gogo* gogo = context->gogo();
tree rhs_type_tree = TREE_TYPE(rhs_tree);
tree lhs_type_tree = lhs_type->get_tree(gogo);
if (lhs_type_tree == error_mark_node)
return error_mark_node;
// Call a function to check that the type is valid. The function
// will panic with an appropriate runtime type error if the type is
// not valid.
tree lhs_type_descriptor = lhs_type->type_descriptor_pointer(gogo);
if (!DECL_P(rhs_tree))
rhs_tree = save_expr(rhs_tree);
tree rhs_type_descriptor =
Expression::get_interface_type_descriptor(context, rhs_type, rhs_tree,
location);
tree rhs_inter_descriptor = rhs_type->type_descriptor_pointer(gogo);
static tree check_interface_type_decl;
tree call = Gogo::call_builtin(&check_interface_type_decl,
location,
"__go_check_interface_type",
3,
void_type_node,
TREE_TYPE(lhs_type_descriptor),
lhs_type_descriptor,
TREE_TYPE(rhs_type_descriptor),
rhs_type_descriptor,
TREE_TYPE(rhs_inter_descriptor),
rhs_inter_descriptor);
if (call == error_mark_node)
return error_mark_node;
// This call will panic if the conversion is invalid.
TREE_NOTHROW(check_interface_type_decl) = 0;
// If the call succeeds, pull out the value.
gcc_assert(TREE_CODE(rhs_type_tree) == RECORD_TYPE);
tree rhs_field = DECL_CHAIN(TYPE_FIELDS(rhs_type_tree));
gcc_assert(strcmp(IDENTIFIER_POINTER(DECL_NAME(rhs_field)), "__object") == 0);
tree val = build3(COMPONENT_REF, TREE_TYPE(rhs_field), rhs_tree, rhs_field,
NULL_TREE);
// If the value is a pointer, then it is the value we want.
// Otherwise it points to the value.
if (lhs_type->points_to() == NULL)
{
val = fold_convert_loc(location, build_pointer_type(lhs_type_tree), val);
val = build_fold_indirect_ref_loc(location, val);
}
return build2(COMPOUND_EXPR, lhs_type_tree, call,
fold_convert_loc(location, lhs_type_tree, val));
}
// Convert an expression to a tree. This is implemented by the child
// class. Not that it is not in general safe to call this multiple
// times for a single expression, but that we don't catch such errors.
tree
Expression::get_tree(Translate_context* context)
{
// The child may have marked this expression as having an error.
if (this->classification_ == EXPRESSION_ERROR)
return error_mark_node;
return this->do_get_tree(context);
}
// Return a tree for VAL in TYPE.
tree
Expression::integer_constant_tree(mpz_t val, tree type)
{
if (type == error_mark_node)
return error_mark_node;
else if (TREE_CODE(type) == INTEGER_TYPE)
return double_int_to_tree(type,
mpz_get_double_int(type, val, true));
else if (TREE_CODE(type) == REAL_TYPE)
{
mpfr_t fval;
mpfr_init_set_z(fval, val, GMP_RNDN);
tree ret = Expression::float_constant_tree(fval, type);
mpfr_clear(fval);
return ret;
}
else if (TREE_CODE(type) == COMPLEX_TYPE)
{
mpfr_t fval;
mpfr_init_set_z(fval, val, GMP_RNDN);
tree real = Expression::float_constant_tree(fval, TREE_TYPE(type));
mpfr_clear(fval);
tree imag = build_real_from_int_cst(TREE_TYPE(type),
integer_zero_node);
return build_complex(type, real, imag);
}
else
gcc_unreachable();
}
// Return a tree for VAL in TYPE.
tree
Expression::float_constant_tree(mpfr_t val, tree type)
{
if (type == error_mark_node)
return error_mark_node;
else if (TREE_CODE(type) == INTEGER_TYPE)
{
mpz_t ival;
mpz_init(ival);
mpfr_get_z(ival, val, GMP_RNDN);
tree ret = Expression::integer_constant_tree(ival, type);
mpz_clear(ival);
return ret;
}
else if (TREE_CODE(type) == REAL_TYPE)
{
REAL_VALUE_TYPE r1;
real_from_mpfr(&r1, val, type, GMP_RNDN);
REAL_VALUE_TYPE r2;
real_convert(&r2, TYPE_MODE(type), &r1);
return build_real(type, r2);
}
else if (TREE_CODE(type) == COMPLEX_TYPE)
{
REAL_VALUE_TYPE r1;
real_from_mpfr(&r1, val, TREE_TYPE(type), GMP_RNDN);
REAL_VALUE_TYPE r2;
real_convert(&r2, TYPE_MODE(TREE_TYPE(type)), &r1);
tree imag = build_real_from_int_cst(TREE_TYPE(type),
integer_zero_node);
return build_complex(type, build_real(TREE_TYPE(type), r2), imag);
}
else
gcc_unreachable();
}
// Return a tree for REAL/IMAG in TYPE.
tree
Expression::complex_constant_tree(mpfr_t real, mpfr_t imag, tree type)
{
if (TREE_CODE(type) == COMPLEX_TYPE)
{
REAL_VALUE_TYPE r1;
real_from_mpfr(&r1, real, TREE_TYPE(type), GMP_RNDN);
REAL_VALUE_TYPE r2;
real_convert(&r2, TYPE_MODE(TREE_TYPE(type)), &r1);
REAL_VALUE_TYPE r3;
real_from_mpfr(&r3, imag, TREE_TYPE(type), GMP_RNDN);
REAL_VALUE_TYPE r4;
real_convert(&r4, TYPE_MODE(TREE_TYPE(type)), &r3);
return build_complex(type, build_real(TREE_TYPE(type), r2),
build_real(TREE_TYPE(type), r4));
}
else
gcc_unreachable();
}
// Return a tree which evaluates to true if VAL, of arbitrary integer
// type, is negative or is more than the maximum value of BOUND_TYPE.
// If SOFAR is not NULL, it is or'red into the result. The return
// value may be NULL if SOFAR is NULL.
tree
Expression::check_bounds(tree val, tree bound_type, tree sofar,
source_location loc)
{
tree val_type = TREE_TYPE(val);
tree ret = NULL_TREE;
if (!TYPE_UNSIGNED(val_type))
{
ret = fold_build2_loc(loc, LT_EXPR, boolean_type_node, val,
build_int_cst(val_type, 0));
if (ret == boolean_false_node)
ret = NULL_TREE;
}
if ((TYPE_UNSIGNED(val_type) && !TYPE_UNSIGNED(bound_type))
|| TYPE_SIZE(val_type) > TYPE_SIZE(bound_type))
{
tree max = TYPE_MAX_VALUE(bound_type);
tree big = fold_build2_loc(loc, GT_EXPR, boolean_type_node, val,
fold_convert_loc(loc, val_type, max));
if (big == boolean_false_node)
;
else if (ret == NULL_TREE)
ret = big;
else
ret = fold_build2_loc(loc, TRUTH_OR_EXPR, boolean_type_node,
ret, big);
}
if (ret == NULL_TREE)
return sofar;
else if (sofar == NULL_TREE)
return ret;
else
return fold_build2_loc(loc, TRUTH_OR_EXPR, boolean_type_node,
sofar, ret);
}
// Error expressions. This are used to avoid cascading errors.
class Error_expression : public Expression
{
public:
Error_expression(source_location location)
: Expression(EXPRESSION_ERROR, location)
{ }
protected:
bool
do_is_constant() const
{ return true; }
bool
do_integer_constant_value(bool, mpz_t val, Type**) const
{
mpz_set_ui(val, 0);
return true;
}
bool
do_float_constant_value(mpfr_t val, Type**) const
{
mpfr_set_ui(val, 0, GMP_RNDN);
return true;
}
bool
do_complex_constant_value(mpfr_t real, mpfr_t imag, Type**) const
{
mpfr_set_ui(real, 0, GMP_RNDN);
mpfr_set_ui(imag, 0, GMP_RNDN);
return true;
}
void
do_discarding_value()
{ }
Type*
do_type()
{ return Type::make_error_type(); }
void
do_determine_type(const Type_context*)
{ }
Expression*
do_copy()
{ return this; }
bool
do_is_addressable() const
{ return true; }
tree
do_get_tree(Translate_context*)
{ return error_mark_node; }
};
Expression*
Expression::make_error(source_location location)
{
return new Error_expression(location);
}
// An expression which is really a type. This is used during parsing.
// It is an error if these survive after lowering.
class
Type_expression : public Expression
{
public:
Type_expression(Type* type, source_location location)
: Expression(EXPRESSION_TYPE, location),
type_(type)
{ }
protected:
int
do_traverse(Traverse* traverse)
{ return Type::traverse(this->type_, traverse); }
Type*
do_type()
{ return this->type_; }
void
do_determine_type(const Type_context*)
{ }
void
do_check_types(Gogo*)
{ this->report_error(_("invalid use of type")); }
Expression*
do_copy()
{ return this; }
tree
do_get_tree(Translate_context*)
{ gcc_unreachable(); }
private:
// The type which we are representing as an expression.
Type* type_;
};
Expression*
Expression::make_type(Type* type, source_location location)
{
return new Type_expression(type, location);
}
// Class Parser_expression.
Type*
Parser_expression::do_type()
{
// We should never really ask for the type of a Parser_expression.
// However, it can happen, at least when we have an invalid const
// whose initializer refers to the const itself. In that case we
// may ask for the type when lowering the const itself.
gcc_assert(saw_errors());
return Type::make_error_type();
}
// Class Var_expression.
// Lower a variable expression. Here we just make sure that the
// initialization expression of the variable has been lowered. This
// ensures that we will be able to determine the type of the variable
// if necessary.
Expression*
Var_expression::do_lower(Gogo* gogo, Named_object* function, int)
{
if (this->variable_->is_variable())
{
Variable* var = this->variable_->var_value();
// This is either a local variable or a global variable. A
// reference to a variable which is local to an enclosing
// function will be a reference to a field in a closure.
if (var->is_global())
function = NULL;
var->lower_init_expression(gogo, function);
}
return this;
}
// Return the name of the variable.
const std::string&
Var_expression::name() const
{
return this->variable_->name();
}
// Return the type of a reference to a variable.
Type*
Var_expression::do_type()
{
if (this->variable_->is_variable())
return this->variable_->var_value()->type();
else if (this->variable_->is_result_variable())
return this->variable_->result_var_value()->type();
else
gcc_unreachable();
}
// Something takes the address of this variable. This means that we
// may want to move the variable onto the heap.
void
Var_expression::do_address_taken(bool escapes)
{
if (!escapes)
;
else if (this->variable_->is_variable())
this->variable_->var_value()->set_address_taken();
else if (this->variable_->is_result_variable())
this->variable_->result_var_value()->set_address_taken();
else
gcc_unreachable();
}
// Get the tree for a reference to a variable.
tree
Var_expression::do_get_tree(Translate_context* context)
{
return this->variable_->get_tree(context->gogo(), context->function());
}
// Make a reference to a variable in an expression.
Expression*
Expression::make_var_reference(Named_object* var, source_location location)
{
if (var->is_sink())
return Expression::make_sink(location);
// FIXME: Creating a new object for each reference to a variable is
// wasteful.
return new Var_expression(var, location);
}
// Class Temporary_reference_expression.
// The type.
Type*
Temporary_reference_expression::do_type()
{
return this->statement_->type();
}
// Called if something takes the address of this temporary variable.
// We never have to move temporary variables to the heap, but we do
// need to know that they must live in the stack rather than in a
// register.
void
Temporary_reference_expression::do_address_taken(bool)
{
this->statement_->set_is_address_taken();
}
// Get a tree referring to the variable.
tree
Temporary_reference_expression::do_get_tree(Translate_context*)
{
return this->statement_->get_decl();
}
// Make a reference to a temporary variable.
Expression*
Expression::make_temporary_reference(Temporary_statement* statement,
source_location location)
{
return new Temporary_reference_expression(statement, location);
}
// A sink expression--a use of the blank identifier _.
class Sink_expression : public Expression
{
public:
Sink_expression(source_location location)
: Expression(EXPRESSION_SINK, location),
type_(NULL), var_(NULL_TREE)
{ }
protected:
void
do_discarding_value()
{ }
Type*
do_type();
void
do_determine_type(const Type_context*);
Expression*
do_copy()
{ return new Sink_expression(this->location()); }
tree
do_get_tree(Translate_context*);
private:
// The type of this sink variable.
Type* type_;
// The temporary variable we generate.
tree var_;
};
// Return the type of a sink expression.
Type*
Sink_expression::do_type()
{
if (this->type_ == NULL)
return Type::make_sink_type();
return this->type_;
}
// Determine the type of a sink expression.
void
Sink_expression::do_determine_type(const Type_context* context)
{
if (context->type != NULL)
this->type_ = context->type;
}
// Return a temporary variable for a sink expression. This will
// presumably be a write-only variable which the middle-end will drop.
tree
Sink_expression::do_get_tree(Translate_context* context)
{
if (this->var_ == NULL_TREE)
{
gcc_assert(this->type_ != NULL && !this->type_->is_sink_type());
this->var_ = create_tmp_var(this->type_->get_tree(context->gogo()),
"blank");
}
return this->var_;
}
// Make a sink expression.
Expression*
Expression::make_sink(source_location location)
{
return new Sink_expression(location);
}
// Class Func_expression.
// FIXME: Can a function expression appear in a constant expression?
// The value is unchanging. Initializing a constant to the address of
// a function seems like it could work, though there might be little
// point to it.
// Return the name of the function.
const std::string&
Func_expression::name() const
{
return this->function_->name();
}
// Traversal.
int
Func_expression::do_traverse(Traverse* traverse)
{
return (this->closure_ == NULL
? TRAVERSE_CONTINUE
: Expression::traverse(&this->closure_, traverse));
}
// Return the type of a function expression.
Type*
Func_expression::do_type()
{
if (this->function_->is_function())
return this->function_->func_value()->type();
else if (this->function_->is_function_declaration())
return this->function_->func_declaration_value()->type();
else
gcc_unreachable();
}
// Get the tree for a function expression without evaluating the
// closure.
tree
Func_expression::get_tree_without_closure(Gogo* gogo)
{
Function_type* fntype;
if (this->function_->is_function())
fntype = this->function_->func_value()->type();
else if (this->function_->is_function_declaration())
fntype = this->function_->func_declaration_value()->type();
else
gcc_unreachable();
// Builtin functions are handled specially by Call_expression. We
// can't take their address.
if (fntype->is_builtin())
{
error_at(this->location(), "invalid use of special builtin function %qs",
this->function_->name().c_str());
return error_mark_node;
}
Named_object* no = this->function_;
tree id = no->get_id(gogo);
if (id == error_mark_node)
return error_mark_node;
tree fndecl;
if (no->is_function())
fndecl = no->func_value()->get_or_make_decl(gogo, no, id);
else if (no->is_function_declaration())
fndecl = no->func_declaration_value()->get_or_make_decl(gogo, no, id);
else
gcc_unreachable();
if (fndecl == error_mark_node)
return error_mark_node;
return build_fold_addr_expr_loc(this->location(), fndecl);
}
// Get the tree for a function expression. This is used when we take
// the address of a function rather than simply calling it. If the
// function has a closure, we must use a trampoline.
tree
Func_expression::do_get_tree(Translate_context* context)
{
Gogo* gogo = context->gogo();
tree fnaddr = this->get_tree_without_closure(gogo);
if (fnaddr == error_mark_node)
return error_mark_node;
gcc_assert(TREE_CODE(fnaddr) == ADDR_EXPR
&& TREE_CODE(TREE_OPERAND(fnaddr, 0)) == FUNCTION_DECL);
TREE_ADDRESSABLE(TREE_OPERAND(fnaddr, 0)) = 1;
// For a normal non-nested function call, that is all we have to do.
if (!this->function_->is_function()
|| this->function_->func_value()->enclosing() == NULL)
{
gcc_assert(this->closure_ == NULL);
return fnaddr;
}
// For a nested function call, we have to always allocate a
// trampoline. If we don't always allocate, then closures will not
// be reliably distinct.
Expression* closure = this->closure_;
tree closure_tree;
if (closure == NULL)
closure_tree = null_pointer_node;
else
{
// Get the value of the closure. This will be a pointer to
// space allocated on the heap.
closure_tree = closure->get_tree(context);
if (closure_tree == error_mark_node)
return error_mark_node;
gcc_assert(POINTER_TYPE_P(TREE_TYPE(closure_tree)));
}
// Now we need to build some code on the heap. This code will load
// the static chain pointer with the closure and then jump to the
// body of the function. The normal gcc approach is to build the
// code on the stack. Unfortunately we can not do that, as Go
// permits us to return the function pointer.
return gogo->make_trampoline(fnaddr, closure_tree, this->location());
}
// Make a reference to a function in an expression.
Expression*
Expression::make_func_reference(Named_object* function, Expression* closure,
source_location location)
{
return new Func_expression(function, closure, location);
}
// Class Unknown_expression.
// Return the name of an unknown expression.
const std::string&
Unknown_expression::name() const
{
return this->named_object_->name();
}
// Lower a reference to an unknown name.
Expression*
Unknown_expression::do_lower(Gogo*, Named_object*, int)
{
source_location location = this->location();
Named_object* no = this->named_object_;
Named_object* real;
if (!no->is_unknown())
real = no;
else
{
real = no->unknown_value()->real_named_object();
if (real == NULL)
{
if (this->is_composite_literal_key_)
return this;
error_at(location, "reference to undefined name %qs",
this->named_object_->message_name().c_str());
return Expression::make_error(location);
}
}
switch (real->classification())
{
case Named_object::NAMED_OBJECT_CONST:
return Expression::make_const_reference(real, location);
case Named_object::NAMED_OBJECT_TYPE:
return Expression::make_type(real->type_value(), location);
case Named_object::NAMED_OBJECT_TYPE_DECLARATION:
if (this->is_composite_literal_key_)
return this;
error_at(location, "reference to undefined type %qs",
real->message_name().c_str());
return Expression::make_error(location);
case Named_object::NAMED_OBJECT_VAR:
return Expression::make_var_reference(real, location);
case Named_object::NAMED_OBJECT_FUNC:
case Named_object::NAMED_OBJECT_FUNC_DECLARATION:
return Expression::make_func_reference(real, NULL, location);
case Named_object::NAMED_OBJECT_PACKAGE:
if (this->is_composite_literal_key_)
return this;
error_at(location, "unexpected reference to package");
return Expression::make_error(location);
default:
gcc_unreachable();
}
}
// Make a reference to an unknown name.
Expression*
Expression::make_unknown_reference(Named_object* no, source_location location)
{
gcc_assert(no->resolve()->is_unknown());
return new Unknown_expression(no, location);
}
// A boolean expression.
class Boolean_expression : public Expression
{
public:
Boolean_expression(bool val, source_location location)
: Expression(EXPRESSION_BOOLEAN, location),
val_(val), type_(NULL)
{ }
static Expression*
do_import(Import*);
protected:
bool
do_is_constant() const
{ return true; }
Type*
do_type();
void
do_determine_type(const Type_context*);
Expression*
do_copy()
{ return this; }
tree
do_get_tree(Translate_context*)
{ return this->val_ ? boolean_true_node : boolean_false_node; }
void
do_export(Export* exp) const
{ exp->write_c_string(this->val_ ? "true" : "false"); }
private:
// The constant.
bool val_;
// The type as determined by context.
Type* type_;
};
// Get the type.
Type*
Boolean_expression::do_type()
{
if (this->type_ == NULL)
this->type_ = Type::make_boolean_type();
return this->type_;
}
// Set the type from the context.
void
Boolean_expression::do_determine_type(const Type_context* context)
{
if (this->type_ != NULL && !this->type_->is_abstract())
;
else if (context->type != NULL && context->type->is_boolean_type())
this->type_ = context->type;
else if (!context->may_be_abstract)
this->type_ = Type::lookup_bool_type();
}
// Import a boolean constant.
Expression*
Boolean_expression::do_import(Import* imp)
{
if (imp->peek_char() == 't')
{
imp->require_c_string("true");
return Expression::make_boolean(true, imp->location());
}
else
{
imp->require_c_string("false");
return Expression::make_boolean(false, imp->location());
}
}
// Make a boolean expression.
Expression*
Expression::make_boolean(bool val, source_location location)
{
return new Boolean_expression(val, location);
}
// Class String_expression.
// Get the type.
Type*
String_expression::do_type()
{
if (this->type_ == NULL)
this->type_ = Type::make_string_type();
return this->type_;
}
// Set the type from the context.
void
String_expression::do_determine_type(const Type_context* context)
{
if (this->type_ != NULL && !this->type_->is_abstract())
;
else if (context->type != NULL && context->type->is_string_type())
this->type_ = context->type;
else if (!context->may_be_abstract)
this->type_ = Type::lookup_string_type();
}
// Build a string constant.
tree
String_expression::do_get_tree(Translate_context* context)
{
return context->gogo()->go_string_constant_tree(this->val_);
}
// Export a string expression.
void
String_expression::do_export(Export* exp) const
{
std::string s;
s.reserve(this->val_.length() * 4 + 2);
s += '"';
for (std::string::const_iterator p = this->val_.begin();
p != this->val_.end();
++p)
{
if (*p == '\\' || *p == '"')
{
s += '\\';
s += *p;
}
else if (*p >= 0x20 && *p < 0x7f)
s += *p;
else if (*p == '\n')
s += "\\n";
else if (*p == '\t')
s += "\\t";
else
{
s += "\\x";
unsigned char c = *p;
unsigned int dig = c >> 4;
s += dig < 10 ? '0' + dig : 'A' + dig - 10;
dig = c & 0xf;
s += dig < 10 ? '0' + dig : 'A' + dig - 10;
}
}
s += '"';
exp->write_string(s);
}
// Import a string expression.
Expression*
String_expression::do_import(Import* imp)
{
imp->require_c_string("\"");
std::string val;
while (true)
{
int c = imp->get_char();
if (c == '"' || c == -1)
break;
if (c != '\\')
val += static_cast<char>(c);
else
{
c = imp->get_char();
if (c == '\\' || c == '"')
val += static_cast<char>(c);
else if (c == 'n')
val += '\n';
else if (c == 't')
val += '\t';
else if (c == 'x')
{
c = imp->get_char();
unsigned int vh = c >= '0' && c <= '9' ? c - '0' : c - 'A' + 10;
c = imp->get_char();
unsigned int vl = c >= '0' && c <= '9' ? c - '0' : c - 'A' + 10;
char v = (vh << 4) | vl;
val += v;
}
else
{
error_at(imp->location(), "bad string constant");
return Expression::make_error(imp->location());
}
}
}
return Expression::make_string(val, imp->location());
}
// Make a string expression.
Expression*
Expression::make_string(const std::string& val, source_location location)
{
return new String_expression(val, location);
}
// Make an integer expression.
class Integer_expression : public Expression
{
public:
Integer_expression(const mpz_t* val, Type* type, source_location location)
: Expression(EXPRESSION_INTEGER, location),
type_(type)
{ mpz_init_set(this->val_, *val); }
static Expression*
do_import(Import*);
// Return whether VAL fits in the type.
static bool
check_constant(mpz_t val, Type*, source_location);
// Write VAL to export data.
static void
export_integer(Export* exp, const mpz_t val);
protected:
bool
do_is_constant() const
{ return true; }
bool
do_integer_constant_value(bool, mpz_t val, Type** ptype) const;
Type*
do_type();
void
do_determine_type(const Type_context* context);
void
do_check_types(Gogo*);
tree
do_get_tree(Translate_context*);
Expression*
do_copy()
{ return Expression::make_integer(&this->val_, this->type_,
this->location()); }
void
do_export(Export*) const;
private:
// The integer value.
mpz_t val_;
// The type so far.
Type* type_;
};
// Return an integer constant value.
bool
Integer_expression::do_integer_constant_value(bool, mpz_t val,
Type** ptype) const
{
if (this->type_ != NULL)
*ptype = this->type_;
mpz_set(val, this->val_);
return true;
}
// Return the current type. If we haven't set the type yet, we return
// an abstract integer type.
Type*
Integer_expression::do_type()
{
if (this->type_ == NULL)
this->type_ = Type::make_abstract_integer_type();
return this->type_;
}
// Set the type of the integer value. Here we may switch from an
// abstract type to a real type.
void
Integer_expression::do_determine_type(const Type_context* context)
{
if (this->type_ != NULL && !this->type_->is_abstract())
;
else if (context->type != NULL
&& (context->type->integer_type() != NULL
|| context->type->float_type() != NULL
|| context->type->complex_type() != NULL))
this->type_ = context->type;
else if (!context->may_be_abstract)
this->type_ = Type::lookup_integer_type("int");
}
// Return true if the integer VAL fits in the range of the type TYPE.
// Otherwise give an error and return false. TYPE may be NULL.
bool
Integer_expression::check_constant(mpz_t val, Type* type,
source_location location)
{
if (type == NULL)
return true;
Integer_type* itype = type->integer_type();
if (itype == NULL || itype->is_abstract())
return true;
int bits = mpz_sizeinbase(val, 2);
if (itype->is_unsigned())
{
// For an unsigned type we can only accept a nonnegative number,
// and we must be able to represent at least BITS.
if (mpz_sgn(val) >= 0
&& bits <= itype->bits())
return true;
}
else
{
// For a signed type we need an extra bit to indicate the sign.
// We have to handle the most negative integer specially.
if (bits + 1 <= itype->bits()
|| (bits <= itype->bits()
&& mpz_sgn(val) < 0
&& (mpz_scan1(val, 0)
== static_cast<unsigned long>(itype->bits() - 1))
&& mpz_scan0(val, itype->bits()) == ULONG_MAX))
return true;
}
error_at(location, "integer constant overflow");
return false;
}
// Check the type of an integer constant.
void
Integer_expression::do_check_types(Gogo*)
{
if (this->type_ == NULL)
return;
if (!Integer_expression::check_constant(this->val_, this->type_,
this->location()))
this->set_is_error();
}
// Get a tree for an integer constant.
tree
Integer_expression::do_get_tree(Translate_context* context)
{
Gogo* gogo = context->gogo();
tree type;
if (this->type_ != NULL && !this->type_->is_abstract())
type = this->type_->get_tree(gogo);
else if (this->type_ != NULL && this->type_->float_type() != NULL)
{
// We are converting to an abstract floating point type.
type = Type::lookup_float_type("float64")->get_tree(gogo);
}
else if (this->type_ != NULL && this->type_->complex_type() != NULL)
{
// We are converting to an abstract complex type.
type = Type::lookup_complex_type("complex128")->get_tree(gogo);
}
else
{
// If we still have an abstract type here, then this is being
// used in a constant expression which didn't get reduced for
// some reason. Use a type which will fit the value. We use <,
// not <=, because we need an extra bit for the sign bit.
int bits = mpz_sizeinbase(this->val_, 2);
if (bits < INT_TYPE_SIZE)
type = Type::lookup_integer_type("int")->get_tree(gogo);
else if (bits < 64)
type = Type::lookup_integer_type("int64")->get_tree(gogo);
else
type = long_long_integer_type_node;
}
return Expression::integer_constant_tree(this->val_, type);
}
// Write VAL to export data.
void
Integer_expression::export_integer(Export* exp, const mpz_t val)
{
char* s = mpz_get_str(NULL, 10, val);
exp->write_c_string(s);
free(s);
}
// Export an integer in a constant expression.
void
Integer_expression::do_export(Export* exp) const
{
Integer_expression::export_integer(exp, this->val_);
// A trailing space lets us reliably identify the end of the number.
exp->write_c_string(" ");
}
// Import an integer, floating point, or complex value. This handles
// all these types because they all start with digits.
Expression*
Integer_expression::do_import(Import* imp)
{
std::string num = imp->read_identifier();
imp->require_c_string(" ");
if (!num.empty() && num[num.length() - 1] == 'i')
{
mpfr_t real;
size_t plus_pos = num.find('+', 1);
size_t minus_pos = num.find('-', 1);
size_t pos;
if (plus_pos == std::string::npos)
pos = minus_pos;
else if (minus_pos == std::string::npos)
pos = plus_pos;
else
{
error_at(imp->location(), "bad number in import data: %qs",
num.c_str());
return Expression::make_error(imp->location());
}
if (pos == std::string::npos)
mpfr_set_ui(real, 0, GMP_RNDN);
else
{
std::string real_str = num.substr(0, pos);
if (mpfr_init_set_str(real, real_str.c_str(), 10, GMP_RNDN) != 0)
{
error_at(imp->location(), "bad number in import data: %qs",
real_str.c_str());
return Expression::make_error(imp->location());
}
}
std::string imag_str;
if (pos == std::string::npos)
imag_str = num;
else
imag_str = num.substr(pos);
imag_str = imag_str.substr(0, imag_str.size() - 1);
mpfr_t imag;
if (mpfr_init_set_str(imag, imag_str.c_str(), 10, GMP_RNDN) != 0)
{
error_at(imp->location(), "bad number in import data: %qs",
imag_str.c_str());
return Expression::make_error(imp->location());
}
Expression* ret = Expression::make_complex(&real, &imag, NULL,
imp->location());
mpfr_clear(real);
mpfr_clear(imag);
return ret;
}
else if (num.find('.') == std::string::npos
&& num.find('E') == std::string::npos)
{
mpz_t val;
if (mpz_init_set_str(val, num.c_str(), 10) != 0)
{
error_at(imp->location(), "bad number in import data: %qs",
num.c_str());
return Expression::make_error(imp->location());
}
Expression* ret = Expression::make_integer(&val, NULL, imp->location());
mpz_clear(val);
return ret;
}
else
{
mpfr_t val;
if (mpfr_init_set_str(val, num.c_str(), 10, GMP_RNDN) != 0)
{
error_at(imp->location(), "bad number in import data: %qs",
num.c_str());
return Expression::make_error(imp->location());
}
Expression* ret = Expression::make_float(&val, NULL, imp->location());
mpfr_clear(val);
return ret;
}
}
// Build a new integer value.
Expression*
Expression::make_integer(const mpz_t* val, Type* type,
source_location location)
{
return new Integer_expression(val, type, location);
}
// Floats.
class Float_expression : public Expression
{
public:
Float_expression(const mpfr_t* val, Type* type, source_location location)
: Expression(EXPRESSION_FLOAT, location),
type_(type)
{
mpfr_init_set(this->val_, *val, GMP_RNDN);
}
// Constrain VAL to fit into TYPE.
static void
constrain_float(mpfr_t val, Type* type);
// Return whether VAL fits in the type.
static bool
check_constant(mpfr_t val, Type*, source_location);
// Write VAL to export data.
static void
export_float(Export* exp, const mpfr_t val);
protected:
bool
do_is_constant() const
{ return true; }
bool
do_float_constant_value(mpfr_t val, Type**) const;
Type*
do_type();
void
do_determine_type(const Type_context*);
void
do_check_types(Gogo*);
Expression*
do_copy()
{ return Expression::make_float(&this->val_, this->type_,
this->location()); }
tree
do_get_tree(Translate_context*);
void
do_export(Export*) const;
private:
// The floating point value.
mpfr_t val_;
// The type so far.
Type* type_;
};
// Constrain VAL to fit into TYPE.
void
Float_expression::constrain_float(mpfr_t val, Type* type)
{
Float_type* ftype = type->float_type();
if (ftype != NULL && !ftype->is_abstract())
{
tree type_tree = ftype->type_tree();
REAL_VALUE_TYPE rvt;
real_from_mpfr(&rvt, val, type_tree, GMP_RNDN);
real_convert(&rvt, TYPE_MODE(type_tree), &rvt);
mpfr_from_real(val, &rvt, GMP_RNDN);
}
}
// Return a floating point constant value.
bool
Float_expression::do_float_constant_value(mpfr_t val, Type** ptype) const
{
if (this->type_ != NULL)
*ptype = this->type_;
mpfr_set(val, this->val_, GMP_RNDN);
return true;
}
// Return the current type. If we haven't set the type yet, we return
// an abstract float type.
Type*
Float_expression::do_type()
{
if (this->type_ == NULL)
this->type_ = Type::make_abstract_float_type();
return this->type_;
}
// Set the type of the float value. Here we may switch from an
// abstract type to a real type.
void
Float_expression::do_determine_type(const Type_context* context)
{
if (this->type_ != NULL && !this->type_->is_abstract())
;
else if (context->type != NULL
&& (context->type->integer_type() != NULL
|| context->type->float_type() != NULL
|| context->type->complex_type() != NULL))
this->type_ = context->type;
else if (!context->may_be_abstract)
this->type_ = Type::lookup_float_type("float64");
}
// Return true if the floating point value VAL fits in the range of
// the type TYPE. Otherwise give an error and return false. TYPE may
// be NULL.
bool
Float_expression::check_constant(mpfr_t val, Type* type,
source_location location)
{
if (type == NULL)
return true;
Float_type* ftype = type->float_type();
if (ftype == NULL || ftype->is_abstract())
return true;
// A NaN or Infinity always fits in the range of the type.
if (mpfr_nan_p(val) || mpfr_inf_p(val) || mpfr_zero_p(val))
return true;
mp_exp_t exp = mpfr_get_exp(val);
mp_exp_t max_exp;
switch (ftype->bits())
{
case 32:
max_exp = 128;
break;
case 64:
max_exp = 1024;
break;
default:
gcc_unreachable();
}
if (exp > max_exp)
{
error_at(location, "floating point constant overflow");
return false;
}
return true;
}
// Check the type of a float value.
void
Float_expression::do_check_types(Gogo*)
{
if (this->type_ == NULL)
return;
if (!Float_expression::check_constant(this->val_, this->type_,
this->location()))
this->set_is_error();
Integer_type* integer_type = this->type_->integer_type();
if (integer_type != NULL)
{
if (!mpfr_integer_p(this->val_))
this->report_error(_("floating point constant truncated to integer"));
else
{
gcc_assert(!integer_type->is_abstract());
mpz_t ival;
mpz_init(ival);
mpfr_get_z(ival, this->val_, GMP_RNDN);
Integer_expression::check_constant(ival, integer_type,
this->location());
mpz_clear(ival);
}
}
}
// Get a tree for a float constant.
tree
Float_expression::do_get_tree(Translate_context* context)
{
Gogo* gogo = context->gogo();
tree type;
if (this->type_ != NULL && !this->type_->is_abstract())
type = this->type_->get_tree(gogo);
else if (this->type_ != NULL && this->type_->integer_type() != NULL)
{
// We have an abstract integer type. We just hope for the best.
type = Type::lookup_integer_type("int")->get_tree(gogo);
}
else
{
// If we still have an abstract type here, then this is being
// used in a constant expression which didn't get reduced. We
// just use float64 and hope for the best.
type = Type::lookup_float_type("float64")->get_tree(gogo);
}
return Expression::float_constant_tree(this->val_, type);
}
// Write a floating point number to export data.
void
Float_expression::export_float(Export *exp, const mpfr_t val)
{
mp_exp_t exponent;
char* s = mpfr_get_str(NULL, &exponent, 10, 0, val, GMP_RNDN);
if (*s == '-')
exp->write_c_string("-");
exp->write_c_string("0.");
exp->write_c_string(*s == '-' ? s + 1 : s);
mpfr_free_str(s);
char buf[30];
snprintf(buf, sizeof buf, "E%ld", exponent);
exp->write_c_string(buf);
}
// Export a floating point number in a constant expression.
void
Float_expression::do_export(Export* exp) const
{
Float_expression::export_float(exp, this->val_);
// A trailing space lets us reliably identify the end of the number.
exp->write_c_string(" ");
}
// Make a float expression.
Expression*
Expression::make_float(const mpfr_t* val, Type* type, source_location location)
{
return new Float_expression(val, type, location);
}
// Complex numbers.
class Complex_expression : public Expression
{
public:
Complex_expression(const mpfr_t* real, const mpfr_t* imag, Type* type,
source_location location)
: Expression(EXPRESSION_COMPLEX, location),
type_(type)
{
mpfr_init_set(this->real_, *real, GMP_RNDN);
mpfr_init_set(this->imag_, *imag, GMP_RNDN);
}
// Constrain REAL/IMAG to fit into TYPE.
static void
constrain_complex(mpfr_t real, mpfr_t imag, Type* type);
// Return whether REAL/IMAG fits in the type.
static bool
check_constant(mpfr_t real, mpfr_t imag, Type*, source_location);
// Write REAL/IMAG to export data.
static void
export_complex(Export* exp, const mpfr_t real, const mpfr_t val);
protected:
bool
do_is_constant() const
{ return true; }
bool
do_complex_constant_value(mpfr_t real, mpfr_t imag, Type**) const;
Type*
do_type();
void
do_determine_type(const Type_context*);
void
do_check_types(Gogo*);
Expression*
do_copy()
{
return Expression::make_complex(&this->real_, &this->imag_, this->type_,
this->location());
}
tree
do_get_tree(Translate_context*);
void
do_export(Export*) const;
private:
// The real part.
mpfr_t real_;
// The imaginary part;
mpfr_t imag_;
// The type if known.
Type* type_;
};
// Constrain REAL/IMAG to fit into TYPE.
void
Complex_expression::constrain_complex(mpfr_t real, mpfr_t imag, Type* type)
{
Complex_type* ctype = type->complex_type();
if (ctype != NULL && !ctype->is_abstract())
{
tree type_tree = ctype->type_tree();
REAL_VALUE_TYPE rvt;
real_from_mpfr(&rvt, real, TREE_TYPE(type_tree), GMP_RNDN);
real_convert(&rvt, TYPE_MODE(TREE_TYPE(type_tree)), &rvt);
mpfr_from_real(real, &rvt, GMP_RNDN);
real_from_mpfr(&rvt, imag, TREE_TYPE(type_tree), GMP_RNDN);
real_convert(&rvt, TYPE_MODE(TREE_TYPE(type_tree)), &rvt);
mpfr_from_real(imag, &rvt, GMP_RNDN);
}
}
// Return a complex constant value.
bool
Complex_expression::do_complex_constant_value(mpfr_t real, mpfr_t imag,
Type** ptype) const
{
if (this->type_ != NULL)
*ptype = this->type_;
mpfr_set(real, this->real_, GMP_RNDN);
mpfr_set(imag, this->imag_, GMP_RNDN);
return true;
}
// Return the current type. If we haven't set the type yet, we return
// an abstract complex type.
Type*
Complex_expression::do_type()
{
if (this->type_ == NULL)
this->type_ = Type::make_abstract_complex_type();
return this->type_;
}
// Set the type of the complex value. Here we may switch from an
// abstract type to a real type.
void
Complex_expression::do_determine_type(const Type_context* context)
{
if (this->type_ != NULL && !this->type_->is_abstract())
;
else if (context->type != NULL
&& context->type->complex_type() != NULL)
this->type_ = context->type;
else if (!context->may_be_abstract)
this->type_ = Type::lookup_complex_type("complex128");
}
// Return true if the complex value REAL/IMAG fits in the range of the
// type TYPE. Otherwise give an error and return false. TYPE may be
// NULL.
bool
Complex_expression::check_constant(mpfr_t real, mpfr_t imag, Type* type,
source_location location)
{
if (type == NULL)
return true;
Complex_type* ctype = type->complex_type();
if (ctype == NULL || ctype->is_abstract())
return true;
mp_exp_t max_exp;
switch (ctype->bits())
{
case 64:
max_exp = 128;
break;
case 128:
max_exp = 1024;
break;
default:
gcc_unreachable();
}
// A NaN or Infinity always fits in the range of the type.
if (!mpfr_nan_p(real) && !mpfr_inf_p(real) && !mpfr_zero_p(real))
{
if (mpfr_get_exp(real) > max_exp)
{
error_at(location, "complex real part constant overflow");
return false;
}
}
if (!mpfr_nan_p(imag) && !mpfr_inf_p(imag) && !mpfr_zero_p(imag))
{
if (mpfr_get_exp(imag) > max_exp)
{
error_at(location, "complex imaginary part constant overflow");
return false;
}
}
return true;
}
// Check the type of a complex value.
void
Complex_expression::do_check_types(Gogo*)
{
if (this->type_ == NULL)
return;
if (!Complex_expression::check_constant(this->real_, this->imag_,
this->type_, this->location()))
this->set_is_error();
}
// Get a tree for a complex constant.
tree
Complex_expression::do_get_tree(Translate_context* context)
{
Gogo* gogo = context->gogo();
tree type;
if (this->type_ != NULL && !this->type_->is_abstract())
type = this->type_->get_tree(gogo);
else
{
// If we still have an abstract type here, this this is being
// used in a constant expression which didn't get reduced. We
// just use complex128 and hope for the best.
type = Type::lookup_complex_type("complex128")->get_tree(gogo);
}
return Expression::complex_constant_tree(this->real_, this->imag_, type);
}
// Write REAL/IMAG to export data.
void
Complex_expression::export_complex(Export* exp, const mpfr_t real,
const mpfr_t imag)
{
if (!mpfr_zero_p(real))
{
Float_expression::export_float(exp, real);
if (mpfr_sgn(imag) > 0)
exp->write_c_string("+");
}
Float_expression::export_float(exp, imag);
exp->write_c_string("i");
}
// Export a complex number in a constant expression.
void
Complex_expression::do_export(Export* exp) const
{
Complex_expression::export_complex(exp, this->real_, this->imag_);
// A trailing space lets us reliably identify the end of the number.
exp->write_c_string(" ");
}
// Make a complex expression.
Expression*
Expression::make_complex(const mpfr_t* real, const mpfr_t* imag, Type* type,
source_location location)
{
return new Complex_expression(real, imag, type, location);
}
// Find a named object in an expression.
class Find_named_object : public Traverse
{
public:
Find_named_object(Named_object* no)
: Traverse(traverse_expressions),
no_(no), found_(false)
{ }
// Whether we found the object.
bool
found() const
{ return this->found_; }
protected:
int
expression(Expression**);
private:
// The object we are looking for.
Named_object* no_;
// Whether we found it.
bool found_;
};
// A reference to a const in an expression.
class Const_expression : public Expression
{
public:
Const_expression(Named_object* constant, source_location location)
: Expression(EXPRESSION_CONST_REFERENCE, location),
constant_(constant), type_(NULL), seen_(false)
{ }
Named_object*
named_object()
{ return this->constant_; }
const std::string&
name() const
{ return this->constant_->name(); }
// Check that the initializer does not refer to the constant itself.
void
check_for_init_loop();
protected:
Expression*
do_lower(Gogo*, Named_object*, int);
bool
do_is_constant() const
{ return true; }
bool
do_integer_constant_value(bool, mpz_t val, Type**) const;
bool
do_float_constant_value(mpfr_t val, Type**) const;
bool
do_complex_constant_value(mpfr_t real, mpfr_t imag, Type**) const;
bool
do_string_constant_value(std::string* val) const
{ return this->constant_->const_value()->expr()->string_constant_value(val); }
Type*
do_type();
// The type of a const is set by the declaration, not the use.
void
do_determine_type(const Type_context*);
void
do_check_types(Gogo*);
Expression*
do_copy()
{ return this; }
tree
do_get_tree(Translate_context* context);
// When exporting a reference to a const as part of a const
// expression, we export the value. We ignore the fact that it has
// a name.
void
do_export(Export* exp) const
{ this->constant_->const_value()->expr()->export_expression(exp); }
private:
// The constant.
Named_object* constant_;
// The type of this reference. This is used if the constant has an
// abstract type.
Type* type_;
// Used to prevent infinite recursion when a constant incorrectly
// refers to itself.
mutable bool seen_;
};
// Lower a constant expression. This is where we convert the
// predeclared constant iota into an integer value.
Expression*
Const_expression::do_lower(Gogo* gogo, Named_object*, int iota_value)
{
if (this->constant_->const_value()->expr()->classification()
== EXPRESSION_IOTA)
{
if (iota_value == -1)
{
error_at(this->location(),
"iota is only defined in const declarations");
iota_value = 0;
}
mpz_t val;
mpz_init_set_ui(val, static_cast<unsigned long>(iota_value));
Expression* ret = Expression::make_integer(&val, NULL,
this->location());
mpz_clear(val);
return ret;
}
// Make sure that the constant itself has been lowered.
gogo->lower_constant(this->constant_);
return this;
}
// Return an integer constant value.
bool
Const_expression::do_integer_constant_value(bool iota_is_constant, mpz_t val,
Type** ptype) const
{
if (this->seen_)
return false;
Type* ctype;
if (this->type_ != NULL)
ctype = this->type_;
else
ctype = this->constant_->const_value()->type();
if (ctype != NULL && ctype->integer_type() == NULL)
return false;
Expression* e = this->constant_->const_value()->expr();
this->seen_ = true;
Type* t;
bool r = e->integer_constant_value(iota_is_constant, val, &t);
this->seen_ = false;
if (r
&& ctype != NULL
&& !Integer_expression::check_constant(val, ctype, this->location()))
return false;
*ptype = ctype != NULL ? ctype : t;
return r;
}
// Return a floating point constant value.
bool
Const_expression::do_float_constant_value(mpfr_t val, Type** ptype) const
{
if (this->seen_)
return false;
Type* ctype;
if (this->type_ != NULL)
ctype = this->type_;
else
ctype = this->constant_->const_value()->type();
if (ctype != NULL && ctype->float_type() == NULL)
return false;
this->seen_ = true;
Type* t;
bool r = this->constant_->const_value()->expr()->float_constant_value(val,
&t);
this->seen_ = false;
if (r && ctype != NULL)
{
if (!Float_expression::check_constant(val, ctype, this->location()))
return false;
Float_expression::constrain_float(val, ctype);
}
*ptype = ctype != NULL ? ctype : t;
return r;
}
// Return a complex constant value.
bool
Const_expression::do_complex_constant_value(mpfr_t real, mpfr_t imag,
Type **ptype) const
{
if (this->seen_)
return false;
Type* ctype;
if (this->type_ != NULL)
ctype = this->type_;
else
ctype = this->constant_->const_value()->type();
if (ctype != NULL && ctype->complex_type() == NULL)
return false;
this->seen_ = true;
Type *t;
bool r = this->constant_->const_value()->expr()->complex_constant_value(real,
imag,
&t);
this->seen_ = false;
if (r && ctype != NULL)
{
if (!Complex_expression::check_constant(real, imag, ctype,
this->location()))
return false;
Complex_expression::constrain_complex(real, imag, ctype);
}
*ptype = ctype != NULL ? ctype : t;
return r;
}
// Return the type of the const reference.
Type*
Const_expression::do_type()
{
if (this->type_ != NULL)
return this->type_;
Named_constant* nc = this->constant_->const_value();
if (this->seen_ || nc->lowering())
{
this->report_error(_("constant refers to itself"));
this->type_ = Type::make_error_type();
return this->type_;
}
this->seen_ = true;
Type* ret = nc->type();
if (ret != NULL)
{
this->seen_ = false;
return ret;
}
// During parsing, a named constant may have a NULL type, but we
// must not return a NULL type here.
ret = nc->expr()->type();
this->seen_ = false;
return ret;
}
// Set the type of the const reference.
void
Const_expression::do_determine_type(const Type_context* context)
{
Type* ctype = this->constant_->const_value()->type();
Type* cetype = (ctype != NULL
? ctype
: this->constant_->const_value()->expr()->type());
if (ctype != NULL && !ctype->is_abstract())
;
else if (context->type != NULL
&& (context->type->integer_type() != NULL
|| context->type->float_type() != NULL
|| context->type->complex_type() != NULL)
&& (cetype->integer_type() != NULL
|| cetype->float_type() != NULL
|| cetype->complex_type() != NULL))
this->type_ = context->type;
else if (context->type != NULL
&& context->type->is_string_type()
&& cetype->is_string_type())
this->type_ = context->type;
else if (context->type != NULL
&& context->type->is_boolean_type()
&& cetype->is_boolean_type())
this->type_ = context->type;
else if (!context->may_be_abstract)
{
if (cetype->is_abstract())
cetype = cetype->make_non_abstract_type();
this->type_ = cetype;
}
}
// Check for a loop in which the initializer of a constant refers to
// the constant itself.
void
Const_expression::check_for_init_loop()
{
if (this->type_ != NULL && this->type_->is_error_type())
return;
if (this->seen_)
{
this->report_error(_("constant refers to itself"));
this->type_ = Type::make_error_type();
return;
}
Expression* init = this->constant_->const_value()->expr();
Find_named_object find_named_object(this->constant_);
this->seen_ = true;
Expression::traverse(&init, &find_named_object);
this->seen_ = false;
if (find_named_object.found())
{
if (this->type_ == NULL || !this->type_->is_error_type())
{
this->report_error(_("constant refers to itself"));
this->type_ = Type::make_error_type();
}
return;
}
}
// Check types of a const reference.
void
Const_expression::do_check_types(Gogo*)
{
if (this->type_ != NULL && this->type_->is_error_type())
return;
this->check_for_init_loop();
if (this->type_ == NULL || this->type_->is_abstract())
return;
// Check for integer overflow.
if (this->type_->integer_type() != NULL)
{
mpz_t ival;
mpz_init(ival);
Type* dummy;
if (!this->integer_constant_value(true, ival, &dummy))
{
mpfr_t fval;
mpfr_init(fval);
Expression* cexpr = this->constant_->const_value()->expr();
if (cexpr->float_constant_value(fval, &dummy))
{
if (!mpfr_integer_p(fval))
this->report_error(_("floating point constant "
"truncated to integer"));
else
{
mpfr_get_z(ival, fval, GMP_RNDN);
Integer_expression::check_constant(ival, this->type_,
this->location());
}
}
mpfr_clear(fval);
}
mpz_clear(ival);
}
}
// Return a tree for the const reference.
tree
Const_expression::do_get_tree(Translate_context* context)
{
Gogo* gogo = context->gogo();
tree type_tree;
if (this->type_ == NULL)
type_tree = NULL_TREE;
else
{
type_tree = this->type_->get_tree(gogo);
if (type_tree == error_mark_node)
return error_mark_node;
}
// If the type has been set for this expression, but the underlying
// object is an abstract int or float, we try to get the abstract
// value. Otherwise we may lose something in the conversion.
if (this->type_ != NULL
&& (this->constant_->const_value()->type() == NULL
|| this->constant_->const_value()->type()->is_abstract()))
{
Expression* expr = this->constant_->const_value()->expr();
mpz_t ival;
mpz_init(ival);
Type* t;
if (expr->integer_constant_value(true, ival, &t))
{
tree ret = Expression::integer_constant_tree(ival, type_tree);
mpz_clear(ival);
return ret;
}
mpz_clear(ival);
mpfr_t fval;
mpfr_init(fval);
if (expr->float_constant_value(fval, &t))
{
tree ret = Expression::float_constant_tree(fval, type_tree);
mpfr_clear(fval);
return ret;
}
mpfr_t imag;
mpfr_init(imag);
if (expr->complex_constant_value(fval, imag, &t))
{
tree ret = Expression::complex_constant_tree(fval, imag, type_tree);
mpfr_clear(fval);
mpfr_clear(imag);
return ret;
}
mpfr_clear(imag);
mpfr_clear(fval);
}
tree const_tree = this->constant_->get_tree(gogo, context->function());
if (this->type_ == NULL
|| const_tree == error_mark_node
|| TREE_TYPE(const_tree) == error_mark_node)
return const_tree;
tree ret;
if (TYPE_MAIN_VARIANT(type_tree) == TYPE_MAIN_VARIANT(TREE_TYPE(const_tree)))
ret = fold_convert(type_tree, const_tree);
else if (TREE_CODE(type_tree) == INTEGER_TYPE)
ret = fold(convert_to_integer(type_tree, const_tree));
else if (TREE_CODE(type_tree) == REAL_TYPE)
ret = fold(convert_to_real(type_tree, const_tree));
else if (TREE_CODE(type_tree) == COMPLEX_TYPE)
ret = fold(convert_to_complex(type_tree, const_tree));
else
gcc_unreachable();
return ret;
}
// Make a reference to a constant in an expression.
Expression*
Expression::make_const_reference(Named_object* constant,
source_location location)
{
return new Const_expression(constant, location);
}
// Find a named object in an expression.
int
Find_named_object::expression(Expression** pexpr)
{
switch ((*pexpr)->classification())
{
case Expression::EXPRESSION_CONST_REFERENCE:
{
Const_expression* ce = static_cast<Const_expression*>(*pexpr);
if (ce->named_object() == this->no_)
break;
// We need to check a constant initializer explicitly, as
// loops here will not be caught by the loop checking for
// variable initializers.
ce->check_for_init_loop();
return TRAVERSE_CONTINUE;
}
case Expression::EXPRESSION_VAR_REFERENCE:
if ((*pexpr)->var_expression()->named_object() == this->no_)
break;
return TRAVERSE_CONTINUE;
case Expression::EXPRESSION_FUNC_REFERENCE:
if ((*pexpr)->func_expression()->named_object() == this->no_)
break;
return TRAVERSE_CONTINUE;
default:
return TRAVERSE_CONTINUE;
}
this->found_ = true;
return TRAVERSE_EXIT;
}
// The nil value.
class Nil_expression : public Expression
{
public:
Nil_expression(source_location location)
: Expression(EXPRESSION_NIL, location)
{ }
static Expression*
do_import(Import*);
protected:
bool
do_is_constant() const
{ return true; }
Type*
do_type()
{ return Type::make_nil_type(); }
void
do_determine_type(const Type_context*)
{ }
Expression*
do_copy()
{ return this; }
tree
do_get_tree(Translate_context*)
{ return null_pointer_node; }
void
do_export(Export* exp) const
{ exp->write_c_string("nil"); }
};
// Import a nil expression.
Expression*
Nil_expression::do_import(Import* imp)
{
imp->require_c_string("nil");
return Expression::make_nil(imp->location());
}
// Make a nil expression.
Expression*
Expression::make_nil(source_location location)
{
return new Nil_expression(location);
}
// The value of the predeclared constant iota. This is little more
// than a marker. This will be lowered to an integer in
// Const_expression::do_lower, which is where we know the value that
// it should have.
class Iota_expression : public Parser_expression
{
public:
Iota_expression(source_location location)
: Parser_expression(EXPRESSION_IOTA, location)
{ }
protected:
Expression*
do_lower(Gogo*, Named_object*, int)
{ gcc_unreachable(); }
// There should only ever be one of these.
Expression*
do_copy()
{ gcc_unreachable(); }
};
// Make an iota expression. This is only called for one case: the
// value of the predeclared constant iota.
Expression*
Expression::make_iota()
{
static Iota_expression iota_expression(UNKNOWN_LOCATION);
return &iota_expression;
}
// A type conversion expression.
class Type_conversion_expression : public Expression
{
public:
Type_conversion_expression(Type* type, Expression* expr,
source_location location)
: Expression(EXPRESSION_CONVERSION, location),
type_(type), expr_(expr), may_convert_function_types_(false)
{ }
// Return the type to which we are converting.
Type*
type() const
{ return this->type_; }
// Return the expression which we are converting.
Expression*
expr() const
{ return this->expr_; }
// Permit converting from one function type to another. This is
// used internally for method expressions.
void
set_may_convert_function_types()
{
this->may_convert_function_types_ = true;
}
// Import a type conversion expression.
static Expression*
do_import(Import*);
protected:
int
do_traverse(Traverse* traverse);
Expression*
do_lower(Gogo*, Named_object*, int);
bool
do_is_constant() const
{ return this->expr_->is_constant(); }
bool
do_integer_constant_value(bool, mpz_t, Type**) const;
bool
do_float_constant_value(mpfr_t, Type**) const;
bool
do_complex_constant_value(mpfr_t, mpfr_t, Type**) const;
bool
do_string_constant_value(std::string*) const;
Type*
do_type()
{ return this->type_; }
void
do_determine_type(const Type_context*)
{
Type_context subcontext(this->type_, false);
this->expr_->determine_type(&subcontext);
}
void
do_check_types(Gogo*);
Expression*
do_copy()
{
return new Type_conversion_expression(this->type_, this->expr_->copy(),
this->location());
}
tree
do_get_tree(Translate_context* context);
void
do_export(Export*) const;
private:
// The type to convert to.
Type* type_;
// The expression to convert.
Expression* expr_;
// True if this is permitted to convert function types. This is
// used internally for method expressions.
bool may_convert_function_types_;
};
// Traversal.
int
Type_conversion_expression::do_traverse(Traverse* traverse)
{
if (Expression::traverse(&this->expr_, traverse) == TRAVERSE_EXIT
|| Type::traverse(this->type_, traverse) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
return TRAVERSE_CONTINUE;
}
// Convert to a constant at lowering time.
Expression*
Type_conversion_expression::do_lower(Gogo*, Named_object*, int)
{
Type* type = this->type_;
Expression* val = this->expr_;
source_location location = this->location();
if (type->integer_type() != NULL)
{
mpz_t ival;
mpz_init(ival);
Type* dummy;
if (val->integer_constant_value(false, ival, &dummy))
{
if (!Integer_expression::check_constant(ival, type, location))
mpz_set_ui(ival, 0);
Expression* ret = Expression::make_integer(&ival, type, location);
mpz_clear(ival);
return ret;
}
mpfr_t fval;
mpfr_init(fval);
if (val->float_constant_value(fval, &dummy))
{
if (!mpfr_integer_p(fval))
{
error_at(location,
"floating point constant truncated to integer");
return Expression::make_error(location);
}
mpfr_get_z(ival, fval, GMP_RNDN);
if (!Integer_expression::check_constant(ival, type, location))
mpz_set_ui(ival, 0);
Expression* ret = Expression::make_integer(&ival, type, location);
mpfr_clear(fval);
mpz_clear(ival);
return ret;
}
mpfr_clear(fval);
mpz_clear(ival);
}
if (type->float_type() != NULL)
{
mpfr_t fval;
mpfr_init(fval);
Type* dummy;
if (val->float_constant_value(fval, &dummy))
{
if (!Float_expression::check_constant(fval, type, location))
mpfr_set_ui(fval, 0, GMP_RNDN);
Float_expression::constrain_float(fval, type);
Expression *ret = Expression::make_float(&fval, type, location);
mpfr_clear(fval);
return ret;
}
mpfr_clear(fval);
}
if (type->complex_type() != NULL)
{
mpfr_t real;
mpfr_t imag;
mpfr_init(real);
mpfr_init(imag);
Type* dummy;
if (val->complex_constant_value(real, imag, &dummy))
{
if (!Complex_expression::check_constant(real, imag, type, location))
{
mpfr_set_ui(real, 0, GMP_RNDN);
mpfr_set_ui(imag, 0, GMP_RNDN);
}
Complex_expression::constrain_complex(real, imag, type);
Expression* ret = Expression::make_complex(&real, &imag, type,
location);
mpfr_clear(real);
mpfr_clear(imag);
return ret;
}
mpfr_clear(real);
mpfr_clear(imag);
}
if (type->is_open_array_type() && type->named_type() == NULL)
{
Type* element_type = type->array_type()->element_type()->forwarded();
bool is_byte = element_type == Type::lookup_integer_type("uint8");
bool is_int = element_type == Type::lookup_integer_type("int");
if (is_byte || is_int)
{
std::string s;
if (val->string_constant_value(&s))
{
Expression_list* vals = new Expression_list();
if (is_byte)
{
for (std::string::const_iterator p = s.begin();
p != s.end();
p++)
{
mpz_t val;
mpz_init_set_ui(val, static_cast<unsigned char>(*p));
Expression* v = Expression::make_integer(&val,
element_type,
location);
vals->push_back(v);
mpz_clear(val);
}
}
else
{
const char *p = s.data();
const char *pend = s.data() + s.length();
while (p < pend)
{
unsigned int c;
int adv = Lex::fetch_char(p, &c);
if (adv == 0)
{
warning_at(this->location(), 0,
"invalid UTF-8 encoding");
adv = 1;
}
p += adv;
mpz_t val;
mpz_init_set_ui(val, c);
Expression* v = Expression::make_integer(&val,
element_type,
location);
vals->push_back(v);
mpz_clear(val);
}
}
return Expression::make_slice_composite_literal(type, vals,
location);
}
}
}
return this;
}
// Return the constant integer value if there is one.
bool
Type_conversion_expression::do_integer_constant_value(bool iota_is_constant,
mpz_t val,
Type** ptype) const
{
if (this->type_->integer_type() == NULL)
return false;
mpz_t ival;
mpz_init(ival);
Type* dummy;
if (this->expr_->integer_constant_value(iota_is_constant, ival, &dummy))
{
if (!Integer_expression::check_constant(ival, this->type_,
this->location()))
{
mpz_clear(ival);
return false;
}
mpz_set(val, ival);
mpz_clear(ival);
*ptype = this->type_;
return true;
}
mpz_clear(ival);
mpfr_t fval;
mpfr_init(fval);
if (this->expr_->float_constant_value(fval, &dummy))
{
mpfr_get_z(val, fval, GMP_RNDN);
mpfr_clear(fval);
if (!Integer_expression::check_constant(val, this->type_,
this->location()))
return false;
*ptype = this->type_;
return true;
}
mpfr_clear(fval);
return false;
}
// Return the constant floating point value if there is one.
bool
Type_conversion_expression::do_float_constant_value(mpfr_t val,
Type** ptype) const
{
if (this->type_->float_type() == NULL)
return false;
mpfr_t fval;
mpfr_init(fval);
Type* dummy;
if (this->expr_->float_constant_value(fval, &dummy))
{
if (!Float_expression::check_constant(fval, this->type_,
this->location()))
{
mpfr_clear(fval);
return false;
}
mpfr_set(val, fval, GMP_RNDN);
mpfr_clear(fval);
Float_expression::constrain_float(val, this->type_);
*ptype = this->type_;
return true;
}
mpfr_clear(fval);
return false;
}
// Return the constant complex value if there is one.
bool
Type_conversion_expression::do_complex_constant_value(mpfr_t real,
mpfr_t imag,
Type **ptype) const
{
if (this->type_->complex_type() == NULL)
return false;
mpfr_t rval;
mpfr_t ival;
mpfr_init(rval);
mpfr_init(ival);
Type* dummy;
if (this->expr_->complex_constant_value(rval, ival, &dummy))
{
if (!Complex_expression::check_constant(rval, ival, this->type_,
this->location()))
{
mpfr_clear(rval);
mpfr_clear(ival);
return false;
}
mpfr_set(real, rval, GMP_RNDN);
mpfr_set(imag, ival, GMP_RNDN);
mpfr_clear(rval);
mpfr_clear(ival);
Complex_expression::constrain_complex(real, imag, this->type_);
*ptype = this->type_;
return true;
}
mpfr_clear(rval);
mpfr_clear(ival);
return false;
}
// Return the constant string value if there is one.
bool
Type_conversion_expression::do_string_constant_value(std::string* val) const
{
if (this->type_->is_string_type()
&& this->expr_->type()->integer_type() != NULL)
{
mpz_t ival;
mpz_init(ival);
Type* dummy;
if (this->expr_->integer_constant_value(false, ival, &dummy))
{
unsigned long ulval = mpz_get_ui(ival);
if (mpz_cmp_ui(ival, ulval) == 0)
{
Lex::append_char(ulval, true, val, this->location());
mpz_clear(ival);
return true;
}
}
mpz_clear(ival);
}
// FIXME: Could handle conversion from const []int here.
return false;
}
// Check that types are convertible.
void
Type_conversion_expression::do_check_types(Gogo*)
{
Type* type = this->type_;
Type* expr_type = this->expr_->type();
std::string reason;
if (type->is_error_type()
|| type->is_undefined()
|| expr_type->is_error_type()
|| expr_type->is_undefined())
{
// Make sure we emit an error for an undefined type.
type->base();
expr_type->base();
this->set_is_error();
return;
}
if (this->may_convert_function_types_
&& type->function_type() != NULL
&& expr_type->function_type() != NULL)
return;
if (Type::are_convertible(type, expr_type, &reason))
return;
error_at(this->location(), "%s", reason.c_str());
this->set_is_error();
}
// Get a tree for a type conversion.
tree
Type_conversion_expression::do_get_tree(Translate_context* context)
{
Gogo* gogo = context->gogo();
tree type_tree = this->type_->get_tree(gogo);
tree expr_tree = this->expr_->get_tree(context);
if (type_tree == error_mark_node
|| expr_tree == error_mark_node
|| TREE_TYPE(expr_tree) == error_mark_node)
return error_mark_node;
if (TYPE_MAIN_VARIANT(type_tree) == TYPE_MAIN_VARIANT(TREE_TYPE(expr_tree)))
return fold_convert(type_tree, expr_tree);
Type* type = this->type_;
Type* expr_type = this->expr_->type();
tree ret;
if (type->interface_type() != NULL || expr_type->interface_type() != NULL)
ret = Expression::convert_for_assignment(context, type, expr_type,
expr_tree, this->location());
else if (type->integer_type() != NULL)
{
if (expr_type->integer_type() != NULL
|| expr_type->float_type() != NULL
|| expr_type->is_unsafe_pointer_type())
ret = fold(convert_to_integer(type_tree, expr_tree));
else
gcc_unreachable();
}
else if (type->float_type() != NULL)
{
if (expr_type->integer_type() != NULL
|| expr_type->float_type() != NULL)
ret = fold(convert_to_real(type_tree, expr_tree));
else
gcc_unreachable();
}
else if (type->complex_type() != NULL)
{
if (expr_type->complex_type() != NULL)
ret = fold(convert_to_complex(type_tree, expr_tree));
else
gcc_unreachable();
}
else if (type->is_string_type()
&& expr_type->integer_type() != NULL)
{
expr_tree = fold_convert(integer_type_node, expr_tree);
if (host_integerp(expr_tree, 0))
{
HOST_WIDE_INT intval = tree_low_cst(expr_tree, 0);
std::string s;
Lex::append_char(intval, true, &s, this->location());
Expression* se = Expression::make_string(s, this->location());
return se->get_tree(context);
}
static tree int_to_string_fndecl;
ret = Gogo::call_builtin(&int_to_string_fndecl,
this->location(),
"__go_int_to_string",
1,
type_tree,
integer_type_node,
fold_convert(integer_type_node, expr_tree));
}
else if (type->is_string_type()
&& (expr_type->array_type() != NULL
|| (expr_type->points_to() != NULL
&& expr_type->points_to()->array_type() != NULL)))
{
Type* t = expr_type;
if (t->points_to() != NULL)
{
t = t->points_to();
expr_tree = build_fold_indirect_ref(expr_tree);
}
if (!DECL_P(expr_tree))
expr_tree = save_expr(expr_tree);
Array_type* a = t->array_type();
Type* e = a->element_type()->forwarded();
gcc_assert(e->integer_type() != NULL);
tree valptr = fold_convert(const_ptr_type_node,
a->value_pointer_tree(gogo, expr_tree));
tree len = a->length_tree(gogo, expr_tree);
len = fold_convert_loc(this->location(), size_type_node, len);
if (e->integer_type()->is_unsigned()
&& e->integer_type()->bits() == 8)
{
static tree byte_array_to_string_fndecl;
ret = Gogo::call_builtin(&byte_array_to_string_fndecl,
this->location(),
"__go_byte_array_to_string",
2,
type_tree,
const_ptr_type_node,
valptr,
size_type_node,
len);
}
else
{
gcc_assert(e == Type::lookup_integer_type("int"));
static tree int_array_to_string_fndecl;
ret = Gogo::call_builtin(&int_array_to_string_fndecl,
this->location(),
"__go_int_array_to_string",
2,
type_tree,
const_ptr_type_node,
valptr,
size_type_node,
len);
}
}
else if (type->is_open_array_type() && expr_type->is_string_type())
{
Type* e = type->array_type()->element_type()->forwarded();
gcc_assert(e->integer_type() != NULL);
if (e->integer_type()->is_unsigned()
&& e->integer_type()->bits() == 8)
{
static tree string_to_byte_array_fndecl;
ret = Gogo::call_builtin(&string_to_byte_array_fndecl,
this->location(),
"__go_string_to_byte_array",
1,
type_tree,
TREE_TYPE(expr_tree),
expr_tree);
}
else
{
gcc_assert(e == Type::lookup_integer_type("int"));
static tree string_to_int_array_fndecl;
ret = Gogo::call_builtin(&string_to_int_array_fndecl,
this->location(),
"__go_string_to_int_array",
1,
type_tree,
TREE_TYPE(expr_tree),
expr_tree);
}
}
else if ((type->is_unsafe_pointer_type()
&& expr_type->points_to() != NULL)
|| (expr_type->is_unsafe_pointer_type()
&& type->points_to() != NULL))
ret = fold_convert(type_tree, expr_tree);
else if (type->is_unsafe_pointer_type()
&& expr_type->integer_type() != NULL)
ret = convert_to_pointer(type_tree, expr_tree);
else if (this->may_convert_function_types_
&& type->function_type() != NULL
&& expr_type->function_type() != NULL)
ret = fold_convert_loc(this->location(), type_tree, expr_tree);
else
ret = Expression::convert_for_assignment(context, type, expr_type,
expr_tree, this->location());
return ret;
}
// Output a type conversion in a constant expression.
void
Type_conversion_expression::do_export(Export* exp) const
{
exp->write_c_string("convert(");
exp->write_type(this->type_);
exp->write_c_string(", ");
this->expr_->export_expression(exp);
exp->write_c_string(")");
}
// Import a type conversion or a struct construction.
Expression*
Type_conversion_expression::do_import(Import* imp)
{
imp->require_c_string("convert(");
Type* type = imp->read_type();
imp->require_c_string(", ");
Expression* val = Expression::import_expression(imp);
imp->require_c_string(")");
return Expression::make_cast(type, val, imp->location());
}
// Make a type cast expression.
Expression*
Expression::make_cast(Type* type, Expression* val, source_location location)
{
if (type->is_error_type() || val->is_error_expression())
return Expression::make_error(location);
return new Type_conversion_expression(type, val, location);
}
// Unary expressions.
class Unary_expression : public Expression
{
public:
Unary_expression(Operator op, Expression* expr, source_location location)
: Expression(EXPRESSION_UNARY, location),
op_(op), escapes_(true), expr_(expr)
{ }
// Return the operator.
Operator
op() const
{ return this->op_; }
// Return the operand.
Expression*
operand() const
{ return this->expr_; }
// Record that an address expression does not escape.
void
set_does_not_escape()
{
gcc_assert(this->op_ == OPERATOR_AND);
this->escapes_ = false;
}
// Apply unary opcode OP to UVAL, setting VAL. Return true if this
// could be done, false if not.
static bool
eval_integer(Operator op, Type* utype, mpz_t uval, mpz_t val,
source_location);
// Apply unary opcode OP to UVAL, setting VAL. Return true if this
// could be done, false if not.
static bool
eval_float(Operator op, mpfr_t uval, mpfr_t val);
// Apply unary opcode OP to UREAL/UIMAG, setting REAL/IMAG. Return
// true if this could be done, false if not.
static bool
eval_complex(Operator op, mpfr_t ureal, mpfr_t uimag, mpfr_t real,
mpfr_t imag);
static Expression*
do_import(Import*);
protected:
int
do_traverse(Traverse* traverse)
{ return Expression::traverse(&this->expr_, traverse); }
Expression*
do_lower(Gogo*, Named_object*, int);
bool
do_is_constant() const;
bool
do_integer_constant_value(bool, mpz_t, Type**) const;
bool
do_float_constant_value(mpfr_t, Type**) const;
bool
do_complex_constant_value(mpfr_t, mpfr_t, Type**) const;
Type*
do_type();
void
do_determine_type(const Type_context*);
void
do_check_types(Gogo*);
Expression*
do_copy()
{
return Expression::make_unary(this->op_, this->expr_->copy(),
this->location());
}
bool
do_is_addressable() const
{ return this->op_ == OPERATOR_MULT; }
tree
do_get_tree(Translate_context*);
void
do_export(Export*) const;
private:
// The unary operator to apply.
Operator op_;
// Normally true. False if this is an address expression which does
// not escape the current function.
bool escapes_;
// The operand.
Expression* expr_;
};
// If we are taking the address of a composite literal, and the
// contents are not constant, then we want to make a heap composite
// instead.
Expression*
Unary_expression::do_lower(Gogo*, Named_object*, int)
{
source_location loc = this->location();
Operator op = this->op_;
Expression* expr = this->expr_;
if (op == OPERATOR_MULT && expr->is_type_expression())
return Expression::make_type(Type::make_pointer_type(expr->type()), loc);
// *&x simplifies to x. *(*T)(unsafe.Pointer)(&x) does not require
// moving x to the heap. FIXME: Is it worth doing a real escape
// analysis here? This case is found in math/unsafe.go and is
// therefore worth special casing.
if (op == OPERATOR_MULT)
{
Expression* e = expr;
while (e->classification() == EXPRESSION_CONVERSION)
{
Type_conversion_expression* te
= static_cast<Type_conversion_expression*>(e);
e = te->expr();
}
if (e->classification() == EXPRESSION_UNARY)
{
Unary_expression* ue = static_cast<Unary_expression*>(e);
if (ue->op_ == OPERATOR_AND)
{
if (e == expr)
{
// *&x == x.
return ue->expr_;
}
ue->set_does_not_escape();
}
}
}
if (op == OPERATOR_PLUS || op == OPERATOR_MINUS
|| op == OPERATOR_NOT || op == OPERATOR_XOR)
{
Expression* ret = NULL;
mpz_t eval;
mpz_init(eval);
Type* etype;
if (expr->integer_constant_value(false, eval, &etype))
{
mpz_t val;
mpz_init(val);
if (Unary_expression::eval_integer(op, etype, eval, val, loc))
ret = Expression::make_integer(&val, etype, loc);
mpz_clear(val);
}
mpz_clear(eval);
if (ret != NULL)
return ret;
if (op == OPERATOR_PLUS || op == OPERATOR_MINUS)
{
mpfr_t fval;
mpfr_init(fval);
Type* ftype;
if (expr->float_constant_value(fval, &ftype))
{
mpfr_t val;
mpfr_init(val);
if (Unary_expression::eval_float(op, fval, val))
ret = Expression::make_float(&val, ftype, loc);
mpfr_clear(val);
}
if (ret != NULL)
{
mpfr_clear(fval);
return ret;
}
mpfr_t ival;
mpfr_init(ival);
if (expr->complex_constant_value(fval, ival, &ftype))
{
mpfr_t real;
mpfr_t imag;
mpfr_init(real);
mpfr_init(imag);
if (Unary_expression::eval_complex(op, fval, ival, real, imag))
ret = Expression::make_complex(&real, &imag, ftype, loc);
mpfr_clear(real);
mpfr_clear(imag);
}
mpfr_clear(ival);
mpfr_clear(fval);
if (ret != NULL)
return ret;
}
}
return this;
}
// Return whether a unary expression is a constant.
bool
Unary_expression::do_is_constant() const
{
if (this->op_ == OPERATOR_MULT)
{
// Indirecting through a pointer is only constant if the object
// to which the expression points is constant, but we currently
// have no way to determine that.
return false;
}
else if (this->op_ == OPERATOR_AND)
{
// Taking the address of a variable is constant if it is a
// global variable, not constant otherwise. In other cases
// taking the address is probably not a constant.
Var_expression* ve = this->expr_->var_expression();
if (ve != NULL)
{
Named_object* no = ve->named_object();
return no->is_variable() && no->var_value()->is_global();
}
return false;
}
else
return this->expr_->is_constant();
}
// Apply unary opcode OP to UVAL, setting VAL. UTYPE is the type of
// UVAL, if known; it may be NULL. Return true if this could be done,
// false if not.
bool
Unary_expression::eval_integer(Operator op, Type* utype, mpz_t uval, mpz_t val,
source_location location)
{
switch (op)
{
case OPERATOR_PLUS:
mpz_set(val, uval);
return true;
case OPERATOR_MINUS:
mpz_neg(val, uval);
return Integer_expression::check_constant(val, utype, location);
case OPERATOR_NOT:
mpz_set_ui(val, mpz_cmp_si(uval, 0) == 0 ? 1 : 0);
return true;
case OPERATOR_XOR:
if (utype == NULL
|| utype->integer_type() == NULL
|| utype->integer_type()->is_abstract())
mpz_com(val, uval);
else
{
// The number of HOST_WIDE_INTs that it takes to represent
// UVAL.
size_t count = ((mpz_sizeinbase(uval, 2)
+ HOST_BITS_PER_WIDE_INT
- 1)
/ HOST_BITS_PER_WIDE_INT);
unsigned HOST_WIDE_INT* phwi = new unsigned HOST_WIDE_INT[count];
memset(phwi, 0, count * sizeof(HOST_WIDE_INT));
size_t ecount;
mpz_export(phwi, &ecount, -1, sizeof(HOST_WIDE_INT), 0, 0, uval);
gcc_assert(ecount <= count);
// Trim down to the number of words required by the type.
size_t obits = utype->integer_type()->bits();
if (!utype->integer_type()->is_unsigned())
++obits;
size_t ocount = ((obits + HOST_BITS_PER_WIDE_INT - 1)
/ HOST_BITS_PER_WIDE_INT);
gcc_assert(ocount <= ocount);
for (size_t i = 0; i < ocount; ++i)
phwi[i] = ~phwi[i];
size_t clearbits = ocount * HOST_BITS_PER_WIDE_INT - obits;
if (clearbits != 0)
phwi[ocount - 1] &= (((unsigned HOST_WIDE_INT) (HOST_WIDE_INT) -1)
>> clearbits);
mpz_import(val, ocount, -1, sizeof(HOST_WIDE_INT), 0, 0, phwi);
delete[] phwi;
}
return Integer_expression::check_constant(val, utype, location);
case OPERATOR_AND:
case OPERATOR_MULT:
return false;
default:
gcc_unreachable();
}
}
// Apply unary opcode OP to UVAL, setting VAL. Return true if this
// could be done, false if not.
bool
Unary_expression::eval_float(Operator op, mpfr_t uval, mpfr_t val)
{
switch (op)
{
case OPERATOR_PLUS:
mpfr_set(val, uval, GMP_RNDN);
return true;
case OPERATOR_MINUS:
mpfr_neg(val, uval, GMP_RNDN);
return true;
case OPERATOR_NOT:
case OPERATOR_XOR:
case OPERATOR_AND:
case OPERATOR_MULT:
return false;
default:
gcc_unreachable();
}
}
// Apply unary opcode OP to RVAL/IVAL, setting REAL/IMAG. Return true
// if this could be done, false if not.
bool
Unary_expression::eval_complex(Operator op, mpfr_t rval, mpfr_t ival,
mpfr_t real, mpfr_t imag)
{
switch (op)
{
case OPERATOR_PLUS:
mpfr_set(real, rval, GMP_RNDN);
mpfr_set(imag, ival, GMP_RNDN);
return true;
case OPERATOR_MINUS:
mpfr_neg(real, rval, GMP_RNDN);
mpfr_neg(imag, ival, GMP_RNDN);
return true;
case OPERATOR_NOT:
case OPERATOR_XOR:
case OPERATOR_AND:
case OPERATOR_MULT:
return false;
default:
gcc_unreachable();
}
}
// Return the integral constant value of a unary expression, if it has one.
bool
Unary_expression::do_integer_constant_value(bool iota_is_constant, mpz_t val,
Type** ptype) const
{
mpz_t uval;
mpz_init(uval);
bool ret;
if (!this->expr_->integer_constant_value(iota_is_constant, uval, ptype))
ret = false;
else
ret = Unary_expression::eval_integer(this->op_, *ptype, uval, val,
this->location());
mpz_clear(uval);
return ret;
}
// Return the floating point constant value of a unary expression, if
// it has one.
bool
Unary_expression::do_float_constant_value(mpfr_t val, Type** ptype) const
{
mpfr_t uval;
mpfr_init(uval);
bool ret;
if (!this->expr_->float_constant_value(uval, ptype))
ret = false;
else
ret = Unary_expression::eval_float(this->op_, uval, val);
mpfr_clear(uval);
return ret;
}
// Return the complex constant value of a unary expression, if it has
// one.
bool
Unary_expression::do_complex_constant_value(mpfr_t real, mpfr_t imag,
Type** ptype) const
{
mpfr_t rval;
mpfr_t ival;
mpfr_init(rval);
mpfr_init(ival);
bool ret;
if (!this->expr_->complex_constant_value(rval, ival, ptype))
ret = false;
else
ret = Unary_expression::eval_complex(this->op_, rval, ival, real, imag);
mpfr_clear(rval);
mpfr_clear(ival);
return ret;
}
// Return the type of a unary expression.
Type*
Unary_expression::do_type()
{
switch (this->op_)
{
case OPERATOR_PLUS:
case OPERATOR_MINUS:
case OPERATOR_NOT:
case OPERATOR_XOR:
return this->expr_->type();
case OPERATOR_AND:
return Type::make_pointer_type(this->expr_->type());
case OPERATOR_MULT:
{
Type* subtype = this->expr_->type();
Type* points_to = subtype->points_to();
if (points_to == NULL)
return Type::make_error_type();
return points_to;
}
default:
gcc_unreachable();
}
}
// Determine abstract types for a unary expression.
void
Unary_expression::do_determine_type(const Type_context* context)
{
switch (this->op_)
{
case OPERATOR_PLUS:
case OPERATOR_MINUS:
case OPERATOR_NOT:
case OPERATOR_XOR:
this->expr_->determine_type(context);
break;
case OPERATOR_AND:
// Taking the address of something.
{
Type* subtype = (context->type == NULL
? NULL
: context->type->points_to());
Type_context subcontext(subtype, false);
this->expr_->determine_type(&subcontext);
}
break;
case OPERATOR_MULT:
// Indirecting through a pointer.
{
Type* subtype = (context->type == NULL
? NULL
: Type::make_pointer_type(context->type));
Type_context subcontext(subtype, false);
this->expr_->determine_type(&subcontext);
}
break;
default:
gcc_unreachable();
}
}
// Check types for a unary expression.
void
Unary_expression::do_check_types(Gogo*)
{
Type* type = this->expr_->type();
if (type->is_error_type())
{
this->set_is_error();
return;
}
switch (this->op_)
{
case OPERATOR_PLUS:
case OPERATOR_MINUS:
if (type->integer_type() == NULL
&& type->float_type() == NULL
&& type->complex_type() == NULL)
this->report_error(_("expected numeric type"));
break;
case OPERATOR_NOT:
case OPERATOR_XOR:
if (type->integer_type() == NULL
&& !type->is_boolean_type())
this->report_error(_("expected integer or boolean type"));
break;
case OPERATOR_AND:
if (!this->expr_->is_addressable())
this->report_error(_("invalid operand for unary %<&%>"));
else
this->expr_->address_taken(this->escapes_);
break;
case OPERATOR_MULT:
// Indirecting through a pointer.
if (type->points_to() == NULL)
this->report_error(_("expected pointer"));
break;
default:
gcc_unreachable();
}
}
// Get a tree for a unary expression.
tree
Unary_expression::do_get_tree(Translate_context* context)
{
tree expr = this->expr_->get_tree(context);
if (expr == error_mark_node)
return error_mark_node;
source_location loc = this->location();
switch (this->op_)
{
case OPERATOR_PLUS:
return expr;
case OPERATOR_MINUS:
{
tree type = TREE_TYPE(expr);
tree compute_type = excess_precision_type(type);
if (compute_type != NULL_TREE)
expr = ::convert(compute_type, expr);
tree ret = fold_build1_loc(loc, NEGATE_EXPR,
(compute_type != NULL_TREE
? compute_type
: type),
expr);
if (compute_type != NULL_TREE)
ret = ::convert(type, ret);
return ret;
}
case OPERATOR_NOT:
if (TREE_CODE(TREE_TYPE(expr)) == BOOLEAN_TYPE)
return fold_build1_loc(loc, TRUTH_NOT_EXPR, TREE_TYPE(expr), expr);
else
return fold_build2_loc(loc, NE_EXPR, boolean_type_node, expr,
build_int_cst(TREE_TYPE(expr), 0));
case OPERATOR_XOR:
return fold_build1_loc(loc, BIT_NOT_EXPR, TREE_TYPE(expr), expr);
case OPERATOR_AND:
// We should not see a non-constant constructor here; cases
// where we would see one should have been moved onto the heap
// at parse time. Taking the address of a nonconstant
// constructor will not do what the programmer expects.
gcc_assert(TREE_CODE(expr) != CONSTRUCTOR || TREE_CONSTANT(expr));
gcc_assert(TREE_CODE(expr) != ADDR_EXPR);
// Build a decl for a constant constructor.
if (TREE_CODE(expr) == CONSTRUCTOR && TREE_CONSTANT(expr))
{
tree decl = build_decl(this->location(), VAR_DECL,
create_tmp_var_name("C"), TREE_TYPE(expr));
DECL_EXTERNAL(decl) = 0;
TREE_PUBLIC(decl) = 0;
TREE_READONLY(decl) = 1;
TREE_CONSTANT(decl) = 1;
TREE_STATIC(decl) = 1;
TREE_ADDRESSABLE(decl) = 1;
DECL_ARTIFICIAL(decl) = 1;
DECL_INITIAL(decl) = expr;
rest_of_decl_compilation(decl, 1, 0);
expr = decl;
}
return build_fold_addr_expr_loc(loc, expr);
case OPERATOR_MULT:
{
gcc_assert(POINTER_TYPE_P(TREE_TYPE(expr)));
// If we are dereferencing the pointer to a large struct, we
// need to check for nil. We don't bother to check for small
// structs because we expect the system to crash on a nil
// pointer dereference.
HOST_WIDE_INT s = int_size_in_bytes(TREE_TYPE(TREE_TYPE(expr)));
if (s == -1 || s >= 4096)
{
if (!DECL_P(expr))
expr = save_expr(expr);
tree compare = fold_build2_loc(loc, EQ_EXPR, boolean_type_node,
expr,
fold_convert(TREE_TYPE(expr),
null_pointer_node));
tree crash = Gogo::runtime_error(RUNTIME_ERROR_NIL_DEREFERENCE,
loc);
expr = fold_build2_loc(loc, COMPOUND_EXPR, TREE_TYPE(expr),
build3(COND_EXPR, void_type_node,
compare, crash, NULL_TREE),
expr);
}
// If the type of EXPR is a recursive pointer type, then we
// need to insert a cast before indirecting.
if (TREE_TYPE(TREE_TYPE(expr)) == ptr_type_node)
{
Type* pt = this->expr_->type()->points_to();
tree ind = pt->get_tree(context->gogo());
expr = fold_convert_loc(loc, build_pointer_type(ind), expr);
}
return build_fold_indirect_ref_loc(loc, expr);
}
default:
gcc_unreachable();
}
}
// Export a unary expression.
void
Unary_expression::do_export(Export* exp) const
{
switch (this->op_)
{
case OPERATOR_PLUS:
exp->write_c_string("+ ");
break;
case OPERATOR_MINUS:
exp->write_c_string("- ");
break;
case OPERATOR_NOT:
exp->write_c_string("! ");
break;
case OPERATOR_XOR:
exp->write_c_string("^ ");
break;
case OPERATOR_AND:
case OPERATOR_MULT:
default:
gcc_unreachable();
}
this->expr_->export_expression(exp);
}
// Import a unary expression.
Expression*
Unary_expression::do_import(Import* imp)
{
Operator op;
switch (imp->get_char())
{
case '+':
op = OPERATOR_PLUS;
break;
case '-':
op = OPERATOR_MINUS;
break;
case '!':
op = OPERATOR_NOT;
break;
case '^':
op = OPERATOR_XOR;
break;
default:
gcc_unreachable();
}
imp->require_c_string(" ");
Expression* expr = Expression::import_expression(imp);
return Expression::make_unary(op, expr, imp->location());
}
// Make a unary expression.
Expression*
Expression::make_unary(Operator op, Expression* expr, source_location location)
{
return new Unary_expression(op, expr, location);
}
// If this is an indirection through a pointer, return the expression
// being pointed through. Otherwise return this.
Expression*
Expression::deref()
{
if (this->classification_ == EXPRESSION_UNARY)
{
Unary_expression* ue = static_cast<Unary_expression*>(this);
if (ue->op() == OPERATOR_MULT)
return ue->operand();
}
return this;
}
// Class Binary_expression.
// Traversal.
int
Binary_expression::do_traverse(Traverse* traverse)
{
int t = Expression::traverse(&this->left_, traverse);
if (t == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
return Expression::traverse(&this->right_, traverse);
}
// Compare integer constants according to OP.
bool
Binary_expression::compare_integer(Operator op, mpz_t left_val,
mpz_t right_val)
{
int i = mpz_cmp(left_val, right_val);
switch (op)
{
case OPERATOR_EQEQ:
return i == 0;
case OPERATOR_NOTEQ:
return i != 0;
case OPERATOR_LT:
return i < 0;
case OPERATOR_LE:
return i <= 0;
case OPERATOR_GT:
return i > 0;
case OPERATOR_GE:
return i >= 0;
default:
gcc_unreachable();
}
}
// Compare floating point constants according to OP.
bool
Binary_expression::compare_float(Operator op, Type* type, mpfr_t left_val,
mpfr_t right_val)
{
int i;
if (type == NULL)
i = mpfr_cmp(left_val, right_val);
else
{
mpfr_t lv;
mpfr_init_set(lv, left_val, GMP_RNDN);
mpfr_t rv;
mpfr_init_set(rv, right_val, GMP_RNDN);
Float_expression::constrain_float(lv, type);
Float_expression::constrain_float(rv, type);
i = mpfr_cmp(lv, rv);
mpfr_clear(lv);
mpfr_clear(rv);
}
switch (op)
{
case OPERATOR_EQEQ:
return i == 0;
case OPERATOR_NOTEQ:
return i != 0;
case OPERATOR_LT:
return i < 0;
case OPERATOR_LE:
return i <= 0;
case OPERATOR_GT:
return i > 0;
case OPERATOR_GE:
return i >= 0;
default:
gcc_unreachable();
}
}
// Compare complex constants according to OP. Complex numbers may
// only be compared for equality.
bool
Binary_expression::compare_complex(Operator op, Type* type,
mpfr_t left_real, mpfr_t left_imag,
mpfr_t right_real, mpfr_t right_imag)
{
bool is_equal;
if (type == NULL)
is_equal = (mpfr_cmp(left_real, right_real) == 0
&& mpfr_cmp(left_imag, right_imag) == 0);
else
{
mpfr_t lr;
mpfr_t li;
mpfr_init_set(lr, left_real, GMP_RNDN);
mpfr_init_set(li, left_imag, GMP_RNDN);
mpfr_t rr;
mpfr_t ri;
mpfr_init_set(rr, right_real, GMP_RNDN);
mpfr_init_set(ri, right_imag, GMP_RNDN);
Complex_expression::constrain_complex(lr, li, type);
Complex_expression::constrain_complex(rr, ri, type);
is_equal = mpfr_cmp(lr, rr) == 0 && mpfr_cmp(li, ri) == 0;
mpfr_clear(lr);
mpfr_clear(li);
mpfr_clear(rr);
mpfr_clear(ri);
}
switch (op)
{
case OPERATOR_EQEQ:
return is_equal;
case OPERATOR_NOTEQ:
return !is_equal;
default:
gcc_unreachable();
}
}
// Apply binary opcode OP to LEFT_VAL and RIGHT_VAL, setting VAL.
// LEFT_TYPE is the type of LEFT_VAL, RIGHT_TYPE is the type of
// RIGHT_VAL; LEFT_TYPE and/or RIGHT_TYPE may be NULL. Return true if
// this could be done, false if not.
bool
Binary_expression::eval_integer(Operator op, Type* left_type, mpz_t left_val,
Type* right_type, mpz_t right_val,
source_location location, mpz_t val)
{
bool is_shift_op = false;
switch (op)
{
case OPERATOR_OROR:
case OPERATOR_ANDAND:
case OPERATOR_EQEQ:
case OPERATOR_NOTEQ:
case OPERATOR_LT:
case OPERATOR_LE:
case OPERATOR_GT:
case OPERATOR_GE:
// These return boolean values. We should probably handle them
// anyhow in case a type conversion is used on the result.
return false;
case OPERATOR_PLUS:
mpz_add(val, left_val, right_val);
break;
case OPERATOR_MINUS:
mpz_sub(val, left_val, right_val);
break;
case OPERATOR_OR:
mpz_ior(val, left_val, right_val);
break;
case OPERATOR_XOR:
mpz_xor(val, left_val, right_val);
break;
case OPERATOR_MULT:
mpz_mul(val, left_val, right_val);
break;
case OPERATOR_DIV:
if (mpz_sgn(right_val) != 0)
mpz_tdiv_q(val, left_val, right_val);
else
{
error_at(location, "division by zero");
mpz_set_ui(val, 0);
return true;
}
break;
case OPERATOR_MOD:
if (mpz_sgn(right_val) != 0)
mpz_tdiv_r(val, left_val, right_val);
else
{
error_at(location, "division by zero");
mpz_set_ui(val, 0);
return true;
}
break;
case OPERATOR_LSHIFT:
{
unsigned long shift = mpz_get_ui(right_val);
if (mpz_cmp_ui(right_val, shift) != 0)
{
error_at(location, "shift count overflow");
mpz_set_ui(val, 0);
return true;
}
mpz_mul_2exp(val, left_val, shift);
is_shift_op = true;
break;
}
break;
case OPERATOR_RSHIFT:
{
unsigned long shift = mpz_get_ui(right_val);
if (mpz_cmp_ui(right_val, shift) != 0)
{
error_at(location, "shift count overflow");
mpz_set_ui(val, 0);
return true;
}
if (mpz_cmp_ui(left_val, 0) >= 0)
mpz_tdiv_q_2exp(val, left_val, shift);
else
mpz_fdiv_q_2exp(val, left_val, shift);
is_shift_op = true;
break;
}
break;
case OPERATOR_AND:
mpz_and(val, left_val, right_val);
break;
case OPERATOR_BITCLEAR:
{
mpz_t tval;
mpz_init(tval);
mpz_com(tval, right_val);
mpz_and(val, left_val, tval);
mpz_clear(tval);
}
break;
default:
gcc_unreachable();
}
Type* type = left_type;
if (!is_shift_op)
{
if (type == NULL)
type = right_type;
else if (type != right_type && right_type != NULL)
{
if (type->is_abstract())
type = right_type;
else if (!right_type->is_abstract())
{
// This look like a type error which should be diagnosed
// elsewhere. Don't do anything here, to avoid an
// unhelpful chain of error messages.
return true;
}
}
}
if (type != NULL && !type->is_abstract())
{
// We have to check the operands too, as we have implicitly
// coerced them to TYPE.
if ((type != left_type
&& !Integer_expression::check_constant(left_val, type, location))
|| (!is_shift_op
&& type != right_type
&& !Integer_expression::check_constant(right_val, type,
location))
|| !Integer_expression::check_constant(val, type, location))
mpz_set_ui(val, 0);
}
return true;
}
// Apply binary opcode OP to LEFT_VAL and RIGHT_VAL, setting VAL.
// Return true if this could be done, false if not.
bool
Binary_expression::eval_float(Operator op, Type* left_type, mpfr_t left_val,
Type* right_type, mpfr_t right_val,
mpfr_t val, source_location location)
{
switch (op)
{
case OPERATOR_OROR:
case OPERATOR_ANDAND:
case OPERATOR_EQEQ:
case OPERATOR_NOTEQ:
case OPERATOR_LT:
case OPERATOR_LE:
case OPERATOR_GT:
case OPERATOR_GE:
// These return boolean values. We should probably handle them
// anyhow in case a type conversion is used on the result.
return false;
case OPERATOR_PLUS:
mpfr_add(val, left_val, right_val, GMP_RNDN);
break;
case OPERATOR_MINUS:
mpfr_sub(val, left_val, right_val, GMP_RNDN);
break;
case OPERATOR_OR:
case OPERATOR_XOR:
case OPERATOR_AND:
case OPERATOR_BITCLEAR:
return false;
case OPERATOR_MULT:
mpfr_mul(val, left_val, right_val, GMP_RNDN);
break;
case OPERATOR_DIV:
if (mpfr_zero_p(right_val))
error_at(location, "division by zero");
mpfr_div(val, left_val, right_val, GMP_RNDN);
break;
case OPERATOR_MOD:
return false;
case OPERATOR_LSHIFT:
case OPERATOR_RSHIFT:
return false;
default:
gcc_unreachable();
}
Type* type = left_type;
if (type == NULL)
type = right_type;
else if (type != right_type && right_type != NULL)
{
if (type->is_abstract())
type = right_type;
else if (!right_type->is_abstract())
{
// This looks like a type error which should be diagnosed
// elsewhere. Don't do anything here, to avoid an unhelpful
// chain of error messages.
return true;
}
}
if (type != NULL && !type->is_abstract())
{
if ((type != left_type
&& !Float_expression::check_constant(left_val, type, location))
|| (type != right_type
&& !Float_expression::check_constant(right_val, type,
location))
|| !Float_expression::check_constant(val, type, location))
mpfr_set_ui(val, 0, GMP_RNDN);
}
return true;
}
// Apply binary opcode OP to LEFT_REAL/LEFT_IMAG and
// RIGHT_REAL/RIGHT_IMAG, setting REAL/IMAG. Return true if this
// could be done, false if not.
bool
Binary_expression::eval_complex(Operator op, Type* left_type,
mpfr_t left_real, mpfr_t left_imag,
Type *right_type,
mpfr_t right_real, mpfr_t right_imag,
mpfr_t real, mpfr_t imag,
source_location location)
{
switch (op)
{
case OPERATOR_OROR:
case OPERATOR_ANDAND:
case OPERATOR_EQEQ:
case OPERATOR_NOTEQ:
case OPERATOR_LT:
case OPERATOR_LE:
case OPERATOR_GT:
case OPERATOR_GE:
// These return boolean values and must be handled differently.
return false;
case OPERATOR_PLUS:
mpfr_add(real, left_real, right_real, GMP_RNDN);
mpfr_add(imag, left_imag, right_imag, GMP_RNDN);
break;
case OPERATOR_MINUS:
mpfr_sub(real, left_real, right_real, GMP_RNDN);
mpfr_sub(imag, left_imag, right_imag, GMP_RNDN);
break;
case OPERATOR_OR:
case OPERATOR_XOR:
case OPERATOR_AND:
case OPERATOR_BITCLEAR:
return false;
case OPERATOR_MULT:
{
// You might think that multiplying two complex numbers would
// be simple, and you would be right, until you start to think
// about getting the right answer for infinity. If one
// operand here is infinity and the other is anything other
// than zero or NaN, then we are going to wind up subtracting
// two infinity values. That will give us a NaN, but the
// correct answer is infinity.
mpfr_t lrrr;
mpfr_init(lrrr);
mpfr_mul(lrrr, left_real, right_real, GMP_RNDN);
mpfr_t lrri;
mpfr_init(lrri);
mpfr_mul(lrri, left_real, right_imag, GMP_RNDN);
mpfr_t lirr;
mpfr_init(lirr);
mpfr_mul(lirr, left_imag, right_real, GMP_RNDN);
mpfr_t liri;
mpfr_init(liri);
mpfr_mul(liri, left_imag, right_imag, GMP_RNDN);
mpfr_sub(real, lrrr, liri, GMP_RNDN);
mpfr_add(imag, lrri, lirr, GMP_RNDN);
// If we get NaN on both sides, check whether it should really
// be infinity. The rule is that if either side of the
// complex number is infinity, then the whole value is
// infinity, even if the other side is NaN. So the only case
// we have to fix is the one in which both sides are NaN.
if (mpfr_nan_p(real) && mpfr_nan_p(imag)
&& (!mpfr_nan_p(left_real) || !mpfr_nan_p(left_imag))
&& (!mpfr_nan_p(right_real) || !mpfr_nan_p(right_imag)))
{
bool is_infinity = false;
mpfr_t lr;
mpfr_t li;
mpfr_init_set(lr, left_real, GMP_RNDN);
mpfr_init_set(li, left_imag, GMP_RNDN);
mpfr_t rr;
mpfr_t ri;
mpfr_init_set(rr, right_real, GMP_RNDN);
mpfr_init_set(ri, right_imag, GMP_RNDN);
// If the left side is infinity, then the result is
// infinity.
if (mpfr_inf_p(lr) || mpfr_inf_p(li))
{
mpfr_set_ui(lr, mpfr_inf_p(lr) ? 1 : 0, GMP_RNDN);
mpfr_copysign(lr, lr, left_real, GMP_RNDN);
mpfr_set_ui(li, mpfr_inf_p(li) ? 1 : 0, GMP_RNDN);
mpfr_copysign(li, li, left_imag, GMP_RNDN);
if (mpfr_nan_p(rr))
{
mpfr_set_ui(rr, 0, GMP_RNDN);
mpfr_copysign(rr, rr, right_real, GMP_RNDN);
}
if (mpfr_nan_p(ri))
{
mpfr_set_ui(ri, 0, GMP_RNDN);
mpfr_copysign(ri, ri, right_imag, GMP_RNDN);
}
is_infinity = true;
}
// If the right side is infinity, then the result is
// infinity.
if (mpfr_inf_p(rr) || mpfr_inf_p(ri))
{
mpfr_set_ui(rr, mpfr_inf_p(rr) ? 1 : 0, GMP_RNDN);
mpfr_copysign(rr, rr, right_real, GMP_RNDN);
mpfr_set_ui(ri, mpfr_inf_p(ri) ? 1 : 0, GMP_RNDN);
mpfr_copysign(ri, ri, right_imag, GMP_RNDN);
if (mpfr_nan_p(lr))
{
mpfr_set_ui(lr, 0, GMP_RNDN);
mpfr_copysign(lr, lr, left_real, GMP_RNDN);
}
if (mpfr_nan_p(li))
{
mpfr_set_ui(li, 0, GMP_RNDN);
mpfr_copysign(li, li, left_imag, GMP_RNDN);
}
is_infinity = true;
}
// If we got an overflow in the intermediate computations,
// then the result is infinity.
if (!is_infinity
&& (mpfr_inf_p(lrrr) || mpfr_inf_p(lrri)
|| mpfr_inf_p(lirr) || mpfr_inf_p(liri)))
{
if (mpfr_nan_p(lr))
{
mpfr_set_ui(lr, 0, GMP_RNDN);
mpfr_copysign(lr, lr, left_real, GMP_RNDN);
}
if (mpfr_nan_p(li))
{
mpfr_set_ui(li, 0, GMP_RNDN);
mpfr_copysign(li, li, left_imag, GMP_RNDN);
}
if (mpfr_nan_p(rr))
{
mpfr_set_ui(rr, 0, GMP_RNDN);
mpfr_copysign(rr, rr, right_real, GMP_RNDN);
}
if (mpfr_nan_p(ri))
{
mpfr_set_ui(ri, 0, GMP_RNDN);
mpfr_copysign(ri, ri, right_imag, GMP_RNDN);
}
is_infinity = true;
}
if (is_infinity)
{
mpfr_mul(lrrr, lr, rr, GMP_RNDN);
mpfr_mul(lrri, lr, ri, GMP_RNDN);
mpfr_mul(lirr, li, rr, GMP_RNDN);
mpfr_mul(liri, li, ri, GMP_RNDN);
mpfr_sub(real, lrrr, liri, GMP_RNDN);
mpfr_add(imag, lrri, lirr, GMP_RNDN);
mpfr_set_inf(real, mpfr_sgn(real));
mpfr_set_inf(imag, mpfr_sgn(imag));
}
mpfr_clear(lr);
mpfr_clear(li);
mpfr_clear(rr);
mpfr_clear(ri);
}
mpfr_clear(lrrr);
mpfr_clear(lrri);
mpfr_clear(lirr);
mpfr_clear(liri);
}
break;
case OPERATOR_DIV:
{
// For complex division we want to avoid having an
// intermediate overflow turn the whole result in a NaN. We
// scale the values to try to avoid this.
if (mpfr_zero_p(right_real) && mpfr_zero_p(right_imag))
error_at(location, "division by zero");
mpfr_t rra;
mpfr_t ria;
mpfr_init(rra);
mpfr_init(ria);
mpfr_abs(rra, right_real, GMP_RNDN);
mpfr_abs(ria, right_imag, GMP_RNDN);
mpfr_t t;
mpfr_init(t);
mpfr_max(t, rra, ria, GMP_RNDN);
mpfr_t rr;
mpfr_t ri;
mpfr_init_set(rr, right_real, GMP_RNDN);
mpfr_init_set(ri, right_imag, GMP_RNDN);
long ilogbw = 0;
if (!mpfr_inf_p(t) && !mpfr_nan_p(t) && !mpfr_zero_p(t))
{
ilogbw = mpfr_get_exp(t);
mpfr_mul_2si(rr, rr, - ilogbw, GMP_RNDN);
mpfr_mul_2si(ri, ri, - ilogbw, GMP_RNDN);
}
mpfr_t denom;
mpfr_init(denom);
mpfr_mul(denom, rr, rr, GMP_RNDN);
mpfr_mul(t, ri, ri, GMP_RNDN);
mpfr_add(denom, denom, t, GMP_RNDN);
mpfr_mul(real, left_real, rr, GMP_RNDN);
mpfr_mul(t, left_imag, ri, GMP_RNDN);
mpfr_add(real, real, t, GMP_RNDN);
mpfr_div(real, real, denom, GMP_RNDN);
mpfr_mul_2si(real, real, - ilogbw, GMP_RNDN);
mpfr_mul(imag, left_imag, rr, GMP_RNDN);
mpfr_mul(t, left_real, ri, GMP_RNDN);
mpfr_sub(imag, imag, t, GMP_RNDN);
mpfr_div(imag, imag, denom, GMP_RNDN);
mpfr_mul_2si(imag, imag, - ilogbw, GMP_RNDN);
// If we wind up with NaN on both sides, check whether we
// should really have infinity. The rule is that if either
// side of the complex number is infinity, then the whole
// value is infinity, even if the other side is NaN. So the
// only case we have to fix is the one in which both sides are
// NaN.
if (mpfr_nan_p(real) && mpfr_nan_p(imag)
&& (!mpfr_nan_p(left_real) || !mpfr_nan_p(left_imag))
&& (!mpfr_nan_p(right_real) || !mpfr_nan_p(right_imag)))
{
if (mpfr_zero_p(denom))
{
mpfr_set_inf(real, mpfr_sgn(rr));
mpfr_mul(real, real, left_real, GMP_RNDN);
mpfr_set_inf(imag, mpfr_sgn(rr));
mpfr_mul(imag, imag, left_imag, GMP_RNDN);
}
else if ((mpfr_inf_p(left_real) || mpfr_inf_p(left_imag))
&& mpfr_number_p(rr) && mpfr_number_p(ri))
{
mpfr_set_ui(t, mpfr_inf_p(left_real) ? 1 : 0, GMP_RNDN);
mpfr_copysign(t, t, left_real, GMP_RNDN);
mpfr_t t2;
mpfr_init_set_ui(t2, mpfr_inf_p(left_imag) ? 1 : 0, GMP_RNDN);
mpfr_copysign(t2, t2, left_imag, GMP_RNDN);
mpfr_t t3;
mpfr_init(t3);
mpfr_mul(t3, t, rr, GMP_RNDN);
mpfr_t t4;
mpfr_init(t4);
mpfr_mul(t4, t2, ri, GMP_RNDN);
mpfr_add(t3, t3, t4, GMP_RNDN);
mpfr_set_inf(real, mpfr_sgn(t3));
mpfr_mul(t3, t2, rr, GMP_RNDN);
mpfr_mul(t4, t, ri, GMP_RNDN);
mpfr_sub(t3, t3, t4, GMP_RNDN);
mpfr_set_inf(imag, mpfr_sgn(t3));
mpfr_clear(t2);
mpfr_clear(t3);
mpfr_clear(t4);
}
else if ((mpfr_inf_p(right_real) || mpfr_inf_p(right_imag))
&& mpfr_number_p(left_real) && mpfr_number_p(left_imag))
{
mpfr_set_ui(t, mpfr_inf_p(rr) ? 1 : 0, GMP_RNDN);
mpfr_copysign(t, t, rr, GMP_RNDN);
mpfr_t t2;
mpfr_init_set_ui(t2, mpfr_inf_p(ri) ? 1 : 0, GMP_RNDN);
mpfr_copysign(t2, t2, ri, GMP_RNDN);
mpfr_t t3;
mpfr_init(t3);
mpfr_mul(t3, left_real, t, GMP_RNDN);
mpfr_t t4;
mpfr_init(t4);
mpfr_mul(t4, left_imag, t2, GMP_RNDN);
mpfr_add(t3, t3, t4, GMP_RNDN);
mpfr_set_ui(real, 0, GMP_RNDN);
mpfr_mul(real, real, t3, GMP_RNDN);
mpfr_mul(t3, left_imag, t, GMP_RNDN);
mpfr_mul(t4, left_real, t2, GMP_RNDN);
mpfr_sub(t3, t3, t4, GMP_RNDN);
mpfr_set_ui(imag, 0, GMP_RNDN);
mpfr_mul(imag, imag, t3, GMP_RNDN);
mpfr_clear(t2);
mpfr_clear(t3);
mpfr_clear(t4);
}
}
mpfr_clear(denom);
mpfr_clear(rr);
mpfr_clear(ri);
mpfr_clear(t);
mpfr_clear(rra);
mpfr_clear(ria);
}
break;
case OPERATOR_MOD:
return false;
case OPERATOR_LSHIFT:
case OPERATOR_RSHIFT:
return false;
default:
gcc_unreachable();
}
Type* type = left_type;
if (type == NULL)
type = right_type;
else if (type != right_type && right_type != NULL)
{
if (type->is_abstract())
type = right_type;
else if (!right_type->is_abstract())
{
// This looks like a type error which should be diagnosed
// elsewhere. Don't do anything here, to avoid an unhelpful
// chain of error messages.
return true;
}
}
if (type != NULL && !type->is_abstract())
{
if ((type != left_type
&& !Complex_expression::check_constant(left_real, left_imag,
type, location))
|| (type != right_type
&& !Complex_expression::check_constant(right_real, right_imag,
type, location))
|| !Complex_expression::check_constant(real, imag, type,
location))
{
mpfr_set_ui(real, 0, GMP_RNDN);
mpfr_set_ui(imag, 0, GMP_RNDN);
}
}
return true;
}
// Lower a binary expression. We have to evaluate constant
// expressions now, in order to implement Go's unlimited precision
// constants.
Expression*
Binary_expression::do_lower(Gogo*, Named_object*, int)
{
source_location location = this->location();
Operator op = this->op_;
Expression* left = this->left_;
Expression* right = this->right_;
const bool is_comparison = (op == OPERATOR_EQEQ
|| op == OPERATOR_NOTEQ
|| op == OPERATOR_LT
|| op == OPERATOR_LE
|| op == OPERATOR_GT
|| op == OPERATOR_GE);
// Integer constant expressions.
{
mpz_t left_val;
mpz_init(left_val);
Type* left_type;
mpz_t right_val;
mpz_init(right_val);
Type* right_type;
if (left->integer_constant_value(false, left_val, &left_type)
&& right->integer_constant_value(false, right_val, &right_type))
{
Expression* ret = NULL;
if (left_type != right_type
&& left_type != NULL
&& right_type != NULL
&& left_type->base() != right_type->base()
&& op != OPERATOR_LSHIFT
&& op != OPERATOR_RSHIFT)
{
// May be a type error--let it be diagnosed later.
}
else if (is_comparison)
{
bool b = Binary_expression::compare_integer(op, left_val,
right_val);
ret = Expression::make_cast(Type::lookup_bool_type(),
Expression::make_boolean(b, location),
location);
}
else
{
mpz_t val;
mpz_init(val);
if (Binary_expression::eval_integer(op, left_type, left_val,
right_type, right_val,
location, val))
{
gcc_assert(op != OPERATOR_OROR && op != OPERATOR_ANDAND);
Type* type;
if (op == OPERATOR_LSHIFT || op == OPERATOR_RSHIFT)
type = left_type;
else if (left_type == NULL)
type = right_type;
else if (right_type == NULL)
type = left_type;
else if (!left_type->is_abstract()
&& left_type->named_type() != NULL)
type = left_type;
else if (!right_type->is_abstract()
&& right_type->named_type() != NULL)
type = right_type;
else if (!left_type->is_abstract())
type = left_type;
else if (!right_type->is_abstract())
type = right_type;
else if (left_type->float_type() != NULL)
type = left_type;
else if (right_type->float_type() != NULL)
type = right_type;
else if (left_type->complex_type() != NULL)
type = left_type;
else if (right_type->complex_type() != NULL)
type = right_type;
else
type = left_type;
ret = Expression::make_integer(&val, type, location);
}
mpz_clear(val);
}
if (ret != NULL)
{
mpz_clear(right_val);
mpz_clear(left_val);
return ret;
}
}
mpz_clear(right_val);
mpz_clear(left_val);
}
// Floating point constant expressions.
{
mpfr_t left_val;
mpfr_init(left_val);
Type* left_type;
mpfr_t right_val;
mpfr_init(right_val);
Type* right_type;
if (left->float_constant_value(left_val, &left_type)
&& right->float_constant_value(right_val, &right_type))
{
Expression* ret = NULL;
if (left_type != right_type
&& left_type != NULL
&& right_type != NULL
&& left_type->base() != right_type->base()
&& op != OPERATOR_LSHIFT
&& op != OPERATOR_RSHIFT)
{
// May be a type error--let it be diagnosed later.
}
else if (is_comparison)
{
bool b = Binary_expression::compare_float(op,
(left_type != NULL
? left_type
: right_type),
left_val, right_val);
ret = Expression::make_boolean(b, location);
}
else
{
mpfr_t val;
mpfr_init(val);
if (Binary_expression::eval_float(op, left_type, left_val,
right_type, right_val, val,
location))
{
gcc_assert(op != OPERATOR_OROR && op != OPERATOR_ANDAND
&& op != OPERATOR_LSHIFT && op != OPERATOR_RSHIFT);
Type* type;
if (left_type == NULL)
type = right_type;
else if (right_type == NULL)
type = left_type;
else if (!left_type->is_abstract()
&& left_type->named_type() != NULL)
type = left_type;
else if (!right_type->is_abstract()
&& right_type->named_type() != NULL)
type = right_type;
else if (!left_type->is_abstract())
type = left_type;
else if (!right_type->is_abstract())
type = right_type;
else if (left_type->float_type() != NULL)
type = left_type;
else if (right_type->float_type() != NULL)
type = right_type;
else
type = left_type;
ret = Expression::make_float(&val, type, location);
}
mpfr_clear(val);
}
if (ret != NULL)
{
mpfr_clear(right_val);
mpfr_clear(left_val);
return ret;
}
}
mpfr_clear(right_val);
mpfr_clear(left_val);
}
// Complex constant expressions.
{
mpfr_t left_real;
mpfr_t left_imag;
mpfr_init(left_real);
mpfr_init(left_imag);
Type* left_type;
mpfr_t right_real;
mpfr_t right_imag;
mpfr_init(right_real);
mpfr_init(right_imag);
Type* right_type;
if (left->complex_constant_value(left_real, left_imag, &left_type)
&& right->complex_constant_value(right_real, right_imag, &right_type))
{
Expression* ret = NULL;
if (left_type != right_type
&& left_type != NULL
&& right_type != NULL
&& left_type->base() != right_type->base())
{
// May be a type error--let it be diagnosed later.
}
else if (is_comparison)
{
bool b = Binary_expression::compare_complex(op,
(left_type != NULL
? left_type
: right_type),
left_real,
left_imag,
right_real,
right_imag);
ret = Expression::make_boolean(b, location);
}
else
{
mpfr_t real;
mpfr_t imag;
mpfr_init(real);
mpfr_init(imag);
if (Binary_expression::eval_complex(op, left_type,
left_real, left_imag,
right_type,
right_real, right_imag,
real, imag,
location))
{
gcc_assert(op != OPERATOR_OROR && op != OPERATOR_ANDAND
&& op != OPERATOR_LSHIFT && op != OPERATOR_RSHIFT);
Type* type;
if (left_type == NULL)
type = right_type;
else if (right_type == NULL)
type = left_type;
else if (!left_type->is_abstract()
&& left_type->named_type() != NULL)
type = left_type;
else if (!right_type->is_abstract()
&& right_type->named_type() != NULL)
type = right_type;
else if (!left_type->is_abstract())
type = left_type;
else if (!right_type->is_abstract())
type = right_type;
else if (left_type->complex_type() != NULL)
type = left_type;
else if (right_type->complex_type() != NULL)
type = right_type;
else
type = left_type;
ret = Expression::make_complex(&real, &imag, type,
location);
}
mpfr_clear(real);
mpfr_clear(imag);
}
if (ret != NULL)
{
mpfr_clear(left_real);
mpfr_clear(left_imag);
mpfr_clear(right_real);
mpfr_clear(right_imag);
return ret;
}
}
mpfr_clear(left_real);
mpfr_clear(left_imag);
mpfr_clear(right_real);
mpfr_clear(right_imag);
}
// String constant expressions.
if (op == OPERATOR_PLUS
&& left->type()->is_string_type()
&& right->type()->is_string_type())
{
std::string left_string;
std::string right_string;
if (left->string_constant_value(&left_string)
&& right->string_constant_value(&right_string))
return Expression::make_string(left_string + right_string, location);
}
return this;
}
// Return the integer constant value, if it has one.
bool
Binary_expression::do_integer_constant_value(bool iota_is_constant, mpz_t val,
Type** ptype) const
{
mpz_t left_val;
mpz_init(left_val);
Type* left_type;
if (!this->left_->integer_constant_value(iota_is_constant, left_val,
&left_type))
{
mpz_clear(left_val);
return false;
}
mpz_t right_val;
mpz_init(right_val);
Type* right_type;
if (!this->right_->integer_constant_value(iota_is_constant, right_val,
&right_type))
{
mpz_clear(right_val);
mpz_clear(left_val);
return false;
}
bool ret;
if (left_type != right_type
&& left_type != NULL
&& right_type != NULL
&& left_type->base() != right_type->base()
&& this->op_ != OPERATOR_RSHIFT
&& this->op_ != OPERATOR_LSHIFT)
ret = false;
else
ret = Binary_expression::eval_integer(this->op_, left_type, left_val,
right_type, right_val,
this->location(), val);
mpz_clear(right_val);
mpz_clear(left_val);
if (ret)
*ptype = left_type;
return ret;
}
// Return the floating point constant value, if it has one.
bool
Binary_expression::do_float_constant_value(mpfr_t val, Type** ptype) const
{
mpfr_t left_val;
mpfr_init(left_val);
Type* left_type;
if (!this->left_->float_constant_value(left_val, &left_type))
{
mpfr_clear(left_val);
return false;
}
mpfr_t right_val;
mpfr_init(right_val);
Type* right_type;
if (!this->right_->float_constant_value(right_val, &right_type))
{
mpfr_clear(right_val);
mpfr_clear(left_val);
return false;
}
bool ret;
if (left_type != right_type
&& left_type != NULL
&& right_type != NULL
&& left_type->base() != right_type->base())
ret = false;
else
ret = Binary_expression::eval_float(this->op_, left_type, left_val,
right_type, right_val,
val, this->location());
mpfr_clear(left_val);
mpfr_clear(right_val);
if (ret)
*ptype = left_type;
return ret;
}
// Return the complex constant value, if it has one.
bool
Binary_expression::do_complex_constant_value(mpfr_t real, mpfr_t imag,
Type** ptype) const
{
mpfr_t left_real;
mpfr_t left_imag;
mpfr_init(left_real);
mpfr_init(left_imag);
Type* left_type;
if (!this->left_->complex_constant_value(left_real, left_imag, &left_type))
{
mpfr_clear(left_real);
mpfr_clear(left_imag);
return false;
}
mpfr_t right_real;
mpfr_t right_imag;
mpfr_init(right_real);
mpfr_init(right_imag);
Type* right_type;
if (!this->right_->complex_constant_value(right_real, right_imag,
&right_type))
{
mpfr_clear(left_real);
mpfr_clear(left_imag);
mpfr_clear(right_real);
mpfr_clear(right_imag);
return false;
}
bool ret;
if (left_type != right_type
&& left_type != NULL
&& right_type != NULL
&& left_type->base() != right_type->base())
ret = false;
else
ret = Binary_expression::eval_complex(this->op_, left_type,
left_real, left_imag,
right_type,
right_real, right_imag,
real, imag,
this->location());
mpfr_clear(left_real);
mpfr_clear(left_imag);
mpfr_clear(right_real);
mpfr_clear(right_imag);
if (ret)
*ptype = left_type;
return ret;
}
// Note that the value is being discarded.
void
Binary_expression::do_discarding_value()
{
if (this->op_ == OPERATOR_OROR || this->op_ == OPERATOR_ANDAND)
this->right_->discarding_value();
else
this->warn_about_unused_value();
}
// Get type.
Type*
Binary_expression::do_type()
{
switch (this->op_)
{
case OPERATOR_OROR:
case OPERATOR_ANDAND:
case OPERATOR_EQEQ:
case OPERATOR_NOTEQ:
case OPERATOR_LT:
case OPERATOR_LE:
case OPERATOR_GT:
case OPERATOR_GE:
return Type::lookup_bool_type();
case OPERATOR_PLUS:
case OPERATOR_MINUS:
case OPERATOR_OR:
case OPERATOR_XOR:
case OPERATOR_MULT:
case OPERATOR_DIV:
case OPERATOR_MOD:
case OPERATOR_AND:
case OPERATOR_BITCLEAR:
{
Type* left_type = this->left_->type();
Type* right_type = this->right_->type();
if (left_type->is_error_type())
return left_type;
else if (right_type->is_error_type())
return right_type;
else if (!left_type->is_abstract() && left_type->named_type() != NULL)
return left_type;
else if (!right_type->is_abstract() && right_type->named_type() != NULL)
return right_type;
else if (!left_type->is_abstract())
return left_type;
else if (!right_type->is_abstract())
return right_type;
else if (left_type->complex_type() != NULL)
return left_type;
else if (right_type->complex_type() != NULL)
return right_type;
else if (left_type->float_type() != NULL)
return left_type;
else if (right_type->float_type() != NULL)
return right_type;
else
return left_type;
}
case OPERATOR_LSHIFT:
case OPERATOR_RSHIFT:
return this->left_->type();
default:
gcc_unreachable();
}
}
// Set type for a binary expression.
void
Binary_expression::do_determine_type(const Type_context* context)
{
Type* tleft = this->left_->type();
Type* tright = this->right_->type();
// Both sides should have the same type, except for the shift
// operations. For a comparison, we should ignore the incoming
// type.
bool is_shift_op = (this->op_ == OPERATOR_LSHIFT
|| this->op_ == OPERATOR_RSHIFT);
bool is_comparison = (this->op_ == OPERATOR_EQEQ
|| this->op_ == OPERATOR_NOTEQ
|| this->op_ == OPERATOR_LT
|| this->op_ == OPERATOR_LE
|| this->op_ == OPERATOR_GT
|| this->op_ == OPERATOR_GE);
Type_context subcontext(*context);
if (is_comparison)
{
// In a comparison, the context does not determine the types of
// the operands.
subcontext.type = NULL;
}
// Set the context for the left hand operand.
if (is_shift_op)
{
// The right hand operand plays no role in determining the type
// of the left hand operand. A shift of an abstract integer in
// a string context gets special treatment, which may be a
// language bug.
if (subcontext.type != NULL
&& subcontext.type->is_string_type()
&& tleft->is_abstract())
error_at(this->location(), "shift of non-integer operand");
}
else if (!tleft->is_abstract())
subcontext.type = tleft;
else if (!tright->is_abstract())
subcontext.type = tright;
else if (subcontext.type == NULL)
{
if ((tleft->integer_type() != NULL && tright->integer_type() != NULL)
|| (tleft->float_type() != NULL && tright->float_type() != NULL)
|| (tleft->complex_type() != NULL && tright->complex_type() != NULL))
{
// Both sides have an abstract integer, abstract float, or
// abstract complex type. Just let CONTEXT determine
// whether they may remain abstract or not.
}
else if (tleft->complex_type() != NULL)
subcontext.type = tleft;
else if (tright->complex_type() != NULL)
subcontext.type = tright;
else if (tleft->float_type() != NULL)
subcontext.type = tleft;
else if (tright->float_type() != NULL)
subcontext.type = tright;
else
subcontext.type = tleft;
if (subcontext.type != NULL && !context->may_be_abstract)
subcontext.type = subcontext.type->make_non_abstract_type();
}
this->left_->determine_type(&subcontext);
// The context for the right hand operand is the same as for the
// left hand operand, except for a shift operator.
if (is_shift_op)
{
subcontext.type = Type::lookup_integer_type("uint");
subcontext.may_be_abstract = false;
}
this->right_->determine_type(&subcontext);
}
// Report an error if the binary operator OP does not support TYPE.
// Return whether the operation is OK. This should not be used for
// shift.
bool
Binary_expression::check_operator_type(Operator op, Type* type,
source_location location)
{
switch (op)
{
case OPERATOR_OROR:
case OPERATOR_ANDAND:
if (!type->is_boolean_type())
{
error_at(location, "expected boolean type");
return false;
}
break;
case OPERATOR_EQEQ:
case OPERATOR_NOTEQ:
if (type->integer_type() == NULL
&& type->float_type() == NULL
&& type->complex_type() == NULL
&& !type->is_string_type()
&& type->points_to() == NULL
&& !type->is_nil_type()
&& !type->is_boolean_type()
&& type->interface_type() == NULL
&& (type->array_type() == NULL
|| type->array_type()->length() != NULL)
&& type->map_type() == NULL
&& type->channel_type() == NULL
&& type->function_type() == NULL)
{
error_at(location,
("expected integer, floating, complex, string, pointer, "
"boolean, interface, slice, map, channel, "
"or function type"));
return false;
}
break;
case OPERATOR_LT:
case OPERATOR_LE:
case OPERATOR_GT:
case OPERATOR_GE:
if (type->integer_type() == NULL
&& type->float_type() == NULL
&& !type->is_string_type())
{
error_at(location, "expected integer, floating, or string type");
return false;
}
break;
case OPERATOR_PLUS:
case OPERATOR_PLUSEQ:
if (type->integer_type() == NULL
&& type->float_type() == NULL
&& type->complex_type() == NULL
&& !type->is_string_type())
{
error_at(location,
"expected integer, floating, complex, or string type");
return false;
}
break;
case OPERATOR_MINUS:
case OPERATOR_MINUSEQ:
case OPERATOR_MULT:
case OPERATOR_MULTEQ:
case OPERATOR_DIV:
case OPERATOR_DIVEQ:
if (type->integer_type() == NULL
&& type->float_type() == NULL
&& type->complex_type() == NULL)
{
error_at(location, "expected integer, floating, or complex type");
return false;
}
break;
case OPERATOR_MOD:
case OPERATOR_MODEQ:
case OPERATOR_OR:
case OPERATOR_OREQ:
case OPERATOR_AND:
case OPERATOR_ANDEQ:
case OPERATOR_XOR:
case OPERATOR_XOREQ:
case OPERATOR_BITCLEAR:
case OPERATOR_BITCLEAREQ:
if (type->integer_type() == NULL)
{
error_at(location, "expected integer type");
return false;
}
break;
default:
gcc_unreachable();
}
return true;
}
// Check types.
void
Binary_expression::do_check_types(Gogo*)
{
Type* left_type = this->left_->type();
Type* right_type = this->right_->type();
if (left_type->is_error_type() || right_type->is_error_type())
{
this->set_is_error();
return;
}
if (this->op_ == OPERATOR_EQEQ
|| this->op_ == OPERATOR_NOTEQ
|| this->op_ == OPERATOR_LT
|| this->op_ == OPERATOR_LE
|| this->op_ == OPERATOR_GT
|| this->op_ == OPERATOR_GE)
{
if (!Type::are_assignable(left_type, right_type, NULL)
&& !Type::are_assignable(right_type, left_type, NULL))
{
this->report_error(_("incompatible types in binary expression"));
return;
}
if (!Binary_expression::check_operator_type(this->op_, left_type,
this->location())
|| !Binary_expression::check_operator_type(this->op_, right_type,
this->location()))
{
this->set_is_error();
return;
}
}
else if (this->op_ != OPERATOR_LSHIFT && this->op_ != OPERATOR_RSHIFT)
{
if (!Type::are_compatible_for_binop(left_type, right_type))
{
this->report_error(_("incompatible types in binary expression"));
return;
}
if (!Binary_expression::check_operator_type(this->op_, left_type,
this->location()))
{
this->set_is_error();
return;
}
}
else
{
if (left_type->integer_type() == NULL)
this->report_error(_("shift of non-integer operand"));
if (!right_type->is_abstract()
&& (right_type->integer_type() == NULL
|| !right_type->integer_type()->is_unsigned()))
this->report_error(_("shift count not unsigned integer"));
else
{
mpz_t val;
mpz_init(val);
Type* type;
if (this->right_->integer_constant_value(true, val, &type))
{
if (mpz_sgn(val) < 0)
this->report_error(_("negative shift count"));
}
mpz_clear(val);
}
}
}
// Get a tree for a binary expression.
tree
Binary_expression::do_get_tree(Translate_context* context)
{
tree left = this->left_->get_tree(context);
tree right = this->right_->get_tree(context);
if (left == error_mark_node || right == error_mark_node)
return error_mark_node;
enum tree_code code;
bool use_left_type = true;
bool is_shift_op = false;
switch (this->op_)
{
case OPERATOR_EQEQ:
case OPERATOR_NOTEQ:
case OPERATOR_LT:
case OPERATOR_LE:
case OPERATOR_GT:
case OPERATOR_GE:
return Expression::comparison_tree(context, this->op_,
this->left_->type(), left,
this->right_->type(), right,
this->location());
case OPERATOR_OROR:
code = TRUTH_ORIF_EXPR;
use_left_type = false;
break;
case OPERATOR_ANDAND:
code = TRUTH_ANDIF_EXPR;
use_left_type = false;
break;
case OPERATOR_PLUS:
code = PLUS_EXPR;
break;
case OPERATOR_MINUS:
code = MINUS_EXPR;
break;
case OPERATOR_OR:
code = BIT_IOR_EXPR;
break;
case OPERATOR_XOR:
code = BIT_XOR_EXPR;
break;
case OPERATOR_MULT:
code = MULT_EXPR;
break;
case OPERATOR_DIV:
{
Type *t = this->left_->type();
if (t->float_type() != NULL || t->complex_type() != NULL)
code = RDIV_EXPR;
else
code = TRUNC_DIV_EXPR;
}
break;
case OPERATOR_MOD:
code = TRUNC_MOD_EXPR;
break;
case OPERATOR_LSHIFT:
code = LSHIFT_EXPR;
is_shift_op = true;
break;
case OPERATOR_RSHIFT:
code = RSHIFT_EXPR;
is_shift_op = true;
break;
case OPERATOR_AND:
code = BIT_AND_EXPR;
break;
case OPERATOR_BITCLEAR:
right = fold_build1(BIT_NOT_EXPR, TREE_TYPE(right), right);
code = BIT_AND_EXPR;
break;
default:
gcc_unreachable();
}
tree type = use_left_type ? TREE_TYPE(left) : TREE_TYPE(right);
if (this->left_->type()->is_string_type())
{
gcc_assert(this->op_ == OPERATOR_PLUS);
tree string_type = Type::make_string_type()->get_tree(context->gogo());
static tree string_plus_decl;
return Gogo::call_builtin(&string_plus_decl,
this->location(),
"__go_string_plus",
2,
string_type,
string_type,
left,
string_type,
right);
}
tree compute_type = excess_precision_type(type);
if (compute_type != NULL_TREE)
{
left = ::convert(compute_type, left);
right = ::convert(compute_type, right);
}
tree eval_saved = NULL_TREE;
if (is_shift_op)
{
if (!DECL_P(left))
left = save_expr(left);
if (!DECL_P(right))
right = save_expr(right);
// Make sure the values are evaluated.
eval_saved = fold_build2_loc(this->location(), COMPOUND_EXPR,
void_type_node, left, right);
}
tree ret = fold_build2_loc(this->location(),
code,
compute_type != NULL_TREE ? compute_type : type,
left, right);
if (compute_type != NULL_TREE)
ret = ::convert(type, ret);
// In Go, a shift larger than the size of the type is well-defined.
// This is not true in GENERIC, so we need to insert a conditional.
if (is_shift_op)
{
gcc_assert(INTEGRAL_TYPE_P(TREE_TYPE(left)));
gcc_assert(this->left_->type()->integer_type() != NULL);
int bits = TYPE_PRECISION(TREE_TYPE(left));
tree compare = fold_build2(LT_EXPR, boolean_type_node, right,
build_int_cst_type(TREE_TYPE(right), bits));
tree overflow_result = fold_convert_loc(this->location(),
TREE_TYPE(left),
integer_zero_node);
if (this->op_ == OPERATOR_RSHIFT
&& !this->left_->type()->integer_type()->is_unsigned())
{
tree neg = fold_build2_loc(this->location(), LT_EXPR,
boolean_type_node, left,
fold_convert_loc(this->location(),
TREE_TYPE(left),
integer_zero_node));
tree neg_one = fold_build2_loc(this->location(),
MINUS_EXPR, TREE_TYPE(left),
fold_convert_loc(this->location(),
TREE_TYPE(left),
integer_zero_node),
fold_convert_loc(this->location(),
TREE_TYPE(left),
integer_one_node));
overflow_result = fold_build3_loc(this->location(), COND_EXPR,
TREE_TYPE(left), neg, neg_one,
overflow_result);
}
ret = fold_build3_loc(this->location(), COND_EXPR, TREE_TYPE(left),
compare, ret, overflow_result);
ret = fold_build2_loc(this->location(), COMPOUND_EXPR,
TREE_TYPE(ret), eval_saved, ret);
}
return ret;
}
// Export a binary expression.
void
Binary_expression::do_export(Export* exp) const
{
exp->write_c_string("(");
this->left_->export_expression(exp);
switch (this->op_)
{
case OPERATOR_OROR:
exp->write_c_string(" || ");
break;
case OPERATOR_ANDAND:
exp->write_c_string(" && ");
break;
case OPERATOR_EQEQ:
exp->write_c_string(" == ");
break;
case OPERATOR_NOTEQ:
exp->write_c_string(" != ");
break;
case OPERATOR_LT:
exp->write_c_string(" < ");
break;
case OPERATOR_LE:
exp->write_c_string(" <= ");
break;
case OPERATOR_GT:
exp->write_c_string(" > ");
break;
case OPERATOR_GE:
exp->write_c_string(" >= ");
break;
case OPERATOR_PLUS:
exp->write_c_string(" + ");
break;
case OPERATOR_MINUS:
exp->write_c_string(" - ");
break;
case OPERATOR_OR:
exp->write_c_string(" | ");
break;
case OPERATOR_XOR:
exp->write_c_string(" ^ ");
break;
case OPERATOR_MULT:
exp->write_c_string(" * ");
break;
case OPERATOR_DIV:
exp->write_c_string(" / ");
break;
case OPERATOR_MOD:
exp->write_c_string(" % ");
break;
case OPERATOR_LSHIFT:
exp->write_c_string(" << ");
break;
case OPERATOR_RSHIFT:
exp->write_c_string(" >> ");
break;
case OPERATOR_AND:
exp->write_c_string(" & ");
break;
case OPERATOR_BITCLEAR:
exp->write_c_string(" &^ ");
break;
default:
gcc_unreachable();
}
this->right_->export_expression(exp);
exp->write_c_string(")");
}
// Import a binary expression.
Expression*
Binary_expression::do_import(Import* imp)
{
imp->require_c_string("(");
Expression* left = Expression::import_expression(imp);
Operator op;
if (imp->match_c_string(" || "))
{
op = OPERATOR_OROR;
imp->advance(4);
}
else if (imp->match_c_string(" && "))
{
op = OPERATOR_ANDAND;
imp->advance(4);
}
else if (imp->match_c_string(" == "))
{
op = OPERATOR_EQEQ;
imp->advance(4);
}
else if (imp->match_c_string(" != "))
{
op = OPERATOR_NOTEQ;
imp->advance(4);
}
else if (imp->match_c_string(" < "))
{
op = OPERATOR_LT;
imp->advance(3);
}
else if (imp->match_c_string(" <= "))
{
op = OPERATOR_LE;
imp->advance(4);
}
else if (imp->match_c_string(" > "))
{
op = OPERATOR_GT;
imp->advance(3);
}
else if (imp->match_c_string(" >= "))
{
op = OPERATOR_GE;
imp->advance(4);
}
else if (imp->match_c_string(" + "))
{
op = OPERATOR_PLUS;
imp->advance(3);
}
else if (imp->match_c_string(" - "))
{
op = OPERATOR_MINUS;
imp->advance(3);
}
else if (imp->match_c_string(" | "))
{
op = OPERATOR_OR;
imp->advance(3);
}
else if (imp->match_c_string(" ^ "))
{
op = OPERATOR_XOR;
imp->advance(3);
}
else if (imp->match_c_string(" * "))
{
op = OPERATOR_MULT;
imp->advance(3);
}
else if (imp->match_c_string(" / "))
{
op = OPERATOR_DIV;
imp->advance(3);
}
else if (imp->match_c_string(" % "))
{
op = OPERATOR_MOD;
imp->advance(3);
}
else if (imp->match_c_string(" << "))
{
op = OPERATOR_LSHIFT;
imp->advance(4);
}
else if (imp->match_c_string(" >> "))
{
op = OPERATOR_RSHIFT;
imp->advance(4);
}
else if (imp->match_c_string(" & "))
{
op = OPERATOR_AND;
imp->advance(3);
}
else if (imp->match_c_string(" &^ "))
{
op = OPERATOR_BITCLEAR;
imp->advance(4);
}
else
{
error_at(imp->location(), "unrecognized binary operator");
return Expression::make_error(imp->location());
}
Expression* right = Expression::import_expression(imp);
imp->require_c_string(")");
return Expression::make_binary(op, left, right, imp->location());
}
// Make a binary expression.
Expression*
Expression::make_binary(Operator op, Expression* left, Expression* right,
source_location location)
{
return new Binary_expression(op, left, right, location);
}
// Implement a comparison.
tree
Expression::comparison_tree(Translate_context* context, Operator op,
Type* left_type, tree left_tree,
Type* right_type, tree right_tree,
source_location location)
{
enum tree_code code;
switch (op)
{
case OPERATOR_EQEQ:
code = EQ_EXPR;
break;
case OPERATOR_NOTEQ:
code = NE_EXPR;
break;
case OPERATOR_LT:
code = LT_EXPR;
break;
case OPERATOR_LE:
code = LE_EXPR;
break;
case OPERATOR_GT:
code = GT_EXPR;
break;
case OPERATOR_GE:
code = GE_EXPR;
break;
default:
gcc_unreachable();
}
if (left_type->is_string_type() && right_type->is_string_type())
{
tree string_type = Type::make_string_type()->get_tree(context->gogo());
static tree string_compare_decl;
left_tree = Gogo::call_builtin(&string_compare_decl,
location,
"__go_strcmp",
2,
integer_type_node,
string_type,
left_tree,
string_type,
right_tree);
right_tree = build_int_cst_type(integer_type_node, 0);
}
else if ((left_type->interface_type() != NULL
&& right_type->interface_type() == NULL
&& !right_type->is_nil_type())
|| (left_type->interface_type() == NULL
&& !left_type->is_nil_type()
&& right_type->interface_type() != NULL))
{
// Comparing an interface value to a non-interface value.
if (left_type->interface_type() == NULL)
{
std::swap(left_type, right_type);
std::swap(left_tree, right_tree);
}
// The right operand is not an interface. We need to take its
// address if it is not a pointer.
tree make_tmp;
tree arg;
if (right_type->points_to() != NULL)
{
make_tmp = NULL_TREE;
arg = right_tree;
}
else if (TREE_ADDRESSABLE(TREE_TYPE(right_tree)) || DECL_P(right_tree))
{
make_tmp = NULL_TREE;
arg = build_fold_addr_expr_loc(location, right_tree);
if (DECL_P(right_tree))
TREE_ADDRESSABLE(right_tree) = 1;
}
else
{
tree tmp = create_tmp_var(TREE_TYPE(right_tree),
get_name(right_tree));
DECL_IGNORED_P(tmp) = 0;
DECL_INITIAL(tmp) = right_tree;
TREE_ADDRESSABLE(tmp) = 1;
make_tmp = build1(DECL_EXPR, void_type_node, tmp);
SET_EXPR_LOCATION(make_tmp, location);
arg = build_fold_addr_expr_loc(location, tmp);
}
arg = fold_convert_loc(location, ptr_type_node, arg);
tree descriptor = right_type->type_descriptor_pointer(context->gogo());
if (left_type->interface_type()->is_empty())
{
static tree empty_interface_value_compare_decl;
left_tree = Gogo::call_builtin(&empty_interface_value_compare_decl,
location,
"__go_empty_interface_value_compare",
3,
integer_type_node,
TREE_TYPE(left_tree),
left_tree,
TREE_TYPE(descriptor),
descriptor,
ptr_type_node,
arg);
if (left_tree == error_mark_node)
return error_mark_node;
// This can panic if the type is not comparable.
TREE_NOTHROW(empty_interface_value_compare_decl) = 0;
}
else
{
static tree interface_value_compare_decl;
left_tree = Gogo::call_builtin(&interface_value_compare_decl,
location,
"__go_interface_value_compare",
3,
integer_type_node,
TREE_TYPE(left_tree),
left_tree,
TREE_TYPE(descriptor),
descriptor,
ptr_type_node,
arg);
if (left_tree == error_mark_node)
return error_mark_node;
// This can panic if the type is not comparable.
TREE_NOTHROW(interface_value_compare_decl) = 0;
}
right_tree = build_int_cst_type(integer_type_node, 0);
if (make_tmp != NULL_TREE)
left_tree = build2(COMPOUND_EXPR, TREE_TYPE(left_tree), make_tmp,
left_tree);
}
else if (left_type->interface_type() != NULL
&& right_type->interface_type() != NULL)
{
if (left_type->interface_type()->is_empty())
{
gcc_assert(right_type->interface_type()->is_empty());
static tree empty_interface_compare_decl;
left_tree = Gogo::call_builtin(&empty_interface_compare_decl,
location,
"__go_empty_interface_compare",
2,
integer_type_node,
TREE_TYPE(left_tree),
left_tree,
TREE_TYPE(right_tree),
right_tree);
if (left_tree == error_mark_node)
return error_mark_node;
// This can panic if the type is uncomparable.
TREE_NOTHROW(empty_interface_compare_decl) = 0;
}
else
{
gcc_assert(!right_type->interface_type()->is_empty());
static tree interface_compare_decl;
left_tree = Gogo::call_builtin(&interface_compare_decl,
location,
"__go_interface_compare",
2,
integer_type_node,
TREE_TYPE(left_tree),
left_tree,
TREE_TYPE(right_tree),
right_tree);
if (left_tree == error_mark_node)
return error_mark_node;
// This can panic if the type is uncomparable.
TREE_NOTHROW(interface_compare_decl) = 0;
}
right_tree = build_int_cst_type(integer_type_node, 0);
}
if (left_type->is_nil_type()
&& (op == OPERATOR_EQEQ || op == OPERATOR_NOTEQ))
{
std::swap(left_type, right_type);
std::swap(left_tree, right_tree);
}
if (right_type->is_nil_type())
{
if (left_type->array_type() != NULL
&& left_type->array_type()->length() == NULL)
{
Array_type* at = left_type->array_type();
left_tree = at->value_pointer_tree(context->gogo(), left_tree);
right_tree = fold_convert(TREE_TYPE(left_tree), null_pointer_node);
}
else if (left_type->interface_type() != NULL)
{
// An interface is nil if the first field is nil.
tree left_type_tree = TREE_TYPE(left_tree);
gcc_assert(TREE_CODE(left_type_tree) == RECORD_TYPE);
tree field = TYPE_FIELDS(left_type_tree);
left_tree = build3(COMPONENT_REF, TREE_TYPE(field), left_tree,
field, NULL_TREE);
right_tree = fold_convert(TREE_TYPE(left_tree), null_pointer_node);
}
else
{
gcc_assert(POINTER_TYPE_P(TREE_TYPE(left_tree)));
right_tree = fold_convert(TREE_TYPE(left_tree), null_pointer_node);
}
}
if (left_tree == error_mark_node || right_tree == error_mark_node)
return error_mark_node;
tree ret = fold_build2(code, boolean_type_node, left_tree, right_tree);
if (CAN_HAVE_LOCATION_P(ret))
SET_EXPR_LOCATION(ret, location);
return ret;
}
// Class Bound_method_expression.
// Traversal.
int
Bound_method_expression::do_traverse(Traverse* traverse)
{
if (Expression::traverse(&this->expr_, traverse) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
return Expression::traverse(&this->method_, traverse);
}
// Return the type of a bound method expression. The type of this
// object is really the type of the method with no receiver. We
// should be able to get away with just returning the type of the
// method.
Type*
Bound_method_expression::do_type()
{
return this->method_->type();
}
// Determine the types of a method expression.
void
Bound_method_expression::do_determine_type(const Type_context*)
{
this->method_->determine_type_no_context();
Type* mtype = this->method_->type();
Function_type* fntype = mtype == NULL ? NULL : mtype->function_type();
if (fntype == NULL || !fntype->is_method())
this->expr_->determine_type_no_context();
else
{
Type_context subcontext(fntype->receiver()->type(), false);
this->expr_->determine_type(&subcontext);
}
}
// Check the types of a method expression.
void
Bound_method_expression::do_check_types(Gogo*)
{
Type* type = this->method_->type()->deref();
if (type == NULL
|| type->function_type() == NULL
|| !type->function_type()->is_method())
this->report_error(_("object is not a method"));
else
{
Type* rtype = type->function_type()->receiver()->type()->deref();
Type* etype = (this->expr_type_ != NULL
? this->expr_type_
: this->expr_->type());
etype = etype->deref();
if (!Type::are_identical(rtype, etype, true, NULL))
this->report_error(_("method type does not match object type"));
}
}
// Get the tree for a method expression. There is no standard tree
// representation for this. The only places it may currently be used
// are in a Call_expression or a Go_statement, which will take it
// apart directly. So this has nothing to do at present.
tree
Bound_method_expression::do_get_tree(Translate_context*)
{
gcc_unreachable();
}
// Make a method expression.
Bound_method_expression*
Expression::make_bound_method(Expression* expr, Expression* method,
source_location location)
{
return new Bound_method_expression(expr, method, location);
}
// Class Builtin_call_expression. This is used for a call to a
// builtin function.
class Builtin_call_expression : public Call_expression
{
public:
Builtin_call_expression(Gogo* gogo, Expression* fn, Expression_list* args,
bool is_varargs, source_location location);
protected:
// This overrides Call_expression::do_lower.
Expression*
do_lower(Gogo*, Named_object*, int);
bool
do_is_constant() const;
bool
do_integer_constant_value(bool, mpz_t, Type**) const;
bool
do_float_constant_value(mpfr_t, Type**) const;
bool
do_complex_constant_value(mpfr_t, mpfr_t, Type**) const;
Type*
do_type();
void
do_determine_type(const Type_context*);
void
do_check_types(Gogo*);
Expression*
do_copy()
{
return new Builtin_call_expression(this->gogo_, this->fn()->copy(),
this->args()->copy(),
this->is_varargs(),
this->location());
}
tree
do_get_tree(Translate_context*);
void
do_export(Export*) const;
virtual bool
do_is_recover_call() const;
virtual void
do_set_recover_arg(Expression*);
private:
// The builtin functions.
enum Builtin_function_code
{
BUILTIN_INVALID,
// Predeclared builtin functions.
BUILTIN_APPEND,
BUILTIN_CAP,
BUILTIN_CLOSE,
BUILTIN_CLOSED,
BUILTIN_COMPLEX,
BUILTIN_COPY,
BUILTIN_IMAG,
BUILTIN_LEN,
BUILTIN_MAKE,
BUILTIN_NEW,
BUILTIN_PANIC,
BUILTIN_PRINT,
BUILTIN_PRINTLN,
BUILTIN_REAL,
BUILTIN_RECOVER,
// Builtin functions from the unsafe package.
BUILTIN_ALIGNOF,
BUILTIN_OFFSETOF,
BUILTIN_SIZEOF
};
Expression*
one_arg() const;
bool
check_one_arg();
static Type*
real_imag_type(Type*);
static Type*
complex_type(Type*);
// A pointer back to the general IR structure. This avoids a global
// variable, or passing it around everywhere.
Gogo* gogo_;
// The builtin function being called.
Builtin_function_code code_;
// Used to stop endless loops when the length of an array uses len
// or cap of the array itself.
mutable bool seen_;
};
Builtin_call_expression::Builtin_call_expression(Gogo* gogo,
Expression* fn,
Expression_list* args,
bool is_varargs,
source_location location)
: Call_expression(fn, args, is_varargs, location),
gogo_(gogo), code_(BUILTIN_INVALID), seen_(false)
{
Func_expression* fnexp = this->fn()->func_expression();
gcc_assert(fnexp != NULL);
const std::string& name(fnexp->named_object()->name());
if (name == "append")
this->code_ = BUILTIN_APPEND;
else if (name == "cap")
this->code_ = BUILTIN_CAP;
else if (name == "close")
this->code_ = BUILTIN_CLOSE;
else if (name == "closed")
this->code_ = BUILTIN_CLOSED;
else if (name == "complex")
this->code_ = BUILTIN_COMPLEX;
else if (name == "copy")
this->code_ = BUILTIN_COPY;
else if (name == "imag")
this->code_ = BUILTIN_IMAG;
else if (name == "len")
this->code_ = BUILTIN_LEN;
else if (name == "make")
this->code_ = BUILTIN_MAKE;
else if (name == "new")
this->code_ = BUILTIN_NEW;
else if (name == "panic")
this->code_ = BUILTIN_PANIC;
else if (name == "print")
this->code_ = BUILTIN_PRINT;
else if (name == "println")
this->code_ = BUILTIN_PRINTLN;
else if (name == "real")
this->code_ = BUILTIN_REAL;
else if (name == "recover")
this->code_ = BUILTIN_RECOVER;
else if (name == "Alignof")
this->code_ = BUILTIN_ALIGNOF;
else if (name == "Offsetof")
this->code_ = BUILTIN_OFFSETOF;
else if (name == "Sizeof")
this->code_ = BUILTIN_SIZEOF;
else
gcc_unreachable();
}
// Return whether this is a call to recover. This is a virtual
// function called from the parent class.
bool
Builtin_call_expression::do_is_recover_call() const
{
if (this->classification() == EXPRESSION_ERROR)
return false;
return this->code_ == BUILTIN_RECOVER;
}
// Set the argument for a call to recover.
void
Builtin_call_expression::do_set_recover_arg(Expression* arg)
{
const Expression_list* args = this->args();
gcc_assert(args == NULL || args->empty());
Expression_list* new_args = new Expression_list();
new_args->push_back(arg);
this->set_args(new_args);
}
// A traversal class which looks for a call expression.
class Find_call_expression : public Traverse
{
public:
Find_call_expression()
: Traverse(traverse_expressions),
found_(false)
{ }
int
expression(Expression**);
bool
found()
{ return this->found_; }
private:
bool found_;
};
int
Find_call_expression::expression(Expression** pexpr)
{
if ((*pexpr)->call_expression() != NULL)
{
this->found_ = true;
return TRAVERSE_EXIT;
}
return TRAVERSE_CONTINUE;
}
// Lower a builtin call expression. This turns new and make into
// specific expressions. We also convert to a constant if we can.
Expression*
Builtin_call_expression::do_lower(Gogo* gogo, Named_object* function, int)
{
if (this->code_ == BUILTIN_NEW)
{
const Expression_list* args = this->args();
if (args == NULL || args->size() < 1)
this->report_error(_("not enough arguments"));
else if (args->size() > 1)
this->report_error(_("too many arguments"));
else
{
Expression* arg = args->front();
if (!arg->is_type_expression())
{
error_at(arg->location(), "expected type");
this->set_is_error();
}
else
return Expression::make_allocation(arg->type(), this->location());
}
}
else if (this->code_ == BUILTIN_MAKE)
{
const Expression_list* args = this->args();
if (args == NULL || args->size() < 1)
this->report_error(_("not enough arguments"));
else
{
Expression* arg = args->front();
if (!arg->is_type_expression())
{
error_at(arg->location(), "expected type");
this->set_is_error();
}
else
{
Expression_list* newargs;
if (args->size() == 1)
newargs = NULL;
else
{
newargs = new Expression_list();
Expression_list::const_iterator p = args->begin();
++p;
for (; p != args->end(); ++p)
newargs->push_back(*p);
}
return Expression::make_make(arg->type(), newargs,
this->location());
}
}
}
else if (this->is_constant())
{
// We can only lower len and cap if there are no function calls
// in the arguments. Otherwise we have to make the call.
if (this->code_ == BUILTIN_LEN || this->code_ == BUILTIN_CAP)
{
Expression* arg = this->one_arg();
if (!arg->is_constant())
{
Find_call_expression find_call;
Expression::traverse(&arg, &find_call);
if (find_call.found())
return this;
}
}
mpz_t ival;
mpz_init(ival);
Type* type;
if (this->integer_constant_value(true, ival, &type))
{
Expression* ret = Expression::make_integer(&ival, type,
this->location());
mpz_clear(ival);
return ret;
}
mpz_clear(ival);
mpfr_t rval;
mpfr_init(rval);
if (this->float_constant_value(rval, &type))
{
Expression* ret = Expression::make_float(&rval, type,
this->location());
mpfr_clear(rval);
return ret;
}
mpfr_t imag;
mpfr_init(imag);
if (this->complex_constant_value(rval, imag, &type))
{
Expression* ret = Expression::make_complex(&rval, &imag, type,
this->location());
mpfr_clear(rval);
mpfr_clear(imag);
return ret;
}
mpfr_clear(rval);
mpfr_clear(imag);
}
else if (this->code_ == BUILTIN_RECOVER)
{
if (function != NULL)
function->func_value()->set_calls_recover();
else
{
// Calling recover outside of a function always returns the
// nil empty interface.
Type* eface = Type::make_interface_type(NULL, this->location());
return Expression::make_cast(eface,
Expression::make_nil(this->location()),
this->location());
}
}
else if (this->code_ == BUILTIN_APPEND)
{
// Lower the varargs.
const Expression_list* args = this->args();
if (args == NULL || args->empty())
return this;
Type* slice_type = args->front()->type();
if (!slice_type->is_open_array_type())
{
error_at(args->front()->location(), "argument 1 must be a slice");
this->set_is_error();
return this;
}
return this->lower_varargs(gogo, function, slice_type, 2);
}
return this;
}
// Return the type of the real or imag functions, given the type of
// the argument. We need to map complex to float, complex64 to
// float32, and complex128 to float64, so it has to be done by name.
// This returns NULL if it can't figure out the type.
Type*
Builtin_call_expression::real_imag_type(Type* arg_type)
{
if (arg_type == NULL || arg_type->is_abstract())
return NULL;
Named_type* nt = arg_type->named_type();
if (nt == NULL)
return NULL;
while (nt->real_type()->named_type() != NULL)
nt = nt->real_type()->named_type();
if (nt->name() == "complex64")
return Type::lookup_float_type("float32");
else if (nt->name() == "complex128")
return Type::lookup_float_type("float64");
else
return NULL;
}
// Return the type of the complex function, given the type of one of the
// argments. Like real_imag_type, we have to map by name.
Type*
Builtin_call_expression::complex_type(Type* arg_type)
{
if (arg_type == NULL || arg_type->is_abstract())
return NULL;
Named_type* nt = arg_type->named_type();
if (nt == NULL)
return NULL;
while (nt->real_type()->named_type() != NULL)
nt = nt->real_type()->named_type();
if (nt->name() == "float32")
return Type::lookup_complex_type("complex64");
else if (nt->name() == "float64")
return Type::lookup_complex_type("complex128");
else
return NULL;
}
// Return a single argument, or NULL if there isn't one.
Expression*
Builtin_call_expression::one_arg() const
{
const Expression_list* args = this->args();
if (args->size() != 1)
return NULL;
return args->front();
}
// Return whether this is constant: len of a string, or len or cap of
// a fixed array, or unsafe.Sizeof, unsafe.Offsetof, unsafe.Alignof.
bool
Builtin_call_expression::do_is_constant() const
{
switch (this->code_)
{
case BUILTIN_LEN:
case BUILTIN_CAP:
{
if (this->seen_)
return false;
Expression* arg = this->one_arg();
if (arg == NULL)
return false;
Type* arg_type = arg->type();
if (arg_type->points_to() != NULL
&& arg_type->points_to()->array_type() != NULL
&& !arg_type->points_to()->is_open_array_type())
arg_type = arg_type->points_to();
if (arg_type->array_type() != NULL
&& arg_type->array_type()->length() != NULL)
return true;
if (this->code_ == BUILTIN_LEN && arg_type->is_string_type())
{
this->seen_ = true;
bool ret = arg->is_constant();
this->seen_ = false;
return ret;
}
}
break;
case BUILTIN_SIZEOF:
case BUILTIN_ALIGNOF:
return this->one_arg() != NULL;
case BUILTIN_OFFSETOF:
{
Expression* arg = this->one_arg();
if (arg == NULL)
return false;
return arg->field_reference_expression() != NULL;
}
case BUILTIN_COMPLEX:
{
const Expression_list* args = this->args();
if (args != NULL && args->size() == 2)
return args->front()->is_constant() && args->back()->is_constant();
}
break;
case BUILTIN_REAL:
case BUILTIN_IMAG:
{
Expression* arg = this->one_arg();
return arg != NULL && arg->is_constant();
}
default:
break;
}
return false;
}
// Return an integer constant value if possible.
bool
Builtin_call_expression::do_integer_constant_value(bool iota_is_constant,
mpz_t val,
Type** ptype) const
{
if (this->code_ == BUILTIN_LEN
|| this->code_ == BUILTIN_CAP)
{
Expression* arg = this->one_arg();
if (arg == NULL)
return false;
Type* arg_type = arg->type();
if (this->code_ == BUILTIN_LEN && arg_type->is_string_type())
{
std::string sval;
if (arg->string_constant_value(&sval))
{
mpz_set_ui(val, sval.length());
*ptype = Type::lookup_integer_type("int");
return true;
}
}
if (arg_type->points_to() != NULL
&& arg_type->points_to()->array_type() != NULL
&& !arg_type->points_to()->is_open_array_type())
arg_type = arg_type->points_to();
if (arg_type->array_type() != NULL
&& arg_type->array_type()->length() != NULL)
{
if (this->seen_)
return false;
Expression* e = arg_type->array_type()->length();
this->seen_ = true;
bool r = e->integer_constant_value(iota_is_constant, val, ptype);
this->seen_ = false;
if (r)
{
*ptype = Type::lookup_integer_type("int");
return true;
}
}
}
else if (this->code_ == BUILTIN_SIZEOF
|| this->code_ == BUILTIN_ALIGNOF)
{
Expression* arg = this->one_arg();
if (arg == NULL)
return false;
Type* arg_type = arg->type();
if (arg_type->is_error_type() || arg_type->is_undefined())
return false;
if (arg_type->is_abstract())
return false;
tree arg_type_tree = arg_type->get_tree(this->gogo_);
unsigned long val_long;
if (this->code_ == BUILTIN_SIZEOF)
{
tree type_size = TYPE_SIZE_UNIT(arg_type_tree);
gcc_assert(TREE_CODE(type_size) == INTEGER_CST);
if (TREE_INT_CST_HIGH(type_size) != 0)
return false;
unsigned HOST_WIDE_INT val_wide = TREE_INT_CST_LOW(type_size);
val_long = static_cast<unsigned long>(val_wide);
if (val_long != val_wide)
return false;
}
else if (this->code_ == BUILTIN_ALIGNOF)
{
if (arg->field_reference_expression() == NULL)
val_long = go_type_alignment(arg_type_tree);
else
{
// Calling unsafe.Alignof(s.f) returns the alignment of
// the type of f when it is used as a field in a struct.
val_long = go_field_alignment(arg_type_tree);
}
}
else
gcc_unreachable();
mpz_set_ui(val, val_long);
*ptype = NULL;
return true;
}
else if (this->code_ == BUILTIN_OFFSETOF)
{
Expression* arg = this->one_arg();
if (arg == NULL)
return false;
Field_reference_expression* farg = arg->field_reference_expression();
if (farg == NULL)
return false;
Expression* struct_expr = farg->expr();
Type* st = struct_expr->type();
if (st->struct_type() == NULL)
return false;
tree struct_tree = st->get_tree(this->gogo_);
gcc_assert(TREE_CODE(struct_tree) == RECORD_TYPE);
tree field = TYPE_FIELDS(struct_tree);
for (unsigned int index = farg->field_index(); index > 0; --index)
{
field = DECL_CHAIN(field);
gcc_assert(field != NULL_TREE);
}
HOST_WIDE_INT offset_wide = int_byte_position (field);
if (offset_wide < 0)
return false;
unsigned long offset_long = static_cast<unsigned long>(offset_wide);
if (offset_long != static_cast<unsigned HOST_WIDE_INT>(offset_wide))
return false;
mpz_set_ui(val, offset_long);
return true;
}
return false;
}
// Return a floating point constant value if possible.
bool
Builtin_call_expression::do_float_constant_value(mpfr_t val,
Type** ptype) const
{
if (this->code_ == BUILTIN_REAL || this->code_ == BUILTIN_IMAG)
{
Expression* arg = this->one_arg();
if (arg == NULL)
return false;
mpfr_t real;
mpfr_t imag;
mpfr_init(real);
mpfr_init(imag);
bool ret = false;
Type* type;
if (arg->complex_constant_value(real, imag, &type))
{
if (this->code_ == BUILTIN_REAL)
mpfr_set(val, real, GMP_RNDN);
else
mpfr_set(val, imag, GMP_RNDN);
*ptype = Builtin_call_expression::real_imag_type(type);
ret = true;
}
mpfr_clear(real);
mpfr_clear(imag);
return ret;
}
return false;
}
// Return a complex constant value if possible.
bool
Builtin_call_expression::do_complex_constant_value(mpfr_t real, mpfr_t imag,
Type** ptype) const
{
if (this->code_ == BUILTIN_COMPLEX)
{
const Expression_list* args = this->args();
if (args == NULL || args->size() != 2)
return false;
mpfr_t r;
mpfr_init(r);
Type* rtype;
if (!args->front()->float_constant_value(r, &rtype))
{
mpfr_clear(r);
return false;
}
mpfr_t i;
mpfr_init(i);
bool ret = false;
Type* itype;
if (args->back()->float_constant_value(i, &itype)
&& Type::are_identical(rtype, itype, false, NULL))
{
mpfr_set(real, r, GMP_RNDN);
mpfr_set(imag, i, GMP_RNDN);
*ptype = Builtin_call_expression::complex_type(rtype);
ret = true;
}
mpfr_clear(r);
mpfr_clear(i);
return ret;
}
return false;
}
// Return the type.
Type*
Builtin_call_expression::do_type()
{
switch (this->code_)
{
case BUILTIN_INVALID:
default:
gcc_unreachable();
case BUILTIN_NEW:
case BUILTIN_MAKE:
{
const Expression_list* args = this->args();
if (args == NULL || args->empty())
return Type::make_error_type();
return Type::make_pointer_type(args->front()->type());
}
case BUILTIN_CAP:
case BUILTIN_COPY:
case BUILTIN_LEN:
case BUILTIN_ALIGNOF:
case BUILTIN_OFFSETOF:
case BUILTIN_SIZEOF:
return Type::lookup_integer_type("int");
case BUILTIN_CLOSE:
case BUILTIN_PANIC:
case BUILTIN_PRINT:
case BUILTIN_PRINTLN:
return Type::make_void_type();
case BUILTIN_CLOSED:
return Type::lookup_bool_type();
case BUILTIN_RECOVER:
return Type::make_interface_type(NULL, BUILTINS_LOCATION);
case BUILTIN_APPEND:
{
const Expression_list* args = this->args();
if (args == NULL || args->empty())
return Type::make_error_type();
return args->front()->type();
}
case BUILTIN_REAL:
case BUILTIN_IMAG:
{
Expression* arg = this->one_arg();
if (arg == NULL)
return Type::make_error_type();
Type* t = arg->type();
if (t->is_abstract())
t = t->make_non_abstract_type();
t = Builtin_call_expression::real_imag_type(t);
if (t == NULL)
t = Type::make_error_type();
return t;
}
case BUILTIN_COMPLEX:
{
const Expression_list* args = this->args();
if (args == NULL || args->size() != 2)
return Type::make_error_type();
Type* t = args->front()->type();
if (t->is_abstract())
{
t = args->back()->type();
if (t->is_abstract())
t = t->make_non_abstract_type();
}
t = Builtin_call_expression::complex_type(t);
if (t == NULL)
t = Type::make_error_type();
return t;
}
}
}
// Determine the type.
void
Builtin_call_expression::do_determine_type(const Type_context* context)
{
this->fn()->determine_type_no_context();
const Expression_list* args = this->args();
bool is_print;
Type* arg_type = NULL;
switch (this->code_)
{
case BUILTIN_PRINT:
case BUILTIN_PRINTLN:
// Do not force a large integer constant to "int".
is_print = true;
break;
case BUILTIN_REAL:
case BUILTIN_IMAG:
arg_type = Builtin_call_expression::complex_type(context->type);
is_print = false;
break;
case BUILTIN_COMPLEX:
{
// For the complex function the type of one operand can
// determine the type of the other, as in a binary expression.
arg_type = Builtin_call_expression::real_imag_type(context->type);
if (args != NULL && args->size() == 2)
{
Type* t1 = args->front()->type();
Type* t2 = args->front()->type();
if (!t1->is_abstract())
arg_type = t1;
else if (!t2->is_abstract())
arg_type = t2;
}
is_print = false;
}
break;
default:
is_print = false;
break;
}
if (args != NULL)
{
for (Expression_list::const_iterator pa = args->begin();
pa != args->end();
++pa)
{
Type_context subcontext;
subcontext.type = arg_type;
if (is_print)
{
// We want to print large constants, we so can't just
// use the appropriate nonabstract type. Use uint64 for
// an integer if we know it is nonnegative, otherwise
// use int64 for a integer, otherwise use float64 for a
// float or complex128 for a complex.
Type* want_type = NULL;
Type* atype = (*pa)->type();
if (atype->is_abstract())
{
if (atype->integer_type() != NULL)
{
mpz_t val;
mpz_init(val);
Type* dummy;
if (this->integer_constant_value(true, val, &dummy)
&& mpz_sgn(val) >= 0)
want_type = Type::lookup_integer_type("uint64");
else
want_type = Type::lookup_integer_type("int64");
mpz_clear(val);
}
else if (atype->float_type() != NULL)
want_type = Type::lookup_float_type("float64");
else if (atype->complex_type() != NULL)
want_type = Type::lookup_complex_type("complex128");
else if (atype->is_abstract_string_type())
want_type = Type::lookup_string_type();
else if (atype->is_abstract_boolean_type())
want_type = Type::lookup_bool_type();
else
gcc_unreachable();
subcontext.type = want_type;
}
}
(*pa)->determine_type(&subcontext);
}
}
}
// If there is exactly one argument, return true. Otherwise give an
// error message and return false.
bool
Builtin_call_expression::check_one_arg()
{
const Expression_list* args = this->args();
if (args == NULL || args->size() < 1)
{
this->report_error(_("not enough arguments"));
return false;
}
else if (args->size() > 1)
{
this->report_error(_("too many arguments"));
return false;
}
if (args->front()->is_error_expression()
|| args->front()->type()->is_error_type()
|| args->front()->type()->is_undefined())
{
this->set_is_error();
return false;
}
return true;
}
// Check argument types for a builtin function.
void
Builtin_call_expression::do_check_types(Gogo*)
{
switch (this->code_)
{
case BUILTIN_INVALID:
case BUILTIN_NEW:
case BUILTIN_MAKE:
return;
case BUILTIN_LEN:
case BUILTIN_CAP:
{
// The single argument may be either a string or an array or a
// map or a channel, or a pointer to a closed array.
if (this->check_one_arg())
{
Type* arg_type = this->one_arg()->type();
if (arg_type->points_to() != NULL
&& arg_type->points_to()->array_type() != NULL
&& !arg_type->points_to()->is_open_array_type())
arg_type = arg_type->points_to();
if (this->code_ == BUILTIN_CAP)
{
if (!arg_type->is_error_type()
&& arg_type->array_type() == NULL
&& arg_type->channel_type() == NULL)
this->report_error(_("argument must be array or slice "
"or channel"));
}
else
{
if (!arg_type->is_error_type()
&& !arg_type->is_string_type()
&& arg_type->array_type() == NULL
&& arg_type->map_type() == NULL
&& arg_type->channel_type() == NULL)
this->report_error(_("argument must be string or "
"array or slice or map or channel"));
}
}
}
break;
case BUILTIN_PRINT:
case BUILTIN_PRINTLN:
{
const Expression_list* args = this->args();
if (args == NULL)
{
if (this->code_ == BUILTIN_PRINT)
warning_at(this->location(), 0,
"no arguments for builtin function %<%s%>",
(this->code_ == BUILTIN_PRINT
? "print"
: "println"));
}
else
{
for (Expression_list::const_iterator p = args->begin();
p != args->end();
++p)
{
Type* type = (*p)->type();
if (type->is_error_type()
|| type->is_string_type()
|| type->integer_type() != NULL
|| type->float_type() != NULL
|| type->complex_type() != NULL
|| type->is_boolean_type()
|| type->points_to() != NULL
|| type->interface_type() != NULL
|| type->channel_type() != NULL
|| type->map_type() != NULL
|| type->function_type() != NULL
|| type->is_open_array_type())
;
else
this->report_error(_("unsupported argument type to "
"builtin function"));
}
}
}
break;
case BUILTIN_CLOSE:
case BUILTIN_CLOSED:
if (this->check_one_arg())
{
if (this->one_arg()->type()->channel_type() == NULL)
this->report_error(_("argument must be channel"));
}
break;
case BUILTIN_PANIC:
case BUILTIN_SIZEOF:
case BUILTIN_ALIGNOF:
this->check_one_arg();
break;
case BUILTIN_RECOVER:
if (this->args() != NULL && !this->args()->empty())
this->report_error(_("too many arguments"));
break;
case BUILTIN_OFFSETOF:
if (this->check_one_arg())
{
Expression* arg = this->one_arg();
if (arg->field_reference_expression() == NULL)
this->report_error(_("argument must be a field reference"));
}
break;
case BUILTIN_COPY:
{
const Expression_list* args = this->args();
if (args == NULL || args->size() < 2)
{
this->report_error(_("not enough arguments"));
break;
}
else if (args->size() > 2)
{
this->report_error(_("too many arguments"));
break;
}
Type* arg1_type = args->front()->type();
Type* arg2_type = args->back()->type();
if (arg1_type->is_error_type() || arg2_type->is_error_type())
break;
Type* e1;
if (arg1_type->is_open_array_type())
e1 = arg1_type->array_type()->element_type();
else
{
this->report_error(_("left argument must be a slice"));
break;
}
Type* e2;
if (arg2_type->is_open_array_type())
e2 = arg2_type->array_type()->element_type();
else if (arg2_type->is_string_type())
e2 = Type::lookup_integer_type("uint8");
else
{
this->report_error(_("right argument must be a slice or a string"));
break;
}
if (!Type::are_identical(e1, e2, true, NULL))
this->report_error(_("element types must be the same"));
}
break;
case BUILTIN_APPEND:
{
const Expression_list* args = this->args();
if (args == NULL || args->size() < 2)
{
this->report_error(_("not enough arguments"));
break;
}
if (args->size() > 2)
{
this->report_error(_("too many arguments"));
break;
}
std::string reason;
if (!Type::are_assignable(args->front()->type(), args->back()->type(),
&reason))
{
if (reason.empty())
this->report_error(_("arguments 1 and 2 have different types"));
else
{
error_at(this->location(),
"arguments 1 and 2 have different types (%s)",
reason.c_str());
this->set_is_error();
}
}
break;
}
case BUILTIN_REAL:
case BUILTIN_IMAG:
if (this->check_one_arg())
{
if (this->one_arg()->type()->complex_type() == NULL)
this->report_error(_("argument must have complex type"));
}
break;
case BUILTIN_COMPLEX:
{
const Expression_list* args = this->args();
if (args == NULL || args->size() < 2)
this->report_error(_("not enough arguments"));
else if (args->size() > 2)
this->report_error(_("too many arguments"));
else if (args->front()->is_error_expression()
|| args->front()->type()->is_error_type()
|| args->back()->is_error_expression()
|| args->back()->type()->is_error_type())
this->set_is_error();
else if (!Type::are_identical(args->front()->type(),
args->back()->type(), true, NULL))
this->report_error(_("complex arguments must have identical types"));
else if (args->front()->type()->float_type() == NULL)
this->report_error(_("complex arguments must have "
"floating-point type"));
}
break;
default:
gcc_unreachable();
}
}
// Return the tree for a builtin function.
tree
Builtin_call_expression::do_get_tree(Translate_context* context)
{
Gogo* gogo = context->gogo();
source_location location = this->location();
switch (this->code_)
{
case BUILTIN_INVALID:
case BUILTIN_NEW:
case BUILTIN_MAKE:
gcc_unreachable();
case BUILTIN_LEN:
case BUILTIN_CAP:
{
const Expression_list* args = this->args();
gcc_assert(args != NULL && args->size() == 1);
Expression* arg = *args->begin();
Type* arg_type = arg->type();
if (this->seen_)
{
gcc_assert(saw_errors());
return error_mark_node;
}
this->seen_ = true;
tree arg_tree = arg->get_tree(context);
this->seen_ = false;
if (arg_tree == error_mark_node)
return error_mark_node;
if (arg_type->points_to() != NULL)
{
arg_type = arg_type->points_to();
gcc_assert(arg_type->array_type() != NULL
&& !arg_type->is_open_array_type());
gcc_assert(POINTER_TYPE_P(TREE_TYPE(arg_tree)));
arg_tree = build_fold_indirect_ref(arg_tree);
}
tree val_tree;
if (this->code_ == BUILTIN_LEN)
{
if (arg_type->is_string_type())
val_tree = String_type::length_tree(gogo, arg_tree);
else if (arg_type->array_type() != NULL)
{
if (this->seen_)
{
gcc_assert(saw_errors());
return error_mark_node;
}
this->seen_ = true;
val_tree = arg_type->array_type()->length_tree(gogo, arg_tree);
this->seen_ = false;
}
else if (arg_type->map_type() != NULL)
{
static tree map_len_fndecl;
val_tree = Gogo::call_builtin(&map_len_fndecl,
location,
"__go_map_len",
1,
sizetype,
arg_type->get_tree(gogo),
arg_tree);
}
else if (arg_type->channel_type() != NULL)
{
static tree chan_len_fndecl;
val_tree = Gogo::call_builtin(&chan_len_fndecl,
location,
"__go_chan_len",
1,
sizetype,
arg_type->get_tree(gogo),
arg_tree);
}
else
gcc_unreachable();
}
else
{
if (arg_type->array_type() != NULL)
{
if (this->seen_)
{
gcc_assert(saw_errors());
return error_mark_node;
}
this->seen_ = true;
val_tree = arg_type->array_type()->capacity_tree(gogo,
arg_tree);
this->seen_ = false;
}
else if (arg_type->channel_type() != NULL)
{
static tree chan_cap_fndecl;
val_tree = Gogo::call_builtin(&chan_cap_fndecl,
location,
"__go_chan_cap",
1,
sizetype,
arg_type->get_tree(gogo),
arg_tree);
}
else
gcc_unreachable();
}
if (val_tree == error_mark_node)
return error_mark_node;
tree type_tree = Type::lookup_integer_type("int")->get_tree(gogo);
if (type_tree == TREE_TYPE(val_tree))
return val_tree;
else
return fold(convert_to_integer(type_tree, val_tree));
}
case BUILTIN_PRINT:
case BUILTIN_PRINTLN:
{
const bool is_ln = this->code_ == BUILTIN_PRINTLN;
tree stmt_list = NULL_TREE;
const Expression_list* call_args = this->args();
if (call_args != NULL)
{
for (Expression_list::const_iterator p = call_args->begin();
p != call_args->end();
++p)
{
if (is_ln && p != call_args->begin())
{
static tree print_space_fndecl;
tree call = Gogo::call_builtin(&print_space_fndecl,
location,
"__go_print_space",
0,
void_type_node);
if (call == error_mark_node)
return error_mark_node;
append_to_statement_list(call, &stmt_list);
}
Type* type = (*p)->type();
tree arg = (*p)->get_tree(context);
if (arg == error_mark_node)
return error_mark_node;
tree* pfndecl;
const char* fnname;
if (type->is_string_type())
{
static tree print_string_fndecl;
pfndecl = &print_string_fndecl;
fnname = "__go_print_string";
}
else if (type->integer_type() != NULL
&& type->integer_type()->is_unsigned())
{
static tree print_uint64_fndecl;
pfndecl = &print_uint64_fndecl;
fnname = "__go_print_uint64";
Type* itype = Type::lookup_integer_type("uint64");
arg = fold_convert_loc(location, itype->get_tree(gogo),
arg);
}
else if (type->integer_type() != NULL)
{
static tree print_int64_fndecl;
pfndecl = &print_int64_fndecl;
fnname = "__go_print_int64";
Type* itype = Type::lookup_integer_type("int64");
arg = fold_convert_loc(location, itype->get_tree(gogo),
arg);
}
else if (type->float_type() != NULL)
{
static tree print_double_fndecl;
pfndecl = &print_double_fndecl;
fnname = "__go_print_double";
arg = fold_convert_loc(location, double_type_node, arg);
}
else if (type->complex_type() != NULL)
{
static tree print_complex_fndecl;
pfndecl = &print_complex_fndecl;
fnname = "__go_print_complex";
arg = fold_convert_loc(location, complex_double_type_node,
arg);
}
else if (type->is_boolean_type())
{
static tree print_bool_fndecl;
pfndecl = &print_bool_fndecl;
fnname = "__go_print_bool";
}
else if (type->points_to() != NULL
|| type->channel_type() != NULL
|| type->map_type() != NULL
|| type->function_type() != NULL)
{
static tree print_pointer_fndecl;
pfndecl = &print_pointer_fndecl;
fnname = "__go_print_pointer";
arg = fold_convert_loc(location, ptr_type_node, arg);
}
else if (type->interface_type() != NULL)
{
if (type->interface_type()->is_empty())
{
static tree print_empty_interface_fndecl;
pfndecl = &print_empty_interface_fndecl;
fnname = "__go_print_empty_interface";
}
else
{
static tree print_interface_fndecl;
pfndecl = &print_interface_fndecl;
fnname = "__go_print_interface";
}
}
else if (type->is_open_array_type())
{
static tree print_slice_fndecl;
pfndecl = &print_slice_fndecl;
fnname = "__go_print_slice";
}
else
gcc_unreachable();
tree call = Gogo::call_builtin(pfndecl,
location,
fnname,
1,
void_type_node,
TREE_TYPE(arg),
arg);
if (call == error_mark_node)
return error_mark_node;
append_to_statement_list(call, &stmt_list);
}
}
if (is_ln)
{
static tree print_nl_fndecl;
tree call = Gogo::call_builtin(&print_nl_fndecl,
location,
"__go_print_nl",
0,
void_type_node);
if (call == error_mark_node)
return error_mark_node;
append_to_statement_list(call, &stmt_list);
}
return stmt_list;
}
case BUILTIN_PANIC:
{
const Expression_list* args = this->args();
gcc_assert(args != NULL && args->size() == 1);
Expression* arg = args->front();
tree arg_tree = arg->get_tree(context);
if (arg_tree == error_mark_node)
return error_mark_node;
Type *empty = Type::make_interface_type(NULL, BUILTINS_LOCATION);
arg_tree = Expression::convert_for_assignment(context, empty,
arg->type(),
arg_tree, location);
static tree panic_fndecl;
tree call = Gogo::call_builtin(&panic_fndecl,
location,
"__go_panic",
1,
void_type_node,
TREE_TYPE(arg_tree),
arg_tree);
if (call == error_mark_node)
return error_mark_node;
// This function will throw an exception.
TREE_NOTHROW(panic_fndecl) = 0;
// This function will not return.
TREE_THIS_VOLATILE(panic_fndecl) = 1;
return call;
}
case BUILTIN_RECOVER:
{
// The argument is set when building recover thunks. It's a
// boolean value which is true if we can recover a value now.
const Expression_list* args = this->args();
gcc_assert(args != NULL && args->size() == 1);
Expression* arg = args->front();
tree arg_tree = arg->get_tree(context);
if (arg_tree == error_mark_node)
return error_mark_node;
Type *empty = Type::make_interface_type(NULL, BUILTINS_LOCATION);
tree empty_tree = empty->get_tree(context->gogo());
Type* nil_type = Type::make_nil_type();
Expression* nil = Expression::make_nil(location);
tree nil_tree = nil->get_tree(context);
tree empty_nil_tree = Expression::convert_for_assignment(context,
empty,
nil_type,
nil_tree,
location);
// We need to handle a deferred call to recover specially,
// because it changes whether it can recover a panic or not.
// See test7 in test/recover1.go.
tree call;
if (this->is_deferred())
{
static tree deferred_recover_fndecl;
call = Gogo::call_builtin(&deferred_recover_fndecl,
location,
"__go_deferred_recover",
0,
empty_tree);
}
else
{
static tree recover_fndecl;
call = Gogo::call_builtin(&recover_fndecl,
location,
"__go_recover",
0,
empty_tree);
}
if (call == error_mark_node)
return error_mark_node;
return fold_build3_loc(location, COND_EXPR, empty_tree, arg_tree,
call, empty_nil_tree);
}
case BUILTIN_CLOSE:
case BUILTIN_CLOSED:
{
const Expression_list* args = this->args();
gcc_assert(args != NULL && args->size() == 1);
Expression* arg = args->front();
tree arg_tree = arg->get_tree(context);
if (arg_tree == error_mark_node)
return error_mark_node;
if (this->code_ == BUILTIN_CLOSE)
{
static tree close_fndecl;
return Gogo::call_builtin(&close_fndecl,
location,
"__go_builtin_close",
1,
void_type_node,
TREE_TYPE(arg_tree),
arg_tree);
}
else
{
static tree closed_fndecl;
return Gogo::call_builtin(&closed_fndecl,
location,
"__go_builtin_closed",
1,
boolean_type_node,
TREE_TYPE(arg_tree),
arg_tree);
}
}
case BUILTIN_SIZEOF:
case BUILTIN_OFFSETOF:
case BUILTIN_ALIGNOF:
{
mpz_t val;
mpz_init(val);
Type* dummy;
bool b = this->integer_constant_value(true, val, &dummy);
gcc_assert(b);
tree type = Type::lookup_integer_type("int")->get_tree(gogo);
tree ret = Expression::integer_constant_tree(val, type);
mpz_clear(val);
return ret;
}
case BUILTIN_COPY:
{
const Expression_list* args = this->args();
gcc_assert(args != NULL && args->size() == 2);
Expression* arg1 = args->front();
Expression* arg2 = args->back();
tree arg1_tree = arg1->get_tree(context);
tree arg2_tree = arg2->get_tree(context);
if (arg1_tree == error_mark_node || arg2_tree == error_mark_node)
return error_mark_node;
Type* arg1_type = arg1->type();
Array_type* at = arg1_type->array_type();
arg1_tree = save_expr(arg1_tree);
tree arg1_val = at->value_pointer_tree(gogo, arg1_tree);
tree arg1_len = at->length_tree(gogo, arg1_tree);
if (arg1_val == error_mark_node || arg1_len == error_mark_node)
return error_mark_node;
Type* arg2_type = arg2->type();
tree arg2_val;
tree arg2_len;
if (arg2_type->is_open_array_type())
{
at = arg2_type->array_type();
arg2_tree = save_expr(arg2_tree);
arg2_val = at->value_pointer_tree(gogo, arg2_tree);
arg2_len = at->length_tree(gogo, arg2_tree);
}
else
{
arg2_tree = save_expr(arg2_tree);
arg2_val = String_type::bytes_tree(gogo, arg2_tree);
arg2_len = String_type::length_tree(gogo, arg2_tree);
}
if (arg2_val == error_mark_node || arg2_len == error_mark_node)
return error_mark_node;
arg1_len = save_expr(arg1_len);
arg2_len = save_expr(arg2_len);
tree len = fold_build3_loc(location, COND_EXPR, TREE_TYPE(arg1_len),
fold_build2_loc(location, LT_EXPR,
boolean_type_node,
arg1_len, arg2_len),
arg1_len, arg2_len);
len = save_expr(len);
Type* element_type = at->element_type();
tree element_type_tree = element_type->get_tree(gogo);
if (element_type_tree == error_mark_node)
return error_mark_node;
tree element_size = TYPE_SIZE_UNIT(element_type_tree);
tree bytecount = fold_convert_loc(location, TREE_TYPE(element_size),
len);
bytecount = fold_build2_loc(location, MULT_EXPR,
TREE_TYPE(element_size),
bytecount, element_size);
bytecount = fold_convert_loc(location, size_type_node, bytecount);
arg1_val = fold_convert_loc(location, ptr_type_node, arg1_val);
arg2_val = fold_convert_loc(location, ptr_type_node, arg2_val);
static tree copy_fndecl;
tree call = Gogo::call_builtin(©_fndecl,
location,
"__go_copy",
3,
void_type_node,
ptr_type_node,
arg1_val,
ptr_type_node,
arg2_val,
size_type_node,
bytecount);
if (call == error_mark_node)
return error_mark_node;
return fold_build2_loc(location, COMPOUND_EXPR, TREE_TYPE(len),
call, len);
}
case BUILTIN_APPEND:
{
const Expression_list* args = this->args();
gcc_assert(args != NULL && args->size() == 2);
Expression* arg1 = args->front();
Expression* arg2 = args->back();
tree arg1_tree = arg1->get_tree(context);
tree arg2_tree = arg2->get_tree(context);
if (arg1_tree == error_mark_node || arg2_tree == error_mark_node)
return error_mark_node;
Array_type* at = arg1->type()->array_type();
Type* element_type = at->element_type();
arg2_tree = Expression::convert_for_assignment(context, at,
arg2->type(),
arg2_tree,
location);
if (arg2_tree == error_mark_node)
return error_mark_node;
arg2_tree = save_expr(arg2_tree);
tree arg2_val = at->value_pointer_tree(gogo, arg2_tree);
tree arg2_len = at->length_tree(gogo, arg2_tree);
if (arg2_val == error_mark_node || arg2_len == error_mark_node)
return error_mark_node;
arg2_val = fold_convert_loc(location, ptr_type_node, arg2_val);
arg2_len = fold_convert_loc(location, size_type_node, arg2_len);
tree element_type_tree = element_type->get_tree(gogo);
if (element_type_tree == error_mark_node)
return error_mark_node;
tree element_size = TYPE_SIZE_UNIT(element_type_tree);
element_size = fold_convert_loc(location, size_type_node,
element_size);
// We rebuild the decl each time since the slice types may
// change.
tree append_fndecl = NULL_TREE;
return Gogo::call_builtin(&append_fndecl,
location,
"__go_append",
4,
TREE_TYPE(arg1_tree),
TREE_TYPE(arg1_tree),
arg1_tree,
ptr_type_node,
arg2_val,
size_type_node,
arg2_len,
size_type_node,
element_size);
}
case BUILTIN_REAL:
case BUILTIN_IMAG:
{
const Expression_list* args = this->args();
gcc_assert(args != NULL && args->size() == 1);
Expression* arg = args->front();
tree arg_tree = arg->get_tree(context);
if (arg_tree == error_mark_node)
return error_mark_node;
gcc_assert(COMPLEX_FLOAT_TYPE_P(TREE_TYPE(arg_tree)));
if (this->code_ == BUILTIN_REAL)
return fold_build1_loc(location, REALPART_EXPR,
TREE_TYPE(TREE_TYPE(arg_tree)),
arg_tree);
else
return fold_build1_loc(location, IMAGPART_EXPR,
TREE_TYPE(TREE_TYPE(arg_tree)),
arg_tree);
}
case BUILTIN_COMPLEX:
{
const Expression_list* args = this->args();
gcc_assert(args != NULL && args->size() == 2);
tree r = args->front()->get_tree(context);
tree i = args->back()->get_tree(context);
if (r == error_mark_node || i == error_mark_node)
return error_mark_node;
gcc_assert(TYPE_MAIN_VARIANT(TREE_TYPE(r))
== TYPE_MAIN_VARIANT(TREE_TYPE(i)));
gcc_assert(SCALAR_FLOAT_TYPE_P(TREE_TYPE(r)));
return fold_build2_loc(location, COMPLEX_EXPR,
build_complex_type(TREE_TYPE(r)),
r, i);
}
default:
gcc_unreachable();
}
}
// We have to support exporting a builtin call expression, because
// code can set a constant to the result of a builtin expression.
void
Builtin_call_expression::do_export(Export* exp) const
{
bool ok = false;
mpz_t val;
mpz_init(val);
Type* dummy;
if (this->integer_constant_value(true, val, &dummy))
{
Integer_expression::export_integer(exp, val);
ok = true;
}
mpz_clear(val);
if (!ok)
{
mpfr_t fval;
mpfr_init(fval);
if (this->float_constant_value(fval, &dummy))
{
Float_expression::export_float(exp, fval);
ok = true;
}
mpfr_clear(fval);
}
if (!ok)
{
mpfr_t real;
mpfr_t imag;
mpfr_init(real);
mpfr_init(imag);
if (this->complex_constant_value(real, imag, &dummy))
{
Complex_expression::export_complex(exp, real, imag);
ok = true;
}
mpfr_clear(real);
mpfr_clear(imag);
}
if (!ok)
{
error_at(this->location(), "value is not constant");
return;
}
// A trailing space lets us reliably identify the end of the number.
exp->write_c_string(" ");
}
// Class Call_expression.
// Traversal.
int
Call_expression::do_traverse(Traverse* traverse)
{
if (Expression::traverse(&this->fn_, traverse) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
if (this->args_ != NULL)
{
if (this->args_->traverse(traverse) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
}
return TRAVERSE_CONTINUE;
}
// Lower a call statement.
Expression*
Call_expression::do_lower(Gogo* gogo, Named_object* function, int)
{
// A type case can look like a function call.
if (this->fn_->is_type_expression()
&& this->args_ != NULL
&& this->args_->size() == 1)
return Expression::make_cast(this->fn_->type(), this->args_->front(),
this->location());
// Recognize a call to a builtin function.
Func_expression* fne = this->fn_->func_expression();
if (fne != NULL
&& fne->named_object()->is_function_declaration()
&& fne->named_object()->func_declaration_value()->type()->is_builtin())
return new Builtin_call_expression(gogo, this->fn_, this->args_,
this->is_varargs_, this->location());
// Handle an argument which is a call to a function which returns
// multiple results.
if (this->args_ != NULL
&& this->args_->size() == 1
&& this->args_->front()->call_expression() != NULL
&& this->fn_->type()->function_type() != NULL)
{
Function_type* fntype = this->fn_->type()->function_type();
size_t rc = this->args_->front()->call_expression()->result_count();
if (rc > 1
&& fntype->parameters() != NULL
&& (fntype->parameters()->size() == rc
|| (fntype->is_varargs()
&& fntype->parameters()->size() - 1 <= rc)))
{
Call_expression* call = this->args_->front()->call_expression();
Expression_list* args = new Expression_list;
for (size_t i = 0; i < rc; ++i)
args->push_back(Expression::make_call_result(call, i));
// We can't return a new call expression here, because this
// one may be referenced by Call_result expressions. FIXME.
delete this->args_;
this->args_ = args;
}
}
// Handle a call to a varargs function by packaging up the extra
// parameters.
if (this->fn_->type()->function_type() != NULL
&& this->fn_->type()->function_type()->is_varargs())
{
Function_type* fntype = this->fn_->type()->function_type();
const Typed_identifier_list* parameters = fntype->parameters();
gcc_assert(parameters != NULL && !parameters->empty());
Type* varargs_type = parameters->back().type();
return this->lower_varargs(gogo, function, varargs_type,
parameters->size());
}
return this;
}
// Lower a call to a varargs function. FUNCTION is the function in
// which the call occurs--it's not the function we are calling.
// VARARGS_TYPE is the type of the varargs parameter, a slice type.
// PARAM_COUNT is the number of parameters of the function we are
// calling; the last of these parameters will be the varargs
// parameter.
Expression*
Call_expression::lower_varargs(Gogo* gogo, Named_object* function,
Type* varargs_type, size_t param_count)
{
if (this->varargs_are_lowered_)
return this;
source_location loc = this->location();
gcc_assert(param_count > 0);
gcc_assert(varargs_type->is_open_array_type());
size_t arg_count = this->args_ == NULL ? 0 : this->args_->size();
if (arg_count < param_count - 1)
{
// Not enough arguments; will be caught in check_types.
return this;
}
Expression_list* old_args = this->args_;
Expression_list* new_args = new Expression_list();
bool push_empty_arg = false;
if (old_args == NULL || old_args->empty())
{
gcc_assert(param_count == 1);
push_empty_arg = true;
}
else
{
Expression_list::const_iterator pa;
int i = 1;
for (pa = old_args->begin(); pa != old_args->end(); ++pa, ++i)
{
if (static_cast<size_t>(i) == param_count)
break;
new_args->push_back(*pa);
}
// We have reached the varargs parameter.
bool issued_error = false;
if (pa == old_args->end())
push_empty_arg = true;
else if (pa + 1 == old_args->end() && this->is_varargs_)
new_args->push_back(*pa);
else if (this->is_varargs_)
{
this->report_error(_("too many arguments"));
return this;
}
else if (pa + 1 == old_args->end()
&& this->is_compatible_varargs_argument(function, *pa,
varargs_type,
&issued_error))
new_args->push_back(*pa);
else
{
Type* element_type = varargs_type->array_type()->element_type();
Expression_list* vals = new Expression_list;
for (; pa != old_args->end(); ++pa, ++i)
{
// Check types here so that we get a better message.
Type* patype = (*pa)->type();
source_location paloc = (*pa)->location();
if (!this->check_argument_type(i, element_type, patype,
paloc, issued_error))
continue;
vals->push_back(*pa);
}
Expression* val =
Expression::make_slice_composite_literal(varargs_type, vals, loc);
new_args->push_back(val);
}
}
if (push_empty_arg)
new_args->push_back(Expression::make_nil(loc));
// We can't return a new call expression here, because this one may
// be referenced by Call_result expressions. FIXME.
if (old_args != NULL)
delete old_args;
this->args_ = new_args;
this->varargs_are_lowered_ = true;
// Lower all the new subexpressions.
Expression* ret = this;
gogo->lower_expression(function, &ret);
gcc_assert(ret == this);
return ret;
}
// Return true if ARG is a varargs argment which should be passed to
// the varargs parameter of type PARAM_TYPE without wrapping. ARG
// will be the last argument passed in the call, and PARAM_TYPE will
// be the type of the last parameter of the varargs function being
// called.
bool
Call_expression::is_compatible_varargs_argument(Named_object* function,
Expression* arg,
Type* param_type,
bool* issued_error)
{
*issued_error = false;
Type* var_type = NULL;
// The simple case is passing the varargs parameter of the caller.
Var_expression* ve = arg->var_expression();
if (ve != NULL && ve->named_object()->is_variable())
{
Variable* var = ve->named_object()->var_value();
if (var->is_varargs_parameter())
var_type = var->type();
}
// The complex case is passing the varargs parameter of some
// enclosing function. This will look like passing down *c.f where
// c is the closure variable and f is a field in the closure.
if (function != NULL
&& function->func_value()->needs_closure()
&& arg->classification() == EXPRESSION_UNARY)
{
Unary_expression* ue = static_cast<Unary_expression*>(arg);
if (ue->op() == OPERATOR_MULT)
{
Field_reference_expression* fre =
ue->operand()->deref()->field_reference_expression();
if (fre != NULL)
{
Var_expression* ve = fre->expr()->deref()->var_expression();
if (ve != NULL)
{
Named_object* no = ve->named_object();
Function* f = function->func_value();
if (no == f->closure_var())
{
// At this point we know that this indeed a
// reference to some enclosing variable. Now we
// need to figure out whether that variable is a
// varargs parameter.
Named_object* enclosing =
f->enclosing_var(fre->field_index());
Variable* var = enclosing->var_value();
if (var->is_varargs_parameter())
var_type = var->type();
}
}
}
}
}
if (var_type == NULL)
return false;
// We only match if the parameter is the same, with an identical
// type.
Array_type* var_at = var_type->array_type();
gcc_assert(var_at != NULL);
Array_type* param_at = param_type->array_type();
if (param_at != NULL
&& Type::are_identical(var_at->element_type(),
param_at->element_type(), true, NULL))
return true;
error_at(arg->location(), "... mismatch: passing ...T as ...");
*issued_error = true;
return false;
}
// Get the function type. Returns NULL if we don't know the type. If
// this returns NULL, and if_ERROR is true, issues an error.
Function_type*
Call_expression::get_function_type() const
{
return this->fn_->type()->function_type();
}
// Return the number of values which this call will return.
size_t
Call_expression::result_count() const
{
const Function_type* fntype = this->get_function_type();
if (fntype == NULL)
return 0;
if (fntype->results() == NULL)
return 0;
return fntype->results()->size();
}
// Return whether this is a call to the predeclared function recover.
bool
Call_expression::is_recover_call() const
{
return this->do_is_recover_call();
}
// Set the argument to the recover function.
void
Call_expression::set_recover_arg(Expression* arg)
{
this->do_set_recover_arg(arg);
}
// Virtual functions also implemented by Builtin_call_expression.
bool
Call_expression::do_is_recover_call() const
{
return false;
}
void
Call_expression::do_set_recover_arg(Expression*)
{
gcc_unreachable();
}
// Get the type.
Type*
Call_expression::do_type()
{
if (this->type_ != NULL)
return this->type_;
Type* ret;
Function_type* fntype = this->get_function_type();
if (fntype == NULL)
return Type::make_error_type();
const Typed_identifier_list* results = fntype->results();
if (results == NULL)
ret = Type::make_void_type();
else if (results->size() == 1)
ret = results->begin()->type();
else
ret = Type::make_call_multiple_result_type(this);
this->type_ = ret;
return this->type_;
}
// Determine types for a call expression. We can use the function
// parameter types to set the types of the arguments.
void
Call_expression::do_determine_type(const Type_context*)
{
this->fn_->determine_type_no_context();
Function_type* fntype = this->get_function_type();
const Typed_identifier_list* parameters = NULL;
if (fntype != NULL)
parameters = fntype->parameters();
if (this->args_ != NULL)
{
Typed_identifier_list::const_iterator pt;
if (parameters != NULL)
pt = parameters->begin();
for (Expression_list::const_iterator pa = this->args_->begin();
pa != this->args_->end();
++pa)
{
if (parameters != NULL && pt != parameters->end())
{
Type_context subcontext(pt->type(), false);
(*pa)->determine_type(&subcontext);
++pt;
}
else
(*pa)->determine_type_no_context();
}
}
}
// Check types for parameter I.
bool
Call_expression::check_argument_type(int i, const Type* parameter_type,
const Type* argument_type,
source_location argument_location,
bool issued_error)
{
std::string reason;
if (!Type::are_assignable(parameter_type, argument_type, &reason))
{
if (!issued_error)
{
if (reason.empty())
error_at(argument_location, "argument %d has incompatible type", i);
else
error_at(argument_location,
"argument %d has incompatible type (%s)",
i, reason.c_str());
}
this->set_is_error();
return false;
}
return true;
}
// Check types.
void
Call_expression::do_check_types(Gogo*)
{
Function_type* fntype = this->get_function_type();
if (fntype == NULL)
{
if (!this->fn_->type()->is_error_type())
this->report_error(_("expected function"));
return;
}
if (fntype->is_method())
{
// We don't support pointers to methods, so the function has to
// be a bound method expression.
Bound_method_expression* bme = this->fn_->bound_method_expression();
if (bme == NULL)
{
this->report_error(_("method call without object"));
return;
}
Type* first_arg_type = bme->first_argument()->type();
if (first_arg_type->points_to() == NULL)
{
// When passing a value, we need to check that we are
// permitted to copy it.
std::string reason;
if (!Type::are_assignable(fntype->receiver()->type(),
first_arg_type, &reason))
{
if (reason.empty())
this->report_error(_("incompatible type for receiver"));
else
{
error_at(this->location(),
"incompatible type for receiver (%s)",
reason.c_str());
this->set_is_error();
}
}
}
}
// Note that varargs was handled by the lower_varargs() method, so
// we don't have to worry about it here.
const Typed_identifier_list* parameters = fntype->parameters();
if (this->args_ == NULL)
{
if (parameters != NULL && !parameters->empty())
this->report_error(_("not enough arguments"));
}
else if (parameters == NULL)
this->report_error(_("too many arguments"));
else
{
int i = 0;
Typed_identifier_list::const_iterator pt = parameters->begin();
for (Expression_list::const_iterator pa = this->args_->begin();
pa != this->args_->end();
++pa, ++pt, ++i)
{
if (pt == parameters->end())
{
this->report_error(_("too many arguments"));
return;
}
this->check_argument_type(i + 1, pt->type(), (*pa)->type(),
(*pa)->location(), false);
}
if (pt != parameters->end())
this->report_error(_("not enough arguments"));
}
}
// Return whether we have to use a temporary variable to ensure that
// we evaluate this call expression in order. If the call returns no
// results then it will inevitably be executed last. If the call
// returns more than one result then it will be used with Call_result
// expressions. So we only have to use a temporary variable if the
// call returns exactly one result.
bool
Call_expression::do_must_eval_in_order() const
{
return this->result_count() == 1;
}
// Get the function and the first argument to use when calling a bound
// method.
tree
Call_expression::bound_method_function(Translate_context* context,
Bound_method_expression* bound_method,
tree* first_arg_ptr)
{
Expression* first_argument = bound_method->first_argument();
tree first_arg = first_argument->get_tree(context);
if (first_arg == error_mark_node)
return error_mark_node;
// We always pass a pointer to the first argument when calling a
// method.
if (first_argument->type()->points_to() == NULL)
{
tree pointer_to_arg_type = build_pointer_type(TREE_TYPE(first_arg));
if (TREE_ADDRESSABLE(TREE_TYPE(first_arg))
|| DECL_P(first_arg)
|| TREE_CODE(first_arg) == INDIRECT_REF
|| TREE_CODE(first_arg) == COMPONENT_REF)
{
first_arg = build_fold_addr_expr(first_arg);
if (DECL_P(first_arg))
TREE_ADDRESSABLE(first_arg) = 1;
}
else
{
tree tmp = create_tmp_var(TREE_TYPE(first_arg),
get_name(first_arg));
DECL_IGNORED_P(tmp) = 0;
DECL_INITIAL(tmp) = first_arg;
first_arg = build2(COMPOUND_EXPR, pointer_to_arg_type,
build1(DECL_EXPR, void_type_node, tmp),
build_fold_addr_expr(tmp));
TREE_ADDRESSABLE(tmp) = 1;
}
if (first_arg == error_mark_node)
return error_mark_node;
}
Type* fatype = bound_method->first_argument_type();
if (fatype != NULL)
{
if (fatype->points_to() == NULL)
fatype = Type::make_pointer_type(fatype);
first_arg = fold_convert(fatype->get_tree(context->gogo()), first_arg);
if (first_arg == error_mark_node
|| TREE_TYPE(first_arg) == error_mark_node)
return error_mark_node;
}
*first_arg_ptr = first_arg;
return bound_method->method()->get_tree(context);
}
// Get the function and the first argument to use when calling an
// interface method.
tree
Call_expression::interface_method_function(
Translate_context* context,
Interface_field_reference_expression* interface_method,
tree* first_arg_ptr)
{
tree expr = interface_method->expr()->get_tree(context);
if (expr == error_mark_node)
return error_mark_node;
expr = save_expr(expr);
tree first_arg = interface_method->get_underlying_object_tree(context, expr);
if (first_arg == error_mark_node)
return error_mark_node;
*first_arg_ptr = first_arg;
return interface_method->get_function_tree(context, expr);
}
// Build the call expression.
tree
Call_expression::do_get_tree(Translate_context* context)
{
if (this->tree_ != NULL_TREE)
return this->tree_;
Function_type* fntype = this->get_function_type();
if (fntype == NULL)
return error_mark_node;
if (this->fn_->is_error_expression())
return error_mark_node;
Gogo* gogo = context->gogo();
source_location location = this->location();
Func_expression* func = this->fn_->func_expression();
Bound_method_expression* bound_method = this->fn_->bound_method_expression();
Interface_field_reference_expression* interface_method =
this->fn_->interface_field_reference_expression();
const bool has_closure = func != NULL && func->closure() != NULL;
const bool is_method = bound_method != NULL || interface_method != NULL;
gcc_assert(!fntype->is_method() || is_method);
int nargs;
tree* args;
if (this->args_ == NULL || this->args_->empty())
{
nargs = is_method ? 1 : 0;
args = nargs == 0 ? NULL : new tree[nargs];
}
else
{
const Typed_identifier_list* params = fntype->parameters();
gcc_assert(params != NULL);
nargs = this->args_->size();
int i = is_method ? 1 : 0;
nargs += i;
args = new tree[nargs];
Typed_identifier_list::const_iterator pp = params->begin();
Expression_list::const_iterator pe;
for (pe = this->args_->begin();
pe != this->args_->end();
++pe, ++pp, ++i)
{
gcc_assert(pp != params->end());
tree arg_val = (*pe)->get_tree(context);
args[i] = Expression::convert_for_assignment(context,
pp->type(),
(*pe)->type(),
arg_val,
location);
if (args[i] == error_mark_node)
{
delete[] args;
return error_mark_node;
}
}
gcc_assert(pp == params->end());
gcc_assert(i == nargs);
}
tree rettype = TREE_TYPE(TREE_TYPE(fntype->get_tree(gogo)));
if (rettype == error_mark_node)
{
delete[] args;
return error_mark_node;
}
tree fn;
if (has_closure)
fn = func->get_tree_without_closure(gogo);
else if (!is_method)
fn = this->fn_->get_tree(context);
else if (bound_method != NULL)
fn = this->bound_method_function(context, bound_method, &args[0]);
else if (interface_method != NULL)
fn = this->interface_method_function(context, interface_method, &args[0]);
else
gcc_unreachable();
if (fn == error_mark_node || TREE_TYPE(fn) == error_mark_node)
{
delete[] args;
return error_mark_node;
}
// This is to support builtin math functions when using 80387 math.
tree fndecl = fn;
if (TREE_CODE(fndecl) == ADDR_EXPR)
fndecl = TREE_OPERAND(fndecl, 0);
tree excess_type = NULL_TREE;
if (DECL_P(fndecl)
&& DECL_IS_BUILTIN(fndecl)
&& DECL_BUILT_IN_CLASS(fndecl) == BUILT_IN_NORMAL
&& nargs > 0
&& ((SCALAR_FLOAT_TYPE_P(rettype)
&& SCALAR_FLOAT_TYPE_P(TREE_TYPE(args[0])))
|| (COMPLEX_FLOAT_TYPE_P(rettype)
&& COMPLEX_FLOAT_TYPE_P(TREE_TYPE(args[0])))))
{
excess_type = excess_precision_type(TREE_TYPE(args[0]));
if (excess_type != NULL_TREE)
{
tree excess_fndecl = mathfn_built_in(excess_type,
DECL_FUNCTION_CODE(fndecl));
if (excess_fndecl == NULL_TREE)
excess_type = NULL_TREE;
else
{
fn = build_fold_addr_expr_loc(location, excess_fndecl);
for (int i = 0; i < nargs; ++i)
args[i] = ::convert(excess_type, args[i]);
}
}
}
tree ret = build_call_array(excess_type != NULL_TREE ? excess_type : rettype,
fn, nargs, args);
delete[] args;
SET_EXPR_LOCATION(ret, location);
if (has_closure)
{
tree closure_tree = func->closure()->get_tree(context);
if (closure_tree != error_mark_node)
CALL_EXPR_STATIC_CHAIN(ret) = closure_tree;
}
// If this is a recursive function type which returns itself, as in
// type F func() F
// we have used ptr_type_node for the return type. Add a cast here
// to the correct type.
if (TREE_TYPE(ret) == ptr_type_node)
{
tree t = this->type()->get_tree(gogo);
ret = fold_convert_loc(location, t, ret);
}
if (excess_type != NULL_TREE)
{
// Calling convert here can undo our excess precision change.
// That may or may not be a bug in convert_to_real.
ret = build1(NOP_EXPR, rettype, ret);
}
// If there is more than one result, we will refer to the call
// multiple times.
if (fntype->results() != NULL && fntype->results()->size() > 1)
ret = save_expr(ret);
this->tree_ = ret;
return ret;
}
// Make a call expression.
Call_expression*
Expression::make_call(Expression* fn, Expression_list* args, bool is_varargs,
source_location location)
{
return new Call_expression(fn, args, is_varargs, location);
}
// A single result from a call which returns multiple results.
class Call_result_expression : public Expression
{
public:
Call_result_expression(Call_expression* call, unsigned int index)
: Expression(EXPRESSION_CALL_RESULT, call->location()),
call_(call), index_(index)
{ }
protected:
int
do_traverse(Traverse*);
Type*
do_type();
void
do_determine_type(const Type_context*);
void
do_check_types(Gogo*);
Expression*
do_copy()
{
return new Call_result_expression(this->call_->call_expression(),
this->index_);
}
bool
do_must_eval_in_order() const
{ return true; }
tree
do_get_tree(Translate_context*);
private:
// The underlying call expression.
Expression* call_;
// Which result we want.
unsigned int index_;
};
// Traverse a call result.
int
Call_result_expression::do_traverse(Traverse* traverse)
{
if (traverse->remember_expression(this->call_))
{
// We have already traversed the call expression.
return TRAVERSE_CONTINUE;
}
return Expression::traverse(&this->call_, traverse);
}
// Get the type.
Type*
Call_result_expression::do_type()
{
if (this->classification() == EXPRESSION_ERROR)
return Type::make_error_type();
// THIS->CALL_ can be replaced with a temporary reference due to
// Call_expression::do_must_eval_in_order when there is an error.
Call_expression* ce = this->call_->call_expression();
if (ce == NULL)
{
this->set_is_error();
return Type::make_error_type();
}
Function_type* fntype = ce->get_function_type();
if (fntype == NULL)
{
this->set_is_error();
return Type::make_error_type();
}
const Typed_identifier_list* results = fntype->results();
if (results == NULL)
{
this->report_error(_("number of results does not match "
"number of values"));
return Type::make_error_type();
}
Typed_identifier_list::const_iterator pr = results->begin();
for (unsigned int i = 0; i < this->index_; ++i)
{
if (pr == results->end())
break;
++pr;
}
if (pr == results->end())
{
this->report_error(_("number of results does not match "
"number of values"));
return Type::make_error_type();
}
return pr->type();
}
// Check the type. Just make sure that we trigger the warning in
// do_type.
void
Call_result_expression::do_check_types(Gogo*)
{
this->type();
}
// Determine the type. We have nothing to do here, but the 0 result
// needs to pass down to the caller.
void
Call_result_expression::do_determine_type(const Type_context*)
{
if (this->index_ == 0)
this->call_->determine_type_no_context();
}
// Return the tree.
tree
Call_result_expression::do_get_tree(Translate_context* context)
{
tree call_tree = this->call_->get_tree(context);
if (call_tree == error_mark_node)
return error_mark_node;
if (TREE_CODE(TREE_TYPE(call_tree)) != RECORD_TYPE)
{
gcc_assert(saw_errors());
return error_mark_node;
}
tree field = TYPE_FIELDS(TREE_TYPE(call_tree));
for (unsigned int i = 0; i < this->index_; ++i)
{
gcc_assert(field != NULL_TREE);
field = DECL_CHAIN(field);
}
gcc_assert(field != NULL_TREE);
return build3(COMPONENT_REF, TREE_TYPE(field), call_tree, field, NULL_TREE);
}
// Make a reference to a single result of a call which returns
// multiple results.
Expression*
Expression::make_call_result(Call_expression* call, unsigned int index)
{
return new Call_result_expression(call, index);
}
// Class Index_expression.
// Traversal.
int
Index_expression::do_traverse(Traverse* traverse)
{
if (Expression::traverse(&this->left_, traverse) == TRAVERSE_EXIT
|| Expression::traverse(&this->start_, traverse) == TRAVERSE_EXIT
|| (this->end_ != NULL
&& Expression::traverse(&this->end_, traverse) == TRAVERSE_EXIT))
return TRAVERSE_EXIT;
return TRAVERSE_CONTINUE;
}
// Lower an index expression. This converts the generic index
// expression into an array index, a string index, or a map index.
Expression*
Index_expression::do_lower(Gogo*, Named_object*, int)
{
source_location location = this->location();
Expression* left = this->left_;
Expression* start = this->start_;
Expression* end = this->end_;
Type* type = left->type();
if (type->is_error_type())
return Expression::make_error(location);
else if (type->array_type() != NULL)
return Expression::make_array_index(left, start, end, location);
else if (type->points_to() != NULL
&& type->points_to()->array_type() != NULL
&& !type->points_to()->is_open_array_type())
{
Expression* deref = Expression::make_unary(OPERATOR_MULT, left,
location);
return Expression::make_array_index(deref, start, end, location);
}
else if (type->is_string_type())
return Expression::make_string_index(left, start, end, location);
else if (type->map_type() != NULL)
{
if (end != NULL)
{
error_at(location, "invalid slice of map");
return Expression::make_error(location);
}
Map_index_expression* ret= Expression::make_map_index(left, start,
location);
if (this->is_lvalue_)
ret->set_is_lvalue();
return ret;
}
else
{
error_at(location,
"attempt to index object which is not array, string, or map");
return Expression::make_error(location);
}
}
// Make an index expression.
Expression*
Expression::make_index(Expression* left, Expression* start, Expression* end,
source_location location)
{
return new Index_expression(left, start, end, location);
}
// An array index. This is used for both indexing and slicing.
class Array_index_expression : public Expression
{
public:
Array_index_expression(Expression* array, Expression* start,
Expression* end, source_location location)
: Expression(EXPRESSION_ARRAY_INDEX, location),
array_(array), start_(start), end_(end), type_(NULL)
{ }
protected:
int
do_traverse(Traverse*);
Type*
do_type();
void
do_determine_type(const Type_context*);
void
do_check_types(Gogo*);
Expression*
do_copy()
{
return Expression::make_array_index(this->array_->copy(),
this->start_->copy(),
(this->end_ == NULL
? NULL
: this->end_->copy()),
this->location());
}
bool
do_is_addressable() const;
void
do_address_taken(bool escapes)
{ this->array_->address_taken(escapes); }
tree
do_get_tree(Translate_context*);
private:
// The array we are getting a value from.
Expression* array_;
// The start or only index.
Expression* start_;
// The end index of a slice. This may be NULL for a simple array
// index, or it may be a nil expression for the length of the array.
Expression* end_;
// The type of the expression.
Type* type_;
};
// Array index traversal.
int
Array_index_expression::do_traverse(Traverse* traverse)
{
if (Expression::traverse(&this->array_, traverse) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
if (Expression::traverse(&this->start_, traverse) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
if (this->end_ != NULL)
{
if (Expression::traverse(&this->end_, traverse) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
}
return TRAVERSE_CONTINUE;
}
// Return the type of an array index.
Type*
Array_index_expression::do_type()
{
if (this->type_ == NULL)
{
Array_type* type = this->array_->type()->array_type();
if (type == NULL)
this->type_ = Type::make_error_type();
else if (this->end_ == NULL)
this->type_ = type->element_type();
else if (type->is_open_array_type())
{
// A slice of a slice has the same type as the original
// slice.
this->type_ = this->array_->type()->deref();
}
else
{
// A slice of an array is a slice.
this->type_ = Type::make_array_type(type->element_type(), NULL);
}
}
return this->type_;
}
// Set the type of an array index.
void
Array_index_expression::do_determine_type(const Type_context*)
{
this->array_->determine_type_no_context();
Type_context subcontext(NULL, true);
this->start_->determine_type(&subcontext);
if (this->end_ != NULL)
this->end_->determine_type(&subcontext);
}
// Check types of an array index.
void
Array_index_expression::do_check_types(Gogo*)
{
if (this->start_->type()->integer_type() == NULL)
this->report_error(_("index must be integer"));
if (this->end_ != NULL
&& this->end_->type()->integer_type() == NULL
&& !this->end_->is_nil_expression())
this->report_error(_("slice end must be integer"));
Array_type* array_type = this->array_->type()->array_type();
if (array_type == NULL)
{
gcc_assert(this->array_->type()->is_error_type());
return;
}
unsigned int int_bits =
Type::lookup_integer_type("int")->integer_type()->bits();
Type* dummy;
mpz_t lval;
mpz_init(lval);
bool lval_valid = (array_type->length() != NULL
&& array_type->length()->integer_constant_value(true,
lval,
&dummy));
mpz_t ival;
mpz_init(ival);
if (this->start_->integer_constant_value(true, ival, &dummy))
{
if (mpz_sgn(ival) < 0
|| mpz_sizeinbase(ival, 2) >= int_bits
|| (lval_valid
&& (this->end_ == NULL
? mpz_cmp(ival, lval) >= 0
: mpz_cmp(ival, lval) > 0)))
{
error_at(this->start_->location(), "array index out of bounds");
this->set_is_error();
}
}
if (this->end_ != NULL && !this->end_->is_nil_expression())
{
if (this->end_->integer_constant_value(true, ival, &dummy))
{
if (mpz_sgn(ival) < 0
|| mpz_sizeinbase(ival, 2) >= int_bits
|| (lval_valid && mpz_cmp(ival, lval) > 0))
{
error_at(this->end_->location(), "array index out of bounds");
this->set_is_error();
}
}
}
mpz_clear(ival);
mpz_clear(lval);
// A slice of an array requires an addressable array. A slice of a
// slice is always possible.
if (this->end_ != NULL
&& !array_type->is_open_array_type()
&& !this->array_->is_addressable())
this->report_error(_("array is not addressable"));
}
// Return whether this expression is addressable.
bool
Array_index_expression::do_is_addressable() const
{
// A slice expression is not addressable.
if (this->end_ != NULL)
return false;
// An index into a slice is addressable.
if (this->array_->type()->is_open_array_type())
return true;
// An index into an array is addressable if the array is
// addressable.
return this->array_->is_addressable();
}
// Get a tree for an array index.
tree
Array_index_expression::do_get_tree(Translate_context* context)
{
Gogo* gogo = context->gogo();
source_location loc = this->location();
Array_type* array_type = this->array_->type()->array_type();
if (array_type == NULL)
{
gcc_assert(this->array_->type()->is_error_type());
return error_mark_node;
}
tree type_tree = array_type->get_tree(gogo);
if (type_tree == error_mark_node)
return error_mark_node;
tree array_tree = this->array_->get_tree(context);
if (array_tree == error_mark_node)
return error_mark_node;
if (array_type->length() == NULL && !DECL_P(array_tree))
array_tree = save_expr(array_tree);
tree length_tree = array_type->length_tree(gogo, array_tree);
if (length_tree == error_mark_node)
return error_mark_node;
length_tree = save_expr(length_tree);
tree length_type = TREE_TYPE(length_tree);
tree bad_index = boolean_false_node;
tree start_tree = this->start_->get_tree(context);
if (start_tree == error_mark_node)
return error_mark_node;
if (!DECL_P(start_tree))
start_tree = save_expr(start_tree);
if (!INTEGRAL_TYPE_P(TREE_TYPE(start_tree)))
start_tree = convert_to_integer(length_type, start_tree);
bad_index = Expression::check_bounds(start_tree, length_type, bad_index,
loc);
start_tree = fold_convert_loc(loc, length_type, start_tree);
bad_index = fold_build2_loc(loc, TRUTH_OR_EXPR, boolean_type_node, bad_index,
fold_build2_loc(loc,
(this->end_ == NULL
? GE_EXPR
: GT_EXPR),
boolean_type_node, start_tree,
length_tree));
int code = (array_type->length() != NULL
? (this->end_ == NULL
? RUNTIME_ERROR_ARRAY_INDEX_OUT_OF_BOUNDS
: RUNTIME_ERROR_ARRAY_SLICE_OUT_OF_BOUNDS)
: (this->end_ == NULL
? RUNTIME_ERROR_SLICE_INDEX_OUT_OF_BOUNDS
: RUNTIME_ERROR_SLICE_SLICE_OUT_OF_BOUNDS));
tree crash = Gogo::runtime_error(code, loc);
if (this->end_ == NULL)
{
// Simple array indexing. This has to return an l-value, so
// wrap the index check into START_TREE.
start_tree = build2(COMPOUND_EXPR, TREE_TYPE(start_tree),
build3(COND_EXPR, void_type_node,
bad_index, crash, NULL_TREE),
start_tree);
start_tree = fold_convert_loc(loc, sizetype, start_tree);
if (array_type->length() != NULL)
{
// Fixed array.
return build4(ARRAY_REF, TREE_TYPE(type_tree), array_tree,
start_tree, NULL_TREE, NULL_TREE);
}
else
{
// Open array.
tree values = array_type->value_pointer_tree(gogo, array_tree);
tree element_type_tree = array_type->element_type()->get_tree(gogo);
if (element_type_tree == error_mark_node)
return error_mark_node;
tree element_size = TYPE_SIZE_UNIT(element_type_tree);
tree offset = fold_build2_loc(loc, MULT_EXPR, sizetype,
start_tree, element_size);
tree ptr = fold_build2_loc(loc, POINTER_PLUS_EXPR,
TREE_TYPE(values), values, offset);
return build_fold_indirect_ref(ptr);
}
}
// Array slice.
tree capacity_tree = array_type->capacity_tree(gogo, array_tree);
if (capacity_tree == error_mark_node)
return error_mark_node;
capacity_tree = fold_convert_loc(loc, length_type, capacity_tree);
tree end_tree;
if (this->end_->is_nil_expression())
end_tree = length_tree;
else
{
end_tree = this->end_->get_tree(context);
if (end_tree == error_mark_node)
return error_mark_node;
if (!DECL_P(end_tree))
end_tree = save_expr(end_tree);
if (!INTEGRAL_TYPE_P(TREE_TYPE(end_tree)))
end_tree = convert_to_integer(length_type, end_tree);
bad_index = Expression::check_bounds(end_tree, length_type, bad_index,
loc);
end_tree = fold_convert_loc(loc, length_type, end_tree);
capacity_tree = save_expr(capacity_tree);
tree bad_end = fold_build2_loc(loc, TRUTH_OR_EXPR, boolean_type_node,
fold_build2_loc(loc, LT_EXPR,
boolean_type_node,
end_tree, start_tree),
fold_build2_loc(loc, GT_EXPR,
boolean_type_node,
end_tree, capacity_tree));
bad_index = fold_build2_loc(loc, TRUTH_OR_EXPR, boolean_type_node,
bad_index, bad_end);
}
tree element_type_tree = array_type->element_type()->get_tree(gogo);
if (element_type_tree == error_mark_node)
return error_mark_node;
tree element_size = TYPE_SIZE_UNIT(element_type_tree);
tree offset = fold_build2_loc(loc, MULT_EXPR, sizetype,
fold_convert_loc(loc, sizetype, start_tree),
element_size);
tree value_pointer = array_type->value_pointer_tree(gogo, array_tree);
if (value_pointer == error_mark_node)
return error_mark_node;
value_pointer = fold_build2_loc(loc, POINTER_PLUS_EXPR,
TREE_TYPE(value_pointer),
value_pointer, offset);
tree result_length_tree = fold_build2_loc(loc, MINUS_EXPR, length_type,
end_tree, start_tree);
tree result_capacity_tree = fold_build2_loc(loc, MINUS_EXPR, length_type,
capacity_tree, start_tree);
tree struct_tree = this->type()->get_tree(gogo);
gcc_assert(TREE_CODE(struct_tree) == RECORD_TYPE);
VEC(constructor_elt,gc)* init = VEC_alloc(constructor_elt, gc, 3);
constructor_elt* elt = VEC_quick_push(constructor_elt, init, NULL);
tree field = TYPE_FIELDS(struct_tree);
gcc_assert(strcmp(IDENTIFIER_POINTER(DECL_NAME(field)), "__values") == 0);
elt->index = field;
elt->value = value_pointer;
elt = VEC_quick_push(constructor_elt, init, NULL);
field = DECL_CHAIN(field);
gcc_assert(strcmp(IDENTIFIER_POINTER(DECL_NAME(field)), "__count") == 0);
elt->index = field;
elt->value = fold_convert_loc(loc, TREE_TYPE(field), result_length_tree);
elt = VEC_quick_push(constructor_elt, init, NULL);
field = DECL_CHAIN(field);
gcc_assert(strcmp(IDENTIFIER_POINTER(DECL_NAME(field)), "__capacity") == 0);
elt->index = field;
elt->value = fold_convert_loc(loc, TREE_TYPE(field), result_capacity_tree);
tree constructor = build_constructor(struct_tree, init);
if (TREE_CONSTANT(value_pointer)
&& TREE_CONSTANT(result_length_tree)
&& TREE_CONSTANT(result_capacity_tree))
TREE_CONSTANT(constructor) = 1;
return fold_build2_loc(loc, COMPOUND_EXPR, TREE_TYPE(constructor),
build3(COND_EXPR, void_type_node,
bad_index, crash, NULL_TREE),
constructor);
}
// Make an array index expression. END may be NULL.
Expression*
Expression::make_array_index(Expression* array, Expression* start,
Expression* end, source_location location)
{
// Taking a slice of a composite literal requires moving the literal
// onto the heap.
if (end != NULL && array->is_composite_literal())
{
array = Expression::make_heap_composite(array, location);
array = Expression::make_unary(OPERATOR_MULT, array, location);
}
return new Array_index_expression(array, start, end, location);
}
// A string index. This is used for both indexing and slicing.
class String_index_expression : public Expression
{
public:
String_index_expression(Expression* string, Expression* start,
Expression* end, source_location location)
: Expression(EXPRESSION_STRING_INDEX, location),
string_(string), start_(start), end_(end)
{ }
protected:
int
do_traverse(Traverse*);
Type*
do_type();
void
do_determine_type(const Type_context*);
void
do_check_types(Gogo*);
Expression*
do_copy()
{
return Expression::make_string_index(this->string_->copy(),
this->start_->copy(),
(this->end_ == NULL
? NULL
: this->end_->copy()),
this->location());
}
tree
do_get_tree(Translate_context*);
private:
// The string we are getting a value from.
Expression* string_;
// The start or only index.
Expression* start_;
// The end index of a slice. This may be NULL for a single index,
// or it may be a nil expression for the length of the string.
Expression* end_;
};
// String index traversal.
int
String_index_expression::do_traverse(Traverse* traverse)
{
if (Expression::traverse(&this->string_, traverse) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
if (Expression::traverse(&this->start_, traverse) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
if (this->end_ != NULL)
{
if (Expression::traverse(&this->end_, traverse) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
}
return TRAVERSE_CONTINUE;
}
// Return the type of a string index.
Type*
String_index_expression::do_type()
{
if (this->end_ == NULL)
return Type::lookup_integer_type("uint8");
else
return this->string_->type();
}
// Determine the type of a string index.
void
String_index_expression::do_determine_type(const Type_context*)
{
this->string_->determine_type_no_context();
Type_context subcontext(NULL, true);
this->start_->determine_type(&subcontext);
if (this->end_ != NULL)
this->end_->determine_type(&subcontext);
}
// Check types of a string index.
void
String_index_expression::do_check_types(Gogo*)
{
if (this->start_->type()->integer_type() == NULL)
this->report_error(_("index must be integer"));
if (this->end_ != NULL
&& this->end_->type()->integer_type() == NULL
&& !this->end_->is_nil_expression())
this->report_error(_("slice end must be integer"));
std::string sval;
bool sval_valid = this->string_->string_constant_value(&sval);
mpz_t ival;
mpz_init(ival);
Type* dummy;
if (this->start_->integer_constant_value(true, ival, &dummy))
{
if (mpz_sgn(ival) < 0
|| (sval_valid && mpz_cmp_ui(ival, sval.length()) >= 0))
{
error_at(this->start_->location(), "string index out of bounds");
this->set_is_error();
}
}
if (this->end_ != NULL && !this->end_->is_nil_expression())
{
if (this->end_->integer_constant_value(true, ival, &dummy))
{
if (mpz_sgn(ival) < 0
|| (sval_valid && mpz_cmp_ui(ival, sval.length()) > 0))
{
error_at(this->end_->location(), "string index out of bounds");
this->set_is_error();
}
}
}
mpz_clear(ival);
}
// Get a tree for a string index.
tree
String_index_expression::do_get_tree(Translate_context* context)
{
source_location loc = this->location();
tree string_tree = this->string_->get_tree(context);
if (string_tree == error_mark_node)
return error_mark_node;
if (this->string_->type()->points_to() != NULL)
string_tree = build_fold_indirect_ref(string_tree);
if (!DECL_P(string_tree))
string_tree = save_expr(string_tree);
tree string_type = TREE_TYPE(string_tree);
tree length_tree = String_type::length_tree(context->gogo(), string_tree);
length_tree = save_expr(length_tree);
tree length_type = TREE_TYPE(length_tree);
tree bad_index = boolean_false_node;
tree start_tree = this->start_->get_tree(context);
if (start_tree == error_mark_node)
return error_mark_node;
if (!DECL_P(start_tree))
start_tree = save_expr(start_tree);
if (!INTEGRAL_TYPE_P(TREE_TYPE(start_tree)))
start_tree = convert_to_integer(length_type, start_tree);
bad_index = Expression::check_bounds(start_tree, length_type, bad_index,
loc);
start_tree = fold_convert_loc(loc, length_type, start_tree);
int code = (this->end_ == NULL
? RUNTIME_ERROR_STRING_INDEX_OUT_OF_BOUNDS
: RUNTIME_ERROR_STRING_SLICE_OUT_OF_BOUNDS);
tree crash = Gogo::runtime_error(code, loc);
if (this->end_ == NULL)
{
bad_index = fold_build2_loc(loc, TRUTH_OR_EXPR, boolean_type_node,
bad_index,
fold_build2_loc(loc, GE_EXPR,
boolean_type_node,
start_tree, length_tree));
tree bytes_tree = String_type::bytes_tree(context->gogo(), string_tree);
tree ptr = fold_build2_loc(loc, POINTER_PLUS_EXPR, TREE_TYPE(bytes_tree),
bytes_tree,
fold_convert_loc(loc, sizetype, start_tree));
tree index = build_fold_indirect_ref_loc(loc, ptr);
return build2(COMPOUND_EXPR, TREE_TYPE(index),
build3(COND_EXPR, void_type_node,
bad_index, crash, NULL_TREE),
index);
}
else
{
tree end_tree;
if (this->end_->is_nil_expression())
end_tree = build_int_cst(length_type, -1);
else
{
end_tree = this->end_->get_tree(context);
if (end_tree == error_mark_node)
return error_mark_node;
if (!DECL_P(end_tree))
end_tree = save_expr(end_tree);
if (!INTEGRAL_TYPE_P(TREE_TYPE(end_tree)))
end_tree = convert_to_integer(length_type, end_tree);
bad_index = Expression::check_bounds(end_tree, length_type,
bad_index, loc);
end_tree = fold_convert_loc(loc, length_type, end_tree);
}
static tree strslice_fndecl;
tree ret = Gogo::call_builtin(&strslice_fndecl,
loc,
"__go_string_slice",
3,
string_type,
string_type,
string_tree,
length_type,
start_tree,
length_type,
end_tree);
if (ret == error_mark_node)
return error_mark_node;
// This will panic if the bounds are out of range for the
// string.
TREE_NOTHROW(strslice_fndecl) = 0;
if (bad_index == boolean_false_node)
return ret;
else
return build2(COMPOUND_EXPR, TREE_TYPE(ret),
build3(COND_EXPR, void_type_node,
bad_index, crash, NULL_TREE),
ret);
}
}
// Make a string index expression. END may be NULL.
Expression*
Expression::make_string_index(Expression* string, Expression* start,
Expression* end, source_location location)
{
return new String_index_expression(string, start, end, location);
}
// Class Map_index.
// Get the type of the map.
Map_type*
Map_index_expression::get_map_type() const
{
Map_type* mt = this->map_->type()->deref()->map_type();
if (mt == NULL)
gcc_assert(saw_errors());
return mt;
}
// Map index traversal.
int
Map_index_expression::do_traverse(Traverse* traverse)
{
if (Expression::traverse(&this->map_, traverse) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
return Expression::traverse(&this->index_, traverse);
}
// Return the type of a map index.
Type*
Map_index_expression::do_type()
{
Map_type* mt = this->get_map_type();
if (mt == NULL)
return Type::make_error_type();
Type* type = mt->val_type();
// If this map index is in a tuple assignment, we actually return a
// pointer to the value type. Tuple_map_assignment_statement is
// responsible for handling this correctly. We need to get the type
// right in case this gets assigned to a temporary variable.
if (this->is_in_tuple_assignment_)
type = Type::make_pointer_type(type);
return type;
}
// Fix the type of a map index.
void
Map_index_expression::do_determine_type(const Type_context*)
{
this->map_->determine_type_no_context();
Map_type* mt = this->get_map_type();
Type* key_type = mt == NULL ? NULL : mt->key_type();
Type_context subcontext(key_type, false);
this->index_->determine_type(&subcontext);
}
// Check types of a map index.
void
Map_index_expression::do_check_types(Gogo*)
{
std::string reason;
Map_type* mt = this->get_map_type();
if (mt == NULL)
return;
if (!Type::are_assignable(mt->key_type(), this->index_->type(), &reason))
{
if (reason.empty())
this->report_error(_("incompatible type for map index"));
else
{
error_at(this->location(), "incompatible type for map index (%s)",
reason.c_str());
this->set_is_error();
}
}
}
// Get a tree for a map index.
tree
Map_index_expression::do_get_tree(Translate_context* context)
{
Map_type* type = this->get_map_type();
if (type == NULL)
return error_mark_node;
tree valptr = this->get_value_pointer(context, this->is_lvalue_);
if (valptr == error_mark_node)
return error_mark_node;
valptr = save_expr(valptr);
tree val_type_tree = TREE_TYPE(TREE_TYPE(valptr));
if (this->is_lvalue_)
return build_fold_indirect_ref(valptr);
else if (this->is_in_tuple_assignment_)
{
// Tuple_map_assignment_statement is responsible for using this
// appropriately.
return valptr;
}
else
{
return fold_build3(COND_EXPR, val_type_tree,
fold_build2(EQ_EXPR, boolean_type_node, valptr,
fold_convert(TREE_TYPE(valptr),
null_pointer_node)),
type->val_type()->get_init_tree(context->gogo(),
false),
build_fold_indirect_ref(valptr));
}
}
// Get a tree for the map index. This returns a tree which evaluates
// to a pointer to a value. The pointer will be NULL if the key is
// not in the map.
tree
Map_index_expression::get_value_pointer(Translate_context* context,
bool insert)
{
Map_type* type = this->get_map_type();
if (type == NULL)
return error_mark_node;
tree map_tree = this->map_->get_tree(context);
tree index_tree = this->index_->get_tree(context);
index_tree = Expression::convert_for_assignment(context, type->key_type(),
this->index_->type(),
index_tree,
this->location());
if (map_tree == error_mark_node || index_tree == error_mark_node)
return error_mark_node;
if (this->map_->type()->points_to() != NULL)
map_tree = build_fold_indirect_ref(map_tree);
// We need to pass in a pointer to the key, so stuff it into a
// variable.
tree tmp = create_tmp_var(TREE_TYPE(index_tree), get_name(index_tree));
DECL_IGNORED_P(tmp) = 0;
DECL_INITIAL(tmp) = index_tree;
tree make_tmp = build1(DECL_EXPR, void_type_node, tmp);
tree tmpref = fold_convert(const_ptr_type_node, build_fold_addr_expr(tmp));
TREE_ADDRESSABLE(tmp) = 1;
static tree map_index_fndecl;
tree call = Gogo::call_builtin(&map_index_fndecl,
this->location(),
"__go_map_index",
3,
const_ptr_type_node,
TREE_TYPE(map_tree),
map_tree,
const_ptr_type_node,
tmpref,
boolean_type_node,
(insert
? boolean_true_node
: boolean_false_node));
if (call == error_mark_node)
return error_mark_node;
// This can panic on a map of interface type if the interface holds
// an uncomparable or unhashable type.
TREE_NOTHROW(map_index_fndecl) = 0;
tree val_type_tree = type->val_type()->get_tree(context->gogo());
if (val_type_tree == error_mark_node)
return error_mark_node;
tree ptr_val_type_tree = build_pointer_type(val_type_tree);
return build2(COMPOUND_EXPR, ptr_val_type_tree,
make_tmp,
fold_convert(ptr_val_type_tree, call));
}
// Make a map index expression.
Map_index_expression*
Expression::make_map_index(Expression* map, Expression* index,
source_location location)
{
return new Map_index_expression(map, index, location);
}
// Class Field_reference_expression.
// Return the type of a field reference.
Type*
Field_reference_expression::do_type()
{
Type* type = this->expr_->type();
if (type->is_error_type())
return type;
Struct_type* struct_type = type->struct_type();
gcc_assert(struct_type != NULL);
return struct_type->field(this->field_index_)->type();
}
// Check the types for a field reference.
void
Field_reference_expression::do_check_types(Gogo*)
{
Type* type = this->expr_->type();
if (type->is_error_type())
return;
Struct_type* struct_type = type->struct_type();
gcc_assert(struct_type != NULL);
gcc_assert(struct_type->field(this->field_index_) != NULL);
}
// Get a tree for a field reference.
tree
Field_reference_expression::do_get_tree(Translate_context* context)
{
tree struct_tree = this->expr_->get_tree(context);
if (struct_tree == error_mark_node
|| TREE_TYPE(struct_tree) == error_mark_node)
return error_mark_node;
gcc_assert(TREE_CODE(TREE_TYPE(struct_tree)) == RECORD_TYPE);
tree field = TYPE_FIELDS(TREE_TYPE(struct_tree));
if (field == NULL_TREE)
{
// This can happen for a type which refers to itself indirectly
// and then turns out to be erroneous.
gcc_assert(saw_errors());
return error_mark_node;
}
for (unsigned int i = this->field_index_; i > 0; --i)
{
field = DECL_CHAIN(field);
gcc_assert(field != NULL_TREE);
}
if (TREE_TYPE(field) == error_mark_node)
return error_mark_node;
return build3(COMPONENT_REF, TREE_TYPE(field), struct_tree, field,
NULL_TREE);
}
// Make a reference to a qualified identifier in an expression.
Field_reference_expression*
Expression::make_field_reference(Expression* expr, unsigned int field_index,
source_location location)
{
return new Field_reference_expression(expr, field_index, location);
}
// Class Interface_field_reference_expression.
// Return a tree for the pointer to the function to call.
tree
Interface_field_reference_expression::get_function_tree(Translate_context*,
tree expr)
{
if (this->expr_->type()->points_to() != NULL)
expr = build_fold_indirect_ref(expr);
tree expr_type = TREE_TYPE(expr);
gcc_assert(TREE_CODE(expr_type) == RECORD_TYPE);
tree field = TYPE_FIELDS(expr_type);
gcc_assert(strcmp(IDENTIFIER_POINTER(DECL_NAME(field)), "__methods") == 0);
tree table = build3(COMPONENT_REF, TREE_TYPE(field), expr, field, NULL_TREE);
gcc_assert(POINTER_TYPE_P(TREE_TYPE(table)));
table = build_fold_indirect_ref(table);
gcc_assert(TREE_CODE(TREE_TYPE(table)) == RECORD_TYPE);
std::string name = Gogo::unpack_hidden_name(this->name_);
for (field = DECL_CHAIN(TYPE_FIELDS(TREE_TYPE(table)));
field != NULL_TREE;
field = DECL_CHAIN(field))
{
if (name == IDENTIFIER_POINTER(DECL_NAME(field)))
break;
}
gcc_assert(field != NULL_TREE);
return build3(COMPONENT_REF, TREE_TYPE(field), table, field, NULL_TREE);
}
// Return a tree for the first argument to pass to the interface
// function.
tree
Interface_field_reference_expression::get_underlying_object_tree(
Translate_context*,
tree expr)
{
if (this->expr_->type()->points_to() != NULL)
expr = build_fold_indirect_ref(expr);
tree expr_type = TREE_TYPE(expr);
gcc_assert(TREE_CODE(expr_type) == RECORD_TYPE);
tree field = DECL_CHAIN(TYPE_FIELDS(expr_type));
gcc_assert(strcmp(IDENTIFIER_POINTER(DECL_NAME(field)), "__object") == 0);
return build3(COMPONENT_REF, TREE_TYPE(field), expr, field, NULL_TREE);
}
// Traversal.
int
Interface_field_reference_expression::do_traverse(Traverse* traverse)
{
return Expression::traverse(&this->expr_, traverse);
}
// Return the type of an interface field reference.
Type*
Interface_field_reference_expression::do_type()
{
Type* expr_type = this->expr_->type();
Type* points_to = expr_type->points_to();
if (points_to != NULL)
expr_type = points_to;
Interface_type* interface_type = expr_type->interface_type();
if (interface_type == NULL)
return Type::make_error_type();
const Typed_identifier* method = interface_type->find_method(this->name_);
if (method == NULL)
return Type::make_error_type();
return method->type();
}
// Determine types.
void
Interface_field_reference_expression::do_determine_type(const Type_context*)
{
this->expr_->determine_type_no_context();
}
// Check the types for an interface field reference.
void
Interface_field_reference_expression::do_check_types(Gogo*)
{
Type* type = this->expr_->type();
Type* points_to = type->points_to();
if (points_to != NULL)
type = points_to;
Interface_type* interface_type = type->interface_type();
if (interface_type == NULL)
this->report_error(_("expected interface or pointer to interface"));
else
{
const Typed_identifier* method =
interface_type->find_method(this->name_);
if (method == NULL)
{
error_at(this->location(), "method %qs not in interface",
Gogo::message_name(this->name_).c_str());
this->set_is_error();
}
}
}
// Get a tree for a reference to a field in an interface. There is no
// standard tree type representation for this: it's a function
// attached to its first argument, like a Bound_method_expression.
// The only places it may currently be used are in a Call_expression
// or a Go_statement, which will take it apart directly. So this has
// nothing to do at present.
tree
Interface_field_reference_expression::do_get_tree(Translate_context*)
{
gcc_unreachable();
}
// Make a reference to a field in an interface.
Expression*
Expression::make_interface_field_reference(Expression* expr,
const std::string& field,
source_location location)
{
return new Interface_field_reference_expression(expr, field, location);
}
// A general selector. This is a Parser_expression for LEFT.NAME. It
// is lowered after we know the type of the left hand side.
class Selector_expression : public Parser_expression
{
public:
Selector_expression(Expression* left, const std::string& name,
source_location location)
: Parser_expression(EXPRESSION_SELECTOR, location),
left_(left), name_(name)
{ }
protected:
int
do_traverse(Traverse* traverse)
{ return Expression::traverse(&this->left_, traverse); }
Expression*
do_lower(Gogo*, Named_object*, int);
Expression*
do_copy()
{
return new Selector_expression(this->left_->copy(), this->name_,
this->location());
}
private:
Expression*
lower_method_expression(Gogo*);
// The expression on the left hand side.
Expression* left_;
// The name on the right hand side.
std::string name_;
};
// Lower a selector expression once we know the real type of the left
// hand side.
Expression*
Selector_expression::do_lower(Gogo* gogo, Named_object*, int)
{
Expression* left = this->left_;
if (left->is_type_expression())
return this->lower_method_expression(gogo);
return Type::bind_field_or_method(gogo, left->type(), left, this->name_,
this->location());
}
// Lower a method expression T.M or (*T).M. We turn this into a
// function literal.
Expression*
Selector_expression::lower_method_expression(Gogo* gogo)
{
source_location location = this->location();
Type* type = this->left_->type();
const std::string& name(this->name_);
bool is_pointer;
if (type->points_to() == NULL)
is_pointer = false;
else
{
is_pointer = true;
type = type->points_to();
}
Named_type* nt = type->named_type();
if (nt == NULL)
{
error_at(location,
("method expression requires named type or "
"pointer to named type"));
return Expression::make_error(location);
}
bool is_ambiguous;
Method* method = nt->method_function(name, &is_ambiguous);
if (method == NULL)
{
if (!is_ambiguous)
error_at(location, "type %<%s%> has no method %<%s%>",
nt->message_name().c_str(),
Gogo::message_name(name).c_str());
else
error_at(location, "method %<%s%> is ambiguous in type %<%s%>",
Gogo::message_name(name).c_str(),
nt->message_name().c_str());
return Expression::make_error(location);
}
if (!is_pointer && !method->is_value_method())
{
error_at(location, "method requires pointer (use %<(*%s).%s)%>",
nt->message_name().c_str(),
Gogo::message_name(name).c_str());
return Expression::make_error(location);
}
// Build a new function type in which the receiver becomes the first
// argument.
Function_type* method_type = method->type();
gcc_assert(method_type->is_method());
const char* const receiver_name = "$this";
Typed_identifier_list* parameters = new Typed_identifier_list();
parameters->push_back(Typed_identifier(receiver_name, this->left_->type(),
location));
const Typed_identifier_list* method_parameters = method_type->parameters();
if (method_parameters != NULL)
{
for (Typed_identifier_list::const_iterator p = method_parameters->begin();
p != method_parameters->end();
++p)
parameters->push_back(*p);
}
const Typed_identifier_list* method_results = method_type->results();
Typed_identifier_list* results;
if (method_results == NULL)
results = NULL;
else
{
results = new Typed_identifier_list();
for (Typed_identifier_list::const_iterator p = method_results->begin();
p != method_results->end();
++p)
results->push_back(*p);
}
Function_type* fntype = Type::make_function_type(NULL, parameters, results,
location);
if (method_type->is_varargs())
fntype->set_is_varargs();
// We generate methods which always takes a pointer to the receiver
// as their first argument. If this is for a pointer type, we can
// simply reuse the existing function. We use an internal hack to
// get the right type.
if (is_pointer)
{
Named_object* mno = (method->needs_stub_method()
? method->stub_object()
: method->named_object());
Expression* f = Expression::make_func_reference(mno, NULL, location);
f = Expression::make_cast(fntype, f, location);
Type_conversion_expression* tce =
static_cast<Type_conversion_expression*>(f);
tce->set_may_convert_function_types();
return f;
}
Named_object* no = gogo->start_function(Gogo::thunk_name(), fntype, false,
location);
Named_object* vno = gogo->lookup(receiver_name, NULL);
gcc_assert(vno != NULL);
Expression* ve = Expression::make_var_reference(vno, location);
Expression* bm = Type::bind_field_or_method(gogo, nt, ve, name, location);
gcc_assert(bm != NULL && !bm->is_error_expression());
Expression_list* args;
if (method_parameters == NULL)
args = NULL;
else
{
args = new Expression_list();
for (Typed_identifier_list::const_iterator p = method_parameters->begin();
p != method_parameters->end();
++p)
{
vno = gogo->lookup(p->name(), NULL);
gcc_assert(vno != NULL);
args->push_back(Expression::make_var_reference(vno, location));
}
}
Call_expression* call = Expression::make_call(bm, args,
method_type->is_varargs(),
location);
size_t count = call->result_count();
Statement* s;
if (count == 0)
s = Statement::make_statement(call);
else
{
Expression_list* retvals = new Expression_list();
if (count <= 1)
retvals->push_back(call);
else
{
for (size_t i = 0; i < count; ++i)
retvals->push_back(Expression::make_call_result(call, i));
}
s = Statement::make_return_statement(no->func_value()->type()->results(),
retvals, location);
}
gogo->add_statement(s);
gogo->finish_function(location);
return Expression::make_func_reference(no, NULL, location);
}
// Make a selector expression.
Expression*
Expression::make_selector(Expression* left, const std::string& name,
source_location location)
{
return new Selector_expression(left, name, location);
}
// Implement the builtin function new.
class Allocation_expression : public Expression
{
public:
Allocation_expression(Type* type, source_location location)
: Expression(EXPRESSION_ALLOCATION, location),
type_(type)
{ }
protected:
int
do_traverse(Traverse* traverse)
{ return Type::traverse(this->type_, traverse); }
Type*
do_type()
{ return Type::make_pointer_type(this->type_); }
void
do_determine_type(const Type_context*)
{ }
void
do_check_types(Gogo*);
Expression*
do_copy()
{ return new Allocation_expression(this->type_, this->location()); }
tree
do_get_tree(Translate_context*);
private:
// The type we are allocating.
Type* type_;
};
// Check the type of an allocation expression.
void
Allocation_expression::do_check_types(Gogo*)
{
if (this->type_->function_type() != NULL)
this->report_error(_("invalid new of function type"));
}
// Return a tree for an allocation expression.
tree
Allocation_expression::do_get_tree(Translate_context* context)
{
tree type_tree = this->type_->get_tree(context->gogo());
if (type_tree == error_mark_node)
return error_mark_node;
tree size_tree = TYPE_SIZE_UNIT(type_tree);
tree space = context->gogo()->allocate_memory(this->type_, size_tree,
this->location());
if (space == error_mark_node)
return error_mark_node;
return fold_convert(build_pointer_type(type_tree), space);
}
// Make an allocation expression.
Expression*
Expression::make_allocation(Type* type, source_location location)
{
return new Allocation_expression(type, location);
}
// Implement the builtin function make.
class Make_expression : public Expression
{
public:
Make_expression(Type* type, Expression_list* args, source_location location)
: Expression(EXPRESSION_MAKE, location),
type_(type), args_(args)
{ }
protected:
int
do_traverse(Traverse* traverse);
Type*
do_type()
{ return this->type_; }
void
do_determine_type(const Type_context*);
void
do_check_types(Gogo*);
Expression*
do_copy()
{
return new Make_expression(this->type_, this->args_->copy(),
this->location());
}
tree
do_get_tree(Translate_context*);
private:
// The type we are making.
Type* type_;
// The arguments to pass to the make routine.
Expression_list* args_;
};
// Traversal.
int
Make_expression::do_traverse(Traverse* traverse)
{
if (this->args_ != NULL
&& this->args_->traverse(traverse) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
if (Type::traverse(this->type_, traverse) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
return TRAVERSE_CONTINUE;
}
// Set types of arguments.
void
Make_expression::do_determine_type(const Type_context*)
{
if (this->args_ != NULL)
{
Type_context context(Type::lookup_integer_type("int"), false);
for (Expression_list::const_iterator pe = this->args_->begin();
pe != this->args_->end();
++pe)
(*pe)->determine_type(&context);
}
}
// Check types for a make expression.
void
Make_expression::do_check_types(Gogo*)
{
if (this->type_->channel_type() == NULL
&& this->type_->map_type() == NULL
&& (this->type_->array_type() == NULL
|| this->type_->array_type()->length() != NULL))
this->report_error(_("invalid type for make function"));
else if (!this->type_->check_make_expression(this->args_, this->location()))
this->set_is_error();
}
// Return a tree for a make expression.
tree
Make_expression::do_get_tree(Translate_context* context)
{
return this->type_->make_expression_tree(context, this->args_,
this->location());
}
// Make a make expression.
Expression*
Expression::make_make(Type* type, Expression_list* args,
source_location location)
{
return new Make_expression(type, args, location);
}
// Construct a struct.
class Struct_construction_expression : public Expression
{
public:
Struct_construction_expression(Type* type, Expression_list* vals,
source_location location)
: Expression(EXPRESSION_STRUCT_CONSTRUCTION, location),
type_(type), vals_(vals)
{ }
// Return whether this is a constant initializer.
bool
is_constant_struct() const;
protected:
int
do_traverse(Traverse* traverse);
Type*
do_type()
{ return this->type_; }
void
do_determine_type(const Type_context*);
void
do_check_types(Gogo*);
Expression*
do_copy()
{
return new Struct_construction_expression(this->type_, this->vals_->copy(),
this->location());
}
bool
do_is_addressable() const
{ return true; }
tree
do_get_tree(Translate_context*);
void
do_export(Export*) const;
private:
// The type of the struct to construct.
Type* type_;
// The list of values, in order of the fields in the struct. A NULL
// entry means that the field should be zero-initialized.
Expression_list* vals_;
};
// Traversal.
int
Struct_construction_expression::do_traverse(Traverse* traverse)
{
if (this->vals_ != NULL
&& this->vals_->traverse(traverse) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
if (Type::traverse(this->type_, traverse) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
return TRAVERSE_CONTINUE;
}
// Return whether this is a constant initializer.
bool
Struct_construction_expression::is_constant_struct() const
{
if (this->vals_ == NULL)
return true;
for (Expression_list::const_iterator pv = this->vals_->begin();
pv != this->vals_->end();
++pv)
{
if (*pv != NULL
&& !(*pv)->is_constant()
&& (!(*pv)->is_composite_literal()
|| (*pv)->is_nonconstant_composite_literal()))
return false;
}
const Struct_field_list* fields = this->type_->struct_type()->fields();
for (Struct_field_list::const_iterator pf = fields->begin();
pf != fields->end();
++pf)
{
// There are no constant constructors for interfaces.
if (pf->type()->interface_type() != NULL)
return false;
}
return true;
}
// Final type determination.
void
Struct_construction_expression::do_determine_type(const Type_context*)
{
if (this->vals_ == NULL)
return;
const Struct_field_list* fields = this->type_->struct_type()->fields();
Expression_list::const_iterator pv = this->vals_->begin();
for (Struct_field_list::const_iterator pf = fields->begin();
pf != fields->end();
++pf, ++pv)
{
if (pv == this->vals_->end())
return;
if (*pv != NULL)
{
Type_context subcontext(pf->type(), false);
(*pv)->determine_type(&subcontext);
}
}
// Extra values are an error we will report elsewhere; we still want
// to determine the type to avoid knockon errors.
for (; pv != this->vals_->end(); ++pv)
(*pv)->determine_type_no_context();
}
// Check types.
void
Struct_construction_expression::do_check_types(Gogo*)
{
if (this->vals_ == NULL)
return;
Struct_type* st = this->type_->struct_type();
if (this->vals_->size() > st->field_count())
{
this->report_error(_("too many expressions for struct"));
return;
}
const Struct_field_list* fields = st->fields();
Expression_list::const_iterator pv = this->vals_->begin();
int i = 0;
for (Struct_field_list::const_iterator pf = fields->begin();
pf != fields->end();
++pf, ++pv, ++i)
{
if (pv == this->vals_->end())
{
this->report_error(_("too few expressions for struct"));
break;
}
if (*pv == NULL)
continue;
std::string reason;
if (!Type::are_assignable(pf->type(), (*pv)->type(), &reason))
{
if (reason.empty())
error_at((*pv)->location(),
"incompatible type for field %d in struct construction",
i + 1);
else
error_at((*pv)->location(),
("incompatible type for field %d in "
"struct construction (%s)"),
i + 1, reason.c_str());
this->set_is_error();
}
}
gcc_assert(pv == this->vals_->end());
}
// Return a tree for constructing a struct.
tree
Struct_construction_expression::do_get_tree(Translate_context* context)
{
Gogo* gogo = context->gogo();
if (this->vals_ == NULL)
return this->type_->get_init_tree(gogo, false);
tree type_tree = this->type_->get_tree(gogo);
if (type_tree == error_mark_node)
return error_mark_node;
gcc_assert(TREE_CODE(type_tree) == RECORD_TYPE);
bool is_constant = true;
const Struct_field_list* fields = this->type_->struct_type()->fields();
VEC(constructor_elt,gc)* elts = VEC_alloc(constructor_elt, gc,
fields->size());
Struct_field_list::const_iterator pf = fields->begin();
Expression_list::const_iterator pv = this->vals_->begin();
for (tree field = TYPE_FIELDS(type_tree);
field != NULL_TREE;
field = DECL_CHAIN(field), ++pf)
{
gcc_assert(pf != fields->end());
tree val;
if (pv == this->vals_->end())
val = pf->type()->get_init_tree(gogo, false);
else if (*pv == NULL)
{
val = pf->type()->get_init_tree(gogo, false);
++pv;
}
else
{
val = Expression::convert_for_assignment(context, pf->type(),
(*pv)->type(),
(*pv)->get_tree(context),
this->location());
++pv;
}
if (val == error_mark_node || TREE_TYPE(val) == error_mark_node)
return error_mark_node;
constructor_elt* elt = VEC_quick_push(constructor_elt, elts, NULL);
elt->index = field;
elt->value = val;
if (!TREE_CONSTANT(val))
is_constant = false;
}
gcc_assert(pf == fields->end());
tree ret = build_constructor(type_tree, elts);
if (is_constant)
TREE_CONSTANT(ret) = 1;
return ret;
}
// Export a struct construction.
void
Struct_construction_expression::do_export(Export* exp) const
{
exp->write_c_string("convert(");
exp->write_type(this->type_);
for (Expression_list::const_iterator pv = this->vals_->begin();
pv != this->vals_->end();
++pv)
{
exp->write_c_string(", ");
if (*pv != NULL)
(*pv)->export_expression(exp);
}
exp->write_c_string(")");
}
// Make a struct composite literal. This used by the thunk code.
Expression*
Expression::make_struct_composite_literal(Type* type, Expression_list* vals,
source_location location)
{
gcc_assert(type->struct_type() != NULL);
return new Struct_construction_expression(type, vals, location);
}
// Construct an array. This class is not used directly; instead we
// use the child classes, Fixed_array_construction_expression and
// Open_array_construction_expression.
class Array_construction_expression : public Expression
{
protected:
Array_construction_expression(Expression_classification classification,
Type* type, Expression_list* vals,
source_location location)
: Expression(classification, location),
type_(type), vals_(vals)
{ }
public:
// Return whether this is a constant initializer.
bool
is_constant_array() const;
// Return the number of elements.
size_t
element_count() const
{ return this->vals_ == NULL ? 0 : this->vals_->size(); }
protected:
int
do_traverse(Traverse* traverse);
Type*
do_type()
{ return this->type_; }
void
do_determine_type(const Type_context*);
void
do_check_types(Gogo*);
bool
do_is_addressable() const
{ return true; }
void
do_export(Export*) const;
// The list of values.
Expression_list*
vals()
{ return this->vals_; }
// Get a constructor tree for the array values.
tree
get_constructor_tree(Translate_context* context, tree type_tree);
private:
// The type of the array to construct.
Type* type_;
// The list of values.
Expression_list* vals_;
};
// Traversal.
int
Array_construction_expression::do_traverse(Traverse* traverse)
{
if (this->vals_ != NULL
&& this->vals_->traverse(traverse) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
if (Type::traverse(this->type_, traverse) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
return TRAVERSE_CONTINUE;
}
// Return whether this is a constant initializer.
bool
Array_construction_expression::is_constant_array() const
{
if (this->vals_ == NULL)
return true;
// There are no constant constructors for interfaces.
if (this->type_->array_type()->element_type()->interface_type() != NULL)
return false;
for (Expression_list::const_iterator pv = this->vals_->begin();
pv != this->vals_->end();
++pv)
{
if (*pv != NULL
&& !(*pv)->is_constant()
&& (!(*pv)->is_composite_literal()
|| (*pv)->is_nonconstant_composite_literal()))
return false;
}
return true;
}
// Final type determination.
void
Array_construction_expression::do_determine_type(const Type_context*)
{
if (this->vals_ == NULL)
return;
Type_context subcontext(this->type_->array_type()->element_type(), false);
for (Expression_list::const_iterator pv = this->vals_->begin();
pv != this->vals_->end();
++pv)
{
if (*pv != NULL)
(*pv)->determine_type(&subcontext);
}
}
// Check types.
void
Array_construction_expression::do_check_types(Gogo*)
{
if (this->vals_ == NULL)
return;
Array_type* at = this->type_->array_type();
int i = 0;
Type* element_type = at->element_type();
for (Expression_list::const_iterator pv = this->vals_->begin();
pv != this->vals_->end();
++pv, ++i)
{
if (*pv != NULL
&& !Type::are_assignable(element_type, (*pv)->type(), NULL))
{
error_at((*pv)->location(),
"incompatible type for element %d in composite literal",
i + 1);
this->set_is_error();
}
}
Expression* length = at->length();
if (length != NULL)
{
mpz_t val;
mpz_init(val);
Type* type;
if (at->length()->integer_constant_value(true, val, &type))
{
if (this->vals_->size() > mpz_get_ui(val))
this->report_error(_("too many elements in composite literal"));
}
mpz_clear(val);
}
}
// Get a constructor tree for the array values.
tree
Array_construction_expression::get_constructor_tree(Translate_context* context,
tree type_tree)
{
VEC(constructor_elt,gc)* values = VEC_alloc(constructor_elt, gc,
(this->vals_ == NULL
? 0
: this->vals_->size()));
Type* element_type = this->type_->array_type()->element_type();
bool is_constant = true;
if (this->vals_ != NULL)
{
size_t i = 0;
for (Expression_list::const_iterator pv = this->vals_->begin();
pv != this->vals_->end();
++pv, ++i)
{
constructor_elt* elt = VEC_quick_push(constructor_elt, values, NULL);
elt->index = size_int(i);
if (*pv == NULL)
elt->value = element_type->get_init_tree(context->gogo(), false);
else
{
tree value_tree = (*pv)->get_tree(context);
elt->value = Expression::convert_for_assignment(context,
element_type,
(*pv)->type(),
value_tree,
this->location());
}
if (elt->value == error_mark_node)
return error_mark_node;
if (!TREE_CONSTANT(elt->value))
is_constant = false;
}
}
tree ret = build_constructor(type_tree, values);
if (is_constant)
TREE_CONSTANT(ret) = 1;
return ret;
}
// Export an array construction.
void
Array_construction_expression::do_export(Export* exp) const
{
exp->write_c_string("convert(");
exp->write_type(this->type_);
if (this->vals_ != NULL)
{
for (Expression_list::const_iterator pv = this->vals_->begin();
pv != this->vals_->end();
++pv)
{
exp->write_c_string(", ");
if (*pv != NULL)
(*pv)->export_expression(exp);
}
}
exp->write_c_string(")");
}
// Construct a fixed array.
class Fixed_array_construction_expression :
public Array_construction_expression
{
public:
Fixed_array_construction_expression(Type* type, Expression_list* vals,
source_location location)
: Array_construction_expression(EXPRESSION_FIXED_ARRAY_CONSTRUCTION,
type, vals, location)
{
gcc_assert(type->array_type() != NULL
&& type->array_type()->length() != NULL);
}
protected:
Expression*
do_copy()
{
return new Fixed_array_construction_expression(this->type(),
(this->vals() == NULL
? NULL
: this->vals()->copy()),
this->location());
}
tree
do_get_tree(Translate_context*);
};
// Return a tree for constructing a fixed array.
tree
Fixed_array_construction_expression::do_get_tree(Translate_context* context)
{
return this->get_constructor_tree(context,
this->type()->get_tree(context->gogo()));
}
// Construct an open array.
class Open_array_construction_expression : public Array_construction_expression
{
public:
Open_array_construction_expression(Type* type, Expression_list* vals,
source_location location)
: Array_construction_expression(EXPRESSION_OPEN_ARRAY_CONSTRUCTION,
type, vals, location)
{
gcc_assert(type->array_type() != NULL
&& type->array_type()->length() == NULL);
}
protected:
// Note that taking the address of an open array literal is invalid.
Expression*
do_copy()
{
return new Open_array_construction_expression(this->type(),
(this->vals() == NULL
? NULL
: this->vals()->copy()),
this->location());
}
tree
do_get_tree(Translate_context*);
};
// Return a tree for constructing an open array.
tree
Open_array_construction_expression::do_get_tree(Translate_context* context)
{
Array_type* array_type = this->type()->array_type();
if (array_type == NULL)
{
gcc_assert(this->type()->is_error_type());
return error_mark_node;
}
Type* element_type = array_type->element_type();
tree element_type_tree = element_type->get_tree(context->gogo());
if (element_type_tree == error_mark_node)
return error_mark_node;
tree values;
tree length_tree;
if (this->vals() == NULL || this->vals()->empty())
{
// We need to create a unique value.
tree max = size_int(0);
tree constructor_type = build_array_type(element_type_tree,
build_index_type(max));
if (constructor_type == error_mark_node)
return error_mark_node;
VEC(constructor_elt,gc)* vec = VEC_alloc(constructor_elt, gc, 1);
constructor_elt* elt = VEC_quick_push(constructor_elt, vec, NULL);
elt->index = size_int(0);
elt->value = element_type->get_init_tree(context->gogo(), false);
values = build_constructor(constructor_type, vec);
if (TREE_CONSTANT(elt->value))
TREE_CONSTANT(values) = 1;
length_tree = size_int(0);
}
else
{
tree max = size_int(this->vals()->size() - 1);
tree constructor_type = build_array_type(element_type_tree,
build_index_type(max));
if (constructor_type == error_mark_node)
return error_mark_node;
values = this->get_constructor_tree(context, constructor_type);
length_tree = size_int(this->vals()->size());
}
if (values == error_mark_node)
return error_mark_node;
bool is_constant_initializer = TREE_CONSTANT(values);
// We have to copy the initial values into heap memory if we are in
// a function or if the values are not constants. We also have to
// copy them if they may contain pointers in a non-constant context,
// as otherwise the garbage collector won't see them.
bool copy_to_heap = (context->function() != NULL
|| !is_constant_initializer
|| (element_type->has_pointer()
&& !context->is_const()));
if (is_constant_initializer)
{
tree tmp = build_decl(this->location(), VAR_DECL,
create_tmp_var_name("C"), TREE_TYPE(values));
DECL_EXTERNAL(tmp) = 0;
TREE_PUBLIC(tmp) = 0;
TREE_STATIC(tmp) = 1;
DECL_ARTIFICIAL(tmp) = 1;
if (copy_to_heap)
{
// If we are not copying the value to the heap, we will only
// initialize the value once, so we can use this directly
// rather than copying it. In that case we can't make it
// read-only, because the program is permitted to change it.
TREE_READONLY(tmp) = 1;
TREE_CONSTANT(tmp) = 1;
}
DECL_INITIAL(tmp) = values;
rest_of_decl_compilation(tmp, 1, 0);
values = tmp;
}
tree space;
tree set;
if (!copy_to_heap)
{
// the initializer will only run once.
space = build_fold_addr_expr(values);
set = NULL_TREE;
}
else
{
tree memsize = TYPE_SIZE_UNIT(TREE_TYPE(values));
space = context->gogo()->allocate_memory(element_type, memsize,
this->location());
space = save_expr(space);
tree s = fold_convert(build_pointer_type(TREE_TYPE(values)), space);
tree ref = build_fold_indirect_ref_loc(this->location(), s);
TREE_THIS_NOTRAP(ref) = 1;
set = build2(MODIFY_EXPR, void_type_node, ref, values);
}
// Build a constructor for the open array.
tree type_tree = this->type()->get_tree(context->gogo());
if (type_tree == error_mark_node)
return error_mark_node;
gcc_assert(TREE_CODE(type_tree) == RECORD_TYPE);
VEC(constructor_elt,gc)* init = VEC_alloc(constructor_elt, gc, 3);
constructor_elt* elt = VEC_quick_push(constructor_elt, init, NULL);
tree field = TYPE_FIELDS(type_tree);
gcc_assert(strcmp(IDENTIFIER_POINTER(DECL_NAME(field)), "__values") == 0);
elt->index = field;
elt->value = fold_convert(TREE_TYPE(field), space);
elt = VEC_quick_push(constructor_elt, init, NULL);
field = DECL_CHAIN(field);
gcc_assert(strcmp(IDENTIFIER_POINTER(DECL_NAME(field)), "__count") == 0);
elt->index = field;
elt->value = fold_convert(TREE_TYPE(field), length_tree);
elt = VEC_quick_push(constructor_elt, init, NULL);
field = DECL_CHAIN(field);
gcc_assert(strcmp(IDENTIFIER_POINTER(DECL_NAME(field)),"__capacity") == 0);
elt->index = field;
elt->value = fold_convert(TREE_TYPE(field), length_tree);
tree constructor = build_constructor(type_tree, init);
if (constructor == error_mark_node)
return error_mark_node;
if (!copy_to_heap)
TREE_CONSTANT(constructor) = 1;
if (set == NULL_TREE)
return constructor;
else
return build2(COMPOUND_EXPR, type_tree, set, constructor);
}
// Make a slice composite literal. This is used by the type
// descriptor code.
Expression*
Expression::make_slice_composite_literal(Type* type, Expression_list* vals,
source_location location)
{
gcc_assert(type->is_open_array_type());
return new Open_array_construction_expression(type, vals, location);
}
// Construct a map.
class Map_construction_expression : public Expression
{
public:
Map_construction_expression(Type* type, Expression_list* vals,
source_location location)
: Expression(EXPRESSION_MAP_CONSTRUCTION, location),
type_(type), vals_(vals)
{ gcc_assert(vals == NULL || vals->size() % 2 == 0); }
protected:
int
do_traverse(Traverse* traverse);
Type*
do_type()
{ return this->type_; }
void
do_determine_type(const Type_context*);
void
do_check_types(Gogo*);
Expression*
do_copy()
{
return new Map_construction_expression(this->type_, this->vals_->copy(),
this->location());
}
tree
do_get_tree(Translate_context*);
void
do_export(Export*) const;
private:
// The type of the map to construct.
Type* type_;
// The list of values.
Expression_list* vals_;
};
// Traversal.
int
Map_construction_expression::do_traverse(Traverse* traverse)
{
if (this->vals_ != NULL
&& this->vals_->traverse(traverse) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
if (Type::traverse(this->type_, traverse) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
return TRAVERSE_CONTINUE;
}
// Final type determination.
void
Map_construction_expression::do_determine_type(const Type_context*)
{
if (this->vals_ == NULL)
return;
Map_type* mt = this->type_->map_type();
Type_context key_context(mt->key_type(), false);
Type_context val_context(mt->val_type(), false);
for (Expression_list::const_iterator pv = this->vals_->begin();
pv != this->vals_->end();
++pv)
{
(*pv)->determine_type(&key_context);
++pv;
(*pv)->determine_type(&val_context);
}
}
// Check types.
void
Map_construction_expression::do_check_types(Gogo*)
{
if (this->vals_ == NULL)
return;
Map_type* mt = this->type_->map_type();
int i = 0;
Type* key_type = mt->key_type();
Type* val_type = mt->val_type();
for (Expression_list::const_iterator pv = this->vals_->begin();
pv != this->vals_->end();
++pv, ++i)
{
if (!Type::are_assignable(key_type, (*pv)->type(), NULL))
{
error_at((*pv)->location(),
"incompatible type for element %d key in map construction",
i + 1);
this->set_is_error();
}
++pv;
if (!Type::are_assignable(val_type, (*pv)->type(), NULL))
{
error_at((*pv)->location(),
("incompatible type for element %d value "
"in map construction"),
i + 1);
this->set_is_error();
}
}
}
// Return a tree for constructing a map.
tree
Map_construction_expression::do_get_tree(Translate_context* context)
{
Gogo* gogo = context->gogo();
source_location loc = this->location();
Map_type* mt = this->type_->map_type();
// Build a struct to hold the key and value.
tree struct_type = make_node(RECORD_TYPE);
Type* key_type = mt->key_type();
tree id = get_identifier("__key");
tree key_type_tree = key_type->get_tree(gogo);
if (key_type_tree == error_mark_node)
return error_mark_node;
tree key_field = build_decl(loc, FIELD_DECL, id, key_type_tree);
DECL_CONTEXT(key_field) = struct_type;
TYPE_FIELDS(struct_type) = key_field;
Type* val_type = mt->val_type();
id = get_identifier("__val");
tree val_type_tree = val_type->get_tree(gogo);
if (val_type_tree == error_mark_node)
return error_mark_node;
tree val_field = build_decl(loc, FIELD_DECL, id, val_type_tree);
DECL_CONTEXT(val_field) = struct_type;
DECL_CHAIN(key_field) = val_field;
layout_type(struct_type);
bool is_constant = true;
size_t i = 0;
tree valaddr;
tree make_tmp;
if (this->vals_ == NULL || this->vals_->empty())
{
valaddr = null_pointer_node;
make_tmp = NULL_TREE;
}
else
{
VEC(constructor_elt,gc)* values = VEC_alloc(constructor_elt, gc,
this->vals_->size() / 2);
for (Expression_list::const_iterator pv = this->vals_->begin();
pv != this->vals_->end();
++pv, ++i)
{
bool one_is_constant = true;
VEC(constructor_elt,gc)* one = VEC_alloc(constructor_elt, gc, 2);
constructor_elt* elt = VEC_quick_push(constructor_elt, one, NULL);
elt->index = key_field;
tree val_tree = (*pv)->get_tree(context);
elt->value = Expression::convert_for_assignment(context, key_type,
(*pv)->type(),
val_tree, loc);
if (elt->value == error_mark_node)
return error_mark_node;
if (!TREE_CONSTANT(elt->value))
one_is_constant = false;
++pv;
elt = VEC_quick_push(constructor_elt, one, NULL);
elt->index = val_field;
val_tree = (*pv)->get_tree(context);
elt->value = Expression::convert_for_assignment(context, val_type,
(*pv)->type(),
val_tree, loc);
if (elt->value == error_mark_node)
return error_mark_node;
if (!TREE_CONSTANT(elt->value))
one_is_constant = false;
elt = VEC_quick_push(constructor_elt, values, NULL);
elt->index = size_int(i);
elt->value = build_constructor(struct_type, one);
if (one_is_constant)
TREE_CONSTANT(elt->value) = 1;
else
is_constant = false;
}
tree index_type = build_index_type(size_int(i - 1));
tree array_type = build_array_type(struct_type, index_type);
tree init = build_constructor(array_type, values);
if (is_constant)
TREE_CONSTANT(init) = 1;
tree tmp;
if (current_function_decl != NULL)
{
tmp = create_tmp_var(array_type, get_name(array_type));
DECL_INITIAL(tmp) = init;
make_tmp = fold_build1_loc(loc, DECL_EXPR, void_type_node, tmp);
TREE_ADDRESSABLE(tmp) = 1;
}
else
{
tmp = build_decl(loc, VAR_DECL, create_tmp_var_name("M"), array_type);
DECL_EXTERNAL(tmp) = 0;
TREE_PUBLIC(tmp) = 0;
TREE_STATIC(tmp) = 1;
DECL_ARTIFICIAL(tmp) = 1;
if (!TREE_CONSTANT(init))
make_tmp = fold_build2_loc(loc, INIT_EXPR, void_type_node, tmp,
init);
else
{
TREE_READONLY(tmp) = 1;
TREE_CONSTANT(tmp) = 1;
DECL_INITIAL(tmp) = init;
make_tmp = NULL_TREE;
}
rest_of_decl_compilation(tmp, 1, 0);
}
valaddr = build_fold_addr_expr(tmp);
}
tree descriptor = gogo->map_descriptor(mt);
tree type_tree = this->type_->get_tree(gogo);
if (type_tree == error_mark_node)
return error_mark_node;
static tree construct_map_fndecl;
tree call = Gogo::call_builtin(&construct_map_fndecl,
loc,
"__go_construct_map",
6,
type_tree,
TREE_TYPE(descriptor),
descriptor,
sizetype,
size_int(i),
sizetype,
TYPE_SIZE_UNIT(struct_type),
sizetype,
byte_position(val_field),
sizetype,
TYPE_SIZE_UNIT(TREE_TYPE(val_field)),
const_ptr_type_node,
fold_convert(const_ptr_type_node, valaddr));
if (call == error_mark_node)
return error_mark_node;
tree ret;
if (make_tmp == NULL)
ret = call;
else
ret = fold_build2_loc(loc, COMPOUND_EXPR, type_tree, make_tmp, call);
return ret;
}
// Export an array construction.
void
Map_construction_expression::do_export(Export* exp) const
{
exp->write_c_string("convert(");
exp->write_type(this->type_);
for (Expression_list::const_iterator pv = this->vals_->begin();
pv != this->vals_->end();
++pv)
{
exp->write_c_string(", ");
(*pv)->export_expression(exp);
}
exp->write_c_string(")");
}
// A general composite literal. This is lowered to a type specific
// version.
class Composite_literal_expression : public Parser_expression
{
public:
Composite_literal_expression(Type* type, int depth, bool has_keys,
Expression_list* vals, source_location location)
: Parser_expression(EXPRESSION_COMPOSITE_LITERAL, location),
type_(type), depth_(depth), vals_(vals), has_keys_(has_keys)
{ }
protected:
int
do_traverse(Traverse* traverse);
Expression*
do_lower(Gogo*, Named_object*, int);
Expression*
do_copy()
{
return new Composite_literal_expression(this->type_, this->depth_,
this->has_keys_,
(this->vals_ == NULL
? NULL
: this->vals_->copy()),
this->location());
}
private:
Expression*
lower_struct(Type*);
Expression*
lower_array(Type*);
Expression*
make_array(Type*, Expression_list*);
Expression*
lower_map(Gogo*, Named_object*, Type*);
// The type of the composite literal.
Type* type_;
// The depth within a list of composite literals within a composite
// literal, when the type is omitted.
int depth_;
// The values to put in the composite literal.
Expression_list* vals_;
// If this is true, then VALS_ is a list of pairs: a key and a
// value. In an array initializer, a missing key will be NULL.
bool has_keys_;
};
// Traversal.
int
Composite_literal_expression::do_traverse(Traverse* traverse)
{
if (this->vals_ != NULL
&& this->vals_->traverse(traverse) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
return Type::traverse(this->type_, traverse);
}
// Lower a generic composite literal into a specific version based on
// the type.
Expression*
Composite_literal_expression::do_lower(Gogo* gogo, Named_object* function, int)
{
Type* type = this->type_;
for (int depth = this->depth_; depth > 0; --depth)
{
if (type->array_type() != NULL)
type = type->array_type()->element_type();
else if (type->map_type() != NULL)
type = type->map_type()->val_type();
else
{
if (!type->is_error_type())
error_at(this->location(),
("may only omit types within composite literals "
"of slice, array, or map type"));
return Expression::make_error(this->location());
}
}
if (type->is_error_type())
return Expression::make_error(this->location());
else if (type->struct_type() != NULL)
return this->lower_struct(type);
else if (type->array_type() != NULL)
return this->lower_array(type);
else if (type->map_type() != NULL)
return this->lower_map(gogo, function, type);
else
{
error_at(this->location(),
("expected struct, slice, array, or map type "
"for composite literal"));
return Expression::make_error(this->location());
}
}
// Lower a struct composite literal.
Expression*
Composite_literal_expression::lower_struct(Type* type)
{
source_location location = this->location();
Struct_type* st = type->struct_type();
if (this->vals_ == NULL || !this->has_keys_)
return new Struct_construction_expression(type, this->vals_, location);
size_t field_count = st->field_count();
std::vector<Expression*> vals(field_count);
Expression_list::const_iterator p = this->vals_->begin();
while (p != this->vals_->end())
{
Expression* name_expr = *p;
++p;
gcc_assert(p != this->vals_->end());
Expression* val = *p;
++p;
if (name_expr == NULL)
{
error_at(val->location(), "mixture of field and value initializers");
return Expression::make_error(location);
}
bool bad_key = false;
std::string name;
switch (name_expr->classification())
{
case EXPRESSION_UNKNOWN_REFERENCE:
name = name_expr->unknown_expression()->name();
break;
case EXPRESSION_CONST_REFERENCE:
name = static_cast<Const_expression*>(name_expr)->name();
break;
case EXPRESSION_TYPE:
{
Type* t = name_expr->type();
Named_type* nt = t->named_type();
if (nt == NULL)
bad_key = true;
else
name = nt->name();
}
break;
case EXPRESSION_VAR_REFERENCE:
name = name_expr->var_expression()->name();
break;
case EXPRESSION_FUNC_REFERENCE:
name = name_expr->func_expression()->name();
break;
case EXPRESSION_UNARY:
// If there is a local variable around with the same name as
// the field, and this occurs in the closure, then the
// parser may turn the field reference into an indirection
// through the closure. FIXME: This is a mess.
{
bad_key = true;
Unary_expression* ue = static_cast<Unary_expression*>(name_expr);
if (ue->op() == OPERATOR_MULT)
{
Field_reference_expression* fre =
ue->operand()->field_reference_expression();
if (fre != NULL)
{
Struct_type* st =
fre->expr()->type()->deref()->struct_type();
if (st != NULL)
{
const Struct_field* sf = st->field(fre->field_index());
name = sf->field_name();
char buf[20];
snprintf(buf, sizeof buf, "%u", fre->field_index());
size_t buflen = strlen(buf);
if (name.compare(name.length() - buflen, buflen, buf)
== 0)
{
name = name.substr(0, name.length() - buflen);
bad_key = false;
}
}
}
}
}
break;
default:
bad_key = true;
break;
}
if (bad_key)
{
error_at(name_expr->location(), "expected struct field name");
return Expression::make_error(location);
}
unsigned int index;
const Struct_field* sf = st->find_local_field(name, &index);
if (sf == NULL)
{
error_at(name_expr->location(), "unknown field %qs in %qs",
Gogo::message_name(name).c_str(),
(type->named_type() != NULL
? type->named_type()->message_name().c_str()
: "unnamed struct"));
return Expression::make_error(location);
}
if (vals[index] != NULL)
{
error_at(name_expr->location(),
"duplicate value for field %qs in %qs",
Gogo::message_name(name).c_str(),
(type->named_type() != NULL
? type->named_type()->message_name().c_str()
: "unnamed struct"));
return Expression::make_error(location);
}
vals[index] = val;
}
Expression_list* list = new Expression_list;
list->reserve(field_count);
for (size_t i = 0; i < field_count; ++i)
list->push_back(vals[i]);
return new Struct_construction_expression(type, list, location);
}
// Lower an array composite literal.
Expression*
Composite_literal_expression::lower_array(Type* type)
{
source_location location = this->location();
if (this->vals_ == NULL || !this->has_keys_)
return this->make_array(type, this->vals_);
std::vector<Expression*> vals;
vals.reserve(this->vals_->size());
unsigned long index = 0;
Expression_list::const_iterator p = this->vals_->begin();
while (p != this->vals_->end())
{
Expression* index_expr = *p;
++p;
gcc_assert(p != this->vals_->end());
Expression* val = *p;
++p;
if (index_expr != NULL)
{
mpz_t ival;
mpz_init(ival);
Type* dummy;
if (!index_expr->integer_constant_value(true, ival, &dummy))
{
mpz_clear(ival);
error_at(index_expr->location(),
"index expression is not integer constant");
return Expression::make_error(location);
}
if (mpz_sgn(ival) < 0)
{
mpz_clear(ival);
error_at(index_expr->location(), "index expression is negative");
return Expression::make_error(location);
}
index = mpz_get_ui(ival);
if (mpz_cmp_ui(ival, index) != 0)
{
mpz_clear(ival);
error_at(index_expr->location(), "index value overflow");
return Expression::make_error(location);
}
mpz_clear(ival);
}
if (index == vals.size())
vals.push_back(val);
else
{
if (index > vals.size())
{
vals.reserve(index + 32);
vals.resize(index + 1, static_cast<Expression*>(NULL));
}
if (vals[index] != NULL)
{
error_at((index_expr != NULL
? index_expr->location()
: val->location()),
"duplicate value for index %lu",
index);
return Expression::make_error(location);
}
vals[index] = val;
}
++index;
}
size_t size = vals.size();
Expression_list* list = new Expression_list;
list->reserve(size);
for (size_t i = 0; i < size; ++i)
list->push_back(vals[i]);
return this->make_array(type, list);
}
// Actually build the array composite literal. This handles
// [...]{...}.
Expression*
Composite_literal_expression::make_array(Type* type, Expression_list* vals)
{
source_location location = this->location();
Array_type* at = type->array_type();
if (at->length() != NULL && at->length()->is_nil_expression())
{
size_t size = vals == NULL ? 0 : vals->size();
mpz_t vlen;
mpz_init_set_ui(vlen, size);
Expression* elen = Expression::make_integer(&vlen, NULL, location);
mpz_clear(vlen);
at = Type::make_array_type(at->element_type(), elen);
type = at;
}
if (at->length() != NULL)
return new Fixed_array_construction_expression(type, vals, location);
else
return new Open_array_construction_expression(type, vals, location);
}
// Lower a map composite literal.
Expression*
Composite_literal_expression::lower_map(Gogo* gogo, Named_object* function,
Type* type)
{
source_location location = this->location();
if (this->vals_ != NULL)
{
if (!this->has_keys_)
{
error_at(location, "map composite literal must have keys");
return Expression::make_error(location);
}
for (Expression_list::iterator p = this->vals_->begin();
p != this->vals_->end();
p += 2)
{
if (*p == NULL)
{
++p;
error_at((*p)->location(),
"map composite literal must have keys for every value");
return Expression::make_error(location);
}
// Make sure we have lowered the key; it may not have been
// lowered in order to handle keys for struct composite
// literals. Lower it now to get the right error message.
if ((*p)->unknown_expression() != NULL)
{
(*p)->unknown_expression()->clear_is_composite_literal_key();
gogo->lower_expression(function, &*p);
gcc_assert((*p)->is_error_expression());
return Expression::make_error(location);
}
}
}
return new Map_construction_expression(type, this->vals_, location);
}
// Make a composite literal expression.
Expression*
Expression::make_composite_literal(Type* type, int depth, bool has_keys,
Expression_list* vals,
source_location location)
{
return new Composite_literal_expression(type, depth, has_keys, vals,
location);
}
// Return whether this expression is a composite literal.
bool
Expression::is_composite_literal() const
{
switch (this->classification_)
{
case EXPRESSION_COMPOSITE_LITERAL:
case EXPRESSION_STRUCT_CONSTRUCTION:
case EXPRESSION_FIXED_ARRAY_CONSTRUCTION:
case EXPRESSION_OPEN_ARRAY_CONSTRUCTION:
case EXPRESSION_MAP_CONSTRUCTION:
return true;
default:
return false;
}
}
// Return whether this expression is a composite literal which is not
// constant.
bool
Expression::is_nonconstant_composite_literal() const
{
switch (this->classification_)
{
case EXPRESSION_STRUCT_CONSTRUCTION:
{
const Struct_construction_expression *psce =
static_cast<const Struct_construction_expression*>(this);
return !psce->is_constant_struct();
}
case EXPRESSION_FIXED_ARRAY_CONSTRUCTION:
{
const Fixed_array_construction_expression *pace =
static_cast<const Fixed_array_construction_expression*>(this);
return !pace->is_constant_array();
}
case EXPRESSION_OPEN_ARRAY_CONSTRUCTION:
{
const Open_array_construction_expression *pace =
static_cast<const Open_array_construction_expression*>(this);
return !pace->is_constant_array();
}
case EXPRESSION_MAP_CONSTRUCTION:
return true;
default:
return false;
}
}
// Return true if this is a reference to a local variable.
bool
Expression::is_local_variable() const
{
const Var_expression* ve = this->var_expression();
if (ve == NULL)
return false;
const Named_object* no = ve->named_object();
return (no->is_result_variable()
|| (no->is_variable() && !no->var_value()->is_global()));
}
// Class Type_guard_expression.
// Traversal.
int
Type_guard_expression::do_traverse(Traverse* traverse)
{
if (Expression::traverse(&this->expr_, traverse) == TRAVERSE_EXIT
|| Type::traverse(this->type_, traverse) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
return TRAVERSE_CONTINUE;
}
// Check types of a type guard expression. The expression must have
// an interface type, but the actual type conversion is checked at run
// time.
void
Type_guard_expression::do_check_types(Gogo*)
{
// 6g permits using a type guard with unsafe.pointer; we are
// compatible.
Type* expr_type = this->expr_->type();
if (expr_type->is_unsafe_pointer_type())
{
if (this->type_->points_to() == NULL
&& (this->type_->integer_type() == NULL
|| (this->type_->forwarded()
!= Type::lookup_integer_type("uintptr"))))
this->report_error(_("invalid unsafe.Pointer conversion"));
}
else if (this->type_->is_unsafe_pointer_type())
{
if (expr_type->points_to() == NULL
&& (expr_type->integer_type() == NULL
|| (expr_type->forwarded()
!= Type::lookup_integer_type("uintptr"))))
this->report_error(_("invalid unsafe.Pointer conversion"));
}
else if (expr_type->interface_type() == NULL)
{
if (!expr_type->is_error_type() && !this->type_->is_error_type())
this->report_error(_("type assertion only valid for interface types"));
this->set_is_error();
}
else if (this->type_->interface_type() == NULL)
{
std::string reason;
if (!expr_type->interface_type()->implements_interface(this->type_,
&reason))
{
if (!this->type_->is_error_type())
{
if (reason.empty())
this->report_error(_("impossible type assertion: "
"type does not implement interface"));
else
error_at(this->location(),
("impossible type assertion: "
"type does not implement interface (%s)"),
reason.c_str());
}
this->set_is_error();
}
}
}
// Return a tree for a type guard expression.
tree
Type_guard_expression::do_get_tree(Translate_context* context)
{
Gogo* gogo = context->gogo();
tree expr_tree = this->expr_->get_tree(context);
if (expr_tree == error_mark_node)
return error_mark_node;
Type* expr_type = this->expr_->type();
if ((this->type_->is_unsafe_pointer_type()
&& (expr_type->points_to() != NULL
|| expr_type->integer_type() != NULL))
|| (expr_type->is_unsafe_pointer_type()
&& this->type_->points_to() != NULL))
return convert_to_pointer(this->type_->get_tree(gogo), expr_tree);
else if (expr_type->is_unsafe_pointer_type()
&& this->type_->integer_type() != NULL)
return convert_to_integer(this->type_->get_tree(gogo), expr_tree);
else if (this->type_->interface_type() != NULL)
return Expression::convert_interface_to_interface(context, this->type_,
this->expr_->type(),
expr_tree, true,
this->location());
else
return Expression::convert_for_assignment(context, this->type_,
this->expr_->type(), expr_tree,
this->location());
}
// Make a type guard expression.
Expression*
Expression::make_type_guard(Expression* expr, Type* type,
source_location location)
{
return new Type_guard_expression(expr, type, location);
}
// Class Heap_composite_expression.
// When you take the address of a composite literal, it is allocated
// on the heap. This class implements that.
class Heap_composite_expression : public Expression
{
public:
Heap_composite_expression(Expression* expr, source_location location)
: Expression(EXPRESSION_HEAP_COMPOSITE, location),
expr_(expr)
{ }
protected:
int
do_traverse(Traverse* traverse)
{ return Expression::traverse(&this->expr_, traverse); }
Type*
do_type()
{ return Type::make_pointer_type(this->expr_->type()); }
void
do_determine_type(const Type_context*)
{ this->expr_->determine_type_no_context(); }
Expression*
do_copy()
{
return Expression::make_heap_composite(this->expr_->copy(),
this->location());
}
tree
do_get_tree(Translate_context*);
// We only export global objects, and the parser does not generate
// this in global scope.
void
do_export(Export*) const
{ gcc_unreachable(); }
private:
// The composite literal which is being put on the heap.
Expression* expr_;
};
// Return a tree which allocates a composite literal on the heap.
tree
Heap_composite_expression::do_get_tree(Translate_context* context)
{
tree expr_tree = this->expr_->get_tree(context);
if (expr_tree == error_mark_node)
return error_mark_node;
tree expr_size = TYPE_SIZE_UNIT(TREE_TYPE(expr_tree));
gcc_assert(TREE_CODE(expr_size) == INTEGER_CST);
tree space = context->gogo()->allocate_memory(this->expr_->type(),
expr_size, this->location());
space = fold_convert(build_pointer_type(TREE_TYPE(expr_tree)), space);
space = save_expr(space);
tree ref = build_fold_indirect_ref_loc(this->location(), space);
TREE_THIS_NOTRAP(ref) = 1;
tree ret = build2(COMPOUND_EXPR, TREE_TYPE(space),
build2(MODIFY_EXPR, void_type_node, ref, expr_tree),
space);
SET_EXPR_LOCATION(ret, this->location());
return ret;
}
// Allocate a composite literal on the heap.
Expression*
Expression::make_heap_composite(Expression* expr, source_location location)
{
return new Heap_composite_expression(expr, location);
}
// Class Receive_expression.
// Return the type of a receive expression.
Type*
Receive_expression::do_type()
{
Channel_type* channel_type = this->channel_->type()->channel_type();
if (channel_type == NULL)
return Type::make_error_type();
return channel_type->element_type();
}
// Check types for a receive expression.
void
Receive_expression::do_check_types(Gogo*)
{
Type* type = this->channel_->type();
if (type->is_error_type())
{
this->set_is_error();
return;
}
if (type->channel_type() == NULL)
{
this->report_error(_("expected channel"));
return;
}
if (!type->channel_type()->may_receive())
{
this->report_error(_("invalid receive on send-only channel"));
return;
}
}
// Get a tree for a receive expression.
tree
Receive_expression::do_get_tree(Translate_context* context)
{
Channel_type* channel_type = this->channel_->type()->channel_type();
gcc_assert(channel_type != NULL);
Type* element_type = channel_type->element_type();
tree element_type_tree = element_type->get_tree(context->gogo());
tree channel = this->channel_->get_tree(context);
if (element_type_tree == error_mark_node || channel == error_mark_node)
return error_mark_node;
return Gogo::receive_from_channel(element_type_tree, channel,
this->for_select_, this->location());
}
// Make a receive expression.
Receive_expression*
Expression::make_receive(Expression* channel, source_location location)
{
return new Receive_expression(channel, location);
}
// Class Send_expression.
// Traversal.
int
Send_expression::do_traverse(Traverse* traverse)
{
if (Expression::traverse(&this->channel_, traverse) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
return Expression::traverse(&this->val_, traverse);
}
// Get the type.
Type*
Send_expression::do_type()
{
return Type::lookup_bool_type();
}
// Set types.
void
Send_expression::do_determine_type(const Type_context*)
{
this->channel_->determine_type_no_context();
Type* type = this->channel_->type();
Type_context subcontext;
if (type->channel_type() != NULL)
subcontext.type = type->channel_type()->element_type();
this->val_->determine_type(&subcontext);
}
// Check types.
void
Send_expression::do_check_types(Gogo*)
{
Type* type = this->channel_->type();
if (type->is_error_type())
{
this->set_is_error();
return;
}
Channel_type* channel_type = type->channel_type();
if (channel_type == NULL)
{
error_at(this->location(), "left operand of %<<-%> must be channel");
this->set_is_error();
return;
}
Type* element_type = channel_type->element_type();
if (element_type != NULL
&& !Type::are_assignable(element_type, this->val_->type(), NULL))
{
this->report_error(_("incompatible types in send"));
return;
}
if (!channel_type->may_send())
{
this->report_error(_("invalid send on receive-only channel"));
return;
}
}
// Get a tree for a send expression.
tree
Send_expression::do_get_tree(Translate_context* context)
{
tree channel = this->channel_->get_tree(context);
tree val = this->val_->get_tree(context);
if (channel == error_mark_node || val == error_mark_node)
return error_mark_node;
Channel_type* channel_type = this->channel_->type()->channel_type();
val = Expression::convert_for_assignment(context,
channel_type->element_type(),
this->val_->type(),
val,
this->location());
return Gogo::send_on_channel(channel, val, this->is_value_discarded_,
this->for_select_, this->location());
}
// Make a send expression
Send_expression*
Expression::make_send(Expression* channel, Expression* val,
source_location location)
{
return new Send_expression(channel, val, location);
}
// An expression which evaluates to a pointer to the type descriptor
// of a type.
class Type_descriptor_expression : public Expression
{
public:
Type_descriptor_expression(Type* type, source_location location)
: Expression(EXPRESSION_TYPE_DESCRIPTOR, location),
type_(type)
{ }
protected:
Type*
do_type()
{ return Type::make_type_descriptor_ptr_type(); }
void
do_determine_type(const Type_context*)
{ }
Expression*
do_copy()
{ return this; }
tree
do_get_tree(Translate_context* context)
{ return this->type_->type_descriptor_pointer(context->gogo()); }
private:
// The type for which this is the descriptor.
Type* type_;
};
// Make a type descriptor expression.
Expression*
Expression::make_type_descriptor(Type* type, source_location location)
{
return new Type_descriptor_expression(type, location);
}
// An expression which evaluates to some characteristic of a type.
// This is only used to initialize fields of a type descriptor. Using
// a new expression class is slightly inefficient but gives us a good
// separation between the frontend and the middle-end with regard to
// how types are laid out.
class Type_info_expression : public Expression
{
public:
Type_info_expression(Type* type, Type_info type_info)
: Expression(EXPRESSION_TYPE_INFO, BUILTINS_LOCATION),
type_(type), type_info_(type_info)
{ }
protected:
Type*
do_type();
void
do_determine_type(const Type_context*)
{ }
Expression*
do_copy()
{ return this; }
tree
do_get_tree(Translate_context* context);
private:
// The type for which we are getting information.
Type* type_;
// What information we want.
Type_info type_info_;
};
// The type is chosen to match what the type descriptor struct
// expects.
Type*
Type_info_expression::do_type()
{
switch (this->type_info_)
{
case TYPE_INFO_SIZE:
return Type::lookup_integer_type("uintptr");
case TYPE_INFO_ALIGNMENT:
case TYPE_INFO_FIELD_ALIGNMENT:
return Type::lookup_integer_type("uint8");
default:
gcc_unreachable();
}
}
// Return type information in GENERIC.
tree
Type_info_expression::do_get_tree(Translate_context* context)
{
tree type_tree = this->type_->get_tree(context->gogo());
if (type_tree == error_mark_node)
return error_mark_node;
tree val_type_tree = this->type()->get_tree(context->gogo());
gcc_assert(val_type_tree != error_mark_node);
if (this->type_info_ == TYPE_INFO_SIZE)
return fold_convert_loc(BUILTINS_LOCATION, val_type_tree,
TYPE_SIZE_UNIT(type_tree));
else
{
unsigned int val;
if (this->type_info_ == TYPE_INFO_ALIGNMENT)
val = go_type_alignment(type_tree);
else
val = go_field_alignment(type_tree);
return build_int_cstu(val_type_tree, val);
}
}
// Make a type info expression.
Expression*
Expression::make_type_info(Type* type, Type_info type_info)
{
return new Type_info_expression(type, type_info);
}
// An expression which evaluates to the offset of a field within a
// struct. This, like Type_info_expression, q.v., is only used to
// initialize fields of a type descriptor.
class Struct_field_offset_expression : public Expression
{
public:
Struct_field_offset_expression(Struct_type* type, const Struct_field* field)
: Expression(EXPRESSION_STRUCT_FIELD_OFFSET, BUILTINS_LOCATION),
type_(type), field_(field)
{ }
protected:
Type*
do_type()
{ return Type::lookup_integer_type("uintptr"); }
void
do_determine_type(const Type_context*)
{ }
Expression*
do_copy()
{ return this; }
tree
do_get_tree(Translate_context* context);
private:
// The type of the struct.
Struct_type* type_;
// The field.
const Struct_field* field_;
};
// Return a struct field offset in GENERIC.
tree
Struct_field_offset_expression::do_get_tree(Translate_context* context)
{
tree type_tree = this->type_->get_tree(context->gogo());
if (type_tree == error_mark_node)
return error_mark_node;
tree val_type_tree = this->type()->get_tree(context->gogo());
gcc_assert(val_type_tree != error_mark_node);
const Struct_field_list* fields = this->type_->fields();
tree struct_field_tree = TYPE_FIELDS(type_tree);
Struct_field_list::const_iterator p;
for (p = fields->begin();
p != fields->end();
++p, struct_field_tree = DECL_CHAIN(struct_field_tree))
{
gcc_assert(struct_field_tree != NULL_TREE);
if (&*p == this->field_)
break;
}
gcc_assert(&*p == this->field_);
return fold_convert_loc(BUILTINS_LOCATION, val_type_tree,
byte_position(struct_field_tree));
}
// Make an expression for a struct field offset.
Expression*
Expression::make_struct_field_offset(Struct_type* type,
const Struct_field* field)
{
return new Struct_field_offset_expression(type, field);
}
// An expression which evaluates to the address of an unnamed label.
class Label_addr_expression : public Expression
{
public:
Label_addr_expression(Label* label, source_location location)
: Expression(EXPRESSION_LABEL_ADDR, location),
label_(label)
{ }
protected:
Type*
do_type()
{ return Type::make_pointer_type(Type::make_void_type()); }
void
do_determine_type(const Type_context*)
{ }
Expression*
do_copy()
{ return new Label_addr_expression(this->label_, this->location()); }
tree
do_get_tree(Translate_context*)
{ return this->label_->get_addr(this->location()); }
private:
// The label whose address we are taking.
Label* label_;
};
// Make an expression for the address of an unnamed label.
Expression*
Expression::make_label_addr(Label* label, source_location location)
{
return new Label_addr_expression(label, location);
}
// Import an expression. This comes at the end in order to see the
// various class definitions.
Expression*
Expression::import_expression(Import* imp)
{
int c = imp->peek_char();
if (imp->match_c_string("- ")
|| imp->match_c_string("! ")
|| imp->match_c_string("^ "))
return Unary_expression::do_import(imp);
else if (c == '(')
return Binary_expression::do_import(imp);
else if (imp->match_c_string("true")
|| imp->match_c_string("false"))
return Boolean_expression::do_import(imp);
else if (c == '"')
return String_expression::do_import(imp);
else if (c == '-' || (c >= '0' && c <= '9'))
{
// This handles integers, floats and complex constants.
return Integer_expression::do_import(imp);
}
else if (imp->match_c_string("nil"))
return Nil_expression::do_import(imp);
else if (imp->match_c_string("convert"))
return Type_conversion_expression::do_import(imp);
else
{
error_at(imp->location(), "import error: expected expression");
return Expression::make_error(imp->location());
}
}
// Class Expression_list.
// Traverse the list.
int
Expression_list::traverse(Traverse* traverse)
{
for (Expression_list::iterator p = this->begin();
p != this->end();
++p)
{
if (*p != NULL)
{
if (Expression::traverse(&*p, traverse) == TRAVERSE_EXIT)
return TRAVERSE_EXIT;
}
}
return TRAVERSE_CONTINUE;
}
// Copy the list.
Expression_list*
Expression_list::copy()
{
Expression_list* ret = new Expression_list();
for (Expression_list::iterator p = this->begin();
p != this->end();
++p)
{
if (*p == NULL)
ret->push_back(NULL);
else
ret->push_back((*p)->copy());
}
return ret;
}
// Return whether an expression list has an error expression.
bool
Expression_list::contains_error() const
{
for (Expression_list::const_iterator p = this->begin();
p != this->end();
++p)
if (*p != NULL && (*p)->is_error_expression())
return true;
return false;
}
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