libcpp, c, middle-end: Optimize initializers using #embed in C

[official-gcc.git] / gcc / config / aarch64 / aarch64-c.cc

/* Target-specific code for C family languages.
   Copyright (C) 2015-2024 Free Software Foundation, Inc.

   This file is part of GCC.

   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/>.  */

#define IN_TARGET_CODE 1

#include "config.h"
#include "system.h"
#include "coretypes.h"
#include "tm.h"
#include "input.h"
#include "memmodel.h"
#include "tm_p.h"
#include "flags.h"
#include "c-family/c-common.h"
#include "cpplib.h"
#include "c-family/c-pragma.h"
#include "langhooks.h"
#include "target.h"


#define builtin_define(TXT) cpp_define (pfile, TXT)
#define builtin_assert(TXT) cpp_assert (pfile, TXT)


static void
aarch64_def_or_undef (bool def_p, const char *macro, cpp_reader *pfile)
{
  if (def_p)
    cpp_define (pfile, macro);
  else
    cpp_undef (pfile, macro);
}

/* Define the macros that we always expect to have on AArch64.  */

static void
aarch64_define_unconditional_macros (cpp_reader *pfile)
{
  builtin_define ("__aarch64__");
  builtin_define ("__ARM_64BIT_STATE");

  builtin_define ("__ARM_ARCH_ISA_A64");
  builtin_define_with_int_value ("__ARM_ALIGN_MAX_PWR", 28);
  builtin_define_with_int_value ("__ARM_ALIGN_MAX_STACK_PWR", 16);

  /* __ARM_ARCH_8A is not mandated by ACLE but we define it unconditionally
     as interoperability with the same arm macro.  */
  builtin_define ("__ARM_ARCH_8A");

  builtin_define_with_int_value ("__ARM_ARCH_PROFILE",
      TARGET_V8R ? 'R' : 'A');
  builtin_define ("__ARM_FEATURE_CLZ");
  builtin_define ("__ARM_FEATURE_IDIV");
  builtin_define ("__ARM_FEATURE_UNALIGNED");
  builtin_define ("__ARM_PCS_AAPCS64");
  builtin_define_with_int_value ("__ARM_SIZEOF_WCHAR_T", WCHAR_TYPE_SIZE / 8);

  builtin_define ("__GCC_ASM_FLAG_OUTPUTS__");

  builtin_define ("__ARM_STATE_ZA");
  builtin_define ("__ARM_STATE_ZT0");
  builtin_define ("__ARM_NEON_SVE_BRIDGE");

  /* Define keyword attributes like __arm_streaming as macros that expand
     to the associated [[...]] attribute.  Use __extension__ in the attribute
     for C, since the [[...]] syntax was only added in C23.  */
#define DEFINE_ARM_KEYWORD_MACRO(NAME) \
  builtin_define_with_value ("__arm_" NAME, \
                             lang_GNU_CXX () \
                             ? "[[arm::" NAME "]]" \
                             : "[[__extension__ arm::" NAME "]]", 0);

  DEFINE_ARM_KEYWORD_MACRO ("streaming");
  DEFINE_ARM_KEYWORD_MACRO ("streaming_compatible");
  DEFINE_ARM_KEYWORD_MACRO ("locally_streaming");

#undef DEFINE_ARM_KEYWORD_MACRO

  /* Same for the keyword attributes that take arguments.  The snag here
     is that some old modes warn about or reject variadic arguments.  */
  auto *cpp_opts = cpp_get_options (parse_in);
  if (!cpp_opts->traditional)
    {
      auto old_warn_variadic_macros = cpp_opts->warn_variadic_macros;
      auto old_cpp_warn_c90_c99_compat = cpp_opts->cpp_warn_c90_c99_compat;

      cpp_opts->warn_variadic_macros = false;
      cpp_opts->cpp_warn_c90_c99_compat = 0;

#define DEFINE_ARM_KEYWORD_MACRO_ARGS(NAME) \
  builtin_define_with_value ("__arm_" NAME "(...)", \
                             lang_GNU_CXX () \
                             ? "[[arm::" NAME "(__VA_ARGS__)]]" \
                             : "[[__extension__ arm::" NAME \
                               "(__VA_ARGS__)]]", 0);

      DEFINE_ARM_KEYWORD_MACRO_ARGS ("new");
      DEFINE_ARM_KEYWORD_MACRO_ARGS ("preserves");
      DEFINE_ARM_KEYWORD_MACRO_ARGS ("in");
      DEFINE_ARM_KEYWORD_MACRO_ARGS ("out");
      DEFINE_ARM_KEYWORD_MACRO_ARGS ("inout");

#undef DEFINE_ARM_KEYWORD_MACRO_ARGS

      cpp_opts->warn_variadic_macros = old_warn_variadic_macros;
      cpp_opts->cpp_warn_c90_c99_compat = old_cpp_warn_c90_c99_compat;
    }
}

/* Undefine/redefine macros that depend on the current backend state and may
   need to change when a target pragma modifies the backend state.  */

static void
aarch64_update_cpp_builtins (cpp_reader *pfile)
{
  aarch64_def_or_undef (flag_unsafe_math_optimizations, "__ARM_FP_FAST", pfile);

  cpp_undef (pfile, "__ARM_ARCH");
  builtin_define_with_int_value ("__ARM_ARCH", TARGET_V9A ? 9 : 8);

  builtin_define_with_int_value ("__ARM_SIZEOF_MINIMAL_ENUM",
                                 flag_short_enums ? 1 : 4);
  aarch64_def_or_undef (TARGET_BIG_END, "__AARCH64EB__", pfile);
  aarch64_def_or_undef (TARGET_BIG_END, "__ARM_BIG_ENDIAN", pfile);
  aarch64_def_or_undef (!TARGET_BIG_END, "__AARCH64EL__", pfile);

  aarch64_def_or_undef (TARGET_FLOAT, "__ARM_FEATURE_FMA", pfile);

  if (TARGET_FLOAT)
    {
      builtin_define_with_int_value ("__ARM_FP", 0x0E);
      builtin_define ("__ARM_FP16_FORMAT_IEEE");
      builtin_define ("__ARM_FP16_ARGS");
    }
  else
    cpp_undef (pfile, "__ARM_FP");

  aarch64_def_or_undef (TARGET_FP_F16INST,
                        "__ARM_FEATURE_FP16_SCALAR_ARITHMETIC", pfile);
  aarch64_def_or_undef (TARGET_SIMD_F16INST,
                        "__ARM_FEATURE_FP16_VECTOR_ARITHMETIC", pfile);

  aarch64_def_or_undef (TARGET_SIMD, "__ARM_FEATURE_NUMERIC_MAXMIN", pfile);
  aarch64_def_or_undef (TARGET_SIMD, "__ARM_NEON", pfile);


  aarch64_def_or_undef (TARGET_CRC32, "__ARM_FEATURE_CRC32", pfile);
  aarch64_def_or_undef (TARGET_DOTPROD, "__ARM_FEATURE_DOTPROD", pfile);
  aarch64_def_or_undef (TARGET_COMPLEX, "__ARM_FEATURE_COMPLEX", pfile);
  aarch64_def_or_undef (TARGET_JSCVT, "__ARM_FEATURE_JCVT", pfile);

  cpp_undef (pfile, "__AARCH64_CMODEL_TINY__");
  cpp_undef (pfile, "__AARCH64_CMODEL_SMALL__");
  cpp_undef (pfile, "__AARCH64_CMODEL_LARGE__");

  switch (aarch64_cmodel)
    {
      case AARCH64_CMODEL_TINY:
      case AARCH64_CMODEL_TINY_PIC:
        builtin_define ("__AARCH64_CMODEL_TINY__");
        break;
      case AARCH64_CMODEL_SMALL:
      case AARCH64_CMODEL_SMALL_PIC:
        builtin_define ("__AARCH64_CMODEL_SMALL__");
        break;
      case AARCH64_CMODEL_LARGE:
        builtin_define ("__AARCH64_CMODEL_LARGE__");
        break;
      default:
        break;
    }

  aarch64_def_or_undef (TARGET_ILP32, "_ILP32", pfile);
  aarch64_def_or_undef (TARGET_ILP32, "__ILP32__", pfile);

  aarch64_def_or_undef (TARGET_AES && TARGET_SHA2, "__ARM_FEATURE_CRYPTO", pfile);
  aarch64_def_or_undef (TARGET_SIMD_RDMA, "__ARM_FEATURE_QRDMX", pfile);
  aarch64_def_or_undef (TARGET_SVE, "__ARM_FEATURE_SVE", pfile);
  cpp_undef (pfile, "__ARM_FEATURE_SVE_BITS");
  if (TARGET_SVE)
    {
      int bits;
      if (!BITS_PER_SVE_VECTOR.is_constant (&bits))
        bits = 0;
      builtin_define_with_int_value ("__ARM_FEATURE_SVE_BITS", bits);
    }
  aarch64_def_or_undef (TARGET_SVE, "__ARM_FEATURE_SVE_VECTOR_OPERATORS",
                        pfile);
  aarch64_def_or_undef (TARGET_SVE_I8MM,
                        "__ARM_FEATURE_SVE_MATMUL_INT8", pfile);
  aarch64_def_or_undef (TARGET_SVE_F32MM,
                        "__ARM_FEATURE_SVE_MATMUL_FP32", pfile);
  aarch64_def_or_undef (TARGET_SVE_F64MM,
                        "__ARM_FEATURE_SVE_MATMUL_FP64", pfile);
  aarch64_def_or_undef (TARGET_SVE2, "__ARM_FEATURE_SVE2", pfile);
  aarch64_def_or_undef (TARGET_SVE2_AES, "__ARM_FEATURE_SVE2_AES", pfile);
  aarch64_def_or_undef (TARGET_SVE2_BITPERM,
                        "__ARM_FEATURE_SVE2_BITPERM", pfile);
  aarch64_def_or_undef (TARGET_SVE2_SHA3, "__ARM_FEATURE_SVE2_SHA3", pfile);
  aarch64_def_or_undef (TARGET_SVE2_SM4, "__ARM_FEATURE_SVE2_SM4", pfile);

  aarch64_def_or_undef (TARGET_LSE, "__ARM_FEATURE_ATOMICS", pfile);
  aarch64_def_or_undef (TARGET_AES, "__ARM_FEATURE_AES", pfile);
  aarch64_def_or_undef (TARGET_SHA2, "__ARM_FEATURE_SHA2", pfile);
  aarch64_def_or_undef (TARGET_SHA3, "__ARM_FEATURE_SHA3", pfile);
  aarch64_def_or_undef (TARGET_SHA3, "__ARM_FEATURE_SHA512", pfile);
  aarch64_def_or_undef (TARGET_SM4, "__ARM_FEATURE_SM3", pfile);
  aarch64_def_or_undef (TARGET_SM4, "__ARM_FEATURE_SM4", pfile);
  aarch64_def_or_undef (TARGET_F16FML, "__ARM_FEATURE_FP16_FML", pfile);

  aarch64_def_or_undef (TARGET_FRINT, "__ARM_FEATURE_FRINT", pfile);
  aarch64_def_or_undef (TARGET_TME, "__ARM_FEATURE_TME", pfile);
  aarch64_def_or_undef (TARGET_RNG, "__ARM_FEATURE_RNG", pfile);
  aarch64_def_or_undef (TARGET_MEMTAG, "__ARM_FEATURE_MEMORY_TAGGING", pfile);

  aarch64_def_or_undef (aarch_bti_enabled (),
                        "__ARM_FEATURE_BTI_DEFAULT", pfile);

  cpp_undef (pfile, "__ARM_FEATURE_PAC_DEFAULT");
  if (aarch_ra_sign_scope != AARCH_FUNCTION_NONE)
    {
      int v = 0;
      if (aarch64_ra_sign_key == AARCH64_KEY_A)
        v |= 1;
      if (aarch64_ra_sign_key == AARCH64_KEY_B)
        v |= 2;
      if (aarch_ra_sign_scope == AARCH_FUNCTION_ALL)
        v |= 4;
      builtin_define_with_int_value ("__ARM_FEATURE_PAC_DEFAULT", v);
    }

  aarch64_def_or_undef (TARGET_PAUTH, "__ARM_FEATURE_PAUTH", pfile);
  aarch64_def_or_undef (TARGET_BTI, "__ARM_FEATURE_BTI", pfile);
  aarch64_def_or_undef (TARGET_I8MM, "__ARM_FEATURE_MATMUL_INT8", pfile);
  aarch64_def_or_undef (TARGET_BF16_SIMD,
                        "__ARM_FEATURE_BF16_VECTOR_ARITHMETIC", pfile);
  aarch64_def_or_undef (TARGET_BF16_FP,
                        "__ARM_FEATURE_BF16_SCALAR_ARITHMETIC", pfile);
  aarch64_def_or_undef (TARGET_BF16_FP,
                        "__ARM_FEATURE_BF16", pfile);
  aarch64_def_or_undef (TARGET_SVE_BF16,
                        "__ARM_FEATURE_SVE_BF16", pfile);

  aarch64_def_or_undef (TARGET_LS64,
                        "__ARM_FEATURE_LS64", pfile);
  aarch64_def_or_undef (TARGET_RCPC, "__ARM_FEATURE_RCPC", pfile);
  aarch64_def_or_undef (TARGET_D128, "__ARM_FEATURE_SYSREG128", pfile);

  aarch64_def_or_undef (TARGET_SME, "__ARM_FEATURE_SME", pfile);
  aarch64_def_or_undef (TARGET_SME_I16I64, "__ARM_FEATURE_SME_I16I64", pfile);
  aarch64_def_or_undef (TARGET_SME_F64F64, "__ARM_FEATURE_SME_F64F64", pfile);
  aarch64_def_or_undef (TARGET_SME2, "__ARM_FEATURE_SME2", pfile);

  /* Not for ACLE, but required to keep "float.h" correct if we switch
     target between implementations that do or do not support ARMv8.2-A
     16-bit floating-point extensions.  */
  cpp_undef (pfile, "__FLT_EVAL_METHOD__");
  builtin_define_with_int_value ("__FLT_EVAL_METHOD__",
                                 c_flt_eval_method (true));
  cpp_undef (pfile, "__FLT_EVAL_METHOD_C99__");
  builtin_define_with_int_value ("__FLT_EVAL_METHOD_C99__",
                                 c_flt_eval_method (false));
}

/* Implement TARGET_CPU_CPP_BUILTINS.  */

void
aarch64_cpu_cpp_builtins (cpp_reader *pfile)
{
  aarch64_define_unconditional_macros (pfile);
  aarch64_update_cpp_builtins (pfile);
}

/* Hook to validate the current #pragma GCC target and set the state, and
   update the macros based on what was changed.  If ARGS is NULL, then
   POP_TARGET is used to reset the options.  */

static bool
aarch64_pragma_target_parse (tree args, tree pop_target)
{
  /* If args is not NULL then process it and setup the target-specific
     information that it specifies.  */
  if (args)
    {
      if (!aarch64_process_target_attr (args))
        return false;

      aarch64_override_options_internal (&global_options);
    }

  /* args is NULL, restore to the state described in pop_target.  */
  else
    {
      pop_target = pop_target ? pop_target : target_option_default_node;
      cl_target_option_restore (&global_options, &global_options_set,
                                TREE_TARGET_OPTION (pop_target));
    }

  target_option_current_node
    = build_target_option_node (&global_options, &global_options_set);

  aarch64_reset_previous_fndecl ();
  /* For the definitions, ensure all newly defined macros are considered
     as used for -Wunused-macros.  There is no point warning about the
     compiler predefined macros.  */
  cpp_options *cpp_opts = cpp_get_options (parse_in);
  unsigned char saved_warn_unused_macros = cpp_opts->warn_unused_macros;
  cpp_opts->warn_unused_macros = 0;

  cpp_force_token_locations (parse_in, BUILTINS_LOCATION);
  aarch64_update_cpp_builtins (parse_in);
  cpp_stop_forcing_token_locations (parse_in);

  cpp_opts->warn_unused_macros = saved_warn_unused_macros;

  /* If we're popping or reseting make sure to update the globals so that
     the optab availability predicates get recomputed.  */
  if (pop_target)
    aarch64_save_restore_target_globals (pop_target);

  return true;
}

/* Implement "#pragma GCC aarch64".  */
static void
aarch64_pragma_aarch64 (cpp_reader *)
{
  tree x;
  if (pragma_lex (&x) != CPP_STRING)
    {
      error ("%<#pragma GCC aarch64%> requires a string parameter");
      return;
    }

  const char *name = TREE_STRING_POINTER (x);
  if (strcmp (name, "arm_sve.h") == 0)
    aarch64_sve::handle_arm_sve_h (false);
  else if (strcmp (name, "arm_sme.h") == 0)
    aarch64_sve::handle_arm_sme_h (false);
  else if (strcmp (name, "arm_neon.h") == 0)
    handle_arm_neon_h ();
  else if (strcmp (name, "arm_acle.h") == 0)
    handle_arm_acle_h ();
  else if (strcmp (name, "arm_neon_sve_bridge.h") == 0)
    aarch64_sve::handle_arm_neon_sve_bridge_h (false);
  else
    error ("unknown %<#pragma GCC aarch64%> option %qs", name);
}

/* Implement TARGET_RESOLVE_OVERLOADED_BUILTIN.  */
static tree
aarch64_resolve_overloaded_builtin (unsigned int uncast_location,
                                    tree fndecl, void *uncast_arglist)
{
  vec<tree, va_gc> empty = {};
  location_t location = (location_t) uncast_location;
  vec<tree, va_gc> *arglist = (uncast_arglist
                               ? (vec<tree, va_gc> *) uncast_arglist
                               : &empty);
  unsigned int code = DECL_MD_FUNCTION_CODE (fndecl);
  unsigned int subcode = code >> AARCH64_BUILTIN_SHIFT;
  tree new_fndecl;
  switch (code & AARCH64_BUILTIN_CLASS)
    {
    case AARCH64_BUILTIN_GENERAL:
      return aarch64_resolve_overloaded_builtin_general (location, fndecl,
                                                         uncast_arglist);
    case AARCH64_BUILTIN_SVE:
      new_fndecl = aarch64_sve::resolve_overloaded_builtin (location, subcode,
                                                            arglist);
      break;
    }
  if (new_fndecl == NULL_TREE || new_fndecl == error_mark_node)
    return new_fndecl;
  return build_function_call_vec (location, vNULL, new_fndecl, arglist,
                                  NULL, fndecl);
}

/* Implement TARGET_CHECK_BUILTIN_CALL.  */
static bool
aarch64_check_builtin_call (location_t loc, vec<location_t> arg_loc,
                            tree fndecl, tree orig_fndecl,
                            unsigned int nargs, tree *args)
{
  unsigned int code = DECL_MD_FUNCTION_CODE (fndecl);
  unsigned int subcode = code >> AARCH64_BUILTIN_SHIFT;
  switch (code & AARCH64_BUILTIN_CLASS)
    {
    case AARCH64_BUILTIN_GENERAL:
      return aarch64_general_check_builtin_call (loc, arg_loc, subcode,
                                                 orig_fndecl, nargs, args);
    case AARCH64_BUILTIN_SVE:
      return aarch64_sve::check_builtin_call (loc, arg_loc, subcode,
                                              orig_fndecl, nargs, args);
    }
  gcc_unreachable ();
}

/* Implement REGISTER_TARGET_PRAGMAS.  */

void
aarch64_register_pragmas (void)
{
  /* Update pragma hook to allow parsing #pragma GCC target.  */
  targetm.target_option.pragma_parse = aarch64_pragma_target_parse;

  targetm.resolve_overloaded_builtin = aarch64_resolve_overloaded_builtin;
  targetm.check_builtin_call = aarch64_check_builtin_call;

  c_register_pragma ("GCC", "aarch64", aarch64_pragma_aarch64);
}