gcc/d/d-target.cc - gcc - Git at Google

 /* d-target.cc -- Target interface for the D front end.
    Copyright (C) 2013-2021 Free Software Foundation, Inc.

 GCC is free software; you can redistribute it and/or modify
 it under the terms of the GNU General Public License as published by
 the Free Software Foundation; either version 3, or (at your option)
 any later version.

 GCC is distributed in the hope that it will be useful,
 but WITHOUT ANY WARRANTY; without even the implied warranty of
 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 GNU General Public License for more details.

 You should have received a copy of the GNU General Public License
 along with GCC; see the file COPYING3.  If not see
 <http://www.gnu.org/licenses/>.  */

 #include "config.h"
 #include "system.h"
 #include "coretypes.h"

 #include "dmd/aggregate.h"
 #include "dmd/declaration.h"
 #include "dmd/expression.h"
 #include "dmd/mangle.h"
 #include "dmd/mtype.h"
 #include "dmd/tokens.h"
 #include "dmd/target.h"

 #include "tree.h"
 #include "memmodel.h"
 #include "fold-const.h"
 #include "diagnostic.h"
 #include "stor-layout.h"
 #include "tm.h"
 #include "tm_p.h"
 #include "target.h"

 #include "d-tree.h"
 #include "d-target.h"

 /* Implements the Target interface defined by the front end.
    Used for retrieving target-specific information.  */

 Target target;

 /* Internal key handlers for `__traits(getTargetInfo)'.  */
 static tree d_handle_target_cpp_std (void);
 static tree d_handle_target_cpp_runtime_library (void);
 static tree d_handle_target_object_format (void);

 /* In [traits/getTargetInfo], a reliable subset of getTargetInfo keys exists
    which are always available.  */
 static const struct d_target_info_spec d_language_target_info[] =
 {
   /* { name, handler } */
   { "cppStd", d_handle_target_cpp_std },
   { "cppRuntimeLibrary", d_handle_target_cpp_runtime_library },
   { "floatAbi", NULL },
   { "objectFormat", d_handle_target_object_format },
   { NULL, NULL },
 };

 /* Table `__traits(getTargetInfo)' keys.  */
 static vec<d_target_info_spec> d_target_info_table;


 /* Initialize the floating-point constants for TYPE.  */

 template <typename T>
 static void
 define_float_constants (T &f, tree type)
 {
   const double log10_2 = 0.30102999566398119521;
   char buf[128];

   /* Get back-end real mode format.  */
   const machine_mode mode = TYPE_MODE (type);
   const real_format *fmt = REAL_MODE_FORMAT (mode);

   /* The largest representable value that's not infinity.  */
   get_max_float (fmt, buf, sizeof (buf), false);
   real_from_string (&f.max.rv (), buf);

   /* The smallest representable normalized value that's not 0.  */
   snprintf (buf, sizeof (buf), "0x1p%d", fmt->emin - 1);
   real_from_string (&f.min_normal.rv (), buf);

   /* Floating-point NaN.  */
   real_nan (&f.nan.rv (), "", 1, mode);

   /* Signalling floating-point NaN.  */
   real_nan (&f.snan.rv (), "", 0, mode);

   /* Floating-point +Infinity if the target supports infinities.  */
   real_inf (&f.infinity.rv ());

   /* The smallest increment to the value 1.  */
   if (fmt->pnan < fmt->p)
     snprintf (buf, sizeof (buf), "0x1p%d", fmt->emin - fmt->p);
   else
     snprintf (buf, sizeof (buf), "0x1p%d", 1 - fmt->p);
   real_from_string (&f.epsilon.rv (), buf);

   /* The number of decimal digits of precision.  */
   f.dig = (fmt->p - 1) * log10_2;

   /* The number of bits in mantissa.  */
   f.mant_dig = fmt->p;

   /* The maximum int value such that 2** (value-1) is representable.  */
   f.max_exp = fmt->emax;

   /* The minimum int value such that 2** (value-1) is representable as a
      normalized value.  */
   f.min_exp = fmt->emin;

   /* The maximum int value such that 10**value is representable.  */
   f.max_10_exp = fmt->emax * log10_2;

   /* The minimum int value such that 10**value is representable as a
      normalized value.  */
   f.min_10_exp = (fmt->emin - 1) * log10_2;
 }

 /* Initialize all variables of the Target structure.  */

 void
 Target::_init (const Param &)
 {
   /* Map D frontend type and sizes to GCC back-end types.  */
   this->ptrsize = (POINTER_SIZE / BITS_PER_UNIT);
   this->realsize = int_size_in_bytes (long_double_type_node);
   this->realpad = (this->realsize -
 		   (TYPE_PRECISION (long_double_type_node) / BITS_PER_UNIT));
   this->realalignsize = TYPE_ALIGN_UNIT (long_double_type_node);

   /* Much of the dmd front-end uses ints for sizes and offsets, and cannot
      handle any larger data type without some pervasive rework.  */
   this->maxStaticDataSize = tree_to_shwi (TYPE_MAX_VALUE (integer_type_node));

   /* Define what type to use for size_t, ptrdiff_t.  */
   if (this->ptrsize == 8)
     {
       global.params.isLP64 = true;
       Type::tsize_t = Type::basic[Tuns64];
       Type::tptrdiff_t = Type::basic[Tint64];
     }
   else if (this->ptrsize == 4)
     {
       Type::tsize_t = Type::basic[Tuns32];
       Type::tptrdiff_t = Type::basic[Tint32];
     }
   else if (this->ptrsize == 2)
     {
       Type::tsize_t = Type::basic[Tuns16];
       Type::tptrdiff_t = Type::basic[Tint16];
     }
   else
     sorry ("D does not support pointers on this target.");

   Type::thash_t = Type::tsize_t;

   /* Set-up target C ABI.  */
   this->c.longsize = int_size_in_bytes (long_integer_type_node);
   this->c.long_doublesize = int_size_in_bytes (long_double_type_node);

   /* Define what type to use for wchar_t.  We don't want to support wide
      characters less than "short" in D.  */
   if (WCHAR_TYPE_SIZE == 32)
     this->c.twchar_t = Type::basic[Tdchar];
   else if (WCHAR_TYPE_SIZE == 16)
     this->c.twchar_t = Type::basic[Twchar];
   else
     sorry ("D does not support wide characters on this target.");

   /* Set-up target C++ ABI.  */
   this->cpp.reverseOverloads = false;
   this->cpp.exceptions = true;
   this->cpp.twoDtorInVtable = true;

   /* Set-up target Objective-C ABI.  */
   this->objc.supported = false;

   /* Initialize all compile-time properties for floating-point types.
      Should ensure that our real_t type is able to represent real_value.  */
   gcc_assert (sizeof (real_t) >= sizeof (real_value));

   define_float_constants (this->FloatProperties, float_type_node);
   define_float_constants (this->DoubleProperties, double_type_node);
   define_float_constants (this->RealProperties, long_double_type_node);

   /* Commonly used floating-point constants.  */
   const machine_mode mode = TYPE_MODE (long_double_type_node);
   real_convert (&CTFloat::zero.rv (), mode, &dconst0);
   real_convert (&CTFloat::one.rv (), mode, &dconst1);
   real_convert (&CTFloat::minusone.rv (), mode, &dconstm1);
   real_convert (&CTFloat::half.rv (), mode, &dconsthalf);

   /* Initialize target info tables, the keys required by the language are added
      last, so that the OS and CPU handlers can override.  */
   targetdm.d_register_cpu_target_info ();
   targetdm.d_register_os_target_info ();
   d_add_target_info_handlers (d_language_target_info);
 }

 /* Return GCC memory alignment size for type TYPE.  */

 unsigned
 Target::alignsize (Type *type)
 {
   gcc_assert (type->isTypeBasic ());
   return min_align_of_type (build_ctype (type));
 }

 /* Return GCC field alignment size for type TYPE.  */

 unsigned
 Target::fieldalign (Type *type)
 {
   /* Work out the correct alignment for the field decl.  */
   unsigned int align = type->alignsize () * BITS_PER_UNIT;

 #ifdef BIGGEST_FIELD_ALIGNMENT
   align = MIN (align, (unsigned) BIGGEST_FIELD_ALIGNMENT);
 #endif

 #ifdef ADJUST_FIELD_ALIGN
   if (type->isTypeBasic ())
     align = ADJUST_FIELD_ALIGN (NULL_TREE, build_ctype (type), align);
 #endif

   /* Also controlled by -fpack-struct=  */
   if (maximum_field_alignment)
     align = MIN (align, maximum_field_alignment);

   return align / BITS_PER_UNIT;
 }

 /* Returns a Type for the va_list type of the target.  */

 Type *
 Target::va_listType (const Loc &, Scope *)
 {
   if (this->tvalist)
     return this->tvalist;

   /* Build the "standard" abi va_list.  */
   this->tvalist = build_frontend_type (va_list_type_node);
   if (!this->tvalist)
     sorry ("cannot represent built-in %<va_list%> type in D");

   /* Map the va_list type to the D frontend Type.  This is to prevent both
      errors in gimplification or an ICE in targetm.canonical_va_list_type.  */
   this->tvalist->ctype = va_list_type_node;
   TYPE_LANG_SPECIFIC (va_list_type_node) = build_lang_type (this->tvalist);

   return this->tvalist;
 }

 /* Checks whether the target supports a vector type with total size SZ
    (in bytes) and element type TYPE.  */

 int
 Target::isVectorTypeSupported (int sz, Type *type)
 {
   /* Size must be greater than zero, and a power of two.  */
   if (sz <= 0 || sz & (sz - 1))
     return 3;

   /* __vector(void[]) is treated same as __vector(ubyte[])  */
   if (type == Type::tvoid)
     type = Type::tuns8;

   /* No support for non-trivial types, complex types, or booleans.  */
   if (!type->isTypeBasic () || type->iscomplex () || type->ty == Tbool)
     return 2;

   /* In [simd/vector extensions], which vector types are supported depends on
      the target.  The implementation is expected to only support the vector
      types that are implemented in the target's hardware.  */
   unsigned HOST_WIDE_INT nunits = sz / type->size ();
   tree ctype = build_vector_type (build_ctype (type), nunits);

   if (!targetm.vector_mode_supported_p (TYPE_MODE (ctype)))
     return 2;

   return 0;
 }

 /* Checks whether the target supports operation OP for vectors of type TYPE.
    For binary ops T2 is the type of the right-hand operand.
    Returns true if the operation is supported or type is not a vector.  */

 bool
 Target::isVectorOpSupported (Type *type, TOK op, Type *)
 {
   if (type->ty != Tvector)
     return true;

   /* Don't support if type is non-scalar, such as __vector(void[]).  */
   if (!type->isscalar ())
     return false;

   /* Don't support if expression cannot be represented.  */
   switch (op)
     {
     case TOKpow:
     case TOKpowass:
       /* pow() is lowered as a function call.  */
       return false;

     case TOKmod:
     case TOKmodass:
       /* fmod() is lowered as a function call.  */
       if (type->isfloating ())
 	return false;
       break;

     case TOKandand:
     case TOKoror:
       /* Logical operators must have a result type of bool.  */
       return false;

     case TOKue:
     case TOKlg:
     case TOKule:
     case TOKul:
     case TOKuge:
     case TOKug:
     case TOKle:
     case TOKlt:
     case TOKge:
     case TOKgt:
     case TOKleg:
     case TOKunord:
     case TOKequal:
     case TOKnotequal:
     case TOKidentity:
     case TOKnotidentity:
       /* Comparison operators must have a result type of bool.  */
       return false;

     default:
       break;
     }

   return true;
 }

 /* Return the symbol mangling of S for C++ linkage.  */

 const char *
 TargetCPP::toMangle (Dsymbol *s)
 {
   return toCppMangleItanium (s);
 }

 /* Return the symbol mangling of CD for C++ linkage.  */

 const char *
 TargetCPP::typeInfoMangle (ClassDeclaration *cd)
 {
   return cppTypeInfoMangleItanium (cd);
 }

 /* Get mangle name of a this-adjusting thunk to the function declaration FD
    at call offset OFFSET for C++ linkage.  */

 const char *
 TargetCPP::thunkMangle (FuncDeclaration *fd, int offset)
 {
   return cppThunkMangleItanium (fd, offset);
 }

 /* For a vendor-specific type, return a string containing the C++ mangling.
    In all other cases, return NULL.  */

 const char *
 TargetCPP::typeMangle (Type *type)
 {
   if (type->isTypeBasic () || type->ty == Tvector || type->ty == Tstruct)
     {
       tree ctype = build_ctype (type);
       return targetm.mangle_type (ctype);
     }

   return NULL;
 }

 /* Return the type that will really be used for passing the given parameter
    ARG to an extern(C++) function.  */

 Type *
 TargetCPP::parameterType (Parameter *arg)
 {
   Type *t = arg->type->merge2 ();
   if (arg->storageClass & (STCout | STCref))
     t = t->referenceTo ();
   else if (arg->storageClass & STClazy)
     {
       /* Mangle as delegate.  */
       Type *td = TypeFunction::create (NULL, t, VARARGnone, LINKd);
       td = TypeDelegate::create (td);
       t = t->merge2 ();
     }

   /* Could be a va_list, which we mangle as a pointer.  */
   Type *tvalist = target.va_listType (Loc (), NULL);
   if (t->ty == Tsarray && tvalist->ty == Tsarray)
     {
       Type *tb = t->toBasetype ()->mutableOf ();
       if (tb == tvalist)
 	{
 	  tb = t->nextOf ()->pointerTo ();
 	  t = tb->castMod (t->mod);
 	}
     }

   return t;
 }

 /* Checks whether TYPE is a vendor-specific fundamental type.  Stores the result
    in IS_FUNDAMENTAL and returns true if the parameter was set.  */

 bool
 TargetCPP::fundamentalType (const Type *, bool &)
 {
   return false;
 }

 /* Get the starting offset position for fields of an `extern(C++)` class
    that is derived from the given BASE_CLASS.  */

 unsigned
 TargetCPP::derivedClassOffset(ClassDeclaration *base_class)
 {
   return base_class->structsize;
 }

 /* Return the default `extern (System)' linkage for the target.  */

 LINK
 Target::systemLinkage (void)
 {
   unsigned link_system, link_windows;

   if (targetdm.d_has_stdcall_convention (&link_system, &link_windows))
     {
       /* In [attribute/linkage], `System' is the same as `Windows' on Windows
 	 platforms, and `C' on other platforms.  */
       if (link_system)
 	return LINKwindows;
     }

   return LINKc;
 }

 /* Generate a TypeTuple of the equivalent types used to determine if a
    function argument of the given type can be passed in registers.
    The results of this are highly platform dependent, and intended
    primarly for use in implementing va_arg() with RTTI.  */

 TypeTuple *
 Target::toArgTypes (Type *)
 {
   /* Not implemented, however this is not currently used anywhere.  */
   return NULL;
 }

 /* Determine return style of function, whether in registers or through a
    hidden pointer to the caller's stack.  */

 bool
 Target::isReturnOnStack (TypeFunction *tf, bool)
 {
   /* Need the back-end type to determine this, but this is called from the
      frontend before semantic processing is finished.  An accurate value
      is not currently needed anyway.  */
   if (tf->isref)
     return false;

   Type *tn = tf->next->toBasetype ();

   return (tn->ty == Tstruct || tn->ty == Tsarray);
 }

 /* Add all target info in HANDLERS to D_TARGET_INFO_TABLE for use by
    Target::getTargetInfo().  */

 void
 d_add_target_info_handlers (const d_target_info_spec *handlers)
 {
   gcc_assert (handlers != NULL);

   if (d_target_info_table.is_empty ())
     d_target_info_table.create (8);

   for (size_t i = 0; handlers[i].name != NULL; i++)
     d_target_info_table.safe_push (handlers[i]);
 }

 /* Handle a call to `__traits(getTargetInfo, "cppStd")'.  */

 tree
 d_handle_target_cpp_std (void)
 {
   return build_integer_cst (global.params.cplusplus);
 }

 /* Handle a call to `__traits(getTargetInfo, "cppRuntimeLibrary")'.  */

 tree
 d_handle_target_cpp_runtime_library (void)
 {
   /* The driver only ever optionally links to libstdc++.  */
   const char *libstdcxx = "libstdc++";
   return build_string_literal (strlen (libstdcxx) + 1, libstdcxx);
 }

 /* Handle a call to `__traits(getTargetInfo, "objectFormat")'.  */

 tree
 d_handle_target_object_format (void)
 {
   const char *objfmt;

 #ifdef OBJECT_FORMAT_ELF
   objfmt = "elf";
 #else
   if (TARGET_COFF || TARGET_PECOFF)
     objfmt = "coff";
   else
     objfmt = "";
 #endif

   return build_string_literal (strlen (objfmt) + 1, objfmt);
 }

 /* Look up the target info KEY in the available getTargetInfo tables, and return
    the result as an Expression, or NULL if KEY is not found.  When the key must
    always exist, but is not supported, an empty string expression is returned.
    LOC is the location to use for the returned expression.  */

 Expression *
 Target::getTargetInfo (const char *key, const Loc &loc)
 {
   unsigned ix;
   d_target_info_spec *spec;

   FOR_EACH_VEC_ELT (d_target_info_table, ix, spec)
     {
       tree result;

       if (strcmp (key, spec->name) != 0)
 	continue;

       /* Get the requested information, or empty string if unhandled.  */
       if (spec->handler)
 	{
 	  result = (spec->handler) ();
 	  /* Handler didn't return a result, meaning it really does not support
 	     the key in the current target configuration.  Check whether there
 	     are any other handlers which may recognize the key.  */
 	  if (result == NULL_TREE)
 	    continue;
 	}
       else
 	result = build_string_literal (1, "");

       gcc_assert (result);
       return d_eval_constant_expression (loc, result);
     }

   return NULL;
 }

 /**
  * Returns true if the implementation for object monitors is always defined
  * in the D runtime library (rt/monitor_.d).  */

 bool
 Target::libraryObjectMonitors (FuncDeclaration *, Statement *)
 {
   return true;
 }
	/* d-target.cc -- Target interface for the D front end.
	Copyright (C) 2013-2021 Free Software Foundation, Inc.

	GCC is free software; you can redistribute it and/or modify
	it under the terms of the GNU General Public License as published by
	the Free Software Foundation; either version 3, or (at your option)
	any later version.

	GCC is distributed in the hope that it will be useful,
	but WITHOUT ANY WARRANTY; without even the implied warranty of
	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	GNU General Public License for more details.

	You should have received a copy of the GNU General Public License
	along with GCC; see the file COPYING3. If not see
	<http://www.gnu.org/licenses/>. */

	#include "config.h"
	#include "system.h"
	#include "coretypes.h"

	#include "dmd/aggregate.h"
	#include "dmd/declaration.h"
	#include "dmd/expression.h"
	#include "dmd/mangle.h"
	#include "dmd/mtype.h"
	#include "dmd/tokens.h"
	#include "dmd/target.h"

	#include "tree.h"
	#include "memmodel.h"
	#include "fold-const.h"
	#include "diagnostic.h"
	#include "stor-layout.h"
	#include "tm.h"
	#include "tm_p.h"
	#include "target.h"

	#include "d-tree.h"
	#include "d-target.h"

	/* Implements the Target interface defined by the front end.
	Used for retrieving target-specific information. */

	Target target;

	/* Internal key handlers for `__traits(getTargetInfo)'. */
	static tree d_handle_target_cpp_std (void);
	static tree d_handle_target_cpp_runtime_library (void);
	static tree d_handle_target_object_format (void);

	/* In [traits/getTargetInfo], a reliable subset of getTargetInfo keys exists
	which are always available. */
	static const struct d_target_info_spec d_language_target_info[] =
	{
	/* { name, handler } */
	{ "cppStd", d_handle_target_cpp_std },
	{ "cppRuntimeLibrary", d_handle_target_cpp_runtime_library },
	{ "floatAbi", NULL },
	{ "objectFormat", d_handle_target_object_format },
	{ NULL, NULL },
	};

	/* Table `__traits(getTargetInfo)' keys. */
	static vec<d_target_info_spec> d_target_info_table;


	/* Initialize the floating-point constants for TYPE. */

	template <typename T>
	static void
	define_float_constants (T &f, tree type)
	{
	const double log10_2 = 0.30102999566398119521;
	char buf[128];

	/* Get back-end real mode format. */
	const machine_mode mode = TYPE_MODE (type);
	const real_format *fmt = REAL_MODE_FORMAT (mode);

	/* The largest representable value that's not infinity. */
	get_max_float (fmt, buf, sizeof (buf), false);
	real_from_string (&f.max.rv (), buf);

	/* The smallest representable normalized value that's not 0. */
	snprintf (buf, sizeof (buf), "0x1p%d", fmt->emin - 1);
	real_from_string (&f.min_normal.rv (), buf);

	/* Floating-point NaN. */
	real_nan (&f.nan.rv (), "", 1, mode);

	/* Signalling floating-point NaN. */
	real_nan (&f.snan.rv (), "", 0, mode);

	/* Floating-point +Infinity if the target supports infinities. */
	real_inf (&f.infinity.rv ());

	/* The smallest increment to the value 1. */
	if (fmt->pnan < fmt->p)
	snprintf (buf, sizeof (buf), "0x1p%d", fmt->emin - fmt->p);
	else
	snprintf (buf, sizeof (buf), "0x1p%d", 1 - fmt->p);
	real_from_string (&f.epsilon.rv (), buf);

	/* The number of decimal digits of precision. */
	f.dig = (fmt->p - 1) * log10_2;

	/* The number of bits in mantissa. */
	f.mant_dig = fmt->p;

	/* The maximum int value such that 2** (value-1) is representable. */
	f.max_exp = fmt->emax;

	/* The minimum int value such that 2** (value-1) is representable as a
	normalized value. */
	f.min_exp = fmt->emin;

	/* The maximum int value such that 10*value is representable. /
	f.max_10_exp = fmt->emax * log10_2;

	/* The minimum int value such that 10**value is representable as a
	normalized value. */
	f.min_10_exp = (fmt->emin - 1) * log10_2;
	}

	/* Initialize all variables of the Target structure. */

	void
	Target::_init (const Param &)
	{
	/* Map D frontend type and sizes to GCC back-end types. */
	this->ptrsize = (POINTER_SIZE / BITS_PER_UNIT);
	this->realsize = int_size_in_bytes (long_double_type_node);
	this->realpad = (this->realsize -
	(TYPE_PRECISION (long_double_type_node) / BITS_PER_UNIT));
	this->realalignsize = TYPE_ALIGN_UNIT (long_double_type_node);

	/* Much of the dmd front-end uses ints for sizes and offsets, and cannot
	handle any larger data type without some pervasive rework. */
	this->maxStaticDataSize = tree_to_shwi (TYPE_MAX_VALUE (integer_type_node));

	/* Define what type to use for size_t, ptrdiff_t. */
	if (this->ptrsize == 8)
	{
	global.params.isLP64 = true;
	Type::tsize_t = Type::basic[Tuns64];
	Type::tptrdiff_t = Type::basic[Tint64];
	}
	else if (this->ptrsize == 4)
	{
	Type::tsize_t = Type::basic[Tuns32];
	Type::tptrdiff_t = Type::basic[Tint32];
	}
	else if (this->ptrsize == 2)
	{
	Type::tsize_t = Type::basic[Tuns16];
	Type::tptrdiff_t = Type::basic[Tint16];
	}
	else
	sorry ("D does not support pointers on this target.");

	Type::thash_t = Type::tsize_t;

	/* Set-up target C ABI. */
	this->c.longsize = int_size_in_bytes (long_integer_type_node);
	this->c.long_doublesize = int_size_in_bytes (long_double_type_node);

	/* Define what type to use for wchar_t. We don't want to support wide
	characters less than "short" in D. */
	if (WCHAR_TYPE_SIZE == 32)
	this->c.twchar_t = Type::basic[Tdchar];
	else if (WCHAR_TYPE_SIZE == 16)
	this->c.twchar_t = Type::basic[Twchar];
	else
	sorry ("D does not support wide characters on this target.");

	/* Set-up target C++ ABI. */
	this->cpp.reverseOverloads = false;
	this->cpp.exceptions = true;
	this->cpp.twoDtorInVtable = true;

	/* Set-up target Objective-C ABI. */
	this->objc.supported = false;

	/* Initialize all compile-time properties for floating-point types.
	Should ensure that our real_t type is able to represent real_value. */
	gcc_assert (sizeof (real_t) >= sizeof (real_value));

	define_float_constants (this->FloatProperties, float_type_node);
	define_float_constants (this->DoubleProperties, double_type_node);
	define_float_constants (this->RealProperties, long_double_type_node);

	/* Commonly used floating-point constants. */
	const machine_mode mode = TYPE_MODE (long_double_type_node);
	real_convert (&CTFloat::zero.rv (), mode, &dconst0);
	real_convert (&CTFloat::one.rv (), mode, &dconst1);
	real_convert (&CTFloat::minusone.rv (), mode, &dconstm1);
	real_convert (&CTFloat::half.rv (), mode, &dconsthalf);

	/* Initialize target info tables, the keys required by the language are added
	last, so that the OS and CPU handlers can override. */
	targetdm.d_register_cpu_target_info ();
	targetdm.d_register_os_target_info ();
	d_add_target_info_handlers (d_language_target_info);
	}

	/* Return GCC memory alignment size for type TYPE. */

	unsigned
	Target::alignsize (Type *type)
	{
	gcc_assert (type->isTypeBasic ());
	return min_align_of_type (build_ctype (type));
	}

	/* Return GCC field alignment size for type TYPE. */

	unsigned
	Target::fieldalign (Type *type)
	{
	/* Work out the correct alignment for the field decl. */
	unsigned int align = type->alignsize () * BITS_PER_UNIT;

	#ifdef BIGGEST_FIELD_ALIGNMENT
	align = MIN (align, (unsigned) BIGGEST_FIELD_ALIGNMENT);
	#endif

	#ifdef ADJUST_FIELD_ALIGN
	if (type->isTypeBasic ())
	align = ADJUST_FIELD_ALIGN (NULL_TREE, build_ctype (type), align);
	#endif

	/* Also controlled by -fpack-struct= */
	if (maximum_field_alignment)
	align = MIN (align, maximum_field_alignment);

	return align / BITS_PER_UNIT;
	}

	/* Returns a Type for the va_list type of the target. */

	Type *
	Target::va_listType (const Loc &, Scope *)
	{
	if (this->tvalist)
	return this->tvalist;

	/* Build the "standard" abi va_list. */
	this->tvalist = build_frontend_type (va_list_type_node);
	if (!this->tvalist)
	sorry ("cannot represent built-in %<va_list%> type in D");

	/* Map the va_list type to the D frontend Type. This is to prevent both
	errors in gimplification or an ICE in targetm.canonical_va_list_type. */
	this->tvalist->ctype = va_list_type_node;
	TYPE_LANG_SPECIFIC (va_list_type_node) = build_lang_type (this->tvalist);

	return this->tvalist;
	}

	/* Checks whether the target supports a vector type with total size SZ
	(in bytes) and element type TYPE. */

	int
	Target::isVectorTypeSupported (int sz, Type *type)
	{
	/* Size must be greater than zero, and a power of two. */
	if (sz <= 0 \|\| sz & (sz - 1))
	return 3;

	/* __vector(void[]) is treated same as __vector(ubyte[]) */
	if (type == Type::tvoid)
	type = Type::tuns8;

	/* No support for non-trivial types, complex types, or booleans. */
	if (!type->isTypeBasic () \|\| type->iscomplex () \|\| type->ty == Tbool)
	return 2;

	/* In [simd/vector extensions], which vector types are supported depends on
	the target. The implementation is expected to only support the vector
	types that are implemented in the target's hardware. */
	unsigned HOST_WIDE_INT nunits = sz / type->size ();
	tree ctype = build_vector_type (build_ctype (type), nunits);

	if (!targetm.vector_mode_supported_p (TYPE_MODE (ctype)))
	return 2;

	return 0;
	}

	/* Checks whether the target supports operation OP for vectors of type TYPE.
	For binary ops T2 is the type of the right-hand operand.
	Returns true if the operation is supported or type is not a vector. */

	bool
	Target::isVectorOpSupported (Type type, TOK op, Type )
	{
	if (type->ty != Tvector)
	return true;

	/* Don't support if type is non-scalar, such as __vector(void[]). */
	if (!type->isscalar ())
	return false;

	/* Don't support if expression cannot be represented. */
	switch (op)
	{
	case TOKpow:
	case TOKpowass:
	/* pow() is lowered as a function call. */
	return false;

	case TOKmod:
	case TOKmodass:
	/* fmod() is lowered as a function call. */
	if (type->isfloating ())
	return false;
	break;

	case TOKandand:
	case TOKoror:
	/* Logical operators must have a result type of bool. */
	return false;

	case TOKue:
	case TOKlg:
	case TOKule:
	case TOKul:
	case TOKuge:
	case TOKug:
	case TOKle:
	case TOKlt:
	case TOKge:
	case TOKgt:
	case TOKleg:
	case TOKunord:
	case TOKequal:
	case TOKnotequal:
	case TOKidentity:
	case TOKnotidentity:
	/* Comparison operators must have a result type of bool. */
	return false;

	default:
	break;
	}

	return true;
	}

	/* Return the symbol mangling of S for C++ linkage. */

	const char *
	TargetCPP::toMangle (Dsymbol *s)
	{
	return toCppMangleItanium (s);
	}

	/* Return the symbol mangling of CD for C++ linkage. */

	const char *
	TargetCPP::typeInfoMangle (ClassDeclaration *cd)
	{
	return cppTypeInfoMangleItanium (cd);
	}

	/* Get mangle name of a this-adjusting thunk to the function declaration FD
	at call offset OFFSET for C++ linkage. */

	const char *
	TargetCPP::thunkMangle (FuncDeclaration *fd, int offset)
	{
	return cppThunkMangleItanium (fd, offset);
	}

	/* For a vendor-specific type, return a string containing the C++ mangling.
	In all other cases, return NULL. */

	const char *
	TargetCPP::typeMangle (Type *type)
	{
	if (type->isTypeBasic () \|\| type->ty == Tvector \|\| type->ty == Tstruct)
	{
	tree ctype = build_ctype (type);
	return targetm.mangle_type (ctype);
	}

	return NULL;
	}

	/* Return the type that will really be used for passing the given parameter
	ARG to an extern(C++) function. */

	Type *
	TargetCPP::parameterType (Parameter *arg)
	{
	Type *t = arg->type->merge2 ();
	if (arg->storageClass & (STCout \| STCref))
	t = t->referenceTo ();
	else if (arg->storageClass & STClazy)
	{
	/* Mangle as delegate. */
	Type *td = TypeFunction::create (NULL, t, VARARGnone, LINKd);
	td = TypeDelegate::create (td);
	t = t->merge2 ();
	}

	/* Could be a va_list, which we mangle as a pointer. */
	Type *tvalist = target.va_listType (Loc (), NULL);
	if (t->ty == Tsarray && tvalist->ty == Tsarray)
	{
	Type *tb = t->toBasetype ()->mutableOf ();
	if (tb == tvalist)
	{
	tb = t->nextOf ()->pointerTo ();
	t = tb->castMod (t->mod);
	}
	}

	return t;
	}

	/* Checks whether TYPE is a vendor-specific fundamental type. Stores the result
	in IS_FUNDAMENTAL and returns true if the parameter was set. */

	bool
	TargetCPP::fundamentalType (const Type *, bool &)
	{
	return false;
	}

	/* Get the starting offset position for fields of an `extern(C++)` class
	that is derived from the given BASE_CLASS. */

	unsigned
	TargetCPP::derivedClassOffset(ClassDeclaration *base_class)
	{
	return base_class->structsize;
	}

	/* Return the default `extern (System)' linkage for the target. */

	LINK
	Target::systemLinkage (void)
	{
	unsigned link_system, link_windows;

	if (targetdm.d_has_stdcall_convention (&link_system, &link_windows))
	{
	/* In [attribute/linkage], `System' is the same as `Windows' on Windows
	platforms, and `C' on other platforms. */
	if (link_system)
	return LINKwindows;
	}

	return LINKc;
	}

	/* Generate a TypeTuple of the equivalent types used to determine if a
	function argument of the given type can be passed in registers.
	The results of this are highly platform dependent, and intended
	primarly for use in implementing va_arg() with RTTI. */

	TypeTuple *
	Target::toArgTypes (Type *)
	{
	/* Not implemented, however this is not currently used anywhere. */
	return NULL;
	}

	/* Determine return style of function, whether in registers or through a
	hidden pointer to the caller's stack. */

	bool
	Target::isReturnOnStack (TypeFunction *tf, bool)
	{
	/* Need the back-end type to determine this, but this is called from the
	frontend before semantic processing is finished. An accurate value
	is not currently needed anyway. */
	if (tf->isref)
	return false;

	Type *tn = tf->next->toBasetype ();

	return (tn->ty == Tstruct \|\| tn->ty == Tsarray);
	}

	/* Add all target info in HANDLERS to D_TARGET_INFO_TABLE for use by
	Target::getTargetInfo(). */

	void
	d_add_target_info_handlers (const d_target_info_spec *handlers)
	{
	gcc_assert (handlers != NULL);

	if (d_target_info_table.is_empty ())
	d_target_info_table.create (8);

	for (size_t i = 0; handlers[i].name != NULL; i++)
	d_target_info_table.safe_push (handlers[i]);
	}

	/* Handle a call to `__traits(getTargetInfo, "cppStd")'. */

	tree
	d_handle_target_cpp_std (void)
	{
	return build_integer_cst (global.params.cplusplus);
	}

	/* Handle a call to `__traits(getTargetInfo, "cppRuntimeLibrary")'. */

	tree
	d_handle_target_cpp_runtime_library (void)
	{
	/* The driver only ever optionally links to libstdc++. */
	const char *libstdcxx = "libstdc++";
	return build_string_literal (strlen (libstdcxx) + 1, libstdcxx);
	}

	/* Handle a call to `__traits(getTargetInfo, "objectFormat")'. */

	tree
	d_handle_target_object_format (void)
	{
	const char *objfmt;

	#ifdef OBJECT_FORMAT_ELF
	objfmt = "elf";
	#else
	if (TARGET_COFF \|\| TARGET_PECOFF)
	objfmt = "coff";
	else
	objfmt = "";
	#endif

	return build_string_literal (strlen (objfmt) + 1, objfmt);
	}

	/* Look up the target info KEY in the available getTargetInfo tables, and return
	the result as an Expression, or NULL if KEY is not found. When the key must
	always exist, but is not supported, an empty string expression is returned.
	LOC is the location to use for the returned expression. */

	Expression *
	Target::getTargetInfo (const char *key, const Loc &loc)
	{
	unsigned ix;
	d_target_info_spec *spec;

	FOR_EACH_VEC_ELT (d_target_info_table, ix, spec)
	{
	tree result;

	if (strcmp (key, spec->name) != 0)
	continue;

	/* Get the requested information, or empty string if unhandled. */
	if (spec->handler)
	{
	result = (spec->handler) ();
	/* Handler didn't return a result, meaning it really does not support
	the key in the current target configuration. Check whether there
	are any other handlers which may recognize the key. */
	if (result == NULL_TREE)
	continue;
	}
	else
	result = build_string_literal (1, "");

	gcc_assert (result);
	return d_eval_constant_expression (loc, result);
	}

	return NULL;
	}

	/**
	* Returns true if the implementation for object monitors is always defined
	* in the D runtime library (rt/monitor_.d). */

	bool
	Target::libraryObjectMonitors (FuncDeclaration , Statement )
	{
	return true;
	}