dist/bfd/elf32-spu.c

    1.1     skrll /* SPU specific support for 32-bit ELF
    1.1     skrll
1.1.1.4  christos    Copyright (C) 2006-2015 Free Software Foundation, Inc.
    1.1     skrll
    1.1     skrll    This file is part of BFD, the Binary File Descriptor library.
    1.1     skrll
    1.1     skrll    This program is free software; you can redistribute it and/or modify
    1.1     skrll    it under the terms of the GNU General Public License as published by
    1.1     skrll    the Free Software Foundation; either version 3 of the License, or
    1.1     skrll    (at your option) any later version.
    1.1     skrll
    1.1     skrll    This program is distributed in the hope that it will be useful,
    1.1     skrll    but WITHOUT ANY WARRANTY; without even the implied warranty of
    1.1     skrll    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    1.1     skrll    GNU General Public License for more details.
    1.1     skrll
    1.1     skrll    You should have received a copy of the GNU General Public License along
    1.1     skrll    with this program; if not, write to the Free Software Foundation, Inc.,
    1.1     skrll    51 Franklin Street - Fifth Floor, Boston, MA 02110-1301, USA.  */
    1.1     skrll
    1.1     skrll #include "sysdep.h"
    1.1     skrll #include "libiberty.h"
    1.1     skrll #include "bfd.h"
    1.1     skrll #include "bfdlink.h"
    1.1     skrll #include "libbfd.h"
    1.1     skrll #include "elf-bfd.h"
    1.1     skrll #include "elf/spu.h"
    1.1     skrll #include "elf32-spu.h"
    1.1     skrll
    1.1     skrll /* We use RELA style relocs.  Don't define USE_REL.  */
    1.1     skrll
    1.1     skrll static bfd_reloc_status_type spu_elf_rel9 (bfd *, arelent *, asymbol *,
    1.1     skrll 					   void *, asection *,
    1.1     skrll 					   bfd *, char **);
    1.1     skrll
    1.1     skrll /* Values of type 'enum elf_spu_reloc_type' are used to index this
    1.1     skrll    array, so it must be declared in the order of that type.  */
    1.1     skrll
    1.1     skrll static reloc_howto_type elf_howto_table[] = {
1.1.1.4  christos   HOWTO (R_SPU_NONE,       0, 3,  0, FALSE,  0, complain_overflow_dont,
    1.1     skrll 	 bfd_elf_generic_reloc, "SPU_NONE",
    1.1     skrll 	 FALSE, 0, 0x00000000, FALSE),
    1.1     skrll   HOWTO (R_SPU_ADDR10,     4, 2, 10, FALSE, 14, complain_overflow_bitfield,
    1.1     skrll 	 bfd_elf_generic_reloc, "SPU_ADDR10",
    1.1     skrll 	 FALSE, 0, 0x00ffc000, FALSE),
    1.1     skrll   HOWTO (R_SPU_ADDR16,     2, 2, 16, FALSE,  7, complain_overflow_bitfield,
    1.1     skrll 	 bfd_elf_generic_reloc, "SPU_ADDR16",
    1.1     skrll 	 FALSE, 0, 0x007fff80, FALSE),
    1.1     skrll   HOWTO (R_SPU_ADDR16_HI, 16, 2, 16, FALSE,  7, complain_overflow_bitfield,
    1.1     skrll 	 bfd_elf_generic_reloc, "SPU_ADDR16_HI",
    1.1     skrll 	 FALSE, 0, 0x007fff80, FALSE),
    1.1     skrll   HOWTO (R_SPU_ADDR16_LO,  0, 2, 16, FALSE,  7, complain_overflow_dont,
    1.1     skrll 	 bfd_elf_generic_reloc, "SPU_ADDR16_LO",
    1.1     skrll 	 FALSE, 0, 0x007fff80, FALSE),
    1.1     skrll   HOWTO (R_SPU_ADDR18,     0, 2, 18, FALSE,  7, complain_overflow_bitfield,
    1.1     skrll 	 bfd_elf_generic_reloc, "SPU_ADDR18",
    1.1     skrll 	 FALSE, 0, 0x01ffff80, FALSE),
    1.1     skrll   HOWTO (R_SPU_ADDR32,     0, 2, 32, FALSE,  0, complain_overflow_dont,
    1.1     skrll 	 bfd_elf_generic_reloc, "SPU_ADDR32",
    1.1     skrll 	 FALSE, 0, 0xffffffff, FALSE),
    1.1     skrll   HOWTO (R_SPU_REL16,      2, 2, 16,  TRUE,  7, complain_overflow_bitfield,
    1.1     skrll 	 bfd_elf_generic_reloc, "SPU_REL16",
    1.1     skrll 	 FALSE, 0, 0x007fff80, TRUE),
    1.1     skrll   HOWTO (R_SPU_ADDR7,      0, 2,  7, FALSE, 14, complain_overflow_dont,
    1.1     skrll 	 bfd_elf_generic_reloc, "SPU_ADDR7",
    1.1     skrll 	 FALSE, 0, 0x001fc000, FALSE),
    1.1     skrll   HOWTO (R_SPU_REL9,       2, 2,  9,  TRUE,  0, complain_overflow_signed,
    1.1     skrll 	 spu_elf_rel9,          "SPU_REL9",
    1.1     skrll 	 FALSE, 0, 0x0180007f, TRUE),
    1.1     skrll   HOWTO (R_SPU_REL9I,      2, 2,  9,  TRUE,  0, complain_overflow_signed,
    1.1     skrll 	 spu_elf_rel9,          "SPU_REL9I",
    1.1     skrll 	 FALSE, 0, 0x0000c07f, TRUE),
    1.1     skrll   HOWTO (R_SPU_ADDR10I,    0, 2, 10, FALSE, 14, complain_overflow_signed,
    1.1     skrll 	 bfd_elf_generic_reloc, "SPU_ADDR10I",
    1.1     skrll 	 FALSE, 0, 0x00ffc000, FALSE),
    1.1     skrll   HOWTO (R_SPU_ADDR16I,    0, 2, 16, FALSE,  7, complain_overflow_signed,
    1.1     skrll 	 bfd_elf_generic_reloc, "SPU_ADDR16I",
    1.1     skrll 	 FALSE, 0, 0x007fff80, FALSE),
    1.1     skrll   HOWTO (R_SPU_REL32,      0, 2, 32, TRUE,  0, complain_overflow_dont,
    1.1     skrll 	 bfd_elf_generic_reloc, "SPU_REL32",
    1.1     skrll 	 FALSE, 0, 0xffffffff, TRUE),
    1.1     skrll   HOWTO (R_SPU_ADDR16X,    0, 2, 16, FALSE,  7, complain_overflow_bitfield,
    1.1     skrll 	 bfd_elf_generic_reloc, "SPU_ADDR16X",
    1.1     skrll 	 FALSE, 0, 0x007fff80, FALSE),
    1.1     skrll   HOWTO (R_SPU_PPU32,      0, 2, 32, FALSE,  0, complain_overflow_dont,
    1.1     skrll 	 bfd_elf_generic_reloc, "SPU_PPU32",
    1.1     skrll 	 FALSE, 0, 0xffffffff, FALSE),
    1.1     skrll   HOWTO (R_SPU_PPU64,      0, 4, 64, FALSE,  0, complain_overflow_dont,
    1.1     skrll 	 bfd_elf_generic_reloc, "SPU_PPU64",
    1.1     skrll 	 FALSE, 0, -1, FALSE),
1.1.1.2  christos   HOWTO (R_SPU_ADD_PIC,      0, 0, 0, FALSE,  0, complain_overflow_dont,
1.1.1.2  christos 	 bfd_elf_generic_reloc, "SPU_ADD_PIC",
1.1.1.2  christos 	 FALSE, 0, 0x00000000, FALSE),
    1.1     skrll };
    1.1     skrll
    1.1     skrll static struct bfd_elf_special_section const spu_elf_special_sections[] = {
    1.1     skrll   { "._ea", 4, 0, SHT_PROGBITS, SHF_WRITE },
    1.1     skrll   { ".toe", 4, 0, SHT_NOBITS, SHF_ALLOC },
    1.1     skrll   { NULL, 0, 0, 0, 0 }
    1.1     skrll };
    1.1     skrll
    1.1     skrll static enum elf_spu_reloc_type
    1.1     skrll spu_elf_bfd_to_reloc_type (bfd_reloc_code_real_type code)
    1.1     skrll {
    1.1     skrll   switch (code)
    1.1     skrll     {
    1.1     skrll     default:
1.1.1.4  christos       return (enum elf_spu_reloc_type) -1;
1.1.1.4  christos     case BFD_RELOC_NONE:
    1.1     skrll       return R_SPU_NONE;
    1.1     skrll     case BFD_RELOC_SPU_IMM10W:
    1.1     skrll       return R_SPU_ADDR10;
    1.1     skrll     case BFD_RELOC_SPU_IMM16W:
    1.1     skrll       return R_SPU_ADDR16;
    1.1     skrll     case BFD_RELOC_SPU_LO16:
    1.1     skrll       return R_SPU_ADDR16_LO;
    1.1     skrll     case BFD_RELOC_SPU_HI16:
    1.1     skrll       return R_SPU_ADDR16_HI;
    1.1     skrll     case BFD_RELOC_SPU_IMM18:
    1.1     skrll       return R_SPU_ADDR18;
    1.1     skrll     case BFD_RELOC_SPU_PCREL16:
    1.1     skrll       return R_SPU_REL16;
    1.1     skrll     case BFD_RELOC_SPU_IMM7:
    1.1     skrll       return R_SPU_ADDR7;
    1.1     skrll     case BFD_RELOC_SPU_IMM8:
    1.1     skrll       return R_SPU_NONE;
    1.1     skrll     case BFD_RELOC_SPU_PCREL9a:
    1.1     skrll       return R_SPU_REL9;
    1.1     skrll     case BFD_RELOC_SPU_PCREL9b:
    1.1     skrll       return R_SPU_REL9I;
    1.1     skrll     case BFD_RELOC_SPU_IMM10:
    1.1     skrll       return R_SPU_ADDR10I;
    1.1     skrll     case BFD_RELOC_SPU_IMM16:
    1.1     skrll       return R_SPU_ADDR16I;
    1.1     skrll     case BFD_RELOC_32:
    1.1     skrll       return R_SPU_ADDR32;
    1.1     skrll     case BFD_RELOC_32_PCREL:
    1.1     skrll       return R_SPU_REL32;
    1.1     skrll     case BFD_RELOC_SPU_PPU32:
    1.1     skrll       return R_SPU_PPU32;
    1.1     skrll     case BFD_RELOC_SPU_PPU64:
    1.1     skrll       return R_SPU_PPU64;
1.1.1.2  christos     case BFD_RELOC_SPU_ADD_PIC:
1.1.1.2  christos       return R_SPU_ADD_PIC;
    1.1     skrll     }
    1.1     skrll }
    1.1     skrll
    1.1     skrll static void
    1.1     skrll spu_elf_info_to_howto (bfd *abfd ATTRIBUTE_UNUSED,
    1.1     skrll 		       arelent *cache_ptr,
    1.1     skrll 		       Elf_Internal_Rela *dst)
    1.1     skrll {
    1.1     skrll   enum elf_spu_reloc_type r_type;
    1.1     skrll
    1.1     skrll   r_type = (enum elf_spu_reloc_type) ELF32_R_TYPE (dst->r_info);
1.1.1.4  christos   /* PR 17512: file: 90c2a92e.  */
1.1.1.4  christos   if (r_type >= R_SPU_max)
1.1.1.4  christos     {
1.1.1.4  christos       (*_bfd_error_handler) (_("%B: unrecognised SPU reloc number: %d"),
1.1.1.4  christos 			     abfd, r_type);
1.1.1.4  christos       bfd_set_error (bfd_error_bad_value);
1.1.1.4  christos       r_type = R_SPU_NONE;
1.1.1.4  christos     }
    1.1     skrll   cache_ptr->howto = &elf_howto_table[(int) r_type];
    1.1     skrll }
    1.1     skrll
    1.1     skrll static reloc_howto_type *
    1.1     skrll spu_elf_reloc_type_lookup (bfd *abfd ATTRIBUTE_UNUSED,
    1.1     skrll 			   bfd_reloc_code_real_type code)
    1.1     skrll {
    1.1     skrll   enum elf_spu_reloc_type r_type = spu_elf_bfd_to_reloc_type (code);
    1.1     skrll
1.1.1.4  christos   if (r_type == (enum elf_spu_reloc_type) -1)
    1.1     skrll     return NULL;
    1.1     skrll
    1.1     skrll   return elf_howto_table + r_type;
    1.1     skrll }
    1.1     skrll
    1.1     skrll static reloc_howto_type *
    1.1     skrll spu_elf_reloc_name_lookup (bfd *abfd ATTRIBUTE_UNUSED,
    1.1     skrll 			   const char *r_name)
    1.1     skrll {
    1.1     skrll   unsigned int i;
    1.1     skrll
    1.1     skrll   for (i = 0; i < sizeof (elf_howto_table) / sizeof (elf_howto_table[0]); i++)
    1.1     skrll     if (elf_howto_table[i].name != NULL
    1.1     skrll 	&& strcasecmp (elf_howto_table[i].name, r_name) == 0)
    1.1     skrll       return &elf_howto_table[i];
    1.1     skrll
    1.1     skrll   return NULL;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Apply R_SPU_REL9 and R_SPU_REL9I relocs.  */
    1.1     skrll
    1.1     skrll static bfd_reloc_status_type
    1.1     skrll spu_elf_rel9 (bfd *abfd, arelent *reloc_entry, asymbol *symbol,
    1.1     skrll 	      void *data, asection *input_section,
    1.1     skrll 	      bfd *output_bfd, char **error_message)
    1.1     skrll {
    1.1     skrll   bfd_size_type octets;
    1.1     skrll   bfd_vma val;
    1.1     skrll   long insn;
    1.1     skrll
    1.1     skrll   /* If this is a relocatable link (output_bfd test tells us), just
    1.1     skrll      call the generic function.  Any adjustment will be done at final
    1.1     skrll      link time.  */
    1.1     skrll   if (output_bfd != NULL)
    1.1     skrll     return bfd_elf_generic_reloc (abfd, reloc_entry, symbol, data,
    1.1     skrll 				  input_section, output_bfd, error_message);
    1.1     skrll
    1.1     skrll   if (reloc_entry->address > bfd_get_section_limit (abfd, input_section))
    1.1     skrll     return bfd_reloc_outofrange;
    1.1     skrll   octets = reloc_entry->address * bfd_octets_per_byte (abfd);
    1.1     skrll
    1.1     skrll   /* Get symbol value.  */
    1.1     skrll   val = 0;
    1.1     skrll   if (!bfd_is_com_section (symbol->section))
    1.1     skrll     val = symbol->value;
    1.1     skrll   if (symbol->section->output_section)
    1.1     skrll     val += symbol->section->output_section->vma;
    1.1     skrll
    1.1     skrll   val += reloc_entry->addend;
    1.1     skrll
    1.1     skrll   /* Make it pc-relative.  */
    1.1     skrll   val -= input_section->output_section->vma + input_section->output_offset;
    1.1     skrll
    1.1     skrll   val >>= 2;
    1.1     skrll   if (val + 256 >= 512)
    1.1     skrll     return bfd_reloc_overflow;
    1.1     skrll
    1.1     skrll   insn = bfd_get_32 (abfd, (bfd_byte *) data + octets);
    1.1     skrll
    1.1     skrll   /* Move two high bits of value to REL9I and REL9 position.
    1.1     skrll      The mask will take care of selecting the right field.  */
    1.1     skrll   val = (val & 0x7f) | ((val & 0x180) << 7) | ((val & 0x180) << 16);
    1.1     skrll   insn &= ~reloc_entry->howto->dst_mask;
    1.1     skrll   insn |= val & reloc_entry->howto->dst_mask;
    1.1     skrll   bfd_put_32 (abfd, insn, (bfd_byte *) data + octets);
    1.1     skrll   return bfd_reloc_ok;
    1.1     skrll }
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll spu_elf_new_section_hook (bfd *abfd, asection *sec)
    1.1     skrll {
    1.1     skrll   if (!sec->used_by_bfd)
    1.1     skrll     {
    1.1     skrll       struct _spu_elf_section_data *sdata;
    1.1     skrll
    1.1     skrll       sdata = bfd_zalloc (abfd, sizeof (*sdata));
    1.1     skrll       if (sdata == NULL)
    1.1     skrll 	return FALSE;
    1.1     skrll       sec->used_by_bfd = sdata;
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   return _bfd_elf_new_section_hook (abfd, sec);
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Set up overlay info for executables.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll spu_elf_object_p (bfd *abfd)
    1.1     skrll {
    1.1     skrll   if ((abfd->flags & (EXEC_P | DYNAMIC)) != 0)
    1.1     skrll     {
    1.1     skrll       unsigned int i, num_ovl, num_buf;
    1.1     skrll       Elf_Internal_Phdr *phdr = elf_tdata (abfd)->phdr;
    1.1     skrll       Elf_Internal_Ehdr *ehdr = elf_elfheader (abfd);
    1.1     skrll       Elf_Internal_Phdr *last_phdr = NULL;
    1.1     skrll
    1.1     skrll       for (num_buf = 0, num_ovl = 0, i = 0; i < ehdr->e_phnum; i++, phdr++)
    1.1     skrll 	if (phdr->p_type == PT_LOAD && (phdr->p_flags & PF_OVERLAY) != 0)
    1.1     skrll 	  {
    1.1     skrll 	    unsigned int j;
    1.1     skrll
    1.1     skrll 	    ++num_ovl;
    1.1     skrll 	    if (last_phdr == NULL
    1.1     skrll 		|| ((last_phdr->p_vaddr ^ phdr->p_vaddr) & 0x3ffff) != 0)
    1.1     skrll 	      ++num_buf;
    1.1     skrll 	    last_phdr = phdr;
    1.1     skrll 	    for (j = 1; j < elf_numsections (abfd); j++)
    1.1     skrll 	      {
    1.1     skrll 		Elf_Internal_Shdr *shdr = elf_elfsections (abfd)[j];
    1.1     skrll
1.1.1.2  christos 		if (ELF_SECTION_SIZE (shdr, phdr) != 0
1.1.1.2  christos 		    && ELF_SECTION_IN_SEGMENT (shdr, phdr))
    1.1     skrll 		  {
    1.1     skrll 		    asection *sec = shdr->bfd_section;
    1.1     skrll 		    spu_elf_section_data (sec)->u.o.ovl_index = num_ovl;
    1.1     skrll 		    spu_elf_section_data (sec)->u.o.ovl_buf = num_buf;
    1.1     skrll 		  }
    1.1     skrll 	      }
    1.1     skrll 	  }
    1.1     skrll     }
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Specially mark defined symbols named _EAR_* with BSF_KEEP so that
    1.1     skrll    strip --strip-unneeded will not remove them.  */
    1.1     skrll
    1.1     skrll static void
    1.1     skrll spu_elf_backend_symbol_processing (bfd *abfd ATTRIBUTE_UNUSED, asymbol *sym)
    1.1     skrll {
    1.1     skrll   if (sym->name != NULL
    1.1     skrll       && sym->section != bfd_abs_section_ptr
    1.1     skrll       && strncmp (sym->name, "_EAR_", 5) == 0)
    1.1     skrll     sym->flags |= BSF_KEEP;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* SPU ELF linker hash table.  */
    1.1     skrll
    1.1     skrll struct spu_link_hash_table
    1.1     skrll {
    1.1     skrll   struct elf_link_hash_table elf;
    1.1     skrll
1.1.1.2  christos   struct spu_elf_params *params;
1.1.1.2  christos
    1.1     skrll   /* Shortcuts to overlay sections.  */
    1.1     skrll   asection *ovtab;
1.1.1.2  christos   asection *init;
    1.1     skrll   asection *toe;
    1.1     skrll   asection **ovl_sec;
    1.1     skrll
    1.1     skrll   /* Count of stubs in each overlay section.  */
    1.1     skrll   unsigned int *stub_count;
    1.1     skrll
    1.1     skrll   /* The stub section for each overlay section.  */
    1.1     skrll   asection **stub_sec;
    1.1     skrll
1.1.1.2  christos   struct elf_link_hash_entry *ovly_entry[2];
    1.1     skrll
    1.1     skrll   /* Number of overlay buffers.  */
    1.1     skrll   unsigned int num_buf;
    1.1     skrll
    1.1     skrll   /* Total number of overlays.  */
    1.1     skrll   unsigned int num_overlays;
    1.1     skrll
1.1.1.2  christos   /* For soft icache.  */
1.1.1.2  christos   unsigned int line_size_log2;
1.1.1.2  christos   unsigned int num_lines_log2;
1.1.1.2  christos   unsigned int fromelem_size_log2;
1.1.1.2  christos
    1.1     skrll   /* How much memory we have.  */
    1.1     skrll   unsigned int local_store;
1.1.1.2  christos
    1.1     skrll   /* Count of overlay stubs needed in non-overlay area.  */
    1.1     skrll   unsigned int non_ovly_stub;
    1.1     skrll
1.1.1.2  christos   /* Pointer to the fixup section */
1.1.1.2  christos   asection *sfixup;
    1.1     skrll
    1.1     skrll   /* Set on error.  */
    1.1     skrll   unsigned int stub_err : 1;
    1.1     skrll };
    1.1     skrll
    1.1     skrll /* Hijack the generic got fields for overlay stub accounting.  */
    1.1     skrll
    1.1     skrll struct got_entry
    1.1     skrll {
    1.1     skrll   struct got_entry *next;
    1.1     skrll   unsigned int ovl;
1.1.1.2  christos   union {
1.1.1.2  christos     bfd_vma addend;
1.1.1.2  christos     bfd_vma br_addr;
1.1.1.2  christos   };
    1.1     skrll   bfd_vma stub_addr;
    1.1     skrll };
    1.1     skrll
    1.1     skrll #define spu_hash_table(p) \
1.1.1.2  christos   (elf_hash_table_id ((struct elf_link_hash_table *) ((p)->hash)) \
1.1.1.2  christos   == SPU_ELF_DATA ? ((struct spu_link_hash_table *) ((p)->hash)) : NULL)
1.1.1.2  christos
1.1.1.2  christos struct call_info
1.1.1.2  christos {
1.1.1.2  christos   struct function_info *fun;
1.1.1.2  christos   struct call_info *next;
1.1.1.2  christos   unsigned int count;
1.1.1.2  christos   unsigned int max_depth;
1.1.1.2  christos   unsigned int is_tail : 1;
1.1.1.2  christos   unsigned int is_pasted : 1;
1.1.1.2  christos   unsigned int broken_cycle : 1;
1.1.1.2  christos   unsigned int priority : 13;
1.1.1.2  christos };
1.1.1.2  christos
1.1.1.2  christos struct function_info
1.1.1.2  christos {
1.1.1.2  christos   /* List of functions called.  Also branches to hot/cold part of
1.1.1.2  christos      function.  */
1.1.1.2  christos   struct call_info *call_list;
1.1.1.2  christos   /* For hot/cold part of function, point to owner.  */
1.1.1.2  christos   struct function_info *start;
1.1.1.2  christos   /* Symbol at start of function.  */
1.1.1.2  christos   union {
1.1.1.2  christos     Elf_Internal_Sym *sym;
1.1.1.2  christos     struct elf_link_hash_entry *h;
1.1.1.2  christos   } u;
1.1.1.2  christos   /* Function section.  */
1.1.1.2  christos   asection *sec;
1.1.1.2  christos   asection *rodata;
1.1.1.2  christos   /* Where last called from, and number of sections called from.  */
1.1.1.2  christos   asection *last_caller;
1.1.1.2  christos   unsigned int call_count;
1.1.1.2  christos   /* Address range of (this part of) function.  */
1.1.1.2  christos   bfd_vma lo, hi;
1.1.1.2  christos   /* Offset where we found a store of lr, or -1 if none found.  */
1.1.1.2  christos   bfd_vma lr_store;
1.1.1.2  christos   /* Offset where we found the stack adjustment insn.  */
1.1.1.2  christos   bfd_vma sp_adjust;
1.1.1.2  christos   /* Stack usage.  */
1.1.1.2  christos   int stack;
1.1.1.2  christos   /* Distance from root of call tree.  Tail and hot/cold branches
1.1.1.2  christos      count as one deeper.  We aren't counting stack frames here.  */
1.1.1.2  christos   unsigned int depth;
1.1.1.2  christos   /* Set if global symbol.  */
1.1.1.2  christos   unsigned int global : 1;
1.1.1.2  christos   /* Set if known to be start of function (as distinct from a hunk
1.1.1.2  christos      in hot/cold section.  */
1.1.1.2  christos   unsigned int is_func : 1;
1.1.1.2  christos   /* Set if not a root node.  */
1.1.1.2  christos   unsigned int non_root : 1;
1.1.1.2  christos   /* Flags used during call tree traversal.  It's cheaper to replicate
1.1.1.2  christos      the visit flags than have one which needs clearing after a traversal.  */
1.1.1.2  christos   unsigned int visit1 : 1;
1.1.1.2  christos   unsigned int visit2 : 1;
1.1.1.2  christos   unsigned int marking : 1;
1.1.1.2  christos   unsigned int visit3 : 1;
1.1.1.2  christos   unsigned int visit4 : 1;
1.1.1.2  christos   unsigned int visit5 : 1;
1.1.1.2  christos   unsigned int visit6 : 1;
1.1.1.2  christos   unsigned int visit7 : 1;
1.1.1.2  christos };
1.1.1.2  christos
1.1.1.2  christos struct spu_elf_stack_info
1.1.1.2  christos {
1.1.1.2  christos   int num_fun;
1.1.1.2  christos   int max_fun;
1.1.1.2  christos   /* Variable size array describing functions, one per contiguous
1.1.1.2  christos      address range belonging to a function.  */
1.1.1.2  christos   struct function_info fun[1];
1.1.1.2  christos };
1.1.1.2  christos
1.1.1.2  christos static struct function_info *find_function (asection *, bfd_vma,
1.1.1.2  christos 					    struct bfd_link_info *);
    1.1     skrll
    1.1     skrll /* Create a spu ELF linker hash table.  */
    1.1     skrll
    1.1     skrll static struct bfd_link_hash_table *
    1.1     skrll spu_elf_link_hash_table_create (bfd *abfd)
    1.1     skrll {
    1.1     skrll   struct spu_link_hash_table *htab;
    1.1     skrll
1.1.1.4  christos   htab = bfd_zmalloc (sizeof (*htab));
    1.1     skrll   if (htab == NULL)
    1.1     skrll     return NULL;
    1.1     skrll
    1.1     skrll   if (!_bfd_elf_link_hash_table_init (&htab->elf, abfd,
    1.1     skrll 				      _bfd_elf_link_hash_newfunc,
1.1.1.2  christos 				      sizeof (struct elf_link_hash_entry),
1.1.1.2  christos 				      SPU_ELF_DATA))
    1.1     skrll     {
    1.1     skrll       free (htab);
    1.1     skrll       return NULL;
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   htab->elf.init_got_refcount.refcount = 0;
    1.1     skrll   htab->elf.init_got_refcount.glist = NULL;
    1.1     skrll   htab->elf.init_got_offset.offset = 0;
    1.1     skrll   htab->elf.init_got_offset.glist = NULL;
    1.1     skrll   return &htab->elf.root;
    1.1     skrll }
    1.1     skrll
1.1.1.2  christos void
1.1.1.2  christos spu_elf_setup (struct bfd_link_info *info, struct spu_elf_params *params)
1.1.1.2  christos {
1.1.1.2  christos   bfd_vma max_branch_log2;
1.1.1.2  christos
1.1.1.2  christos   struct spu_link_hash_table *htab = spu_hash_table (info);
1.1.1.2  christos   htab->params = params;
1.1.1.2  christos   htab->line_size_log2 = bfd_log2 (htab->params->line_size);
1.1.1.2  christos   htab->num_lines_log2 = bfd_log2 (htab->params->num_lines);
1.1.1.2  christos
1.1.1.2  christos   /* For the software i-cache, we provide a "from" list whose size
1.1.1.2  christos      is a power-of-two number of quadwords, big enough to hold one
1.1.1.2  christos      byte per outgoing branch.  Compute this number here.  */
1.1.1.2  christos   max_branch_log2 = bfd_log2 (htab->params->max_branch);
1.1.1.2  christos   htab->fromelem_size_log2 = max_branch_log2 > 4 ? max_branch_log2 - 4 : 0;
1.1.1.2  christos }
1.1.1.2  christos
    1.1     skrll /* Find the symbol for the given R_SYMNDX in IBFD and set *HP and *SYMP
    1.1     skrll    to (hash, NULL) for global symbols, and (NULL, sym) for locals.  Set
    1.1     skrll    *SYMSECP to the symbol's section.  *LOCSYMSP caches local syms.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll get_sym_h (struct elf_link_hash_entry **hp,
    1.1     skrll 	   Elf_Internal_Sym **symp,
    1.1     skrll 	   asection **symsecp,
    1.1     skrll 	   Elf_Internal_Sym **locsymsp,
    1.1     skrll 	   unsigned long r_symndx,
    1.1     skrll 	   bfd *ibfd)
    1.1     skrll {
    1.1     skrll   Elf_Internal_Shdr *symtab_hdr = &elf_tdata (ibfd)->symtab_hdr;
    1.1     skrll
    1.1     skrll   if (r_symndx >= symtab_hdr->sh_info)
    1.1     skrll     {
    1.1     skrll       struct elf_link_hash_entry **sym_hashes = elf_sym_hashes (ibfd);
    1.1     skrll       struct elf_link_hash_entry *h;
    1.1     skrll
    1.1     skrll       h = sym_hashes[r_symndx - symtab_hdr->sh_info];
    1.1     skrll       while (h->root.type == bfd_link_hash_indirect
    1.1     skrll 	     || h->root.type == bfd_link_hash_warning)
    1.1     skrll 	h = (struct elf_link_hash_entry *) h->root.u.i.link;
    1.1     skrll
    1.1     skrll       if (hp != NULL)
    1.1     skrll 	*hp = h;
    1.1     skrll
    1.1     skrll       if (symp != NULL)
    1.1     skrll 	*symp = NULL;
    1.1     skrll
    1.1     skrll       if (symsecp != NULL)
    1.1     skrll 	{
    1.1     skrll 	  asection *symsec = NULL;
    1.1     skrll 	  if (h->root.type == bfd_link_hash_defined
    1.1     skrll 	      || h->root.type == bfd_link_hash_defweak)
    1.1     skrll 	    symsec = h->root.u.def.section;
    1.1     skrll 	  *symsecp = symsec;
    1.1     skrll 	}
    1.1     skrll     }
    1.1     skrll   else
    1.1     skrll     {
    1.1     skrll       Elf_Internal_Sym *sym;
    1.1     skrll       Elf_Internal_Sym *locsyms = *locsymsp;
    1.1     skrll
    1.1     skrll       if (locsyms == NULL)
    1.1     skrll 	{
    1.1     skrll 	  locsyms = (Elf_Internal_Sym *) symtab_hdr->contents;
    1.1     skrll 	  if (locsyms == NULL)
    1.1     skrll 	    locsyms = bfd_elf_get_elf_syms (ibfd, symtab_hdr,
    1.1     skrll 					    symtab_hdr->sh_info,
    1.1     skrll 					    0, NULL, NULL, NULL);
    1.1     skrll 	  if (locsyms == NULL)
    1.1     skrll 	    return FALSE;
    1.1     skrll 	  *locsymsp = locsyms;
    1.1     skrll 	}
    1.1     skrll       sym = locsyms + r_symndx;
    1.1     skrll
    1.1     skrll       if (hp != NULL)
    1.1     skrll 	*hp = NULL;
    1.1     skrll
    1.1     skrll       if (symp != NULL)
    1.1     skrll 	*symp = sym;
    1.1     skrll
    1.1     skrll       if (symsecp != NULL)
    1.1     skrll 	*symsecp = bfd_section_from_elf_index (ibfd, sym->st_shndx);
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Create the note section if not already present.  This is done early so
    1.1     skrll    that the linker maps the sections to the right place in the output.  */
    1.1     skrll
    1.1     skrll bfd_boolean
1.1.1.2  christos spu_elf_create_sections (struct bfd_link_info *info)
    1.1     skrll {
    1.1     skrll   struct spu_link_hash_table *htab = spu_hash_table (info);
1.1.1.2  christos   bfd *ibfd;
    1.1     skrll
1.1.1.4  christos   for (ibfd = info->input_bfds; ibfd != NULL; ibfd = ibfd->link.next)
    1.1     skrll     if (bfd_get_section_by_name (ibfd, SPU_PTNOTE_SPUNAME) != NULL)
    1.1     skrll       break;
    1.1     skrll
    1.1     skrll   if (ibfd == NULL)
    1.1     skrll     {
    1.1     skrll       /* Make SPU_PTNOTE_SPUNAME section.  */
    1.1     skrll       asection *s;
    1.1     skrll       size_t name_len;
    1.1     skrll       size_t size;
    1.1     skrll       bfd_byte *data;
    1.1     skrll       flagword flags;
    1.1     skrll
    1.1     skrll       ibfd = info->input_bfds;
    1.1     skrll       flags = SEC_LOAD | SEC_READONLY | SEC_HAS_CONTENTS | SEC_IN_MEMORY;
    1.1     skrll       s = bfd_make_section_anyway_with_flags (ibfd, SPU_PTNOTE_SPUNAME, flags);
    1.1     skrll       if (s == NULL
    1.1     skrll 	  || !bfd_set_section_alignment (ibfd, s, 4))
    1.1     skrll 	return FALSE;
    1.1     skrll
    1.1     skrll       name_len = strlen (bfd_get_filename (info->output_bfd)) + 1;
    1.1     skrll       size = 12 + ((sizeof (SPU_PLUGIN_NAME) + 3) & -4);
    1.1     skrll       size += (name_len + 3) & -4;
    1.1     skrll
    1.1     skrll       if (!bfd_set_section_size (ibfd, s, size))
    1.1     skrll 	return FALSE;
    1.1     skrll
    1.1     skrll       data = bfd_zalloc (ibfd, size);
    1.1     skrll       if (data == NULL)
    1.1     skrll 	return FALSE;
    1.1     skrll
    1.1     skrll       bfd_put_32 (ibfd, sizeof (SPU_PLUGIN_NAME), data + 0);
    1.1     skrll       bfd_put_32 (ibfd, name_len, data + 4);
    1.1     skrll       bfd_put_32 (ibfd, 1, data + 8);
    1.1     skrll       memcpy (data + 12, SPU_PLUGIN_NAME, sizeof (SPU_PLUGIN_NAME));
    1.1     skrll       memcpy (data + 12 + ((sizeof (SPU_PLUGIN_NAME) + 3) & -4),
    1.1     skrll 	      bfd_get_filename (info->output_bfd), name_len);
    1.1     skrll       s->contents = data;
    1.1     skrll     }
    1.1     skrll
1.1.1.2  christos   if (htab->params->emit_fixups)
1.1.1.2  christos     {
1.1.1.2  christos       asection *s;
1.1.1.2  christos       flagword flags;
1.1.1.2  christos
1.1.1.2  christos       if (htab->elf.dynobj == NULL)
1.1.1.2  christos 	htab->elf.dynobj = ibfd;
1.1.1.2  christos       ibfd = htab->elf.dynobj;
1.1.1.2  christos       flags = (SEC_LOAD | SEC_ALLOC | SEC_READONLY | SEC_HAS_CONTENTS
1.1.1.2  christos 	       | SEC_IN_MEMORY | SEC_LINKER_CREATED);
1.1.1.2  christos       s = bfd_make_section_anyway_with_flags (ibfd, ".fixup", flags);
1.1.1.2  christos       if (s == NULL || !bfd_set_section_alignment (ibfd, s, 2))
1.1.1.2  christos 	return FALSE;
1.1.1.2  christos       htab->sfixup = s;
1.1.1.2  christos     }
1.1.1.2  christos
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* qsort predicate to sort sections by vma.  */
    1.1     skrll
    1.1     skrll static int
    1.1     skrll sort_sections (const void *a, const void *b)
    1.1     skrll {
    1.1     skrll   const asection *const *s1 = a;
    1.1     skrll   const asection *const *s2 = b;
    1.1     skrll   bfd_signed_vma delta = (*s1)->vma - (*s2)->vma;
    1.1     skrll
    1.1     skrll   if (delta != 0)
    1.1     skrll     return delta < 0 ? -1 : 1;
    1.1     skrll
    1.1     skrll   return (*s1)->index - (*s2)->index;
    1.1     skrll }
    1.1     skrll
1.1.1.2  christos /* Identify overlays in the output bfd, and number them.
1.1.1.2  christos    Returns 0 on error, 1 if no overlays, 2 if overlays.  */
    1.1     skrll
1.1.1.2  christos int
    1.1     skrll spu_elf_find_overlays (struct bfd_link_info *info)
    1.1     skrll {
    1.1     skrll   struct spu_link_hash_table *htab = spu_hash_table (info);
    1.1     skrll   asection **alloc_sec;
    1.1     skrll   unsigned int i, n, ovl_index, num_buf;
    1.1     skrll   asection *s;
    1.1     skrll   bfd_vma ovl_end;
1.1.1.2  christos   static const char *const entry_names[2][2] = {
1.1.1.2  christos     { "__ovly_load", "__icache_br_handler" },
1.1.1.2  christos     { "__ovly_return", "__icache_call_handler" }
1.1.1.2  christos   };
    1.1     skrll
    1.1     skrll   if (info->output_bfd->section_count < 2)
1.1.1.2  christos     return 1;
    1.1     skrll
    1.1     skrll   alloc_sec
    1.1     skrll     = bfd_malloc (info->output_bfd->section_count * sizeof (*alloc_sec));
    1.1     skrll   if (alloc_sec == NULL)
1.1.1.2  christos     return 0;
    1.1     skrll
    1.1     skrll   /* Pick out all the alloced sections.  */
    1.1     skrll   for (n = 0, s = info->output_bfd->sections; s != NULL; s = s->next)
    1.1     skrll     if ((s->flags & SEC_ALLOC) != 0
    1.1     skrll 	&& (s->flags & (SEC_LOAD | SEC_THREAD_LOCAL)) != SEC_THREAD_LOCAL
    1.1     skrll 	&& s->size != 0)
    1.1     skrll       alloc_sec[n++] = s;
    1.1     skrll
    1.1     skrll   if (n == 0)
    1.1     skrll     {
    1.1     skrll       free (alloc_sec);
1.1.1.2  christos       return 1;
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   /* Sort them by vma.  */
    1.1     skrll   qsort (alloc_sec, n, sizeof (*alloc_sec), sort_sections);
    1.1     skrll
    1.1     skrll   ovl_end = alloc_sec[0]->vma + alloc_sec[0]->size;
1.1.1.2  christos   if (htab->params->ovly_flavour == ovly_soft_icache)
    1.1     skrll     {
1.1.1.2  christos       unsigned int prev_buf = 0, set_id = 0;
1.1.1.2  christos
1.1.1.2  christos       /* Look for an overlapping vma to find the first overlay section.  */
1.1.1.2  christos       bfd_vma vma_start = 0;
1.1.1.2  christos
1.1.1.2  christos       for (i = 1; i < n; i++)
1.1.1.2  christos 	{
1.1.1.2  christos 	  s = alloc_sec[i];
1.1.1.2  christos 	  if (s->vma < ovl_end)
1.1.1.2  christos 	    {
1.1.1.2  christos 	      asection *s0 = alloc_sec[i - 1];
1.1.1.2  christos 	      vma_start = s0->vma;
1.1.1.2  christos 	      ovl_end = (s0->vma
1.1.1.2  christos 			 + ((bfd_vma) 1
1.1.1.2  christos 			    << (htab->num_lines_log2 + htab->line_size_log2)));
1.1.1.2  christos 	      --i;
1.1.1.2  christos 	      break;
1.1.1.2  christos 	    }
1.1.1.2  christos 	  else
1.1.1.2  christos 	    ovl_end = s->vma + s->size;
1.1.1.2  christos 	}
1.1.1.2  christos
1.1.1.2  christos       /* Now find any sections within the cache area.  */
1.1.1.2  christos       for (ovl_index = 0, num_buf = 0; i < n; i++)
    1.1     skrll 	{
1.1.1.2  christos 	  s = alloc_sec[i];
1.1.1.2  christos 	  if (s->vma >= ovl_end)
1.1.1.2  christos 	    break;
    1.1     skrll
1.1.1.2  christos 	  /* A section in an overlay area called .ovl.init is not
1.1.1.2  christos 	     an overlay, in the sense that it might be loaded in
1.1.1.2  christos 	     by the overlay manager, but rather the initial
1.1.1.2  christos 	     section contents for the overlay buffer.  */
1.1.1.2  christos 	  if (strncmp (s->name, ".ovl.init", 9) != 0)
    1.1     skrll 	    {
1.1.1.2  christos 	      num_buf = ((s->vma - vma_start) >> htab->line_size_log2) + 1;
1.1.1.2  christos 	      set_id = (num_buf == prev_buf)? set_id + 1 : 0;
1.1.1.2  christos 	      prev_buf = num_buf;
1.1.1.2  christos
1.1.1.2  christos 	      if ((s->vma - vma_start) & (htab->params->line_size - 1))
1.1.1.2  christos 		{
1.1.1.2  christos 		  info->callbacks->einfo (_("%X%P: overlay section %A "
1.1.1.2  christos 					    "does not start on a cache line.\n"),
1.1.1.2  christos 					  s);
1.1.1.2  christos 		  bfd_set_error (bfd_error_bad_value);
1.1.1.2  christos 		  return 0;
1.1.1.2  christos 		}
1.1.1.2  christos 	      else if (s->size > htab->params->line_size)
1.1.1.2  christos 		{
1.1.1.2  christos 		  info->callbacks->einfo (_("%X%P: overlay section %A "
1.1.1.2  christos 					    "is larger than a cache line.\n"),
1.1.1.2  christos 					  s);
1.1.1.2  christos 		  bfd_set_error (bfd_error_bad_value);
1.1.1.2  christos 		  return 0;
1.1.1.2  christos 		}
1.1.1.2  christos
1.1.1.2  christos 	      alloc_sec[ovl_index++] = s;
1.1.1.2  christos 	      spu_elf_section_data (s)->u.o.ovl_index
1.1.1.2  christos 		= (set_id << htab->num_lines_log2) + num_buf;
1.1.1.2  christos 	      spu_elf_section_data (s)->u.o.ovl_buf = num_buf;
    1.1     skrll 	    }
1.1.1.2  christos 	}
1.1.1.2  christos
1.1.1.2  christos       /* Ensure there are no more overlay sections.  */
1.1.1.2  christos       for ( ; i < n; i++)
1.1.1.2  christos 	{
1.1.1.2  christos 	  s = alloc_sec[i];
1.1.1.2  christos 	  if (s->vma < ovl_end)
    1.1     skrll 	    {
1.1.1.2  christos 	      info->callbacks->einfo (_("%X%P: overlay section %A "
1.1.1.2  christos 					"is not in cache area.\n"),
1.1.1.2  christos 				      alloc_sec[i-1]);
1.1.1.2  christos 	      bfd_set_error (bfd_error_bad_value);
1.1.1.2  christos 	      return 0;
    1.1     skrll 	    }
1.1.1.2  christos 	  else
1.1.1.2  christos 	    ovl_end = s->vma + s->size;
1.1.1.2  christos 	}
1.1.1.2  christos     }
1.1.1.2  christos   else
1.1.1.2  christos     {
1.1.1.2  christos       /* Look for overlapping vmas.  Any with overlap must be overlays.
1.1.1.2  christos 	 Count them.  Also count the number of overlay regions.  */
1.1.1.2  christos       for (ovl_index = 0, num_buf = 0, i = 1; i < n; i++)
1.1.1.2  christos 	{
1.1.1.2  christos 	  s = alloc_sec[i];
1.1.1.2  christos 	  if (s->vma < ovl_end)
1.1.1.2  christos 	    {
1.1.1.2  christos 	      asection *s0 = alloc_sec[i - 1];
1.1.1.2  christos
1.1.1.2  christos 	      if (spu_elf_section_data (s0)->u.o.ovl_index == 0)
1.1.1.2  christos 		{
1.1.1.2  christos 		  ++num_buf;
1.1.1.2  christos 		  if (strncmp (s0->name, ".ovl.init", 9) != 0)
1.1.1.2  christos 		    {
1.1.1.2  christos 		      alloc_sec[ovl_index] = s0;
1.1.1.2  christos 		      spu_elf_section_data (s0)->u.o.ovl_index = ++ovl_index;
1.1.1.2  christos 		      spu_elf_section_data (s0)->u.o.ovl_buf = num_buf;
1.1.1.2  christos 		    }
1.1.1.2  christos 		  else
1.1.1.2  christos 		    ovl_end = s->vma + s->size;
1.1.1.2  christos 		}
1.1.1.2  christos 	      if (strncmp (s->name, ".ovl.init", 9) != 0)
1.1.1.2  christos 		{
1.1.1.2  christos 		  alloc_sec[ovl_index] = s;
1.1.1.2  christos 		  spu_elf_section_data (s)->u.o.ovl_index = ++ovl_index;
1.1.1.2  christos 		  spu_elf_section_data (s)->u.o.ovl_buf = num_buf;
1.1.1.2  christos 		  if (s0->vma != s->vma)
1.1.1.2  christos 		    {
1.1.1.2  christos 		      info->callbacks->einfo (_("%X%P: overlay sections %A "
1.1.1.2  christos 						"and %A do not start at the "
1.1.1.2  christos 						"same address.\n"),
1.1.1.2  christos 					      s0, s);
1.1.1.2  christos 		      bfd_set_error (bfd_error_bad_value);
1.1.1.2  christos 		      return 0;
1.1.1.2  christos 		    }
1.1.1.2  christos 		  if (ovl_end < s->vma + s->size)
1.1.1.2  christos 		    ovl_end = s->vma + s->size;
1.1.1.2  christos 		}
1.1.1.2  christos 	    }
1.1.1.2  christos 	  else
    1.1     skrll 	    ovl_end = s->vma + s->size;
    1.1     skrll 	}
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   htab->num_overlays = ovl_index;
    1.1     skrll   htab->num_buf = num_buf;
    1.1     skrll   htab->ovl_sec = alloc_sec;
1.1.1.2  christos
1.1.1.2  christos   if (ovl_index == 0)
1.1.1.2  christos     return 1;
1.1.1.2  christos
1.1.1.2  christos   for (i = 0; i < 2; i++)
1.1.1.2  christos     {
1.1.1.2  christos       const char *name;
1.1.1.2  christos       struct elf_link_hash_entry *h;
1.1.1.2  christos
1.1.1.2  christos       name = entry_names[i][htab->params->ovly_flavour];
1.1.1.2  christos       h = elf_link_hash_lookup (&htab->elf, name, TRUE, FALSE, FALSE);
1.1.1.2  christos       if (h == NULL)
1.1.1.2  christos 	return 0;
1.1.1.2  christos
1.1.1.2  christos       if (h->root.type == bfd_link_hash_new)
1.1.1.2  christos 	{
1.1.1.2  christos 	  h->root.type = bfd_link_hash_undefined;
1.1.1.2  christos 	  h->ref_regular = 1;
1.1.1.2  christos 	  h->ref_regular_nonweak = 1;
1.1.1.2  christos 	  h->non_elf = 0;
1.1.1.2  christos 	}
1.1.1.2  christos       htab->ovly_entry[i] = h;
1.1.1.2  christos     }
1.1.1.2  christos
1.1.1.2  christos   return 2;
    1.1     skrll }
    1.1     skrll
1.1.1.2  christos /* Non-zero to use bra in overlay stubs rather than br.  */
1.1.1.2  christos #define BRA_STUBS 0
1.1.1.2  christos
1.1.1.2  christos #define BRA	0x30000000
1.1.1.2  christos #define BRASL	0x31000000
    1.1     skrll #define BR	0x32000000
1.1.1.2  christos #define BRSL	0x33000000
    1.1     skrll #define NOP	0x40200000
    1.1     skrll #define LNOP	0x00200000
    1.1     skrll #define ILA	0x42000000
    1.1     skrll
    1.1     skrll /* Return true for all relative and absolute branch instructions.
    1.1     skrll    bra   00110000 0..
    1.1     skrll    brasl 00110001 0..
    1.1     skrll    br    00110010 0..
    1.1     skrll    brsl  00110011 0..
    1.1     skrll    brz   00100000 0..
    1.1     skrll    brnz  00100001 0..
    1.1     skrll    brhz  00100010 0..
    1.1     skrll    brhnz 00100011 0..  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll is_branch (const unsigned char *insn)
    1.1     skrll {
    1.1     skrll   return (insn[0] & 0xec) == 0x20 && (insn[1] & 0x80) == 0;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Return true for all indirect branch instructions.
    1.1     skrll    bi     00110101 000
    1.1     skrll    bisl   00110101 001
    1.1     skrll    iret   00110101 010
    1.1     skrll    bisled 00110101 011
    1.1     skrll    biz    00100101 000
    1.1     skrll    binz   00100101 001
    1.1     skrll    bihz   00100101 010
    1.1     skrll    bihnz  00100101 011  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll is_indirect_branch (const unsigned char *insn)
    1.1     skrll {
    1.1     skrll   return (insn[0] & 0xef) == 0x25 && (insn[1] & 0x80) == 0;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Return true for branch hint instructions.
    1.1     skrll    hbra  0001000..
    1.1     skrll    hbrr  0001001..  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll is_hint (const unsigned char *insn)
    1.1     skrll {
    1.1     skrll   return (insn[0] & 0xfc) == 0x10;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* True if INPUT_SECTION might need overlay stubs.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
1.1.1.2  christos maybe_needs_stubs (asection *input_section)
    1.1     skrll {
    1.1     skrll   /* No stubs for debug sections and suchlike.  */
    1.1     skrll   if ((input_section->flags & SEC_ALLOC) == 0)
    1.1     skrll     return FALSE;
    1.1     skrll
    1.1     skrll   /* No stubs for link-once sections that will be discarded.  */
1.1.1.2  christos   if (input_section->output_section == bfd_abs_section_ptr)
    1.1     skrll     return FALSE;
    1.1     skrll
    1.1     skrll   /* Don't create stubs for .eh_frame references.  */
    1.1     skrll   if (strcmp (input_section->name, ".eh_frame") == 0)
    1.1     skrll     return FALSE;
    1.1     skrll
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll enum _stub_type
    1.1     skrll {
    1.1     skrll   no_stub,
1.1.1.2  christos   call_ovl_stub,
1.1.1.2  christos   br000_ovl_stub,
1.1.1.2  christos   br001_ovl_stub,
1.1.1.2  christos   br010_ovl_stub,
1.1.1.2  christos   br011_ovl_stub,
1.1.1.2  christos   br100_ovl_stub,
1.1.1.2  christos   br101_ovl_stub,
1.1.1.2  christos   br110_ovl_stub,
1.1.1.2  christos   br111_ovl_stub,
    1.1     skrll   nonovl_stub,
    1.1     skrll   stub_error
    1.1     skrll };
    1.1     skrll
    1.1     skrll /* Return non-zero if this reloc symbol should go via an overlay stub.
    1.1     skrll    Return 2 if the stub must be in non-overlay area.  */
    1.1     skrll
    1.1     skrll static enum _stub_type
    1.1     skrll needs_ovl_stub (struct elf_link_hash_entry *h,
    1.1     skrll 		Elf_Internal_Sym *sym,
    1.1     skrll 		asection *sym_sec,
    1.1     skrll 		asection *input_section,
    1.1     skrll 		Elf_Internal_Rela *irela,
    1.1     skrll 		bfd_byte *contents,
    1.1     skrll 		struct bfd_link_info *info)
    1.1     skrll {
    1.1     skrll   struct spu_link_hash_table *htab = spu_hash_table (info);
    1.1     skrll   enum elf_spu_reloc_type r_type;
    1.1     skrll   unsigned int sym_type;
1.1.1.2  christos   bfd_boolean branch, hint, call;
    1.1     skrll   enum _stub_type ret = no_stub;
1.1.1.2  christos   bfd_byte insn[4];
    1.1     skrll
    1.1     skrll   if (sym_sec == NULL
1.1.1.2  christos       || sym_sec->output_section == bfd_abs_section_ptr
    1.1     skrll       || spu_elf_section_data (sym_sec->output_section) == NULL)
    1.1     skrll     return ret;
    1.1     skrll
    1.1     skrll   if (h != NULL)
    1.1     skrll     {
    1.1     skrll       /* Ensure no stubs for user supplied overlay manager syms.  */
1.1.1.2  christos       if (h == htab->ovly_entry[0] || h == htab->ovly_entry[1])
    1.1     skrll 	return ret;
    1.1     skrll
    1.1     skrll       /* setjmp always goes via an overlay stub, because then the return
    1.1     skrll 	 and hence the longjmp goes via __ovly_return.  That magically
    1.1     skrll 	 makes setjmp/longjmp between overlays work.  */
    1.1     skrll       if (strncmp (h->root.root.string, "setjmp", 6) == 0
    1.1     skrll 	  && (h->root.root.string[6] == '\0' || h->root.root.string[6] == '@'))
1.1.1.2  christos 	ret = call_ovl_stub;
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   if (h != NULL)
    1.1     skrll     sym_type = h->type;
    1.1     skrll   else
    1.1     skrll     sym_type = ELF_ST_TYPE (sym->st_info);
    1.1     skrll
    1.1     skrll   r_type = ELF32_R_TYPE (irela->r_info);
    1.1     skrll   branch = FALSE;
1.1.1.2  christos   hint = FALSE;
1.1.1.2  christos   call = FALSE;
    1.1     skrll   if (r_type == R_SPU_REL16 || r_type == R_SPU_ADDR16)
    1.1     skrll     {
    1.1     skrll       if (contents == NULL)
    1.1     skrll 	{
    1.1     skrll 	  contents = insn;
    1.1     skrll 	  if (!bfd_get_section_contents (input_section->owner,
    1.1     skrll 					 input_section,
    1.1     skrll 					 contents,
    1.1     skrll 					 irela->r_offset, 4))
    1.1     skrll 	    return stub_error;
    1.1     skrll 	}
    1.1     skrll       else
    1.1     skrll 	contents += irela->r_offset;
    1.1     skrll
1.1.1.2  christos       branch = is_branch (contents);
1.1.1.2  christos       hint = is_hint (contents);
1.1.1.2  christos       if (branch || hint)
    1.1     skrll 	{
1.1.1.2  christos 	  call = (contents[0] & 0xfd) == 0x31;
1.1.1.2  christos 	  if (call
    1.1     skrll 	      && sym_type != STT_FUNC
    1.1     skrll 	      && contents != insn)
    1.1     skrll 	    {
    1.1     skrll 	      /* It's common for people to write assembly and forget
    1.1     skrll 		 to give function symbols the right type.  Handle
    1.1     skrll 		 calls to such symbols, but warn so that (hopefully)
    1.1     skrll 		 people will fix their code.  We need the symbol
    1.1     skrll 		 type to be correct to distinguish function pointer
    1.1     skrll 		 initialisation from other pointer initialisations.  */
    1.1     skrll 	      const char *sym_name;
    1.1     skrll
    1.1     skrll 	      if (h != NULL)
    1.1     skrll 		sym_name = h->root.root.string;
    1.1     skrll 	      else
    1.1     skrll 		{
    1.1     skrll 		  Elf_Internal_Shdr *symtab_hdr;
    1.1     skrll 		  symtab_hdr = &elf_tdata (input_section->owner)->symtab_hdr;
    1.1     skrll 		  sym_name = bfd_elf_sym_name (input_section->owner,
    1.1     skrll 					       symtab_hdr,
    1.1     skrll 					       sym,
    1.1     skrll 					       sym_sec);
    1.1     skrll 		}
    1.1     skrll 	      (*_bfd_error_handler) (_("warning: call to non-function"
    1.1     skrll 				       " symbol %s defined in %B"),
    1.1     skrll 				     sym_sec->owner, sym_name);
    1.1     skrll
    1.1     skrll 	    }
    1.1     skrll 	}
    1.1     skrll     }
    1.1     skrll
1.1.1.2  christos   if ((!branch && htab->params->ovly_flavour == ovly_soft_icache)
1.1.1.2  christos       || (sym_type != STT_FUNC
1.1.1.2  christos 	  && !(branch || hint)
1.1.1.2  christos 	  && (sym_sec->flags & SEC_CODE) == 0))
1.1.1.2  christos     return no_stub;
1.1.1.2  christos
1.1.1.2  christos   /* Usually, symbols in non-overlay sections don't need stubs.  */
1.1.1.2  christos   if (spu_elf_section_data (sym_sec->output_section)->u.o.ovl_index == 0
1.1.1.2  christos       && !htab->params->non_overlay_stubs)
    1.1     skrll     return ret;
    1.1     skrll
    1.1     skrll   /* A reference from some other section to a symbol in an overlay
    1.1     skrll      section needs a stub.  */
    1.1     skrll   if (spu_elf_section_data (sym_sec->output_section)->u.o.ovl_index
    1.1     skrll        != spu_elf_section_data (input_section->output_section)->u.o.ovl_index)
1.1.1.2  christos     {
1.1.1.2  christos       unsigned int lrlive = 0;
1.1.1.2  christos       if (branch)
1.1.1.2  christos 	lrlive = (contents[1] & 0x70) >> 4;
1.1.1.2  christos
1.1.1.2  christos       if (!lrlive && (call || sym_type == STT_FUNC))
1.1.1.2  christos 	ret = call_ovl_stub;
1.1.1.2  christos       else
1.1.1.2  christos 	ret = br000_ovl_stub + lrlive;
1.1.1.2  christos     }
    1.1     skrll
    1.1     skrll   /* If this insn isn't a branch then we are possibly taking the
1.1.1.2  christos      address of a function and passing it out somehow.  Soft-icache code
1.1.1.2  christos      always generates inline code to do indirect branches.  */
1.1.1.2  christos   if (!(branch || hint)
1.1.1.2  christos       && sym_type == STT_FUNC
1.1.1.2  christos       && htab->params->ovly_flavour != ovly_soft_icache)
1.1.1.2  christos     ret = nonovl_stub;
1.1.1.2  christos
1.1.1.2  christos   return ret;
    1.1     skrll }
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll count_stub (struct spu_link_hash_table *htab,
    1.1     skrll 	    bfd *ibfd,
    1.1     skrll 	    asection *isec,
    1.1     skrll 	    enum _stub_type stub_type,
    1.1     skrll 	    struct elf_link_hash_entry *h,
    1.1     skrll 	    const Elf_Internal_Rela *irela)
    1.1     skrll {
    1.1     skrll   unsigned int ovl = 0;
    1.1     skrll   struct got_entry *g, **head;
    1.1     skrll   bfd_vma addend;
    1.1     skrll
    1.1     skrll   /* If this instruction is a branch or call, we need a stub
    1.1     skrll      for it.  One stub per function per overlay.
    1.1     skrll      If it isn't a branch, then we are taking the address of
    1.1     skrll      this function so need a stub in the non-overlay area
    1.1     skrll      for it.  One stub per function.  */
    1.1     skrll   if (stub_type != nonovl_stub)
    1.1     skrll     ovl = spu_elf_section_data (isec->output_section)->u.o.ovl_index;
    1.1     skrll
    1.1     skrll   if (h != NULL)
    1.1     skrll     head = &h->got.glist;
    1.1     skrll   else
    1.1     skrll     {
    1.1     skrll       if (elf_local_got_ents (ibfd) == NULL)
    1.1     skrll 	{
    1.1     skrll 	  bfd_size_type amt = (elf_tdata (ibfd)->symtab_hdr.sh_info
    1.1     skrll 			       * sizeof (*elf_local_got_ents (ibfd)));
    1.1     skrll 	  elf_local_got_ents (ibfd) = bfd_zmalloc (amt);
    1.1     skrll 	  if (elf_local_got_ents (ibfd) == NULL)
    1.1     skrll 	    return FALSE;
    1.1     skrll 	}
    1.1     skrll       head = elf_local_got_ents (ibfd) + ELF32_R_SYM (irela->r_info);
    1.1     skrll     }
    1.1     skrll
1.1.1.2  christos   if (htab->params->ovly_flavour == ovly_soft_icache)
1.1.1.2  christos     {
1.1.1.2  christos       htab->stub_count[ovl] += 1;
1.1.1.2  christos       return TRUE;
1.1.1.2  christos     }
1.1.1.2  christos
    1.1     skrll   addend = 0;
    1.1     skrll   if (irela != NULL)
    1.1     skrll     addend = irela->r_addend;
    1.1     skrll
    1.1     skrll   if (ovl == 0)
    1.1     skrll     {
    1.1     skrll       struct got_entry *gnext;
    1.1     skrll
    1.1     skrll       for (g = *head; g != NULL; g = g->next)
    1.1     skrll 	if (g->addend == addend && g->ovl == 0)
    1.1     skrll 	  break;
    1.1     skrll
    1.1     skrll       if (g == NULL)
    1.1     skrll 	{
    1.1     skrll 	  /* Need a new non-overlay area stub.  Zap other stubs.  */
    1.1     skrll 	  for (g = *head; g != NULL; g = gnext)
    1.1     skrll 	    {
    1.1     skrll 	      gnext = g->next;
    1.1     skrll 	      if (g->addend == addend)
    1.1     skrll 		{
    1.1     skrll 		  htab->stub_count[g->ovl] -= 1;
    1.1     skrll 		  free (g);
    1.1     skrll 		}
    1.1     skrll 	    }
    1.1     skrll 	}
    1.1     skrll     }
    1.1     skrll   else
    1.1     skrll     {
    1.1     skrll       for (g = *head; g != NULL; g = g->next)
    1.1     skrll 	if (g->addend == addend && (g->ovl == ovl || g->ovl == 0))
    1.1     skrll 	  break;
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   if (g == NULL)
    1.1     skrll     {
    1.1     skrll       g = bfd_malloc (sizeof *g);
    1.1     skrll       if (g == NULL)
    1.1     skrll 	return FALSE;
    1.1     skrll       g->ovl = ovl;
    1.1     skrll       g->addend = addend;
    1.1     skrll       g->stub_addr = (bfd_vma) -1;
    1.1     skrll       g->next = *head;
    1.1     skrll       *head = g;
    1.1     skrll
    1.1     skrll       htab->stub_count[ovl] += 1;
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
1.1.1.2  christos /* Support two sizes of overlay stubs, a slower more compact stub of two
1.1.1.4  christos    instructions, and a faster stub of four instructions.
1.1.1.2  christos    Soft-icache stubs are four or eight words.  */
1.1.1.2  christos
1.1.1.2  christos static unsigned int
1.1.1.2  christos ovl_stub_size (struct spu_elf_params *params)
1.1.1.2  christos {
1.1.1.2  christos   return 16 << params->ovly_flavour >> params->compact_stub;
1.1.1.2  christos }
1.1.1.2  christos
1.1.1.2  christos static unsigned int
1.1.1.2  christos ovl_stub_size_log2 (struct spu_elf_params *params)
1.1.1.2  christos {
1.1.1.2  christos   return 4 + params->ovly_flavour - params->compact_stub;
1.1.1.2  christos }
1.1.1.2  christos
    1.1     skrll /* Two instruction overlay stubs look like:
    1.1     skrll
    1.1     skrll    brsl $75,__ovly_load
    1.1     skrll    .word target_ovl_and_address
    1.1     skrll
    1.1     skrll    ovl_and_address is a word with the overlay number in the top 14 bits
    1.1     skrll    and local store address in the bottom 18 bits.
    1.1     skrll
    1.1     skrll    Four instruction overlay stubs look like:
    1.1     skrll
    1.1     skrll    ila $78,ovl_number
    1.1     skrll    lnop
    1.1     skrll    ila $79,target_address
1.1.1.2  christos    br __ovly_load
1.1.1.2  christos
1.1.1.2  christos    Software icache stubs are:
1.1.1.2  christos
1.1.1.2  christos    .word target_index
1.1.1.2  christos    .word target_ia;
1.1.1.2  christos    .word lrlive_branchlocalstoreaddr;
1.1.1.2  christos    brasl $75,__icache_br_handler
1.1.1.2  christos    .quad xor_pattern
1.1.1.2  christos */
    1.1     skrll
    1.1     skrll static bfd_boolean
1.1.1.2  christos build_stub (struct bfd_link_info *info,
    1.1     skrll 	    bfd *ibfd,
    1.1     skrll 	    asection *isec,
    1.1     skrll 	    enum _stub_type stub_type,
    1.1     skrll 	    struct elf_link_hash_entry *h,
    1.1     skrll 	    const Elf_Internal_Rela *irela,
    1.1     skrll 	    bfd_vma dest,
    1.1     skrll 	    asection *dest_sec)
    1.1     skrll {
1.1.1.2  christos   struct spu_link_hash_table *htab = spu_hash_table (info);
1.1.1.2  christos   unsigned int ovl, dest_ovl, set_id;
    1.1     skrll   struct got_entry *g, **head;
    1.1     skrll   asection *sec;
1.1.1.2  christos   bfd_vma addend, from, to, br_dest, patt;
1.1.1.2  christos   unsigned int lrlive;
    1.1     skrll
    1.1     skrll   ovl = 0;
    1.1     skrll   if (stub_type != nonovl_stub)
    1.1     skrll     ovl = spu_elf_section_data (isec->output_section)->u.o.ovl_index;
    1.1     skrll
    1.1     skrll   if (h != NULL)
    1.1     skrll     head = &h->got.glist;
    1.1     skrll   else
    1.1     skrll     head = elf_local_got_ents (ibfd) + ELF32_R_SYM (irela->r_info);
    1.1     skrll
    1.1     skrll   addend = 0;
    1.1     skrll   if (irela != NULL)
    1.1     skrll     addend = irela->r_addend;
    1.1     skrll
1.1.1.2  christos   if (htab->params->ovly_flavour == ovly_soft_icache)
1.1.1.2  christos     {
1.1.1.2  christos       g = bfd_malloc (sizeof *g);
1.1.1.2  christos       if (g == NULL)
1.1.1.2  christos 	return FALSE;
1.1.1.2  christos       g->ovl = ovl;
1.1.1.2  christos       g->br_addr = 0;
1.1.1.2  christos       if (irela != NULL)
1.1.1.2  christos 	g->br_addr = (irela->r_offset
1.1.1.2  christos 		      + isec->output_offset
1.1.1.2  christos 		      + isec->output_section->vma);
1.1.1.2  christos       g->next = *head;
1.1.1.2  christos       *head = g;
1.1.1.2  christos     }
1.1.1.2  christos   else
1.1.1.2  christos     {
1.1.1.2  christos       for (g = *head; g != NULL; g = g->next)
1.1.1.2  christos 	if (g->addend == addend && (g->ovl == ovl || g->ovl == 0))
1.1.1.2  christos 	  break;
1.1.1.2  christos       if (g == NULL)
1.1.1.2  christos 	abort ();
    1.1     skrll
1.1.1.2  christos       if (g->ovl == 0 && ovl != 0)
1.1.1.2  christos 	return TRUE;
    1.1     skrll
1.1.1.2  christos       if (g->stub_addr != (bfd_vma) -1)
1.1.1.2  christos 	return TRUE;
1.1.1.2  christos     }
    1.1     skrll
    1.1     skrll   sec = htab->stub_sec[ovl];
    1.1     skrll   dest += dest_sec->output_offset + dest_sec->output_section->vma;
    1.1     skrll   from = sec->size + sec->output_offset + sec->output_section->vma;
    1.1     skrll   g->stub_addr = from;
1.1.1.2  christos   to = (htab->ovly_entry[0]->root.u.def.value
1.1.1.2  christos 	+ htab->ovly_entry[0]->root.u.def.section->output_offset
1.1.1.2  christos 	+ htab->ovly_entry[0]->root.u.def.section->output_section->vma);
1.1.1.2  christos
1.1.1.2  christos   if (((dest | to | from) & 3) != 0)
    1.1     skrll     {
    1.1     skrll       htab->stub_err = 1;
    1.1     skrll       return FALSE;
    1.1     skrll     }
1.1.1.2  christos   dest_ovl = spu_elf_section_data (dest_sec->output_section)->u.o.ovl_index;
    1.1     skrll
1.1.1.2  christos   if (htab->params->ovly_flavour == ovly_normal
1.1.1.2  christos       && !htab->params->compact_stub)
    1.1     skrll     {
1.1.1.2  christos       bfd_put_32 (sec->owner, ILA + ((dest_ovl << 7) & 0x01ffff80) + 78,
    1.1     skrll 		  sec->contents + sec->size);
    1.1     skrll       bfd_put_32 (sec->owner, LNOP,
    1.1     skrll 		  sec->contents + sec->size + 4);
    1.1     skrll       bfd_put_32 (sec->owner, ILA + ((dest << 7) & 0x01ffff80) + 79,
    1.1     skrll 		  sec->contents + sec->size + 8);
1.1.1.2  christos       if (!BRA_STUBS)
1.1.1.2  christos 	bfd_put_32 (sec->owner, BR + (((to - (from + 12)) << 5) & 0x007fff80),
1.1.1.2  christos 		    sec->contents + sec->size + 12);
1.1.1.2  christos       else
1.1.1.2  christos 	bfd_put_32 (sec->owner, BRA + ((to << 5) & 0x007fff80),
1.1.1.2  christos 		    sec->contents + sec->size + 12);
    1.1     skrll     }
1.1.1.2  christos   else if (htab->params->ovly_flavour == ovly_normal
1.1.1.2  christos 	   && htab->params->compact_stub)
    1.1     skrll     {
1.1.1.2  christos       if (!BRA_STUBS)
1.1.1.2  christos 	bfd_put_32 (sec->owner, BRSL + (((to - from) << 5) & 0x007fff80) + 75,
1.1.1.2  christos 		    sec->contents + sec->size);
1.1.1.2  christos       else
1.1.1.2  christos 	bfd_put_32 (sec->owner, BRASL + ((to << 5) & 0x007fff80) + 75,
1.1.1.2  christos 		    sec->contents + sec->size);
1.1.1.2  christos       bfd_put_32 (sec->owner, (dest & 0x3ffff) | (dest_ovl << 18),
1.1.1.2  christos 		  sec->contents + sec->size + 4);
1.1.1.2  christos     }
1.1.1.2  christos   else if (htab->params->ovly_flavour == ovly_soft_icache
1.1.1.2  christos 	   && htab->params->compact_stub)
1.1.1.2  christos     {
1.1.1.2  christos       lrlive = 0;
1.1.1.2  christos       if (stub_type == nonovl_stub)
1.1.1.2  christos 	;
1.1.1.2  christos       else if (stub_type == call_ovl_stub)
1.1.1.2  christos 	/* A brsl makes lr live and *(*sp+16) is live.
1.1.1.2  christos 	   Tail calls have the same liveness.  */
1.1.1.2  christos 	lrlive = 5;
1.1.1.2  christos       else if (!htab->params->lrlive_analysis)
1.1.1.2  christos 	/* Assume stack frame and lr save.  */
1.1.1.2  christos 	lrlive = 1;
1.1.1.2  christos       else if (irela != NULL)
1.1.1.2  christos 	{
1.1.1.2  christos 	  /* Analyse branch instructions.  */
1.1.1.2  christos 	  struct function_info *caller;
1.1.1.2  christos 	  bfd_vma off;
1.1.1.2  christos
1.1.1.2  christos 	  caller = find_function (isec, irela->r_offset, info);
1.1.1.2  christos 	  if (caller->start == NULL)
1.1.1.2  christos 	    off = irela->r_offset;
1.1.1.2  christos 	  else
1.1.1.2  christos 	    {
1.1.1.2  christos 	      struct function_info *found = NULL;
1.1.1.2  christos
1.1.1.2  christos 	      /* Find the earliest piece of this function that
1.1.1.2  christos 		 has frame adjusting instructions.  We might
1.1.1.2  christos 		 see dynamic frame adjustment (eg. for alloca)
1.1.1.2  christos 		 in some later piece, but functions using
1.1.1.2  christos 		 alloca always set up a frame earlier.  Frame
1.1.1.2  christos 		 setup instructions are always in one piece.  */
1.1.1.2  christos 	      if (caller->lr_store != (bfd_vma) -1
1.1.1.2  christos 		  || caller->sp_adjust != (bfd_vma) -1)
1.1.1.2  christos 		found = caller;
1.1.1.2  christos 	      while (caller->start != NULL)
1.1.1.2  christos 		{
1.1.1.2  christos 		  caller = caller->start;
1.1.1.2  christos 		  if (caller->lr_store != (bfd_vma) -1
1.1.1.2  christos 		      || caller->sp_adjust != (bfd_vma) -1)
1.1.1.2  christos 		    found = caller;
1.1.1.2  christos 		}
1.1.1.2  christos 	      if (found != NULL)
1.1.1.2  christos 		caller = found;
1.1.1.2  christos 	      off = (bfd_vma) -1;
1.1.1.2  christos 	    }
1.1.1.2  christos
1.1.1.2  christos 	  if (off > caller->sp_adjust)
1.1.1.2  christos 	    {
1.1.1.2  christos 	      if (off > caller->lr_store)
1.1.1.2  christos 		/* Only *(*sp+16) is live.  */
1.1.1.2  christos 		lrlive = 1;
1.1.1.2  christos 	      else
1.1.1.2  christos 		/* If no lr save, then we must be in a
1.1.1.2  christos 		   leaf function with a frame.
1.1.1.2  christos 		   lr is still live.  */
1.1.1.2  christos 		lrlive = 4;
1.1.1.2  christos 	    }
1.1.1.2  christos 	  else if (off > caller->lr_store)
1.1.1.2  christos 	    {
1.1.1.2  christos 	      /* Between lr save and stack adjust.  */
1.1.1.2  christos 	      lrlive = 3;
1.1.1.2  christos 	      /* This should never happen since prologues won't
1.1.1.2  christos 		 be split here.  */
1.1.1.2  christos 	      BFD_ASSERT (0);
1.1.1.2  christos 	    }
1.1.1.2  christos 	  else
1.1.1.2  christos 	    /* On entry to function.  */
1.1.1.2  christos 	    lrlive = 5;
1.1.1.2  christos
1.1.1.2  christos 	  if (stub_type != br000_ovl_stub
1.1.1.2  christos 	      && lrlive != stub_type - br000_ovl_stub)
1.1.1.2  christos 	    info->callbacks->einfo (_("%A:0x%v lrlive .brinfo (%u) differs "
1.1.1.2  christos 				      "from analysis (%u)\n"),
1.1.1.2  christos 				    isec, irela->r_offset, lrlive,
1.1.1.2  christos 				    stub_type - br000_ovl_stub);
1.1.1.2  christos 	}
1.1.1.2  christos
1.1.1.2  christos       /* If given lrlive info via .brinfo, use it.  */
1.1.1.2  christos       if (stub_type > br000_ovl_stub)
1.1.1.2  christos 	lrlive = stub_type - br000_ovl_stub;
1.1.1.2  christos
1.1.1.2  christos       if (ovl == 0)
1.1.1.2  christos 	to = (htab->ovly_entry[1]->root.u.def.value
1.1.1.2  christos 	      + htab->ovly_entry[1]->root.u.def.section->output_offset
1.1.1.2  christos 	      + htab->ovly_entry[1]->root.u.def.section->output_section->vma);
1.1.1.2  christos
1.1.1.2  christos       /* The branch that uses this stub goes to stub_addr + 4.  We'll
1.1.1.2  christos 	 set up an xor pattern that can be used by the icache manager
1.1.1.2  christos 	 to modify this branch to go directly to its destination.  */
1.1.1.2  christos       g->stub_addr += 4;
1.1.1.2  christos       br_dest = g->stub_addr;
1.1.1.2  christos       if (irela == NULL)
1.1.1.2  christos 	{
1.1.1.2  christos 	  /* Except in the case of _SPUEAR_ stubs, the branch in
1.1.1.2  christos 	     question is the one in the stub itself.  */
1.1.1.2  christos 	  BFD_ASSERT (stub_type == nonovl_stub);
1.1.1.2  christos 	  g->br_addr = g->stub_addr;
1.1.1.2  christos 	  br_dest = to;
1.1.1.2  christos 	}
    1.1     skrll
1.1.1.2  christos       set_id = ((dest_ovl - 1) >> htab->num_lines_log2) + 1;
1.1.1.2  christos       bfd_put_32 (sec->owner, (set_id << 18) | (dest & 0x3ffff),
1.1.1.2  christos 		  sec->contents + sec->size);
1.1.1.2  christos       bfd_put_32 (sec->owner, BRASL + ((to << 5) & 0x007fff80) + 75,
    1.1     skrll 		  sec->contents + sec->size + 4);
1.1.1.2  christos       bfd_put_32 (sec->owner, (lrlive << 29) | (g->br_addr & 0x3ffff),
1.1.1.2  christos 		  sec->contents + sec->size + 8);
1.1.1.2  christos       patt = dest ^ br_dest;
1.1.1.2  christos       if (irela != NULL && ELF32_R_TYPE (irela->r_info) == R_SPU_REL16)
1.1.1.2  christos 	patt = (dest - g->br_addr) ^ (br_dest - g->br_addr);
1.1.1.2  christos       bfd_put_32 (sec->owner, (patt << 5) & 0x007fff80,
1.1.1.2  christos 		  sec->contents + sec->size + 12);
1.1.1.2  christos
1.1.1.2  christos       if (ovl == 0)
1.1.1.2  christos 	/* Extra space for linked list entries.  */
1.1.1.2  christos 	sec->size += 16;
    1.1     skrll     }
    1.1     skrll   else
    1.1     skrll     abort ();
    1.1     skrll
1.1.1.2  christos   sec->size += ovl_stub_size (htab->params);
1.1.1.2  christos
1.1.1.2  christos   if (htab->params->emit_stub_syms)
    1.1     skrll     {
    1.1     skrll       size_t len;
    1.1     skrll       char *name;
    1.1     skrll       int add;
    1.1     skrll
    1.1     skrll       len = 8 + sizeof (".ovl_call.") - 1;
    1.1     skrll       if (h != NULL)
    1.1     skrll 	len += strlen (h->root.root.string);
    1.1     skrll       else
    1.1     skrll 	len += 8 + 1 + 8;
    1.1     skrll       add = 0;
    1.1     skrll       if (irela != NULL)
    1.1     skrll 	add = (int) irela->r_addend & 0xffffffff;
    1.1     skrll       if (add != 0)
    1.1     skrll 	len += 1 + 8;
1.1.1.3  christos       name = bfd_malloc (len + 1);
    1.1     skrll       if (name == NULL)
    1.1     skrll 	return FALSE;
    1.1     skrll
    1.1     skrll       sprintf (name, "%08x.ovl_call.", g->ovl);
    1.1     skrll       if (h != NULL)
    1.1     skrll 	strcpy (name + 8 + sizeof (".ovl_call.") - 1, h->root.root.string);
    1.1     skrll       else
    1.1     skrll 	sprintf (name + 8 + sizeof (".ovl_call.") - 1, "%x:%x",
    1.1     skrll 		 dest_sec->id & 0xffffffff,
    1.1     skrll 		 (int) ELF32_R_SYM (irela->r_info) & 0xffffffff);
    1.1     skrll       if (add != 0)
    1.1     skrll 	sprintf (name + len - 9, "+%x", add);
    1.1     skrll
    1.1     skrll       h = elf_link_hash_lookup (&htab->elf, name, TRUE, TRUE, FALSE);
    1.1     skrll       free (name);
    1.1     skrll       if (h == NULL)
    1.1     skrll 	return FALSE;
    1.1     skrll       if (h->root.type == bfd_link_hash_new)
    1.1     skrll 	{
    1.1     skrll 	  h->root.type = bfd_link_hash_defined;
    1.1     skrll 	  h->root.u.def.section = sec;
1.1.1.2  christos 	  h->size = ovl_stub_size (htab->params);
1.1.1.2  christos 	  h->root.u.def.value = sec->size - h->size;
    1.1     skrll 	  h->type = STT_FUNC;
    1.1     skrll 	  h->ref_regular = 1;
    1.1     skrll 	  h->def_regular = 1;
    1.1     skrll 	  h->ref_regular_nonweak = 1;
    1.1     skrll 	  h->forced_local = 1;
    1.1     skrll 	  h->non_elf = 0;
    1.1     skrll 	}
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Called via elf_link_hash_traverse to allocate stubs for any _SPUEAR_
    1.1     skrll    symbols.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll allocate_spuear_stubs (struct elf_link_hash_entry *h, void *inf)
    1.1     skrll {
    1.1     skrll   /* Symbols starting with _SPUEAR_ need a stub because they may be
    1.1     skrll      invoked by the PPU.  */
    1.1     skrll   struct bfd_link_info *info = inf;
    1.1     skrll   struct spu_link_hash_table *htab = spu_hash_table (info);
    1.1     skrll   asection *sym_sec;
    1.1     skrll
    1.1     skrll   if ((h->root.type == bfd_link_hash_defined
    1.1     skrll        || h->root.type == bfd_link_hash_defweak)
    1.1     skrll       && h->def_regular
    1.1     skrll       && strncmp (h->root.root.string, "_SPUEAR_", 8) == 0
    1.1     skrll       && (sym_sec = h->root.u.def.section) != NULL
1.1.1.2  christos       && sym_sec->output_section != bfd_abs_section_ptr
    1.1     skrll       && spu_elf_section_data (sym_sec->output_section) != NULL
    1.1     skrll       && (spu_elf_section_data (sym_sec->output_section)->u.o.ovl_index != 0
1.1.1.2  christos 	  || htab->params->non_overlay_stubs))
    1.1     skrll     {
    1.1     skrll       return count_stub (htab, NULL, NULL, nonovl_stub, h, NULL);
    1.1     skrll     }
1.1.1.4  christos
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll build_spuear_stubs (struct elf_link_hash_entry *h, void *inf)
    1.1     skrll {
    1.1     skrll   /* Symbols starting with _SPUEAR_ need a stub because they may be
    1.1     skrll      invoked by the PPU.  */
    1.1     skrll   struct bfd_link_info *info = inf;
    1.1     skrll   struct spu_link_hash_table *htab = spu_hash_table (info);
    1.1     skrll   asection *sym_sec;
    1.1     skrll
    1.1     skrll   if ((h->root.type == bfd_link_hash_defined
    1.1     skrll        || h->root.type == bfd_link_hash_defweak)
    1.1     skrll       && h->def_regular
    1.1     skrll       && strncmp (h->root.root.string, "_SPUEAR_", 8) == 0
    1.1     skrll       && (sym_sec = h->root.u.def.section) != NULL
1.1.1.2  christos       && sym_sec->output_section != bfd_abs_section_ptr
    1.1     skrll       && spu_elf_section_data (sym_sec->output_section) != NULL
    1.1     skrll       && (spu_elf_section_data (sym_sec->output_section)->u.o.ovl_index != 0
1.1.1.2  christos 	  || htab->params->non_overlay_stubs))
    1.1     skrll     {
1.1.1.2  christos       return build_stub (info, NULL, NULL, nonovl_stub, h, NULL,
    1.1     skrll 			 h->root.u.def.value, sym_sec);
    1.1     skrll     }
1.1.1.4  christos
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Size or build stubs.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll process_stubs (struct bfd_link_info *info, bfd_boolean build)
    1.1     skrll {
    1.1     skrll   struct spu_link_hash_table *htab = spu_hash_table (info);
    1.1     skrll   bfd *ibfd;
    1.1     skrll
1.1.1.4  christos   for (ibfd = info->input_bfds; ibfd != NULL; ibfd = ibfd->link.next)
    1.1     skrll     {
1.1.1.4  christos       extern const bfd_target spu_elf32_vec;
    1.1     skrll       Elf_Internal_Shdr *symtab_hdr;
    1.1     skrll       asection *isec;
    1.1     skrll       Elf_Internal_Sym *local_syms = NULL;
    1.1     skrll
1.1.1.4  christos       if (ibfd->xvec != &spu_elf32_vec)
    1.1     skrll 	continue;
    1.1     skrll
    1.1     skrll       /* We'll need the symbol table in a second.  */
    1.1     skrll       symtab_hdr = &elf_tdata (ibfd)->symtab_hdr;
    1.1     skrll       if (symtab_hdr->sh_info == 0)
    1.1     skrll 	continue;
    1.1     skrll
    1.1     skrll       /* Walk over each section attached to the input bfd.  */
    1.1     skrll       for (isec = ibfd->sections; isec != NULL; isec = isec->next)
    1.1     skrll 	{
    1.1     skrll 	  Elf_Internal_Rela *internal_relocs, *irelaend, *irela;
    1.1     skrll
    1.1     skrll 	  /* If there aren't any relocs, then there's nothing more to do.  */
    1.1     skrll 	  if ((isec->flags & SEC_RELOC) == 0
    1.1     skrll 	      || isec->reloc_count == 0)
    1.1     skrll 	    continue;
    1.1     skrll
1.1.1.2  christos 	  if (!maybe_needs_stubs (isec))
    1.1     skrll 	    continue;
    1.1     skrll
    1.1     skrll 	  /* Get the relocs.  */
    1.1     skrll 	  internal_relocs = _bfd_elf_link_read_relocs (ibfd, isec, NULL, NULL,
    1.1     skrll 						       info->keep_memory);
    1.1     skrll 	  if (internal_relocs == NULL)
    1.1     skrll 	    goto error_ret_free_local;
    1.1     skrll
    1.1     skrll 	  /* Now examine each relocation.  */
    1.1     skrll 	  irela = internal_relocs;
    1.1     skrll 	  irelaend = irela + isec->reloc_count;
    1.1     skrll 	  for (; irela < irelaend; irela++)
    1.1     skrll 	    {
    1.1     skrll 	      enum elf_spu_reloc_type r_type;
    1.1     skrll 	      unsigned int r_indx;
    1.1     skrll 	      asection *sym_sec;
    1.1     skrll 	      Elf_Internal_Sym *sym;
    1.1     skrll 	      struct elf_link_hash_entry *h;
    1.1     skrll 	      enum _stub_type stub_type;
    1.1     skrll
    1.1     skrll 	      r_type = ELF32_R_TYPE (irela->r_info);
    1.1     skrll 	      r_indx = ELF32_R_SYM (irela->r_info);
    1.1     skrll
    1.1     skrll 	      if (r_type >= R_SPU_max)
    1.1     skrll 		{
    1.1     skrll 		  bfd_set_error (bfd_error_bad_value);
    1.1     skrll 		error_ret_free_internal:
    1.1     skrll 		  if (elf_section_data (isec)->relocs != internal_relocs)
    1.1     skrll 		    free (internal_relocs);
    1.1     skrll 		error_ret_free_local:
    1.1     skrll 		  if (local_syms != NULL
    1.1     skrll 		      && (symtab_hdr->contents
    1.1     skrll 			  != (unsigned char *) local_syms))
    1.1     skrll 		    free (local_syms);
    1.1     skrll 		  return FALSE;
    1.1     skrll 		}
    1.1     skrll
    1.1     skrll 	      /* Determine the reloc target section.  */
    1.1     skrll 	      if (!get_sym_h (&h, &sym, &sym_sec, &local_syms, r_indx, ibfd))
    1.1     skrll 		goto error_ret_free_internal;
    1.1     skrll
    1.1     skrll 	      stub_type = needs_ovl_stub (h, sym, sym_sec, isec, irela,
    1.1     skrll 					  NULL, info);
    1.1     skrll 	      if (stub_type == no_stub)
    1.1     skrll 		continue;
    1.1     skrll 	      else if (stub_type == stub_error)
    1.1     skrll 		goto error_ret_free_internal;
    1.1     skrll
    1.1     skrll 	      if (htab->stub_count == NULL)
    1.1     skrll 		{
    1.1     skrll 		  bfd_size_type amt;
    1.1     skrll 		  amt = (htab->num_overlays + 1) * sizeof (*htab->stub_count);
    1.1     skrll 		  htab->stub_count = bfd_zmalloc (amt);
    1.1     skrll 		  if (htab->stub_count == NULL)
    1.1     skrll 		    goto error_ret_free_internal;
    1.1     skrll 		}
    1.1     skrll
    1.1     skrll 	      if (!build)
    1.1     skrll 		{
    1.1     skrll 		  if (!count_stub (htab, ibfd, isec, stub_type, h, irela))
    1.1     skrll 		    goto error_ret_free_internal;
    1.1     skrll 		}
    1.1     skrll 	      else
    1.1     skrll 		{
    1.1     skrll 		  bfd_vma dest;
    1.1     skrll
    1.1     skrll 		  if (h != NULL)
    1.1     skrll 		    dest = h->root.u.def.value;
    1.1     skrll 		  else
    1.1     skrll 		    dest = sym->st_value;
    1.1     skrll 		  dest += irela->r_addend;
1.1.1.2  christos 		  if (!build_stub (info, ibfd, isec, stub_type, h, irela,
    1.1     skrll 				   dest, sym_sec))
    1.1     skrll 		    goto error_ret_free_internal;
    1.1     skrll 		}
    1.1     skrll 	    }
    1.1     skrll
    1.1     skrll 	  /* We're done with the internal relocs, free them.  */
    1.1     skrll 	  if (elf_section_data (isec)->relocs != internal_relocs)
    1.1     skrll 	    free (internal_relocs);
    1.1     skrll 	}
    1.1     skrll
    1.1     skrll       if (local_syms != NULL
    1.1     skrll 	  && symtab_hdr->contents != (unsigned char *) local_syms)
    1.1     skrll 	{
    1.1     skrll 	  if (!info->keep_memory)
    1.1     skrll 	    free (local_syms);
    1.1     skrll 	  else
    1.1     skrll 	    symtab_hdr->contents = (unsigned char *) local_syms;
    1.1     skrll 	}
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
1.1.1.2  christos /* Allocate space for overlay call and return stubs.
1.1.1.2  christos    Return 0 on error, 1 if no overlays, 2 otherwise.  */
    1.1     skrll
    1.1     skrll int
1.1.1.2  christos spu_elf_size_stubs (struct bfd_link_info *info)
    1.1     skrll {
1.1.1.2  christos   struct spu_link_hash_table *htab;
    1.1     skrll   bfd *ibfd;
    1.1     skrll   bfd_size_type amt;
    1.1     skrll   flagword flags;
    1.1     skrll   unsigned int i;
    1.1     skrll   asection *stub;
    1.1     skrll
    1.1     skrll   if (!process_stubs (info, FALSE))
    1.1     skrll     return 0;
    1.1     skrll
1.1.1.2  christos   htab = spu_hash_table (info);
    1.1     skrll   elf_link_hash_traverse (&htab->elf, allocate_spuear_stubs, info);
    1.1     skrll   if (htab->stub_err)
    1.1     skrll     return 0;
    1.1     skrll
    1.1     skrll   ibfd = info->input_bfds;
1.1.1.2  christos   if (htab->stub_count != NULL)
    1.1     skrll     {
1.1.1.2  christos       amt = (htab->num_overlays + 1) * sizeof (*htab->stub_sec);
1.1.1.2  christos       htab->stub_sec = bfd_zmalloc (amt);
1.1.1.2  christos       if (htab->stub_sec == NULL)
1.1.1.2  christos 	return 0;
1.1.1.2  christos
1.1.1.2  christos       flags = (SEC_ALLOC | SEC_LOAD | SEC_CODE | SEC_READONLY
1.1.1.2  christos 	       | SEC_HAS_CONTENTS | SEC_IN_MEMORY);
    1.1     skrll       stub = bfd_make_section_anyway_with_flags (ibfd, ".stub", flags);
1.1.1.2  christos       htab->stub_sec[0] = stub;
    1.1     skrll       if (stub == NULL
1.1.1.2  christos 	  || !bfd_set_section_alignment (ibfd, stub,
1.1.1.2  christos 					 ovl_stub_size_log2 (htab->params)))
    1.1     skrll 	return 0;
1.1.1.2  christos       stub->size = htab->stub_count[0] * ovl_stub_size (htab->params);
1.1.1.2  christos       if (htab->params->ovly_flavour == ovly_soft_icache)
1.1.1.2  christos 	/* Extra space for linked list entries.  */
1.1.1.2  christos 	stub->size += htab->stub_count[0] * 16;
1.1.1.2  christos
1.1.1.2  christos       for (i = 0; i < htab->num_overlays; ++i)
1.1.1.2  christos 	{
1.1.1.2  christos 	  asection *osec = htab->ovl_sec[i];
1.1.1.2  christos 	  unsigned int ovl = spu_elf_section_data (osec)->u.o.ovl_index;
1.1.1.2  christos 	  stub = bfd_make_section_anyway_with_flags (ibfd, ".stub", flags);
1.1.1.2  christos 	  htab->stub_sec[ovl] = stub;
1.1.1.2  christos 	  if (stub == NULL
1.1.1.2  christos 	      || !bfd_set_section_alignment (ibfd, stub,
1.1.1.2  christos 					     ovl_stub_size_log2 (htab->params)))
1.1.1.2  christos 	    return 0;
1.1.1.2  christos 	  stub->size = htab->stub_count[ovl] * ovl_stub_size (htab->params);
1.1.1.2  christos 	}
    1.1     skrll     }
    1.1     skrll
1.1.1.2  christos   if (htab->params->ovly_flavour == ovly_soft_icache)
1.1.1.2  christos     {
1.1.1.2  christos       /* Space for icache manager tables.
1.1.1.2  christos 	 a) Tag array, one quadword per cache line.
1.1.1.2  christos 	 b) Rewrite "to" list, one quadword per cache line.
1.1.1.2  christos 	 c) Rewrite "from" list, one byte per outgoing branch (rounded up to
1.1.1.2  christos 	    a power-of-two number of full quadwords) per cache line.  */
1.1.1.2  christos
1.1.1.2  christos       flags = SEC_ALLOC;
1.1.1.2  christos       htab->ovtab = bfd_make_section_anyway_with_flags (ibfd, ".ovtab", flags);
1.1.1.2  christos       if (htab->ovtab == NULL
1.1.1.2  christos 	  || !bfd_set_section_alignment (ibfd, htab->ovtab, 4))
1.1.1.2  christos 	return 0;
1.1.1.2  christos
1.1.1.2  christos       htab->ovtab->size = (16 + 16 + (16 << htab->fromelem_size_log2))
1.1.1.2  christos 			  << htab->num_lines_log2;
    1.1     skrll
1.1.1.2  christos       flags = SEC_ALLOC | SEC_LOAD | SEC_HAS_CONTENTS | SEC_IN_MEMORY;
1.1.1.2  christos       htab->init = bfd_make_section_anyway_with_flags (ibfd, ".ovini", flags);
1.1.1.2  christos       if (htab->init == NULL
1.1.1.2  christos 	  || !bfd_set_section_alignment (ibfd, htab->init, 4))
1.1.1.2  christos 	return 0;
1.1.1.2  christos
1.1.1.2  christos       htab->init->size = 16;
1.1.1.2  christos     }
1.1.1.2  christos   else if (htab->stub_count == NULL)
1.1.1.2  christos     return 1;
1.1.1.2  christos   else
1.1.1.2  christos     {
1.1.1.2  christos       /* htab->ovtab consists of two arrays.
1.1.1.2  christos 	 .	struct {
1.1.1.2  christos 	 .	  u32 vma;
1.1.1.2  christos 	 .	  u32 size;
1.1.1.2  christos 	 .	  u32 file_off;
1.1.1.2  christos 	 .	  u32 buf;
1.1.1.2  christos 	 .	} _ovly_table[];
1.1.1.2  christos 	 .
1.1.1.2  christos 	 .	struct {
1.1.1.2  christos 	 .	  u32 mapped;
1.1.1.2  christos 	 .	} _ovly_buf_table[];
1.1.1.2  christos 	 .  */
1.1.1.2  christos
1.1.1.2  christos       flags = SEC_ALLOC | SEC_LOAD | SEC_HAS_CONTENTS | SEC_IN_MEMORY;
1.1.1.2  christos       htab->ovtab = bfd_make_section_anyway_with_flags (ibfd, ".ovtab", flags);
1.1.1.2  christos       if (htab->ovtab == NULL
1.1.1.2  christos 	  || !bfd_set_section_alignment (ibfd, htab->ovtab, 4))
1.1.1.2  christos 	return 0;
1.1.1.2  christos
1.1.1.2  christos       htab->ovtab->size = htab->num_overlays * 16 + 16 + htab->num_buf * 4;
1.1.1.2  christos     }
    1.1     skrll
    1.1     skrll   htab->toe = bfd_make_section_anyway_with_flags (ibfd, ".toe", SEC_ALLOC);
    1.1     skrll   if (htab->toe == NULL
    1.1     skrll       || !bfd_set_section_alignment (ibfd, htab->toe, 4))
    1.1     skrll     return 0;
    1.1     skrll   htab->toe->size = 16;
    1.1     skrll
    1.1     skrll   return 2;
    1.1     skrll }
    1.1     skrll
1.1.1.2  christos /* Called from ld to place overlay manager data sections.  This is done
1.1.1.2  christos    after the overlay manager itself is loaded, mainly so that the
1.1.1.2  christos    linker's htab->init section is placed after any other .ovl.init
1.1.1.2  christos    sections.  */
1.1.1.2  christos
1.1.1.2  christos void
1.1.1.2  christos spu_elf_place_overlay_data (struct bfd_link_info *info)
1.1.1.2  christos {
1.1.1.2  christos   struct spu_link_hash_table *htab = spu_hash_table (info);
1.1.1.2  christos   unsigned int i;
1.1.1.2  christos
1.1.1.2  christos   if (htab->stub_sec != NULL)
1.1.1.2  christos     {
1.1.1.2  christos       (*htab->params->place_spu_section) (htab->stub_sec[0], NULL, ".text");
1.1.1.2  christos
1.1.1.2  christos       for (i = 0; i < htab->num_overlays; ++i)
1.1.1.2  christos 	{
1.1.1.2  christos 	  asection *osec = htab->ovl_sec[i];
1.1.1.2  christos 	  unsigned int ovl = spu_elf_section_data (osec)->u.o.ovl_index;
1.1.1.2  christos 	  (*htab->params->place_spu_section) (htab->stub_sec[ovl], osec, NULL);
1.1.1.2  christos 	}
1.1.1.2  christos     }
1.1.1.2  christos
1.1.1.2  christos   if (htab->params->ovly_flavour == ovly_soft_icache)
1.1.1.2  christos     (*htab->params->place_spu_section) (htab->init, NULL, ".ovl.init");
1.1.1.2  christos
1.1.1.2  christos   if (htab->ovtab != NULL)
1.1.1.2  christos     {
1.1.1.2  christos       const char *ovout = ".data";
1.1.1.2  christos       if (htab->params->ovly_flavour == ovly_soft_icache)
1.1.1.2  christos 	ovout = ".bss";
1.1.1.2  christos       (*htab->params->place_spu_section) (htab->ovtab, NULL, ovout);
1.1.1.2  christos     }
1.1.1.2  christos
1.1.1.2  christos   if (htab->toe != NULL)
1.1.1.2  christos     (*htab->params->place_spu_section) (htab->toe, NULL, ".toe");
1.1.1.2  christos }
1.1.1.2  christos
    1.1     skrll /* Functions to handle embedded spu_ovl.o object.  */
    1.1     skrll
    1.1     skrll static void *
    1.1     skrll ovl_mgr_open (struct bfd *nbfd ATTRIBUTE_UNUSED, void *stream)
    1.1     skrll {
    1.1     skrll   return stream;
    1.1     skrll }
    1.1     skrll
    1.1     skrll static file_ptr
    1.1     skrll ovl_mgr_pread (struct bfd *abfd ATTRIBUTE_UNUSED,
    1.1     skrll 	       void *stream,
    1.1     skrll 	       void *buf,
    1.1     skrll 	       file_ptr nbytes,
    1.1     skrll 	       file_ptr offset)
    1.1     skrll {
    1.1     skrll   struct _ovl_stream *os;
    1.1     skrll   size_t count;
    1.1     skrll   size_t max;
    1.1     skrll
    1.1     skrll   os = (struct _ovl_stream *) stream;
    1.1     skrll   max = (const char *) os->end - (const char *) os->start;
    1.1     skrll
    1.1     skrll   if ((ufile_ptr) offset >= max)
    1.1     skrll     return 0;
    1.1     skrll
    1.1     skrll   count = nbytes;
    1.1     skrll   if (count > max - offset)
    1.1     skrll     count = max - offset;
    1.1     skrll
    1.1     skrll   memcpy (buf, (const char *) os->start + offset, count);
    1.1     skrll   return count;
    1.1     skrll }
    1.1     skrll
1.1.1.4  christos static int
1.1.1.4  christos ovl_mgr_stat (struct bfd *abfd ATTRIBUTE_UNUSED,
1.1.1.4  christos 	      void *stream,
1.1.1.4  christos 	      struct stat *sb)
1.1.1.4  christos {
1.1.1.4  christos   struct _ovl_stream *os = (struct _ovl_stream *) stream;
1.1.1.4  christos
1.1.1.4  christos   memset (sb, 0, sizeof (*sb));
1.1.1.4  christos   sb->st_size = (const char *) os->end - (const char *) os->start;
1.1.1.4  christos   return 0;
1.1.1.4  christos }
1.1.1.4  christos
    1.1     skrll bfd_boolean
    1.1     skrll spu_elf_open_builtin_lib (bfd **ovl_bfd, const struct _ovl_stream *stream)
    1.1     skrll {
    1.1     skrll   *ovl_bfd = bfd_openr_iovec ("builtin ovl_mgr",
    1.1     skrll 			      "elf32-spu",
    1.1     skrll 			      ovl_mgr_open,
    1.1     skrll 			      (void *) stream,
    1.1     skrll 			      ovl_mgr_pread,
    1.1     skrll 			      NULL,
1.1.1.4  christos 			      ovl_mgr_stat);
    1.1     skrll   return *ovl_bfd != NULL;
    1.1     skrll }
    1.1     skrll
1.1.1.2  christos static unsigned int
1.1.1.2  christos overlay_index (asection *sec)
1.1.1.2  christos {
1.1.1.2  christos   if (sec == NULL
1.1.1.2  christos       || sec->output_section == bfd_abs_section_ptr)
1.1.1.2  christos     return 0;
1.1.1.2  christos   return spu_elf_section_data (sec->output_section)->u.o.ovl_index;
1.1.1.2  christos }
1.1.1.2  christos
    1.1     skrll /* Define an STT_OBJECT symbol.  */
    1.1     skrll
    1.1     skrll static struct elf_link_hash_entry *
    1.1     skrll define_ovtab_symbol (struct spu_link_hash_table *htab, const char *name)
    1.1     skrll {
    1.1     skrll   struct elf_link_hash_entry *h;
    1.1     skrll
    1.1     skrll   h = elf_link_hash_lookup (&htab->elf, name, TRUE, FALSE, FALSE);
    1.1     skrll   if (h == NULL)
    1.1     skrll     return NULL;
    1.1     skrll
    1.1     skrll   if (h->root.type != bfd_link_hash_defined
    1.1     skrll       || !h->def_regular)
    1.1     skrll     {
    1.1     skrll       h->root.type = bfd_link_hash_defined;
    1.1     skrll       h->root.u.def.section = htab->ovtab;
    1.1     skrll       h->type = STT_OBJECT;
    1.1     skrll       h->ref_regular = 1;
    1.1     skrll       h->def_regular = 1;
    1.1     skrll       h->ref_regular_nonweak = 1;
    1.1     skrll       h->non_elf = 0;
    1.1     skrll     }
1.1.1.2  christos   else if (h->root.u.def.section->owner != NULL)
    1.1     skrll     {
    1.1     skrll       (*_bfd_error_handler) (_("%B is not allowed to define %s"),
    1.1     skrll 			     h->root.u.def.section->owner,
    1.1     skrll 			     h->root.root.string);
    1.1     skrll       bfd_set_error (bfd_error_bad_value);
    1.1     skrll       return NULL;
    1.1     skrll     }
1.1.1.2  christos   else
1.1.1.2  christos     {
1.1.1.2  christos       (*_bfd_error_handler) (_("you are not allowed to define %s in a script"),
1.1.1.2  christos 			     h->root.root.string);
1.1.1.2  christos       bfd_set_error (bfd_error_bad_value);
1.1.1.2  christos       return NULL;
1.1.1.2  christos     }
    1.1     skrll
    1.1     skrll   return h;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Fill in all stubs and the overlay tables.  */
    1.1     skrll
1.1.1.2  christos static bfd_boolean
1.1.1.2  christos spu_elf_build_stubs (struct bfd_link_info *info)
    1.1     skrll {
    1.1     skrll   struct spu_link_hash_table *htab = spu_hash_table (info);
    1.1     skrll   struct elf_link_hash_entry *h;
    1.1     skrll   bfd_byte *p;
    1.1     skrll   asection *s;
    1.1     skrll   bfd *obfd;
    1.1     skrll   unsigned int i;
    1.1     skrll
1.1.1.2  christos   if (htab->num_overlays != 0)
1.1.1.2  christos     {
1.1.1.2  christos       for (i = 0; i < 2; i++)
1.1.1.2  christos 	{
1.1.1.2  christos 	  h = htab->ovly_entry[i];
1.1.1.2  christos 	  if (h != NULL
    1.1     skrll 	      && (h->root.type == bfd_link_hash_defined
    1.1     skrll 		  || h->root.type == bfd_link_hash_defweak)
1.1.1.2  christos 	      && h->def_regular)
1.1.1.2  christos 	    {
1.1.1.2  christos 	      s = h->root.u.def.section->output_section;
1.1.1.2  christos 	      if (spu_elf_section_data (s)->u.o.ovl_index)
1.1.1.2  christos 		{
1.1.1.2  christos 		  (*_bfd_error_handler) (_("%s in overlay section"),
1.1.1.2  christos 					 h->root.root.string);
1.1.1.2  christos 		  bfd_set_error (bfd_error_bad_value);
1.1.1.2  christos 		  return FALSE;
1.1.1.2  christos 		}
1.1.1.2  christos 	    }
1.1.1.2  christos 	}
    1.1     skrll     }
    1.1     skrll
1.1.1.2  christos   if (htab->stub_sec != NULL)
    1.1     skrll     {
1.1.1.2  christos       for (i = 0; i <= htab->num_overlays; i++)
1.1.1.2  christos 	if (htab->stub_sec[i]->size != 0)
1.1.1.2  christos 	  {
1.1.1.2  christos 	    htab->stub_sec[i]->contents = bfd_zalloc (htab->stub_sec[i]->owner,
1.1.1.2  christos 						      htab->stub_sec[i]->size);
1.1.1.2  christos 	    if (htab->stub_sec[i]->contents == NULL)
1.1.1.2  christos 	      return FALSE;
1.1.1.2  christos 	    htab->stub_sec[i]->rawsize = htab->stub_sec[i]->size;
1.1.1.2  christos 	    htab->stub_sec[i]->size = 0;
1.1.1.2  christos 	  }
    1.1     skrll
1.1.1.2  christos       /* Fill in all the stubs.  */
1.1.1.2  christos       process_stubs (info, TRUE);
1.1.1.2  christos       if (!htab->stub_err)
1.1.1.2  christos 	elf_link_hash_traverse (&htab->elf, build_spuear_stubs, info);
1.1.1.2  christos
1.1.1.2  christos       if (htab->stub_err)
    1.1     skrll 	{
1.1.1.2  christos 	  (*_bfd_error_handler) (_("overlay stub relocation overflow"));
    1.1     skrll 	  bfd_set_error (bfd_error_bad_value);
    1.1     skrll 	  return FALSE;
    1.1     skrll 	}
1.1.1.2  christos
1.1.1.2  christos       for (i = 0; i <= htab->num_overlays; i++)
1.1.1.2  christos 	{
1.1.1.2  christos 	  if (htab->stub_sec[i]->size != htab->stub_sec[i]->rawsize)
1.1.1.2  christos 	    {
1.1.1.2  christos 	      (*_bfd_error_handler)  (_("stubs don't match calculated size"));
1.1.1.2  christos 	      bfd_set_error (bfd_error_bad_value);
1.1.1.2  christos 	      return FALSE;
1.1.1.2  christos 	    }
1.1.1.2  christos 	  htab->stub_sec[i]->rawsize = 0;
1.1.1.2  christos 	}
    1.1     skrll     }
    1.1     skrll
1.1.1.2  christos   if (htab->ovtab == NULL || htab->ovtab->size == 0)
1.1.1.2  christos     return TRUE;
1.1.1.2  christos
    1.1     skrll   htab->ovtab->contents = bfd_zalloc (htab->ovtab->owner, htab->ovtab->size);
    1.1     skrll   if (htab->ovtab->contents == NULL)
    1.1     skrll     return FALSE;
    1.1     skrll
    1.1     skrll   p = htab->ovtab->contents;
1.1.1.2  christos   if (htab->params->ovly_flavour == ovly_soft_icache)
    1.1     skrll     {
1.1.1.2  christos       bfd_vma off;
1.1.1.2  christos
1.1.1.2  christos       h = define_ovtab_symbol (htab, "__icache_tag_array");
1.1.1.2  christos       if (h == NULL)
1.1.1.2  christos 	return FALSE;
1.1.1.2  christos       h->root.u.def.value = 0;
1.1.1.2  christos       h->size = 16 << htab->num_lines_log2;
1.1.1.2  christos       off = h->size;
1.1.1.2  christos
1.1.1.2  christos       h = define_ovtab_symbol (htab, "__icache_tag_array_size");
1.1.1.2  christos       if (h == NULL)
1.1.1.2  christos 	return FALSE;
1.1.1.2  christos       h->root.u.def.value = 16 << htab->num_lines_log2;
1.1.1.2  christos       h->root.u.def.section = bfd_abs_section_ptr;
1.1.1.2  christos
1.1.1.2  christos       h = define_ovtab_symbol (htab, "__icache_rewrite_to");
1.1.1.2  christos       if (h == NULL)
1.1.1.2  christos 	return FALSE;
1.1.1.2  christos       h->root.u.def.value = off;
1.1.1.2  christos       h->size = 16 << htab->num_lines_log2;
1.1.1.2  christos       off += h->size;
1.1.1.2  christos
1.1.1.2  christos       h = define_ovtab_symbol (htab, "__icache_rewrite_to_size");
1.1.1.2  christos       if (h == NULL)
1.1.1.2  christos 	return FALSE;
1.1.1.2  christos       h->root.u.def.value = 16 << htab->num_lines_log2;
1.1.1.2  christos       h->root.u.def.section = bfd_abs_section_ptr;
1.1.1.2  christos
1.1.1.2  christos       h = define_ovtab_symbol (htab, "__icache_rewrite_from");
1.1.1.2  christos       if (h == NULL)
1.1.1.2  christos 	return FALSE;
1.1.1.2  christos       h->root.u.def.value = off;
1.1.1.2  christos       h->size = 16 << (htab->fromelem_size_log2 + htab->num_lines_log2);
1.1.1.2  christos       off += h->size;
1.1.1.2  christos
1.1.1.2  christos       h = define_ovtab_symbol (htab, "__icache_rewrite_from_size");
1.1.1.2  christos       if (h == NULL)
1.1.1.2  christos 	return FALSE;
1.1.1.2  christos       h->root.u.def.value = 16 << (htab->fromelem_size_log2
1.1.1.2  christos 				   + htab->num_lines_log2);
1.1.1.2  christos       h->root.u.def.section = bfd_abs_section_ptr;
1.1.1.2  christos
1.1.1.2  christos       h = define_ovtab_symbol (htab, "__icache_log2_fromelemsize");
1.1.1.2  christos       if (h == NULL)
1.1.1.2  christos 	return FALSE;
1.1.1.2  christos       h->root.u.def.value = htab->fromelem_size_log2;
1.1.1.2  christos       h->root.u.def.section = bfd_abs_section_ptr;
1.1.1.2  christos
1.1.1.2  christos       h = define_ovtab_symbol (htab, "__icache_base");
1.1.1.2  christos       if (h == NULL)
1.1.1.2  christos 	return FALSE;
1.1.1.2  christos       h->root.u.def.value = htab->ovl_sec[0]->vma;
1.1.1.2  christos       h->root.u.def.section = bfd_abs_section_ptr;
1.1.1.2  christos       h->size = htab->num_buf << htab->line_size_log2;
1.1.1.2  christos
1.1.1.2  christos       h = define_ovtab_symbol (htab, "__icache_linesize");
1.1.1.2  christos       if (h == NULL)
1.1.1.2  christos 	return FALSE;
1.1.1.2  christos       h->root.u.def.value = 1 << htab->line_size_log2;
1.1.1.2  christos       h->root.u.def.section = bfd_abs_section_ptr;
1.1.1.2  christos
1.1.1.2  christos       h = define_ovtab_symbol (htab, "__icache_log2_linesize");
1.1.1.2  christos       if (h == NULL)
1.1.1.2  christos 	return FALSE;
1.1.1.2  christos       h->root.u.def.value = htab->line_size_log2;
1.1.1.2  christos       h->root.u.def.section = bfd_abs_section_ptr;
1.1.1.2  christos
1.1.1.2  christos       h = define_ovtab_symbol (htab, "__icache_neg_log2_linesize");
1.1.1.2  christos       if (h == NULL)
1.1.1.2  christos 	return FALSE;
1.1.1.2  christos       h->root.u.def.value = -htab->line_size_log2;
1.1.1.2  christos       h->root.u.def.section = bfd_abs_section_ptr;
1.1.1.2  christos
1.1.1.2  christos       h = define_ovtab_symbol (htab, "__icache_cachesize");
1.1.1.2  christos       if (h == NULL)
1.1.1.2  christos 	return FALSE;
1.1.1.2  christos       h->root.u.def.value = 1 << (htab->num_lines_log2 + htab->line_size_log2);
1.1.1.2  christos       h->root.u.def.section = bfd_abs_section_ptr;
1.1.1.2  christos
1.1.1.2  christos       h = define_ovtab_symbol (htab, "__icache_log2_cachesize");
1.1.1.2  christos       if (h == NULL)
1.1.1.2  christos 	return FALSE;
1.1.1.2  christos       h->root.u.def.value = htab->num_lines_log2 + htab->line_size_log2;
1.1.1.2  christos       h->root.u.def.section = bfd_abs_section_ptr;
    1.1     skrll
1.1.1.2  christos       h = define_ovtab_symbol (htab, "__icache_neg_log2_cachesize");
1.1.1.2  christos       if (h == NULL)
1.1.1.2  christos 	return FALSE;
1.1.1.2  christos       h->root.u.def.value = -(htab->num_lines_log2 + htab->line_size_log2);
1.1.1.2  christos       h->root.u.def.section = bfd_abs_section_ptr;
1.1.1.2  christos
1.1.1.2  christos       if (htab->init != NULL && htab->init->size != 0)
    1.1     skrll 	{
1.1.1.2  christos 	  htab->init->contents = bfd_zalloc (htab->init->owner,
1.1.1.2  christos 					     htab->init->size);
1.1.1.2  christos 	  if (htab->init->contents == NULL)
1.1.1.2  christos 	    return FALSE;
    1.1     skrll
1.1.1.2  christos 	  h = define_ovtab_symbol (htab, "__icache_fileoff");
1.1.1.2  christos 	  if (h == NULL)
1.1.1.2  christos 	    return FALSE;
1.1.1.2  christos 	  h->root.u.def.value = 0;
1.1.1.2  christos 	  h->root.u.def.section = htab->init;
1.1.1.2  christos 	  h->size = 8;
    1.1     skrll 	}
    1.1     skrll     }
1.1.1.2  christos   else
1.1.1.2  christos     {
1.1.1.2  christos       /* Write out _ovly_table.  */
1.1.1.2  christos       /* set low bit of .size to mark non-overlay area as present.  */
1.1.1.2  christos       p[7] = 1;
1.1.1.2  christos       obfd = htab->ovtab->output_section->owner;
1.1.1.2  christos       for (s = obfd->sections; s != NULL; s = s->next)
1.1.1.2  christos 	{
1.1.1.2  christos 	  unsigned int ovl_index = spu_elf_section_data (s)->u.o.ovl_index;
    1.1     skrll
1.1.1.2  christos 	  if (ovl_index != 0)
1.1.1.2  christos 	    {
1.1.1.2  christos 	      unsigned long off = ovl_index * 16;
1.1.1.2  christos 	      unsigned int ovl_buf = spu_elf_section_data (s)->u.o.ovl_buf;
    1.1     skrll
1.1.1.2  christos 	      bfd_put_32 (htab->ovtab->owner, s->vma, p + off);
1.1.1.2  christos 	      bfd_put_32 (htab->ovtab->owner, (s->size + 15) & -16,
1.1.1.2  christos 			  p + off + 4);
1.1.1.2  christos 	      /* file_off written later in spu_elf_modify_program_headers.  */
1.1.1.2  christos 	      bfd_put_32 (htab->ovtab->owner, ovl_buf, p + off + 12);
1.1.1.2  christos 	    }
1.1.1.2  christos 	}
    1.1     skrll
1.1.1.2  christos       h = define_ovtab_symbol (htab, "_ovly_table");
1.1.1.2  christos       if (h == NULL)
1.1.1.2  christos 	return FALSE;
1.1.1.2  christos       h->root.u.def.value = 16;
1.1.1.2  christos       h->size = htab->num_overlays * 16;
    1.1     skrll
1.1.1.2  christos       h = define_ovtab_symbol (htab, "_ovly_table_end");
1.1.1.2  christos       if (h == NULL)
1.1.1.2  christos 	return FALSE;
1.1.1.2  christos       h->root.u.def.value = htab->num_overlays * 16 + 16;
1.1.1.2  christos       h->size = 0;
1.1.1.2  christos
1.1.1.2  christos       h = define_ovtab_symbol (htab, "_ovly_buf_table");
1.1.1.2  christos       if (h == NULL)
1.1.1.2  christos 	return FALSE;
1.1.1.2  christos       h->root.u.def.value = htab->num_overlays * 16 + 16;
1.1.1.2  christos       h->size = htab->num_buf * 4;
1.1.1.2  christos
1.1.1.2  christos       h = define_ovtab_symbol (htab, "_ovly_buf_table_end");
1.1.1.2  christos       if (h == NULL)
1.1.1.2  christos 	return FALSE;
1.1.1.2  christos       h->root.u.def.value = htab->num_overlays * 16 + 16 + htab->num_buf * 4;
1.1.1.2  christos       h->size = 0;
1.1.1.2  christos     }
    1.1     skrll
    1.1     skrll   h = define_ovtab_symbol (htab, "_EAR_");
    1.1     skrll   if (h == NULL)
    1.1     skrll     return FALSE;
    1.1     skrll   h->root.u.def.section = htab->toe;
    1.1     skrll   h->root.u.def.value = 0;
    1.1     skrll   h->size = 16;
    1.1     skrll
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Check that all loadable section VMAs lie in the range
    1.1     skrll    LO .. HI inclusive, and stash some parameters for --auto-overlay.  */
    1.1     skrll
    1.1     skrll asection *
1.1.1.2  christos spu_elf_check_vma (struct bfd_link_info *info)
    1.1     skrll {
    1.1     skrll   struct elf_segment_map *m;
    1.1     skrll   unsigned int i;
    1.1     skrll   struct spu_link_hash_table *htab = spu_hash_table (info);
    1.1     skrll   bfd *abfd = info->output_bfd;
1.1.1.2  christos   bfd_vma hi = htab->params->local_store_hi;
1.1.1.2  christos   bfd_vma lo = htab->params->local_store_lo;
    1.1     skrll
    1.1     skrll   htab->local_store = hi + 1 - lo;
    1.1     skrll
1.1.1.4  christos   for (m = elf_seg_map (abfd); m != NULL; m = m->next)
    1.1     skrll     if (m->p_type == PT_LOAD)
    1.1     skrll       for (i = 0; i < m->count; i++)
    1.1     skrll 	if (m->sections[i]->size != 0
    1.1     skrll 	    && (m->sections[i]->vma < lo
    1.1     skrll 		|| m->sections[i]->vma > hi
    1.1     skrll 		|| m->sections[i]->vma + m->sections[i]->size - 1 > hi))
    1.1     skrll 	  return m->sections[i];
    1.1     skrll
    1.1     skrll   return NULL;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* OFFSET in SEC (presumably) is the beginning of a function prologue.
1.1.1.2  christos    Search for stack adjusting insns, and return the sp delta.
1.1.1.2  christos    If a store of lr is found save the instruction offset to *LR_STORE.
1.1.1.2  christos    If a stack adjusting instruction is found, save that offset to
1.1.1.2  christos    *SP_ADJUST.  */
    1.1     skrll
    1.1     skrll static int
1.1.1.2  christos find_function_stack_adjust (asection *sec,
1.1.1.2  christos 			    bfd_vma offset,
1.1.1.2  christos 			    bfd_vma *lr_store,
1.1.1.2  christos 			    bfd_vma *sp_adjust)
    1.1     skrll {
    1.1     skrll   int reg[128];
    1.1     skrll
    1.1     skrll   memset (reg, 0, sizeof (reg));
1.1.1.2  christos   for ( ; offset + 4 <= sec->size; offset += 4)
    1.1     skrll     {
    1.1     skrll       unsigned char buf[4];
    1.1     skrll       int rt, ra;
    1.1     skrll       int imm;
    1.1     skrll
    1.1     skrll       /* Assume no relocs on stack adjusing insns.  */
    1.1     skrll       if (!bfd_get_section_contents (sec->owner, sec, buf, offset, 4))
    1.1     skrll 	break;
    1.1     skrll
    1.1     skrll       rt = buf[3] & 0x7f;
    1.1     skrll       ra = ((buf[2] & 0x3f) << 1) | (buf[3] >> 7);
1.1.1.2  christos
1.1.1.2  christos       if (buf[0] == 0x24 /* stqd */)
1.1.1.2  christos 	{
1.1.1.2  christos 	  if (rt == 0 /* lr */ && ra == 1 /* sp */)
1.1.1.2  christos 	    *lr_store = offset;
1.1.1.2  christos 	  continue;
1.1.1.2  christos 	}
1.1.1.2  christos
    1.1     skrll       /* Partly decoded immediate field.  */
    1.1     skrll       imm = (buf[1] << 9) | (buf[2] << 1) | (buf[3] >> 7);
    1.1     skrll
    1.1     skrll       if (buf[0] == 0x1c /* ai */)
    1.1     skrll 	{
    1.1     skrll 	  imm >>= 7;
    1.1     skrll 	  imm = (imm ^ 0x200) - 0x200;
    1.1     skrll 	  reg[rt] = reg[ra] + imm;
    1.1     skrll
    1.1     skrll 	  if (rt == 1 /* sp */)
    1.1     skrll 	    {
1.1.1.2  christos 	      if (reg[rt] > 0)
    1.1     skrll 		break;
1.1.1.2  christos 	      *sp_adjust = offset;
    1.1     skrll 	      return reg[rt];
    1.1     skrll 	    }
    1.1     skrll 	}
    1.1     skrll       else if (buf[0] == 0x18 && (buf[1] & 0xe0) == 0 /* a */)
    1.1     skrll 	{
    1.1     skrll 	  int rb = ((buf[1] & 0x1f) << 2) | ((buf[2] & 0xc0) >> 6);
    1.1     skrll
    1.1     skrll 	  reg[rt] = reg[ra] + reg[rb];
    1.1     skrll 	  if (rt == 1)
1.1.1.2  christos 	    {
1.1.1.2  christos 	      if (reg[rt] > 0)
1.1.1.2  christos 		break;
1.1.1.2  christos 	      *sp_adjust = offset;
1.1.1.2  christos 	      return reg[rt];
1.1.1.2  christos 	    }
1.1.1.2  christos 	}
1.1.1.2  christos       else if (buf[0] == 0x08 && (buf[1] & 0xe0) == 0 /* sf */)
1.1.1.2  christos 	{
1.1.1.2  christos 	  int rb = ((buf[1] & 0x1f) << 2) | ((buf[2] & 0xc0) >> 6);
1.1.1.2  christos
1.1.1.2  christos 	  reg[rt] = reg[rb] - reg[ra];
1.1.1.2  christos 	  if (rt == 1)
1.1.1.2  christos 	    {
1.1.1.2  christos 	      if (reg[rt] > 0)
1.1.1.2  christos 		break;
1.1.1.2  christos 	      *sp_adjust = offset;
1.1.1.2  christos 	      return reg[rt];
1.1.1.2  christos 	    }
    1.1     skrll 	}
    1.1     skrll       else if ((buf[0] & 0xfc) == 0x40 /* il, ilh, ilhu, ila */)
    1.1     skrll 	{
    1.1     skrll 	  if (buf[0] >= 0x42 /* ila */)
    1.1     skrll 	    imm |= (buf[0] & 1) << 17;
    1.1     skrll 	  else
    1.1     skrll 	    {
    1.1     skrll 	      imm &= 0xffff;
    1.1     skrll
    1.1     skrll 	      if (buf[0] == 0x40 /* il */)
    1.1     skrll 		{
    1.1     skrll 		  if ((buf[1] & 0x80) == 0)
1.1.1.2  christos 		    continue;
    1.1     skrll 		  imm = (imm ^ 0x8000) - 0x8000;
    1.1     skrll 		}
    1.1     skrll 	      else if ((buf[1] & 0x80) == 0 /* ilhu */)
    1.1     skrll 		imm <<= 16;
    1.1     skrll 	    }
    1.1     skrll 	  reg[rt] = imm;
    1.1     skrll 	  continue;
    1.1     skrll 	}
    1.1     skrll       else if (buf[0] == 0x60 && (buf[1] & 0x80) != 0 /* iohl */)
    1.1     skrll 	{
    1.1     skrll 	  reg[rt] |= imm & 0xffff;
    1.1     skrll 	  continue;
    1.1     skrll 	}
    1.1     skrll       else if (buf[0] == 0x04 /* ori */)
    1.1     skrll 	{
    1.1     skrll 	  imm >>= 7;
    1.1     skrll 	  imm = (imm ^ 0x200) - 0x200;
    1.1     skrll 	  reg[rt] = reg[ra] | imm;
    1.1     skrll 	  continue;
    1.1     skrll 	}
1.1.1.2  christos       else if (buf[0] == 0x32 && (buf[1] & 0x80) != 0 /* fsmbi */)
    1.1     skrll 	{
1.1.1.2  christos 	  reg[rt] = (  ((imm & 0x8000) ? 0xff000000 : 0)
1.1.1.2  christos 		     | ((imm & 0x4000) ? 0x00ff0000 : 0)
1.1.1.2  christos 		     | ((imm & 0x2000) ? 0x0000ff00 : 0)
1.1.1.2  christos 		     | ((imm & 0x1000) ? 0x000000ff : 0));
1.1.1.2  christos 	  continue;
1.1.1.2  christos 	}
1.1.1.2  christos       else if (buf[0] == 0x16 /* andbi */)
1.1.1.2  christos 	{
1.1.1.2  christos 	  imm >>= 7;
1.1.1.2  christos 	  imm &= 0xff;
1.1.1.2  christos 	  imm |= imm << 8;
1.1.1.2  christos 	  imm |= imm << 16;
1.1.1.2  christos 	  reg[rt] = reg[ra] & imm;
1.1.1.2  christos 	  continue;
1.1.1.2  christos 	}
1.1.1.2  christos       else if (buf[0] == 0x33 && imm == 1 /* brsl .+4 */)
1.1.1.2  christos 	{
1.1.1.2  christos 	  /* Used in pic reg load.  Say rt is trashed.  Won't be used
1.1.1.2  christos 	     in stack adjust, but we need to continue past this branch.  */
    1.1     skrll 	  reg[rt] = 0;
    1.1     skrll 	  continue;
    1.1     skrll 	}
    1.1     skrll       else if (is_branch (buf) || is_indirect_branch (buf))
    1.1     skrll 	/* If we hit a branch then we must be out of the prologue.  */
    1.1     skrll 	break;
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   return 0;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* qsort predicate to sort symbols by section and value.  */
    1.1     skrll
    1.1     skrll static Elf_Internal_Sym *sort_syms_syms;
    1.1     skrll static asection **sort_syms_psecs;
    1.1     skrll
    1.1     skrll static int
    1.1     skrll sort_syms (const void *a, const void *b)
    1.1     skrll {
    1.1     skrll   Elf_Internal_Sym *const *s1 = a;
    1.1     skrll   Elf_Internal_Sym *const *s2 = b;
    1.1     skrll   asection *sec1,*sec2;
    1.1     skrll   bfd_signed_vma delta;
    1.1     skrll
    1.1     skrll   sec1 = sort_syms_psecs[*s1 - sort_syms_syms];
    1.1     skrll   sec2 = sort_syms_psecs[*s2 - sort_syms_syms];
    1.1     skrll
    1.1     skrll   if (sec1 != sec2)
    1.1     skrll     return sec1->index - sec2->index;
    1.1     skrll
    1.1     skrll   delta = (*s1)->st_value - (*s2)->st_value;
    1.1     skrll   if (delta != 0)
    1.1     skrll     return delta < 0 ? -1 : 1;
    1.1     skrll
    1.1     skrll   delta = (*s2)->st_size - (*s1)->st_size;
    1.1     skrll   if (delta != 0)
    1.1     skrll     return delta < 0 ? -1 : 1;
    1.1     skrll
    1.1     skrll   return *s1 < *s2 ? -1 : 1;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Allocate a struct spu_elf_stack_info with MAX_FUN struct function_info
    1.1     skrll    entries for section SEC.  */
    1.1     skrll
    1.1     skrll static struct spu_elf_stack_info *
    1.1     skrll alloc_stack_info (asection *sec, int max_fun)
    1.1     skrll {
    1.1     skrll   struct _spu_elf_section_data *sec_data = spu_elf_section_data (sec);
    1.1     skrll   bfd_size_type amt;
    1.1     skrll
    1.1     skrll   amt = sizeof (struct spu_elf_stack_info);
    1.1     skrll   amt += (max_fun - 1) * sizeof (struct function_info);
    1.1     skrll   sec_data->u.i.stack_info = bfd_zmalloc (amt);
    1.1     skrll   if (sec_data->u.i.stack_info != NULL)
    1.1     skrll     sec_data->u.i.stack_info->max_fun = max_fun;
    1.1     skrll   return sec_data->u.i.stack_info;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Add a new struct function_info describing a (part of a) function
    1.1     skrll    starting at SYM_H.  Keep the array sorted by address.  */
    1.1     skrll
    1.1     skrll static struct function_info *
    1.1     skrll maybe_insert_function (asection *sec,
    1.1     skrll 		       void *sym_h,
    1.1     skrll 		       bfd_boolean global,
    1.1     skrll 		       bfd_boolean is_func)
    1.1     skrll {
    1.1     skrll   struct _spu_elf_section_data *sec_data = spu_elf_section_data (sec);
    1.1     skrll   struct spu_elf_stack_info *sinfo = sec_data->u.i.stack_info;
    1.1     skrll   int i;
    1.1     skrll   bfd_vma off, size;
    1.1     skrll
    1.1     skrll   if (sinfo == NULL)
    1.1     skrll     {
    1.1     skrll       sinfo = alloc_stack_info (sec, 20);
    1.1     skrll       if (sinfo == NULL)
    1.1     skrll 	return NULL;
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   if (!global)
    1.1     skrll     {
    1.1     skrll       Elf_Internal_Sym *sym = sym_h;
    1.1     skrll       off = sym->st_value;
    1.1     skrll       size = sym->st_size;
    1.1     skrll     }
    1.1     skrll   else
    1.1     skrll     {
    1.1     skrll       struct elf_link_hash_entry *h = sym_h;
    1.1     skrll       off = h->root.u.def.value;
    1.1     skrll       size = h->size;
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   for (i = sinfo->num_fun; --i >= 0; )
    1.1     skrll     if (sinfo->fun[i].lo <= off)
    1.1     skrll       break;
    1.1     skrll
    1.1     skrll   if (i >= 0)
    1.1     skrll     {
    1.1     skrll       /* Don't add another entry for an alias, but do update some
    1.1     skrll 	 info.  */
    1.1     skrll       if (sinfo->fun[i].lo == off)
    1.1     skrll 	{
    1.1     skrll 	  /* Prefer globals over local syms.  */
    1.1     skrll 	  if (global && !sinfo->fun[i].global)
    1.1     skrll 	    {
    1.1     skrll 	      sinfo->fun[i].global = TRUE;
    1.1     skrll 	      sinfo->fun[i].u.h = sym_h;
    1.1     skrll 	    }
    1.1     skrll 	  if (is_func)
    1.1     skrll 	    sinfo->fun[i].is_func = TRUE;
    1.1     skrll 	  return &sinfo->fun[i];
    1.1     skrll 	}
    1.1     skrll       /* Ignore a zero-size symbol inside an existing function.  */
    1.1     skrll       else if (sinfo->fun[i].hi > off && size == 0)
    1.1     skrll 	return &sinfo->fun[i];
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   if (sinfo->num_fun >= sinfo->max_fun)
    1.1     skrll     {
    1.1     skrll       bfd_size_type amt = sizeof (struct spu_elf_stack_info);
    1.1     skrll       bfd_size_type old = amt;
    1.1     skrll
    1.1     skrll       old += (sinfo->max_fun - 1) * sizeof (struct function_info);
    1.1     skrll       sinfo->max_fun += 20 + (sinfo->max_fun >> 1);
    1.1     skrll       amt += (sinfo->max_fun - 1) * sizeof (struct function_info);
    1.1     skrll       sinfo = bfd_realloc (sinfo, amt);
    1.1     skrll       if (sinfo == NULL)
    1.1     skrll 	return NULL;
    1.1     skrll       memset ((char *) sinfo + old, 0, amt - old);
    1.1     skrll       sec_data->u.i.stack_info = sinfo;
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   if (++i < sinfo->num_fun)
    1.1     skrll     memmove (&sinfo->fun[i + 1], &sinfo->fun[i],
    1.1     skrll 	     (sinfo->num_fun - i) * sizeof (sinfo->fun[i]));
    1.1     skrll   sinfo->fun[i].is_func = is_func;
    1.1     skrll   sinfo->fun[i].global = global;
    1.1     skrll   sinfo->fun[i].sec = sec;
    1.1     skrll   if (global)
    1.1     skrll     sinfo->fun[i].u.h = sym_h;
    1.1     skrll   else
    1.1     skrll     sinfo->fun[i].u.sym = sym_h;
    1.1     skrll   sinfo->fun[i].lo = off;
    1.1     skrll   sinfo->fun[i].hi = off + size;
1.1.1.2  christos   sinfo->fun[i].lr_store = -1;
1.1.1.2  christos   sinfo->fun[i].sp_adjust = -1;
1.1.1.2  christos   sinfo->fun[i].stack = -find_function_stack_adjust (sec, off,
1.1.1.2  christos 						     &sinfo->fun[i].lr_store,
1.1.1.2  christos 						     &sinfo->fun[i].sp_adjust);
    1.1     skrll   sinfo->num_fun += 1;
    1.1     skrll   return &sinfo->fun[i];
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Return the name of FUN.  */
    1.1     skrll
    1.1     skrll static const char *
    1.1     skrll func_name (struct function_info *fun)
    1.1     skrll {
    1.1     skrll   asection *sec;
    1.1     skrll   bfd *ibfd;
    1.1     skrll   Elf_Internal_Shdr *symtab_hdr;
    1.1     skrll
    1.1     skrll   while (fun->start != NULL)
    1.1     skrll     fun = fun->start;
    1.1     skrll
    1.1     skrll   if (fun->global)
    1.1     skrll     return fun->u.h->root.root.string;
    1.1     skrll
    1.1     skrll   sec = fun->sec;
    1.1     skrll   if (fun->u.sym->st_name == 0)
    1.1     skrll     {
    1.1     skrll       size_t len = strlen (sec->name);
    1.1     skrll       char *name = bfd_malloc (len + 10);
    1.1     skrll       if (name == NULL)
    1.1     skrll 	return "(null)";
    1.1     skrll       sprintf (name, "%s+%lx", sec->name,
    1.1     skrll 	       (unsigned long) fun->u.sym->st_value & 0xffffffff);
    1.1     skrll       return name;
    1.1     skrll     }
    1.1     skrll   ibfd = sec->owner;
    1.1     skrll   symtab_hdr = &elf_tdata (ibfd)->symtab_hdr;
    1.1     skrll   return bfd_elf_sym_name (ibfd, symtab_hdr, fun->u.sym, sec);
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Read the instruction at OFF in SEC.  Return true iff the instruction
    1.1     skrll    is a nop, lnop, or stop 0 (all zero insn).  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll is_nop (asection *sec, bfd_vma off)
    1.1     skrll {
    1.1     skrll   unsigned char insn[4];
    1.1     skrll
    1.1     skrll   if (off + 4 > sec->size
    1.1     skrll       || !bfd_get_section_contents (sec->owner, sec, insn, off, 4))
    1.1     skrll     return FALSE;
    1.1     skrll   if ((insn[0] & 0xbf) == 0 && (insn[1] & 0xe0) == 0x20)
    1.1     skrll     return TRUE;
    1.1     skrll   if (insn[0] == 0 && insn[1] == 0 && insn[2] == 0 && insn[3] == 0)
    1.1     skrll     return TRUE;
    1.1     skrll   return FALSE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Extend the range of FUN to cover nop padding up to LIMIT.
    1.1     skrll    Return TRUE iff some instruction other than a NOP was found.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll insns_at_end (struct function_info *fun, bfd_vma limit)
    1.1     skrll {
    1.1     skrll   bfd_vma off = (fun->hi + 3) & -4;
    1.1     skrll
    1.1     skrll   while (off < limit && is_nop (fun->sec, off))
    1.1     skrll     off += 4;
    1.1     skrll   if (off < limit)
    1.1     skrll     {
    1.1     skrll       fun->hi = off;
    1.1     skrll       return TRUE;
    1.1     skrll     }
    1.1     skrll   fun->hi = limit;
    1.1     skrll   return FALSE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Check and fix overlapping function ranges.  Return TRUE iff there
    1.1     skrll    are gaps in the current info we have about functions in SEC.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll check_function_ranges (asection *sec, struct bfd_link_info *info)
    1.1     skrll {
    1.1     skrll   struct _spu_elf_section_data *sec_data = spu_elf_section_data (sec);
    1.1     skrll   struct spu_elf_stack_info *sinfo = sec_data->u.i.stack_info;
    1.1     skrll   int i;
    1.1     skrll   bfd_boolean gaps = FALSE;
    1.1     skrll
    1.1     skrll   if (sinfo == NULL)
    1.1     skrll     return FALSE;
    1.1     skrll
    1.1     skrll   for (i = 1; i < sinfo->num_fun; i++)
    1.1     skrll     if (sinfo->fun[i - 1].hi > sinfo->fun[i].lo)
    1.1     skrll       {
    1.1     skrll 	/* Fix overlapping symbols.  */
    1.1     skrll 	const char *f1 = func_name (&sinfo->fun[i - 1]);
    1.1     skrll 	const char *f2 = func_name (&sinfo->fun[i]);
    1.1     skrll
    1.1     skrll 	info->callbacks->einfo (_("warning: %s overlaps %s\n"), f1, f2);
    1.1     skrll 	sinfo->fun[i - 1].hi = sinfo->fun[i].lo;
    1.1     skrll       }
    1.1     skrll     else if (insns_at_end (&sinfo->fun[i - 1], sinfo->fun[i].lo))
    1.1     skrll       gaps = TRUE;
    1.1     skrll
    1.1     skrll   if (sinfo->num_fun == 0)
    1.1     skrll     gaps = TRUE;
    1.1     skrll   else
    1.1     skrll     {
    1.1     skrll       if (sinfo->fun[0].lo != 0)
    1.1     skrll 	gaps = TRUE;
    1.1     skrll       if (sinfo->fun[sinfo->num_fun - 1].hi > sec->size)
    1.1     skrll 	{
    1.1     skrll 	  const char *f1 = func_name (&sinfo->fun[sinfo->num_fun - 1]);
    1.1     skrll
    1.1     skrll 	  info->callbacks->einfo (_("warning: %s exceeds section size\n"), f1);
    1.1     skrll 	  sinfo->fun[sinfo->num_fun - 1].hi = sec->size;
    1.1     skrll 	}
    1.1     skrll       else if (insns_at_end (&sinfo->fun[sinfo->num_fun - 1], sec->size))
    1.1     skrll 	gaps = TRUE;
    1.1     skrll     }
    1.1     skrll   return gaps;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Search current function info for a function that contains address
    1.1     skrll    OFFSET in section SEC.  */
    1.1     skrll
    1.1     skrll static struct function_info *
    1.1     skrll find_function (asection *sec, bfd_vma offset, struct bfd_link_info *info)
    1.1     skrll {
    1.1     skrll   struct _spu_elf_section_data *sec_data = spu_elf_section_data (sec);
    1.1     skrll   struct spu_elf_stack_info *sinfo = sec_data->u.i.stack_info;
    1.1     skrll   int lo, hi, mid;
    1.1     skrll
    1.1     skrll   lo = 0;
    1.1     skrll   hi = sinfo->num_fun;
    1.1     skrll   while (lo < hi)
    1.1     skrll     {
    1.1     skrll       mid = (lo + hi) / 2;
    1.1     skrll       if (offset < sinfo->fun[mid].lo)
    1.1     skrll 	hi = mid;
    1.1     skrll       else if (offset >= sinfo->fun[mid].hi)
    1.1     skrll 	lo = mid + 1;
    1.1     skrll       else
    1.1     skrll 	return &sinfo->fun[mid];
    1.1     skrll     }
    1.1     skrll   info->callbacks->einfo (_("%A:0x%v not found in function table\n"),
    1.1     skrll 			  sec, offset);
1.1.1.2  christos   bfd_set_error (bfd_error_bad_value);
    1.1     skrll   return NULL;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Add CALLEE to CALLER call list if not already present.  Return TRUE
    1.1     skrll    if CALLEE was new.  If this function return FALSE, CALLEE should
    1.1     skrll    be freed.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll insert_callee (struct function_info *caller, struct call_info *callee)
    1.1     skrll {
    1.1     skrll   struct call_info **pp, *p;
    1.1     skrll
    1.1     skrll   for (pp = &caller->call_list; (p = *pp) != NULL; pp = &p->next)
    1.1     skrll     if (p->fun == callee->fun)
    1.1     skrll       {
    1.1     skrll 	/* Tail calls use less stack than normal calls.  Retain entry
    1.1     skrll 	   for normal call over one for tail call.  */
    1.1     skrll 	p->is_tail &= callee->is_tail;
    1.1     skrll 	if (!p->is_tail)
    1.1     skrll 	  {
    1.1     skrll 	    p->fun->start = NULL;
    1.1     skrll 	    p->fun->is_func = TRUE;
    1.1     skrll 	  }
1.1.1.2  christos 	p->count += callee->count;
    1.1     skrll 	/* Reorder list so most recent call is first.  */
    1.1     skrll 	*pp = p->next;
    1.1     skrll 	p->next = caller->call_list;
    1.1     skrll 	caller->call_list = p;
    1.1     skrll 	return FALSE;
    1.1     skrll       }
    1.1     skrll   callee->next = caller->call_list;
    1.1     skrll   caller->call_list = callee;
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Copy CALL and insert the copy into CALLER.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll copy_callee (struct function_info *caller, const struct call_info *call)
    1.1     skrll {
    1.1     skrll   struct call_info *callee;
    1.1     skrll   callee = bfd_malloc (sizeof (*callee));
    1.1     skrll   if (callee == NULL)
    1.1     skrll     return FALSE;
    1.1     skrll   *callee = *call;
    1.1     skrll   if (!insert_callee (caller, callee))
    1.1     skrll     free (callee);
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* We're only interested in code sections.  Testing SEC_IN_MEMORY excludes
    1.1     skrll    overlay stub sections.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
1.1.1.2  christos interesting_section (asection *s)
    1.1     skrll {
1.1.1.2  christos   return (s->output_section != bfd_abs_section_ptr
    1.1     skrll 	  && ((s->flags & (SEC_ALLOC | SEC_LOAD | SEC_CODE | SEC_IN_MEMORY))
    1.1     skrll 	      == (SEC_ALLOC | SEC_LOAD | SEC_CODE))
    1.1     skrll 	  && s->size != 0);
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Rummage through the relocs for SEC, looking for function calls.
    1.1     skrll    If CALL_TREE is true, fill in call graph.  If CALL_TREE is false,
    1.1     skrll    mark destination symbols on calls as being functions.  Also
    1.1     skrll    look at branches, which may be tail calls or go to hot/cold
    1.1     skrll    section part of same function.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll mark_functions_via_relocs (asection *sec,
    1.1     skrll 			   struct bfd_link_info *info,
    1.1     skrll 			   int call_tree)
    1.1     skrll {
    1.1     skrll   Elf_Internal_Rela *internal_relocs, *irelaend, *irela;
    1.1     skrll   Elf_Internal_Shdr *symtab_hdr;
    1.1     skrll   void *psyms;
1.1.1.2  christos   unsigned int priority = 0;
    1.1     skrll   static bfd_boolean warned;
    1.1     skrll
1.1.1.2  christos   if (!interesting_section (sec)
    1.1     skrll       || sec->reloc_count == 0)
    1.1     skrll     return TRUE;
    1.1     skrll
    1.1     skrll   internal_relocs = _bfd_elf_link_read_relocs (sec->owner, sec, NULL, NULL,
    1.1     skrll 					       info->keep_memory);
    1.1     skrll   if (internal_relocs == NULL)
    1.1     skrll     return FALSE;
    1.1     skrll
    1.1     skrll   symtab_hdr = &elf_tdata (sec->owner)->symtab_hdr;
    1.1     skrll   psyms = &symtab_hdr->contents;
    1.1     skrll   irela = internal_relocs;
    1.1     skrll   irelaend = irela + sec->reloc_count;
    1.1     skrll   for (; irela < irelaend; irela++)
    1.1     skrll     {
    1.1     skrll       enum elf_spu_reloc_type r_type;
    1.1     skrll       unsigned int r_indx;
    1.1     skrll       asection *sym_sec;
    1.1     skrll       Elf_Internal_Sym *sym;
    1.1     skrll       struct elf_link_hash_entry *h;
    1.1     skrll       bfd_vma val;
1.1.1.2  christos       bfd_boolean nonbranch, is_call;
    1.1     skrll       struct function_info *caller;
    1.1     skrll       struct call_info *callee;
    1.1     skrll
    1.1     skrll       r_type = ELF32_R_TYPE (irela->r_info);
1.1.1.2  christos       nonbranch = r_type != R_SPU_REL16 && r_type != R_SPU_ADDR16;
    1.1     skrll
    1.1     skrll       r_indx = ELF32_R_SYM (irela->r_info);
    1.1     skrll       if (!get_sym_h (&h, &sym, &sym_sec, psyms, r_indx, sec->owner))
    1.1     skrll 	return FALSE;
    1.1     skrll
    1.1     skrll       if (sym_sec == NULL
1.1.1.2  christos 	  || sym_sec->output_section == bfd_abs_section_ptr)
    1.1     skrll 	continue;
    1.1     skrll
    1.1     skrll       is_call = FALSE;
1.1.1.2  christos       if (!nonbranch)
    1.1     skrll 	{
    1.1     skrll 	  unsigned char insn[4];
    1.1     skrll
    1.1     skrll 	  if (!bfd_get_section_contents (sec->owner, sec, insn,
    1.1     skrll 					 irela->r_offset, 4))
    1.1     skrll 	    return FALSE;
    1.1     skrll 	  if (is_branch (insn))
    1.1     skrll 	    {
    1.1     skrll 	      is_call = (insn[0] & 0xfd) == 0x31;
1.1.1.2  christos 	      priority = insn[1] & 0x0f;
1.1.1.2  christos 	      priority <<= 8;
1.1.1.2  christos 	      priority |= insn[2];
1.1.1.2  christos 	      priority <<= 8;
1.1.1.2  christos 	      priority |= insn[3];
1.1.1.2  christos 	      priority >>= 7;
    1.1     skrll 	      if ((sym_sec->flags & (SEC_ALLOC | SEC_LOAD | SEC_CODE))
    1.1     skrll 		  != (SEC_ALLOC | SEC_LOAD | SEC_CODE))
    1.1     skrll 		{
    1.1     skrll 		  if (!warned)
    1.1     skrll 		    info->callbacks->einfo
    1.1     skrll 		      (_("%B(%A+0x%v): call to non-code section"
    1.1     skrll 			 " %B(%A), analysis incomplete\n"),
    1.1     skrll 		       sec->owner, sec, irela->r_offset,
    1.1     skrll 		       sym_sec->owner, sym_sec);
    1.1     skrll 		  warned = TRUE;
    1.1     skrll 		  continue;
    1.1     skrll 		}
    1.1     skrll 	    }
    1.1     skrll 	  else
    1.1     skrll 	    {
1.1.1.2  christos 	      nonbranch = TRUE;
1.1.1.2  christos 	      if (is_hint (insn))
    1.1     skrll 		continue;
    1.1     skrll 	    }
    1.1     skrll 	}
    1.1     skrll
1.1.1.2  christos       if (nonbranch)
    1.1     skrll 	{
    1.1     skrll 	  /* For --auto-overlay, count possible stubs we need for
    1.1     skrll 	     function pointer references.  */
    1.1     skrll 	  unsigned int sym_type;
    1.1     skrll 	  if (h)
    1.1     skrll 	    sym_type = h->type;
    1.1     skrll 	  else
    1.1     skrll 	    sym_type = ELF_ST_TYPE (sym->st_info);
    1.1     skrll 	  if (sym_type == STT_FUNC)
1.1.1.2  christos 	    {
1.1.1.2  christos 	      if (call_tree && spu_hash_table (info)->params->auto_overlay)
1.1.1.2  christos 		spu_hash_table (info)->non_ovly_stub += 1;
1.1.1.2  christos 	      /* If the symbol type is STT_FUNC then this must be a
1.1.1.2  christos 		 function pointer initialisation.  */
1.1.1.2  christos 	      continue;
1.1.1.2  christos 	    }
1.1.1.2  christos 	  /* Ignore data references.  */
1.1.1.2  christos 	  if ((sym_sec->flags & (SEC_ALLOC | SEC_LOAD | SEC_CODE))
1.1.1.2  christos 	      != (SEC_ALLOC | SEC_LOAD | SEC_CODE))
1.1.1.2  christos 	    continue;
1.1.1.2  christos 	  /* Otherwise we probably have a jump table reloc for
1.1.1.2  christos 	     a switch statement or some other reference to a
1.1.1.2  christos 	     code label.  */
    1.1     skrll 	}
    1.1     skrll
    1.1     skrll       if (h)
    1.1     skrll 	val = h->root.u.def.value;
    1.1     skrll       else
    1.1     skrll 	val = sym->st_value;
    1.1     skrll       val += irela->r_addend;
    1.1     skrll
    1.1     skrll       if (!call_tree)
    1.1     skrll 	{
    1.1     skrll 	  struct function_info *fun;
    1.1     skrll
    1.1     skrll 	  if (irela->r_addend != 0)
    1.1     skrll 	    {
    1.1     skrll 	      Elf_Internal_Sym *fake = bfd_zmalloc (sizeof (*fake));
    1.1     skrll 	      if (fake == NULL)
    1.1     skrll 		return FALSE;
    1.1     skrll 	      fake->st_value = val;
    1.1     skrll 	      fake->st_shndx
    1.1     skrll 		= _bfd_elf_section_from_bfd_section (sym_sec->owner, sym_sec);
    1.1     skrll 	      sym = fake;
    1.1     skrll 	    }
    1.1     skrll 	  if (sym)
    1.1     skrll 	    fun = maybe_insert_function (sym_sec, sym, FALSE, is_call);
    1.1     skrll 	  else
    1.1     skrll 	    fun = maybe_insert_function (sym_sec, h, TRUE, is_call);
    1.1     skrll 	  if (fun == NULL)
    1.1     skrll 	    return FALSE;
    1.1     skrll 	  if (irela->r_addend != 0
    1.1     skrll 	      && fun->u.sym != sym)
    1.1     skrll 	    free (sym);
    1.1     skrll 	  continue;
    1.1     skrll 	}
    1.1     skrll
    1.1     skrll       caller = find_function (sec, irela->r_offset, info);
    1.1     skrll       if (caller == NULL)
    1.1     skrll 	return FALSE;
    1.1     skrll       callee = bfd_malloc (sizeof *callee);
    1.1     skrll       if (callee == NULL)
    1.1     skrll 	return FALSE;
    1.1     skrll
    1.1     skrll       callee->fun = find_function (sym_sec, val, info);
    1.1     skrll       if (callee->fun == NULL)
    1.1     skrll 	return FALSE;
    1.1     skrll       callee->is_tail = !is_call;
    1.1     skrll       callee->is_pasted = FALSE;
1.1.1.2  christos       callee->broken_cycle = FALSE;
1.1.1.2  christos       callee->priority = priority;
1.1.1.2  christos       callee->count = nonbranch? 0 : 1;
    1.1     skrll       if (callee->fun->last_caller != sec)
    1.1     skrll 	{
    1.1     skrll 	  callee->fun->last_caller = sec;
    1.1     skrll 	  callee->fun->call_count += 1;
    1.1     skrll 	}
    1.1     skrll       if (!insert_callee (caller, callee))
    1.1     skrll 	free (callee);
    1.1     skrll       else if (!is_call
    1.1     skrll 	       && !callee->fun->is_func
    1.1     skrll 	       && callee->fun->stack == 0)
    1.1     skrll 	{
    1.1     skrll 	  /* This is either a tail call or a branch from one part of
    1.1     skrll 	     the function to another, ie. hot/cold section.  If the
    1.1     skrll 	     destination has been called by some other function then
    1.1     skrll 	     it is a separate function.  We also assume that functions
    1.1     skrll 	     are not split across input files.  */
    1.1     skrll 	  if (sec->owner != sym_sec->owner)
    1.1     skrll 	    {
    1.1     skrll 	      callee->fun->start = NULL;
    1.1     skrll 	      callee->fun->is_func = TRUE;
    1.1     skrll 	    }
    1.1     skrll 	  else if (callee->fun->start == NULL)
1.1.1.2  christos 	    {
1.1.1.2  christos 	      struct function_info *caller_start = caller;
1.1.1.2  christos 	      while (caller_start->start)
1.1.1.2  christos 		caller_start = caller_start->start;
1.1.1.2  christos
1.1.1.2  christos 	      if (caller_start != callee->fun)
1.1.1.2  christos 		callee->fun->start = caller_start;
1.1.1.2  christos 	    }
    1.1     skrll 	  else
    1.1     skrll 	    {
    1.1     skrll 	      struct function_info *callee_start;
    1.1     skrll 	      struct function_info *caller_start;
    1.1     skrll 	      callee_start = callee->fun;
    1.1     skrll 	      while (callee_start->start)
    1.1     skrll 		callee_start = callee_start->start;
    1.1     skrll 	      caller_start = caller;
    1.1     skrll 	      while (caller_start->start)
    1.1     skrll 		caller_start = caller_start->start;
    1.1     skrll 	      if (caller_start != callee_start)
    1.1     skrll 		{
    1.1     skrll 		  callee->fun->start = NULL;
    1.1     skrll 		  callee->fun->is_func = TRUE;
    1.1     skrll 		}
    1.1     skrll 	    }
    1.1     skrll 	}
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Handle something like .init or .fini, which has a piece of a function.
    1.1     skrll    These sections are pasted together to form a single function.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
1.1.1.2  christos pasted_function (asection *sec)
    1.1     skrll {
    1.1     skrll   struct bfd_link_order *l;
    1.1     skrll   struct _spu_elf_section_data *sec_data;
    1.1     skrll   struct spu_elf_stack_info *sinfo;
    1.1     skrll   Elf_Internal_Sym *fake;
    1.1     skrll   struct function_info *fun, *fun_start;
    1.1     skrll
    1.1     skrll   fake = bfd_zmalloc (sizeof (*fake));
    1.1     skrll   if (fake == NULL)
    1.1     skrll     return FALSE;
    1.1     skrll   fake->st_value = 0;
    1.1     skrll   fake->st_size = sec->size;
    1.1     skrll   fake->st_shndx
    1.1     skrll     = _bfd_elf_section_from_bfd_section (sec->owner, sec);
    1.1     skrll   fun = maybe_insert_function (sec, fake, FALSE, FALSE);
    1.1     skrll   if (!fun)
    1.1     skrll     return FALSE;
    1.1     skrll
    1.1     skrll   /* Find a function immediately preceding this section.  */
    1.1     skrll   fun_start = NULL;
    1.1     skrll   for (l = sec->output_section->map_head.link_order; l != NULL; l = l->next)
    1.1     skrll     {
    1.1     skrll       if (l->u.indirect.section == sec)
    1.1     skrll 	{
    1.1     skrll 	  if (fun_start != NULL)
    1.1     skrll 	    {
    1.1     skrll 	      struct call_info *callee = bfd_malloc (sizeof *callee);
    1.1     skrll 	      if (callee == NULL)
    1.1     skrll 		return FALSE;
    1.1     skrll
    1.1     skrll 	      fun->start = fun_start;
    1.1     skrll 	      callee->fun = fun;
    1.1     skrll 	      callee->is_tail = TRUE;
    1.1     skrll 	      callee->is_pasted = TRUE;
1.1.1.2  christos 	      callee->broken_cycle = FALSE;
1.1.1.2  christos 	      callee->priority = 0;
1.1.1.2  christos 	      callee->count = 1;
    1.1     skrll 	      if (!insert_callee (fun_start, callee))
    1.1     skrll 		free (callee);
    1.1     skrll 	      return TRUE;
    1.1     skrll 	    }
    1.1     skrll 	  break;
    1.1     skrll 	}
    1.1     skrll       if (l->type == bfd_indirect_link_order
    1.1     skrll 	  && (sec_data = spu_elf_section_data (l->u.indirect.section)) != NULL
    1.1     skrll 	  && (sinfo = sec_data->u.i.stack_info) != NULL
    1.1     skrll 	  && sinfo->num_fun != 0)
    1.1     skrll 	fun_start = &sinfo->fun[sinfo->num_fun - 1];
    1.1     skrll     }
    1.1     skrll
1.1.1.2  christos   /* Don't return an error if we did not find a function preceding this
1.1.1.2  christos      section.  The section may have incorrect flags.  */
1.1.1.2  christos   return TRUE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Map address ranges in code sections to functions.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll discover_functions (struct bfd_link_info *info)
    1.1     skrll {
    1.1     skrll   bfd *ibfd;
    1.1     skrll   int bfd_idx;
    1.1     skrll   Elf_Internal_Sym ***psym_arr;
    1.1     skrll   asection ***sec_arr;
    1.1     skrll   bfd_boolean gaps = FALSE;
    1.1     skrll
    1.1     skrll   bfd_idx = 0;
1.1.1.4  christos   for (ibfd = info->input_bfds; ibfd != NULL; ibfd = ibfd->link.next)
    1.1     skrll     bfd_idx++;
    1.1     skrll
    1.1     skrll   psym_arr = bfd_zmalloc (bfd_idx * sizeof (*psym_arr));
    1.1     skrll   if (psym_arr == NULL)
    1.1     skrll     return FALSE;
    1.1     skrll   sec_arr = bfd_zmalloc (bfd_idx * sizeof (*sec_arr));
    1.1     skrll   if (sec_arr == NULL)
    1.1     skrll     return FALSE;
1.1.1.4  christos
    1.1     skrll   for (ibfd = info->input_bfds, bfd_idx = 0;
    1.1     skrll        ibfd != NULL;
1.1.1.4  christos        ibfd = ibfd->link.next, bfd_idx++)
    1.1     skrll     {
1.1.1.4  christos       extern const bfd_target spu_elf32_vec;
    1.1     skrll       Elf_Internal_Shdr *symtab_hdr;
    1.1     skrll       asection *sec;
    1.1     skrll       size_t symcount;
    1.1     skrll       Elf_Internal_Sym *syms, *sy, **psyms, **psy;
    1.1     skrll       asection **psecs, **p;
    1.1     skrll
1.1.1.4  christos       if (ibfd->xvec != &spu_elf32_vec)
    1.1     skrll 	continue;
    1.1     skrll
    1.1     skrll       /* Read all the symbols.  */
    1.1     skrll       symtab_hdr = &elf_tdata (ibfd)->symtab_hdr;
    1.1     skrll       symcount = symtab_hdr->sh_size / symtab_hdr->sh_entsize;
    1.1     skrll       if (symcount == 0)
    1.1     skrll 	{
    1.1     skrll 	  if (!gaps)
    1.1     skrll 	    for (sec = ibfd->sections; sec != NULL && !gaps; sec = sec->next)
1.1.1.2  christos 	      if (interesting_section (sec))
    1.1     skrll 		{
    1.1     skrll 		  gaps = TRUE;
    1.1     skrll 		  break;
    1.1     skrll 		}
    1.1     skrll 	  continue;
    1.1     skrll 	}
    1.1     skrll
    1.1     skrll       if (symtab_hdr->contents != NULL)
    1.1     skrll 	{
    1.1     skrll 	  /* Don't use cached symbols since the generic ELF linker
1.1.1.4  christos 	     code only reads local symbols, and we need globals too.  */
    1.1     skrll 	  free (symtab_hdr->contents);
    1.1     skrll 	  symtab_hdr->contents = NULL;
    1.1     skrll 	}
    1.1     skrll       syms = bfd_elf_get_elf_syms (ibfd, symtab_hdr, symcount, 0,
    1.1     skrll 				   NULL, NULL, NULL);
    1.1     skrll       symtab_hdr->contents = (void *) syms;
    1.1     skrll       if (syms == NULL)
    1.1     skrll 	return FALSE;
    1.1     skrll
    1.1     skrll       /* Select defined function symbols that are going to be output.  */
    1.1     skrll       psyms = bfd_malloc ((symcount + 1) * sizeof (*psyms));
    1.1     skrll       if (psyms == NULL)
    1.1     skrll 	return FALSE;
    1.1     skrll       psym_arr[bfd_idx] = psyms;
    1.1     skrll       psecs = bfd_malloc (symcount * sizeof (*psecs));
    1.1     skrll       if (psecs == NULL)
    1.1     skrll 	return FALSE;
    1.1     skrll       sec_arr[bfd_idx] = psecs;
    1.1     skrll       for (psy = psyms, p = psecs, sy = syms; sy < syms + symcount; ++p, ++sy)
    1.1     skrll 	if (ELF_ST_TYPE (sy->st_info) == STT_NOTYPE
    1.1     skrll 	    || ELF_ST_TYPE (sy->st_info) == STT_FUNC)
    1.1     skrll 	  {
    1.1     skrll 	    asection *s;
    1.1     skrll
    1.1     skrll 	    *p = s = bfd_section_from_elf_index (ibfd, sy->st_shndx);
1.1.1.2  christos 	    if (s != NULL && interesting_section (s))
    1.1     skrll 	      *psy++ = sy;
    1.1     skrll 	  }
    1.1     skrll       symcount = psy - psyms;
    1.1     skrll       *psy = NULL;
    1.1     skrll
    1.1     skrll       /* Sort them by section and offset within section.  */
    1.1     skrll       sort_syms_syms = syms;
    1.1     skrll       sort_syms_psecs = psecs;
    1.1     skrll       qsort (psyms, symcount, sizeof (*psyms), sort_syms);
    1.1     skrll
    1.1     skrll       /* Now inspect the function symbols.  */
    1.1     skrll       for (psy = psyms; psy < psyms + symcount; )
    1.1     skrll 	{
    1.1     skrll 	  asection *s = psecs[*psy - syms];
    1.1     skrll 	  Elf_Internal_Sym **psy2;
    1.1     skrll
    1.1     skrll 	  for (psy2 = psy; ++psy2 < psyms + symcount; )
    1.1     skrll 	    if (psecs[*psy2 - syms] != s)
    1.1     skrll 	      break;
    1.1     skrll
    1.1     skrll 	  if (!alloc_stack_info (s, psy2 - psy))
    1.1     skrll 	    return FALSE;
    1.1     skrll 	  psy = psy2;
    1.1     skrll 	}
    1.1     skrll
    1.1     skrll       /* First install info about properly typed and sized functions.
    1.1     skrll 	 In an ideal world this will cover all code sections, except
    1.1     skrll 	 when partitioning functions into hot and cold sections,
    1.1     skrll 	 and the horrible pasted together .init and .fini functions.  */
    1.1     skrll       for (psy = psyms; psy < psyms + symcount; ++psy)
    1.1     skrll 	{
    1.1     skrll 	  sy = *psy;
    1.1     skrll 	  if (ELF_ST_TYPE (sy->st_info) == STT_FUNC)
    1.1     skrll 	    {
    1.1     skrll 	      asection *s = psecs[sy - syms];
    1.1     skrll 	      if (!maybe_insert_function (s, sy, FALSE, TRUE))
    1.1     skrll 		return FALSE;
    1.1     skrll 	    }
    1.1     skrll 	}
    1.1     skrll
    1.1     skrll       for (sec = ibfd->sections; sec != NULL && !gaps; sec = sec->next)
1.1.1.2  christos 	if (interesting_section (sec))
    1.1     skrll 	  gaps |= check_function_ranges (sec, info);
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   if (gaps)
    1.1     skrll     {
    1.1     skrll       /* See if we can discover more function symbols by looking at
    1.1     skrll 	 relocations.  */
    1.1     skrll       for (ibfd = info->input_bfds, bfd_idx = 0;
    1.1     skrll 	   ibfd != NULL;
1.1.1.4  christos 	   ibfd = ibfd->link.next, bfd_idx++)
    1.1     skrll 	{
    1.1     skrll 	  asection *sec;
    1.1     skrll
    1.1     skrll 	  if (psym_arr[bfd_idx] == NULL)
    1.1     skrll 	    continue;
    1.1     skrll
    1.1     skrll 	  for (sec = ibfd->sections; sec != NULL; sec = sec->next)
    1.1     skrll 	    if (!mark_functions_via_relocs (sec, info, FALSE))
    1.1     skrll 	      return FALSE;
    1.1     skrll 	}
    1.1     skrll
    1.1     skrll       for (ibfd = info->input_bfds, bfd_idx = 0;
    1.1     skrll 	   ibfd != NULL;
1.1.1.4  christos 	   ibfd = ibfd->link.next, bfd_idx++)
    1.1     skrll 	{
    1.1     skrll 	  Elf_Internal_Shdr *symtab_hdr;
    1.1     skrll 	  asection *sec;
    1.1     skrll 	  Elf_Internal_Sym *syms, *sy, **psyms, **psy;
    1.1     skrll 	  asection **psecs;
    1.1     skrll
    1.1     skrll 	  if ((psyms = psym_arr[bfd_idx]) == NULL)
    1.1     skrll 	    continue;
    1.1     skrll
    1.1     skrll 	  psecs = sec_arr[bfd_idx];
    1.1     skrll
    1.1     skrll 	  symtab_hdr = &elf_tdata (ibfd)->symtab_hdr;
    1.1     skrll 	  syms = (Elf_Internal_Sym *) symtab_hdr->contents;
    1.1     skrll
    1.1     skrll 	  gaps = FALSE;
    1.1     skrll 	  for (sec = ibfd->sections; sec != NULL && !gaps; sec = sec->next)
1.1.1.2  christos 	    if (interesting_section (sec))
    1.1     skrll 	      gaps |= check_function_ranges (sec, info);
    1.1     skrll 	  if (!gaps)
    1.1     skrll 	    continue;
    1.1     skrll
    1.1     skrll 	  /* Finally, install all globals.  */
    1.1     skrll 	  for (psy = psyms; (sy = *psy) != NULL; ++psy)
    1.1     skrll 	    {
    1.1     skrll 	      asection *s;
    1.1     skrll
    1.1     skrll 	      s = psecs[sy - syms];
    1.1     skrll
    1.1     skrll 	      /* Global syms might be improperly typed functions.  */
    1.1     skrll 	      if (ELF_ST_TYPE (sy->st_info) != STT_FUNC
    1.1     skrll 		  && ELF_ST_BIND (sy->st_info) == STB_GLOBAL)
    1.1     skrll 		{
    1.1     skrll 		  if (!maybe_insert_function (s, sy, FALSE, FALSE))
    1.1     skrll 		    return FALSE;
    1.1     skrll 		}
    1.1     skrll 	    }
    1.1     skrll 	}
    1.1     skrll
1.1.1.4  christos       for (ibfd = info->input_bfds; ibfd != NULL; ibfd = ibfd->link.next)
    1.1     skrll 	{
1.1.1.4  christos 	  extern const bfd_target spu_elf32_vec;
    1.1     skrll 	  asection *sec;
    1.1     skrll
1.1.1.4  christos 	  if (ibfd->xvec != &spu_elf32_vec)
    1.1     skrll 	    continue;
    1.1     skrll
    1.1     skrll 	  /* Some of the symbols we've installed as marking the
    1.1     skrll 	     beginning of functions may have a size of zero.  Extend
    1.1     skrll 	     the range of such functions to the beginning of the
    1.1     skrll 	     next symbol of interest.  */
    1.1     skrll 	  for (sec = ibfd->sections; sec != NULL; sec = sec->next)
1.1.1.2  christos 	    if (interesting_section (sec))
    1.1     skrll 	      {
    1.1     skrll 		struct _spu_elf_section_data *sec_data;
    1.1     skrll 		struct spu_elf_stack_info *sinfo;
    1.1     skrll
    1.1     skrll 		sec_data = spu_elf_section_data (sec);
    1.1     skrll 		sinfo = sec_data->u.i.stack_info;
1.1.1.2  christos 		if (sinfo != NULL && sinfo->num_fun != 0)
    1.1     skrll 		  {
    1.1     skrll 		    int fun_idx;
    1.1     skrll 		    bfd_vma hi = sec->size;
    1.1     skrll
    1.1     skrll 		    for (fun_idx = sinfo->num_fun; --fun_idx >= 0; )
    1.1     skrll 		      {
    1.1     skrll 			sinfo->fun[fun_idx].hi = hi;
    1.1     skrll 			hi = sinfo->fun[fun_idx].lo;
    1.1     skrll 		      }
1.1.1.2  christos
1.1.1.2  christos 		    sinfo->fun[0].lo = 0;
    1.1     skrll 		  }
    1.1     skrll 		/* No symbols in this section.  Must be .init or .fini
    1.1     skrll 		   or something similar.  */
1.1.1.2  christos 		else if (!pasted_function (sec))
    1.1     skrll 		  return FALSE;
    1.1     skrll 	      }
    1.1     skrll 	}
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   for (ibfd = info->input_bfds, bfd_idx = 0;
    1.1     skrll        ibfd != NULL;
1.1.1.4  christos        ibfd = ibfd->link.next, bfd_idx++)
    1.1     skrll     {
    1.1     skrll       if (psym_arr[bfd_idx] == NULL)
    1.1     skrll 	continue;
    1.1     skrll
    1.1     skrll       free (psym_arr[bfd_idx]);
    1.1     skrll       free (sec_arr[bfd_idx]);
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   free (psym_arr);
    1.1     skrll   free (sec_arr);
    1.1     skrll
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Iterate over all function_info we have collected, calling DOIT on
    1.1     skrll    each node if ROOT_ONLY is false.  Only call DOIT on root nodes
    1.1     skrll    if ROOT_ONLY.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll for_each_node (bfd_boolean (*doit) (struct function_info *,
    1.1     skrll 				    struct bfd_link_info *,
    1.1     skrll 				    void *),
    1.1     skrll 	       struct bfd_link_info *info,
    1.1     skrll 	       void *param,
    1.1     skrll 	       int root_only)
    1.1     skrll {
    1.1     skrll   bfd *ibfd;
    1.1     skrll
1.1.1.4  christos   for (ibfd = info->input_bfds; ibfd != NULL; ibfd = ibfd->link.next)
    1.1     skrll     {
1.1.1.4  christos       extern const bfd_target spu_elf32_vec;
    1.1     skrll       asection *sec;
    1.1     skrll
1.1.1.4  christos       if (ibfd->xvec != &spu_elf32_vec)
    1.1     skrll 	continue;
    1.1     skrll
    1.1     skrll       for (sec = ibfd->sections; sec != NULL; sec = sec->next)
    1.1     skrll 	{
    1.1     skrll 	  struct _spu_elf_section_data *sec_data;
    1.1     skrll 	  struct spu_elf_stack_info *sinfo;
    1.1     skrll
    1.1     skrll 	  if ((sec_data = spu_elf_section_data (sec)) != NULL
    1.1     skrll 	      && (sinfo = sec_data->u.i.stack_info) != NULL)
    1.1     skrll 	    {
    1.1     skrll 	      int i;
    1.1     skrll 	      for (i = 0; i < sinfo->num_fun; ++i)
    1.1     skrll 		if (!root_only || !sinfo->fun[i].non_root)
    1.1     skrll 		  if (!doit (&sinfo->fun[i], info, param))
    1.1     skrll 		    return FALSE;
    1.1     skrll 	    }
    1.1     skrll 	}
    1.1     skrll     }
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Transfer call info attached to struct function_info entries for
    1.1     skrll    all of a given function's sections to the first entry.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll transfer_calls (struct function_info *fun,
    1.1     skrll 		struct bfd_link_info *info ATTRIBUTE_UNUSED,
    1.1     skrll 		void *param ATTRIBUTE_UNUSED)
    1.1     skrll {
    1.1     skrll   struct function_info *start = fun->start;
    1.1     skrll
    1.1     skrll   if (start != NULL)
    1.1     skrll     {
    1.1     skrll       struct call_info *call, *call_next;
    1.1     skrll
    1.1     skrll       while (start->start != NULL)
    1.1     skrll 	start = start->start;
    1.1     skrll       for (call = fun->call_list; call != NULL; call = call_next)
    1.1     skrll 	{
    1.1     skrll 	  call_next = call->next;
    1.1     skrll 	  if (!insert_callee (start, call))
    1.1     skrll 	    free (call);
    1.1     skrll 	}
    1.1     skrll       fun->call_list = NULL;
    1.1     skrll     }
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Mark nodes in the call graph that are called by some other node.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll mark_non_root (struct function_info *fun,
    1.1     skrll 	       struct bfd_link_info *info ATTRIBUTE_UNUSED,
    1.1     skrll 	       void *param ATTRIBUTE_UNUSED)
    1.1     skrll {
    1.1     skrll   struct call_info *call;
    1.1     skrll
    1.1     skrll   if (fun->visit1)
    1.1     skrll     return TRUE;
    1.1     skrll   fun->visit1 = TRUE;
    1.1     skrll   for (call = fun->call_list; call; call = call->next)
    1.1     skrll     {
    1.1     skrll       call->fun->non_root = TRUE;
    1.1     skrll       mark_non_root (call->fun, 0, 0);
    1.1     skrll     }
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Remove cycles from the call graph.  Set depth of nodes.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll remove_cycles (struct function_info *fun,
    1.1     skrll 	       struct bfd_link_info *info,
    1.1     skrll 	       void *param)
    1.1     skrll {
    1.1     skrll   struct call_info **callp, *call;
    1.1     skrll   unsigned int depth = *(unsigned int *) param;
    1.1     skrll   unsigned int max_depth = depth;
    1.1     skrll
    1.1     skrll   fun->depth = depth;
    1.1     skrll   fun->visit2 = TRUE;
    1.1     skrll   fun->marking = TRUE;
    1.1     skrll
    1.1     skrll   callp = &fun->call_list;
    1.1     skrll   while ((call = *callp) != NULL)
    1.1     skrll     {
1.1.1.2  christos       call->max_depth = depth + !call->is_pasted;
    1.1     skrll       if (!call->fun->visit2)
    1.1     skrll 	{
    1.1     skrll 	  if (!remove_cycles (call->fun, info, &call->max_depth))
    1.1     skrll 	    return FALSE;
    1.1     skrll 	  if (max_depth < call->max_depth)
    1.1     skrll 	    max_depth = call->max_depth;
    1.1     skrll 	}
    1.1     skrll       else if (call->fun->marking)
    1.1     skrll 	{
1.1.1.2  christos 	  struct spu_link_hash_table *htab = spu_hash_table (info);
1.1.1.2  christos
1.1.1.2  christos 	  if (!htab->params->auto_overlay
1.1.1.2  christos 	      && htab->params->stack_analysis)
    1.1     skrll 	    {
    1.1     skrll 	      const char *f1 = func_name (fun);
    1.1     skrll 	      const char *f2 = func_name (call->fun);
    1.1     skrll
    1.1     skrll 	      info->callbacks->info (_("Stack analysis will ignore the call "
    1.1     skrll 				       "from %s to %s\n"),
    1.1     skrll 				     f1, f2);
    1.1     skrll 	    }
1.1.1.2  christos
1.1.1.2  christos 	  call->broken_cycle = TRUE;
    1.1     skrll 	}
    1.1     skrll       callp = &call->next;
    1.1     skrll     }
    1.1     skrll   fun->marking = FALSE;
    1.1     skrll   *(unsigned int *) param = max_depth;
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
1.1.1.2  christos /* Check that we actually visited all nodes in remove_cycles.  If we
1.1.1.2  christos    didn't, then there is some cycle in the call graph not attached to
1.1.1.2  christos    any root node.  Arbitrarily choose a node in the cycle as a new
1.1.1.2  christos    root and break the cycle.  */
1.1.1.2  christos
1.1.1.2  christos static bfd_boolean
1.1.1.2  christos mark_detached_root (struct function_info *fun,
1.1.1.2  christos 		    struct bfd_link_info *info,
1.1.1.2  christos 		    void *param)
1.1.1.2  christos {
1.1.1.2  christos   if (fun->visit2)
1.1.1.2  christos     return TRUE;
1.1.1.2  christos   fun->non_root = FALSE;
1.1.1.2  christos   *(unsigned int *) param = 0;
1.1.1.2  christos   return remove_cycles (fun, info, param);
1.1.1.2  christos }
1.1.1.2  christos
    1.1     skrll /* Populate call_list for each function.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll build_call_tree (struct bfd_link_info *info)
    1.1     skrll {
    1.1     skrll   bfd *ibfd;
    1.1     skrll   unsigned int depth;
    1.1     skrll
1.1.1.4  christos   for (ibfd = info->input_bfds; ibfd != NULL; ibfd = ibfd->link.next)
    1.1     skrll     {
1.1.1.4  christos       extern const bfd_target spu_elf32_vec;
    1.1     skrll       asection *sec;
    1.1     skrll
1.1.1.4  christos       if (ibfd->xvec != &spu_elf32_vec)
    1.1     skrll 	continue;
    1.1     skrll
    1.1     skrll       for (sec = ibfd->sections; sec != NULL; sec = sec->next)
    1.1     skrll 	if (!mark_functions_via_relocs (sec, info, TRUE))
    1.1     skrll 	  return FALSE;
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   /* Transfer call info from hot/cold section part of function
    1.1     skrll      to main entry.  */
1.1.1.2  christos   if (!spu_hash_table (info)->params->auto_overlay
    1.1     skrll       && !for_each_node (transfer_calls, info, 0, FALSE))
    1.1     skrll     return FALSE;
    1.1     skrll
    1.1     skrll   /* Find the call graph root(s).  */
    1.1     skrll   if (!for_each_node (mark_non_root, info, 0, FALSE))
    1.1     skrll     return FALSE;
    1.1     skrll
    1.1     skrll   /* Remove cycles from the call graph.  We start from the root node(s)
    1.1     skrll      so that we break cycles in a reasonable place.  */
    1.1     skrll   depth = 0;
1.1.1.2  christos   if (!for_each_node (remove_cycles, info, &depth, TRUE))
1.1.1.2  christos     return FALSE;
1.1.1.2  christos
1.1.1.2  christos   return for_each_node (mark_detached_root, info, &depth, FALSE);
    1.1     skrll }
    1.1     skrll
1.1.1.2  christos /* qsort predicate to sort calls by priority, max_depth then count.  */
    1.1     skrll
    1.1     skrll static int
    1.1     skrll sort_calls (const void *a, const void *b)
    1.1     skrll {
    1.1     skrll   struct call_info *const *c1 = a;
    1.1     skrll   struct call_info *const *c2 = b;
    1.1     skrll   int delta;
    1.1     skrll
1.1.1.2  christos   delta = (*c2)->priority - (*c1)->priority;
1.1.1.2  christos   if (delta != 0)
1.1.1.2  christos     return delta;
1.1.1.2  christos
    1.1     skrll   delta = (*c2)->max_depth - (*c1)->max_depth;
    1.1     skrll   if (delta != 0)
    1.1     skrll     return delta;
    1.1     skrll
    1.1     skrll   delta = (*c2)->count - (*c1)->count;
    1.1     skrll   if (delta != 0)
    1.1     skrll     return delta;
    1.1     skrll
1.1.1.2  christos   return (char *) c1 - (char *) c2;
    1.1     skrll }
    1.1     skrll
    1.1     skrll struct _mos_param {
    1.1     skrll   unsigned int max_overlay_size;
    1.1     skrll };
    1.1     skrll
    1.1     skrll /* Set linker_mark and gc_mark on any sections that we will put in
    1.1     skrll    overlays.  These flags are used by the generic ELF linker, but we
    1.1     skrll    won't be continuing on to bfd_elf_final_link so it is OK to use
    1.1     skrll    them.  linker_mark is clear before we get here.  Set segment_mark
    1.1     skrll    on sections that are part of a pasted function (excluding the last
    1.1     skrll    section).
    1.1     skrll
    1.1     skrll    Set up function rodata section if --overlay-rodata.  We don't
    1.1     skrll    currently include merged string constant rodata sections since
    1.1     skrll
    1.1     skrll    Sort the call graph so that the deepest nodes will be visited
    1.1     skrll    first.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll mark_overlay_section (struct function_info *fun,
    1.1     skrll 		      struct bfd_link_info *info,
    1.1     skrll 		      void *param)
    1.1     skrll {
    1.1     skrll   struct call_info *call;
    1.1     skrll   unsigned int count;
    1.1     skrll   struct _mos_param *mos_param = param;
1.1.1.2  christos   struct spu_link_hash_table *htab = spu_hash_table (info);
    1.1     skrll
    1.1     skrll   if (fun->visit4)
    1.1     skrll     return TRUE;
    1.1     skrll
    1.1     skrll   fun->visit4 = TRUE;
1.1.1.2  christos   if (!fun->sec->linker_mark
1.1.1.2  christos       && (htab->params->ovly_flavour != ovly_soft_icache
1.1.1.2  christos 	  || htab->params->non_ia_text
1.1.1.2  christos 	  || strncmp (fun->sec->name, ".text.ia.", 9) == 0
1.1.1.2  christos 	  || strcmp (fun->sec->name, ".init") == 0
1.1.1.2  christos 	  || strcmp (fun->sec->name, ".fini") == 0))
    1.1     skrll     {
    1.1     skrll       unsigned int size;
    1.1     skrll
    1.1     skrll       fun->sec->linker_mark = 1;
    1.1     skrll       fun->sec->gc_mark = 1;
    1.1     skrll       fun->sec->segment_mark = 0;
    1.1     skrll       /* Ensure SEC_CODE is set on this text section (it ought to
    1.1     skrll 	 be!), and SEC_CODE is clear on rodata sections.  We use
    1.1     skrll 	 this flag to differentiate the two overlay section types.  */
    1.1     skrll       fun->sec->flags |= SEC_CODE;
    1.1     skrll
1.1.1.2  christos       size = fun->sec->size;
1.1.1.2  christos       if (htab->params->auto_overlay & OVERLAY_RODATA)
    1.1     skrll 	{
    1.1     skrll 	  char *name = NULL;
    1.1     skrll
    1.1     skrll 	  /* Find the rodata section corresponding to this function's
    1.1     skrll 	     text section.  */
    1.1     skrll 	  if (strcmp (fun->sec->name, ".text") == 0)
    1.1     skrll 	    {
    1.1     skrll 	      name = bfd_malloc (sizeof (".rodata"));
    1.1     skrll 	      if (name == NULL)
    1.1     skrll 		return FALSE;
    1.1     skrll 	      memcpy (name, ".rodata", sizeof (".rodata"));
    1.1     skrll 	    }
    1.1     skrll 	  else if (strncmp (fun->sec->name, ".text.", 6) == 0)
    1.1     skrll 	    {
    1.1     skrll 	      size_t len = strlen (fun->sec->name);
    1.1     skrll 	      name = bfd_malloc (len + 3);
    1.1     skrll 	      if (name == NULL)
    1.1     skrll 		return FALSE;
    1.1     skrll 	      memcpy (name, ".rodata", sizeof (".rodata"));
    1.1     skrll 	      memcpy (name + 7, fun->sec->name + 5, len - 4);
    1.1     skrll 	    }
    1.1     skrll 	  else if (strncmp (fun->sec->name, ".gnu.linkonce.t.", 16) == 0)
    1.1     skrll 	    {
    1.1     skrll 	      size_t len = strlen (fun->sec->name) + 1;
    1.1     skrll 	      name = bfd_malloc (len);
    1.1     skrll 	      if (name == NULL)
    1.1     skrll 		return FALSE;
    1.1     skrll 	      memcpy (name, fun->sec->name, len);
    1.1     skrll 	      name[14] = 'r';
    1.1     skrll 	    }
    1.1     skrll
    1.1     skrll 	  if (name != NULL)
    1.1     skrll 	    {
    1.1     skrll 	      asection *rodata = NULL;
    1.1     skrll 	      asection *group_sec = elf_section_data (fun->sec)->next_in_group;
    1.1     skrll 	      if (group_sec == NULL)
    1.1     skrll 		rodata = bfd_get_section_by_name (fun->sec->owner, name);
    1.1     skrll 	      else
    1.1     skrll 		while (group_sec != NULL && group_sec != fun->sec)
    1.1     skrll 		  {
    1.1     skrll 		    if (strcmp (group_sec->name, name) == 0)
    1.1     skrll 		      {
    1.1     skrll 			rodata = group_sec;
    1.1     skrll 			break;
    1.1     skrll 		      }
    1.1     skrll 		    group_sec = elf_section_data (group_sec)->next_in_group;
    1.1     skrll 		  }
    1.1     skrll 	      fun->rodata = rodata;
    1.1     skrll 	      if (fun->rodata)
    1.1     skrll 		{
1.1.1.2  christos 		  size += fun->rodata->size;
1.1.1.2  christos 		  if (htab->params->line_size != 0
1.1.1.2  christos 		      && size > htab->params->line_size)
1.1.1.2  christos 		    {
1.1.1.2  christos 		      size -= fun->rodata->size;
1.1.1.2  christos 		      fun->rodata = NULL;
1.1.1.2  christos 		    }
1.1.1.2  christos 		  else
1.1.1.2  christos 		    {
1.1.1.2  christos 		      fun->rodata->linker_mark = 1;
1.1.1.2  christos 		      fun->rodata->gc_mark = 1;
1.1.1.2  christos 		      fun->rodata->flags &= ~SEC_CODE;
1.1.1.2  christos 		    }
    1.1     skrll 		}
    1.1     skrll 	      free (name);
    1.1     skrll 	    }
    1.1     skrll 	}
    1.1     skrll       if (mos_param->max_overlay_size < size)
    1.1     skrll 	mos_param->max_overlay_size = size;
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   for (count = 0, call = fun->call_list; call != NULL; call = call->next)
    1.1     skrll     count += 1;
    1.1     skrll
    1.1     skrll   if (count > 1)
    1.1     skrll     {
    1.1     skrll       struct call_info **calls = bfd_malloc (count * sizeof (*calls));
    1.1     skrll       if (calls == NULL)
    1.1     skrll 	return FALSE;
    1.1     skrll
    1.1     skrll       for (count = 0, call = fun->call_list; call != NULL; call = call->next)
    1.1     skrll 	calls[count++] = call;
    1.1     skrll
    1.1     skrll       qsort (calls, count, sizeof (*calls), sort_calls);
    1.1     skrll
    1.1     skrll       fun->call_list = NULL;
    1.1     skrll       while (count != 0)
    1.1     skrll 	{
    1.1     skrll 	  --count;
    1.1     skrll 	  calls[count]->next = fun->call_list;
    1.1     skrll 	  fun->call_list = calls[count];
    1.1     skrll 	}
    1.1     skrll       free (calls);
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   for (call = fun->call_list; call != NULL; call = call->next)
    1.1     skrll     {
    1.1     skrll       if (call->is_pasted)
    1.1     skrll 	{
    1.1     skrll 	  /* There can only be one is_pasted call per function_info.  */
    1.1     skrll 	  BFD_ASSERT (!fun->sec->segment_mark);
    1.1     skrll 	  fun->sec->segment_mark = 1;
    1.1     skrll 	}
1.1.1.2  christos       if (!call->broken_cycle
1.1.1.2  christos 	  && !mark_overlay_section (call->fun, info, param))
    1.1     skrll 	return FALSE;
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   /* Don't put entry code into an overlay.  The overlay manager needs
1.1.1.2  christos      a stack!  Also, don't mark .ovl.init as an overlay.  */
    1.1     skrll   if (fun->lo + fun->sec->output_offset + fun->sec->output_section->vma
1.1.1.2  christos       == info->output_bfd->start_address
1.1.1.2  christos       || strncmp (fun->sec->output_section->name, ".ovl.init", 9) == 0)
    1.1     skrll     {
    1.1     skrll       fun->sec->linker_mark = 0;
    1.1     skrll       if (fun->rodata != NULL)
    1.1     skrll 	fun->rodata->linker_mark = 0;
    1.1     skrll     }
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* If non-zero then unmark functions called from those within sections
    1.1     skrll    that we need to unmark.  Unfortunately this isn't reliable since the
    1.1     skrll    call graph cannot know the destination of function pointer calls.  */
    1.1     skrll #define RECURSE_UNMARK 0
    1.1     skrll
    1.1     skrll struct _uos_param {
    1.1     skrll   asection *exclude_input_section;
    1.1     skrll   asection *exclude_output_section;
    1.1     skrll   unsigned long clearing;
    1.1     skrll };
    1.1     skrll
    1.1     skrll /* Undo some of mark_overlay_section's work.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll unmark_overlay_section (struct function_info *fun,
    1.1     skrll 			struct bfd_link_info *info,
    1.1     skrll 			void *param)
    1.1     skrll {
    1.1     skrll   struct call_info *call;
    1.1     skrll   struct _uos_param *uos_param = param;
    1.1     skrll   unsigned int excluded = 0;
    1.1     skrll
    1.1     skrll   if (fun->visit5)
    1.1     skrll     return TRUE;
    1.1     skrll
    1.1     skrll   fun->visit5 = TRUE;
    1.1     skrll
    1.1     skrll   excluded = 0;
    1.1     skrll   if (fun->sec == uos_param->exclude_input_section
    1.1     skrll       || fun->sec->output_section == uos_param->exclude_output_section)
    1.1     skrll     excluded = 1;
    1.1     skrll
    1.1     skrll   if (RECURSE_UNMARK)
    1.1     skrll     uos_param->clearing += excluded;
    1.1     skrll
    1.1     skrll   if (RECURSE_UNMARK ? uos_param->clearing : excluded)
    1.1     skrll     {
    1.1     skrll       fun->sec->linker_mark = 0;
    1.1     skrll       if (fun->rodata)
    1.1     skrll 	fun->rodata->linker_mark = 0;
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   for (call = fun->call_list; call != NULL; call = call->next)
1.1.1.2  christos     if (!call->broken_cycle
1.1.1.2  christos 	&& !unmark_overlay_section (call->fun, info, param))
    1.1     skrll       return FALSE;
    1.1     skrll
    1.1     skrll   if (RECURSE_UNMARK)
    1.1     skrll     uos_param->clearing -= excluded;
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll struct _cl_param {
    1.1     skrll   unsigned int lib_size;
    1.1     skrll   asection **lib_sections;
    1.1     skrll };
    1.1     skrll
    1.1     skrll /* Add sections we have marked as belonging to overlays to an array
    1.1     skrll    for consideration as non-overlay sections.  The array consist of
    1.1     skrll    pairs of sections, (text,rodata), for functions in the call graph.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll collect_lib_sections (struct function_info *fun,
    1.1     skrll 		      struct bfd_link_info *info,
    1.1     skrll 		      void *param)
    1.1     skrll {
    1.1     skrll   struct _cl_param *lib_param = param;
    1.1     skrll   struct call_info *call;
    1.1     skrll   unsigned int size;
    1.1     skrll
    1.1     skrll   if (fun->visit6)
    1.1     skrll     return TRUE;
    1.1     skrll
    1.1     skrll   fun->visit6 = TRUE;
    1.1     skrll   if (!fun->sec->linker_mark || !fun->sec->gc_mark || fun->sec->segment_mark)
    1.1     skrll     return TRUE;
    1.1     skrll
    1.1     skrll   size = fun->sec->size;
    1.1     skrll   if (fun->rodata)
    1.1     skrll     size += fun->rodata->size;
    1.1     skrll
1.1.1.2  christos   if (size <= lib_param->lib_size)
    1.1     skrll     {
1.1.1.2  christos       *lib_param->lib_sections++ = fun->sec;
1.1.1.2  christos       fun->sec->gc_mark = 0;
1.1.1.2  christos       if (fun->rodata && fun->rodata->linker_mark && fun->rodata->gc_mark)
1.1.1.2  christos 	{
1.1.1.2  christos 	  *lib_param->lib_sections++ = fun->rodata;
1.1.1.2  christos 	  fun->rodata->gc_mark = 0;
1.1.1.2  christos 	}
1.1.1.2  christos       else
1.1.1.2  christos 	*lib_param->lib_sections++ = NULL;
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   for (call = fun->call_list; call != NULL; call = call->next)
1.1.1.2  christos     if (!call->broken_cycle)
1.1.1.2  christos       collect_lib_sections (call->fun, info, param);
    1.1     skrll
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* qsort predicate to sort sections by call count.  */
    1.1     skrll
    1.1     skrll static int
    1.1     skrll sort_lib (const void *a, const void *b)
    1.1     skrll {
    1.1     skrll   asection *const *s1 = a;
    1.1     skrll   asection *const *s2 = b;
    1.1     skrll   struct _spu_elf_section_data *sec_data;
    1.1     skrll   struct spu_elf_stack_info *sinfo;
    1.1     skrll   int delta;
    1.1     skrll
    1.1     skrll   delta = 0;
    1.1     skrll   if ((sec_data = spu_elf_section_data (*s1)) != NULL
    1.1     skrll       && (sinfo = sec_data->u.i.stack_info) != NULL)
    1.1     skrll     {
    1.1     skrll       int i;
    1.1     skrll       for (i = 0; i < sinfo->num_fun; ++i)
    1.1     skrll 	delta -= sinfo->fun[i].call_count;
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   if ((sec_data = spu_elf_section_data (*s2)) != NULL
    1.1     skrll       && (sinfo = sec_data->u.i.stack_info) != NULL)
    1.1     skrll     {
    1.1     skrll       int i;
    1.1     skrll       for (i = 0; i < sinfo->num_fun; ++i)
    1.1     skrll 	delta += sinfo->fun[i].call_count;
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   if (delta != 0)
    1.1     skrll     return delta;
    1.1     skrll
    1.1     skrll   return s1 - s2;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Remove some sections from those marked to be in overlays.  Choose
    1.1     skrll    those that are called from many places, likely library functions.  */
    1.1     skrll
    1.1     skrll static unsigned int
    1.1     skrll auto_ovl_lib_functions (struct bfd_link_info *info, unsigned int lib_size)
    1.1     skrll {
    1.1     skrll   bfd *ibfd;
    1.1     skrll   asection **lib_sections;
    1.1     skrll   unsigned int i, lib_count;
    1.1     skrll   struct _cl_param collect_lib_param;
    1.1     skrll   struct function_info dummy_caller;
1.1.1.2  christos   struct spu_link_hash_table *htab;
    1.1     skrll
    1.1     skrll   memset (&dummy_caller, 0, sizeof (dummy_caller));
    1.1     skrll   lib_count = 0;
1.1.1.4  christos   for (ibfd = info->input_bfds; ibfd != NULL; ibfd = ibfd->link.next)
    1.1     skrll     {
1.1.1.4  christos       extern const bfd_target spu_elf32_vec;
    1.1     skrll       asection *sec;
    1.1     skrll
1.1.1.4  christos       if (ibfd->xvec != &spu_elf32_vec)
    1.1     skrll 	continue;
    1.1     skrll
    1.1     skrll       for (sec = ibfd->sections; sec != NULL; sec = sec->next)
    1.1     skrll 	if (sec->linker_mark
    1.1     skrll 	    && sec->size < lib_size
    1.1     skrll 	    && (sec->flags & SEC_CODE) != 0)
    1.1     skrll 	  lib_count += 1;
    1.1     skrll     }
    1.1     skrll   lib_sections = bfd_malloc (lib_count * 2 * sizeof (*lib_sections));
    1.1     skrll   if (lib_sections == NULL)
    1.1     skrll     return (unsigned int) -1;
    1.1     skrll   collect_lib_param.lib_size = lib_size;
    1.1     skrll   collect_lib_param.lib_sections = lib_sections;
    1.1     skrll   if (!for_each_node (collect_lib_sections, info, &collect_lib_param,
    1.1     skrll 		      TRUE))
    1.1     skrll     return (unsigned int) -1;
    1.1     skrll   lib_count = (collect_lib_param.lib_sections - lib_sections) / 2;
    1.1     skrll
    1.1     skrll   /* Sort sections so that those with the most calls are first.  */
    1.1     skrll   if (lib_count > 1)
    1.1     skrll     qsort (lib_sections, lib_count, 2 * sizeof (*lib_sections), sort_lib);
    1.1     skrll
1.1.1.2  christos   htab = spu_hash_table (info);
    1.1     skrll   for (i = 0; i < lib_count; i++)
    1.1     skrll     {
    1.1     skrll       unsigned int tmp, stub_size;
    1.1     skrll       asection *sec;
    1.1     skrll       struct _spu_elf_section_data *sec_data;
    1.1     skrll       struct spu_elf_stack_info *sinfo;
    1.1     skrll
    1.1     skrll       sec = lib_sections[2 * i];
    1.1     skrll       /* If this section is OK, its size must be less than lib_size.  */
    1.1     skrll       tmp = sec->size;
    1.1     skrll       /* If it has a rodata section, then add that too.  */
    1.1     skrll       if (lib_sections[2 * i + 1])
    1.1     skrll 	tmp += lib_sections[2 * i + 1]->size;
    1.1     skrll       /* Add any new overlay call stubs needed by the section.  */
    1.1     skrll       stub_size = 0;
    1.1     skrll       if (tmp < lib_size
    1.1     skrll 	  && (sec_data = spu_elf_section_data (sec)) != NULL
    1.1     skrll 	  && (sinfo = sec_data->u.i.stack_info) != NULL)
    1.1     skrll 	{
    1.1     skrll 	  int k;
    1.1     skrll 	  struct call_info *call;
    1.1     skrll
    1.1     skrll 	  for (k = 0; k < sinfo->num_fun; ++k)
    1.1     skrll 	    for (call = sinfo->fun[k].call_list; call; call = call->next)
    1.1     skrll 	      if (call->fun->sec->linker_mark)
    1.1     skrll 		{
    1.1     skrll 		  struct call_info *p;
    1.1     skrll 		  for (p = dummy_caller.call_list; p; p = p->next)
    1.1     skrll 		    if (p->fun == call->fun)
    1.1     skrll 		      break;
    1.1     skrll 		  if (!p)
1.1.1.2  christos 		    stub_size += ovl_stub_size (htab->params);
    1.1     skrll 		}
    1.1     skrll 	}
    1.1     skrll       if (tmp + stub_size < lib_size)
    1.1     skrll 	{
    1.1     skrll 	  struct call_info **pp, *p;
    1.1     skrll
    1.1     skrll 	  /* This section fits.  Mark it as non-overlay.  */
    1.1     skrll 	  lib_sections[2 * i]->linker_mark = 0;
    1.1     skrll 	  if (lib_sections[2 * i + 1])
    1.1     skrll 	    lib_sections[2 * i + 1]->linker_mark = 0;
    1.1     skrll 	  lib_size -= tmp + stub_size;
    1.1     skrll 	  /* Call stubs to the section we just added are no longer
    1.1     skrll 	     needed.  */
    1.1     skrll 	  pp = &dummy_caller.call_list;
    1.1     skrll 	  while ((p = *pp) != NULL)
    1.1     skrll 	    if (!p->fun->sec->linker_mark)
    1.1     skrll 	      {
1.1.1.2  christos 		lib_size += ovl_stub_size (htab->params);
    1.1     skrll 		*pp = p->next;
    1.1     skrll 		free (p);
    1.1     skrll 	      }
    1.1     skrll 	    else
    1.1     skrll 	      pp = &p->next;
    1.1     skrll 	  /* Add new call stubs to dummy_caller.  */
    1.1     skrll 	  if ((sec_data = spu_elf_section_data (sec)) != NULL
    1.1     skrll 	      && (sinfo = sec_data->u.i.stack_info) != NULL)
    1.1     skrll 	    {
    1.1     skrll 	      int k;
    1.1     skrll 	      struct call_info *call;
    1.1     skrll
    1.1     skrll 	      for (k = 0; k < sinfo->num_fun; ++k)
    1.1     skrll 		for (call = sinfo->fun[k].call_list;
    1.1     skrll 		     call;
    1.1     skrll 		     call = call->next)
    1.1     skrll 		  if (call->fun->sec->linker_mark)
    1.1     skrll 		    {
    1.1     skrll 		      struct call_info *callee;
    1.1     skrll 		      callee = bfd_malloc (sizeof (*callee));
    1.1     skrll 		      if (callee == NULL)
    1.1     skrll 			return (unsigned int) -1;
    1.1     skrll 		      *callee = *call;
    1.1     skrll 		      if (!insert_callee (&dummy_caller, callee))
    1.1     skrll 			free (callee);
    1.1     skrll 		    }
    1.1     skrll 	    }
    1.1     skrll 	}
    1.1     skrll     }
    1.1     skrll   while (dummy_caller.call_list != NULL)
    1.1     skrll     {
    1.1     skrll       struct call_info *call = dummy_caller.call_list;
    1.1     skrll       dummy_caller.call_list = call->next;
    1.1     skrll       free (call);
    1.1     skrll     }
    1.1     skrll   for (i = 0; i < 2 * lib_count; i++)
    1.1     skrll     if (lib_sections[i])
    1.1     skrll       lib_sections[i]->gc_mark = 1;
    1.1     skrll   free (lib_sections);
    1.1     skrll   return lib_size;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Build an array of overlay sections.  The deepest node's section is
    1.1     skrll    added first, then its parent node's section, then everything called
    1.1     skrll    from the parent section.  The idea being to group sections to
    1.1     skrll    minimise calls between different overlays.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll collect_overlays (struct function_info *fun,
    1.1     skrll 		  struct bfd_link_info *info,
    1.1     skrll 		  void *param)
    1.1     skrll {
    1.1     skrll   struct call_info *call;
    1.1     skrll   bfd_boolean added_fun;
    1.1     skrll   asection ***ovly_sections = param;
    1.1     skrll
    1.1     skrll   if (fun->visit7)
    1.1     skrll     return TRUE;
    1.1     skrll
    1.1     skrll   fun->visit7 = TRUE;
    1.1     skrll   for (call = fun->call_list; call != NULL; call = call->next)
1.1.1.2  christos     if (!call->is_pasted && !call->broken_cycle)
    1.1     skrll       {
    1.1     skrll 	if (!collect_overlays (call->fun, info, ovly_sections))
    1.1     skrll 	  return FALSE;
    1.1     skrll 	break;
    1.1     skrll       }
    1.1     skrll
    1.1     skrll   added_fun = FALSE;
    1.1     skrll   if (fun->sec->linker_mark && fun->sec->gc_mark)
    1.1     skrll     {
    1.1     skrll       fun->sec->gc_mark = 0;
    1.1     skrll       *(*ovly_sections)++ = fun->sec;
    1.1     skrll       if (fun->rodata && fun->rodata->linker_mark && fun->rodata->gc_mark)
    1.1     skrll 	{
    1.1     skrll 	  fun->rodata->gc_mark = 0;
    1.1     skrll 	  *(*ovly_sections)++ = fun->rodata;
    1.1     skrll 	}
    1.1     skrll       else
    1.1     skrll 	*(*ovly_sections)++ = NULL;
    1.1     skrll       added_fun = TRUE;
    1.1     skrll
    1.1     skrll       /* Pasted sections must stay with the first section.  We don't
    1.1     skrll 	 put pasted sections in the array, just the first section.
    1.1     skrll 	 Mark subsequent sections as already considered.  */
    1.1     skrll       if (fun->sec->segment_mark)
    1.1     skrll 	{
    1.1     skrll 	  struct function_info *call_fun = fun;
    1.1     skrll 	  do
    1.1     skrll 	    {
    1.1     skrll 	      for (call = call_fun->call_list; call != NULL; call = call->next)
    1.1     skrll 		if (call->is_pasted)
    1.1     skrll 		  {
    1.1     skrll 		    call_fun = call->fun;
    1.1     skrll 		    call_fun->sec->gc_mark = 0;
    1.1     skrll 		    if (call_fun->rodata)
    1.1     skrll 		      call_fun->rodata->gc_mark = 0;
    1.1     skrll 		    break;
    1.1     skrll 		  }
    1.1     skrll 	      if (call == NULL)
    1.1     skrll 		abort ();
    1.1     skrll 	    }
    1.1     skrll 	  while (call_fun->sec->segment_mark);
    1.1     skrll 	}
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   for (call = fun->call_list; call != NULL; call = call->next)
1.1.1.2  christos     if (!call->broken_cycle
1.1.1.2  christos 	&& !collect_overlays (call->fun, info, ovly_sections))
    1.1     skrll       return FALSE;
    1.1     skrll
    1.1     skrll   if (added_fun)
    1.1     skrll     {
    1.1     skrll       struct _spu_elf_section_data *sec_data;
    1.1     skrll       struct spu_elf_stack_info *sinfo;
    1.1     skrll
    1.1     skrll       if ((sec_data = spu_elf_section_data (fun->sec)) != NULL
    1.1     skrll 	  && (sinfo = sec_data->u.i.stack_info) != NULL)
    1.1     skrll 	{
    1.1     skrll 	  int i;
    1.1     skrll 	  for (i = 0; i < sinfo->num_fun; ++i)
    1.1     skrll 	    if (!collect_overlays (&sinfo->fun[i], info, ovly_sections))
    1.1     skrll 	      return FALSE;
    1.1     skrll 	}
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll struct _sum_stack_param {
    1.1     skrll   size_t cum_stack;
    1.1     skrll   size_t overall_stack;
    1.1     skrll   bfd_boolean emit_stack_syms;
    1.1     skrll };
    1.1     skrll
    1.1     skrll /* Descend the call graph for FUN, accumulating total stack required.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll sum_stack (struct function_info *fun,
    1.1     skrll 	   struct bfd_link_info *info,
    1.1     skrll 	   void *param)
    1.1     skrll {
    1.1     skrll   struct call_info *call;
    1.1     skrll   struct function_info *max;
    1.1     skrll   size_t stack, cum_stack;
    1.1     skrll   const char *f1;
    1.1     skrll   bfd_boolean has_call;
    1.1     skrll   struct _sum_stack_param *sum_stack_param = param;
    1.1     skrll   struct spu_link_hash_table *htab;
    1.1     skrll
    1.1     skrll   cum_stack = fun->stack;
    1.1     skrll   sum_stack_param->cum_stack = cum_stack;
    1.1     skrll   if (fun->visit3)
    1.1     skrll     return TRUE;
    1.1     skrll
    1.1     skrll   has_call = FALSE;
    1.1     skrll   max = NULL;
    1.1     skrll   for (call = fun->call_list; call; call = call->next)
    1.1     skrll     {
1.1.1.2  christos       if (call->broken_cycle)
1.1.1.2  christos 	continue;
    1.1     skrll       if (!call->is_pasted)
    1.1     skrll 	has_call = TRUE;
    1.1     skrll       if (!sum_stack (call->fun, info, sum_stack_param))
    1.1     skrll 	return FALSE;
    1.1     skrll       stack = sum_stack_param->cum_stack;
    1.1     skrll       /* Include caller stack for normal calls, don't do so for
    1.1     skrll 	 tail calls.  fun->stack here is local stack usage for
    1.1     skrll 	 this function.  */
    1.1     skrll       if (!call->is_tail || call->is_pasted || call->fun->start != NULL)
    1.1     skrll 	stack += fun->stack;
    1.1     skrll       if (cum_stack < stack)
    1.1     skrll 	{
    1.1     skrll 	  cum_stack = stack;
    1.1     skrll 	  max = call->fun;
    1.1     skrll 	}
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   sum_stack_param->cum_stack = cum_stack;
    1.1     skrll   stack = fun->stack;
    1.1     skrll   /* Now fun->stack holds cumulative stack.  */
    1.1     skrll   fun->stack = cum_stack;
    1.1     skrll   fun->visit3 = TRUE;
    1.1     skrll
    1.1     skrll   if (!fun->non_root
    1.1     skrll       && sum_stack_param->overall_stack < cum_stack)
    1.1     skrll     sum_stack_param->overall_stack = cum_stack;
    1.1     skrll
    1.1     skrll   htab = spu_hash_table (info);
1.1.1.2  christos   if (htab->params->auto_overlay)
    1.1     skrll     return TRUE;
    1.1     skrll
    1.1     skrll   f1 = func_name (fun);
1.1.1.2  christos   if (htab->params->stack_analysis)
1.1.1.2  christos     {
1.1.1.2  christos       if (!fun->non_root)
1.1.1.2  christos 	info->callbacks->info (_("  %s: 0x%v\n"), f1, (bfd_vma) cum_stack);
1.1.1.2  christos       info->callbacks->minfo (_("%s: 0x%v 0x%v\n"),
1.1.1.2  christos 			      f1, (bfd_vma) stack, (bfd_vma) cum_stack);
1.1.1.2  christos
1.1.1.2  christos       if (has_call)
1.1.1.2  christos 	{
1.1.1.2  christos 	  info->callbacks->minfo (_("  calls:\n"));
1.1.1.2  christos 	  for (call = fun->call_list; call; call = call->next)
1.1.1.2  christos 	    if (!call->is_pasted && !call->broken_cycle)
1.1.1.2  christos 	      {
1.1.1.2  christos 		const char *f2 = func_name (call->fun);
1.1.1.2  christos 		const char *ann1 = call->fun == max ? "*" : " ";
1.1.1.2  christos 		const char *ann2 = call->is_tail ? "t" : " ";
    1.1     skrll
1.1.1.2  christos 		info->callbacks->minfo (_("   %s%s %s\n"), ann1, ann2, f2);
1.1.1.2  christos 	      }
1.1.1.2  christos 	}
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   if (sum_stack_param->emit_stack_syms)
    1.1     skrll     {
    1.1     skrll       char *name = bfd_malloc (18 + strlen (f1));
    1.1     skrll       struct elf_link_hash_entry *h;
    1.1     skrll
    1.1     skrll       if (name == NULL)
    1.1     skrll 	return FALSE;
    1.1     skrll
    1.1     skrll       if (fun->global || ELF_ST_BIND (fun->u.sym->st_info) == STB_GLOBAL)
    1.1     skrll 	sprintf (name, "__stack_%s", f1);
    1.1     skrll       else
    1.1     skrll 	sprintf (name, "__stack_%x_%s", fun->sec->id & 0xffffffff, f1);
    1.1     skrll
    1.1     skrll       h = elf_link_hash_lookup (&htab->elf, name, TRUE, TRUE, FALSE);
    1.1     skrll       free (name);
    1.1     skrll       if (h != NULL
    1.1     skrll 	  && (h->root.type == bfd_link_hash_new
    1.1     skrll 	      || h->root.type == bfd_link_hash_undefined
    1.1     skrll 	      || h->root.type == bfd_link_hash_undefweak))
    1.1     skrll 	{
    1.1     skrll 	  h->root.type = bfd_link_hash_defined;
    1.1     skrll 	  h->root.u.def.section = bfd_abs_section_ptr;
    1.1     skrll 	  h->root.u.def.value = cum_stack;
    1.1     skrll 	  h->size = 0;
    1.1     skrll 	  h->type = 0;
    1.1     skrll 	  h->ref_regular = 1;
    1.1     skrll 	  h->def_regular = 1;
    1.1     skrll 	  h->ref_regular_nonweak = 1;
    1.1     skrll 	  h->forced_local = 1;
    1.1     skrll 	  h->non_elf = 0;
    1.1     skrll 	}
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* SEC is part of a pasted function.  Return the call_info for the
    1.1     skrll    next section of this function.  */
    1.1     skrll
    1.1     skrll static struct call_info *
    1.1     skrll find_pasted_call (asection *sec)
    1.1     skrll {
    1.1     skrll   struct _spu_elf_section_data *sec_data = spu_elf_section_data (sec);
    1.1     skrll   struct spu_elf_stack_info *sinfo = sec_data->u.i.stack_info;
    1.1     skrll   struct call_info *call;
    1.1     skrll   int k;
    1.1     skrll
    1.1     skrll   for (k = 0; k < sinfo->num_fun; ++k)
    1.1     skrll     for (call = sinfo->fun[k].call_list; call != NULL; call = call->next)
    1.1     skrll       if (call->is_pasted)
    1.1     skrll 	return call;
    1.1     skrll   abort ();
    1.1     skrll   return 0;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* qsort predicate to sort bfds by file name.  */
    1.1     skrll
1.1.1.2  christos static int
1.1.1.2  christos sort_bfds (const void *a, const void *b)
1.1.1.2  christos {
1.1.1.2  christos   bfd *const *abfd1 = a;
1.1.1.2  christos   bfd *const *abfd2 = b;
1.1.1.2  christos
1.1.1.3  christos   return filename_cmp ((*abfd1)->filename, (*abfd2)->filename);
1.1.1.2  christos }
1.1.1.2  christos
1.1.1.2  christos static unsigned int
1.1.1.2  christos print_one_overlay_section (FILE *script,
1.1.1.2  christos 			   unsigned int base,
1.1.1.2  christos 			   unsigned int count,
1.1.1.2  christos 			   unsigned int ovlynum,
1.1.1.2  christos 			   unsigned int *ovly_map,
1.1.1.2  christos 			   asection **ovly_sections,
1.1.1.2  christos 			   struct bfd_link_info *info)
1.1.1.2  christos {
1.1.1.2  christos   unsigned int j;
1.1.1.4  christos
1.1.1.2  christos   for (j = base; j < count && ovly_map[j] == ovlynum; j++)
1.1.1.2  christos     {
1.1.1.2  christos       asection *sec = ovly_sections[2 * j];
1.1.1.2  christos
1.1.1.2  christos       if (fprintf (script, "   %s%c%s (%s)\n",
1.1.1.2  christos 		   (sec->owner->my_archive != NULL
1.1.1.2  christos 		    ? sec->owner->my_archive->filename : ""),
1.1.1.2  christos 		   info->path_separator,
1.1.1.2  christos 		   sec->owner->filename,
1.1.1.2  christos 		   sec->name) <= 0)
1.1.1.2  christos 	return -1;
1.1.1.2  christos       if (sec->segment_mark)
1.1.1.2  christos 	{
1.1.1.2  christos 	  struct call_info *call = find_pasted_call (sec);
1.1.1.2  christos 	  while (call != NULL)
1.1.1.2  christos 	    {
1.1.1.2  christos 	      struct function_info *call_fun = call->fun;
1.1.1.2  christos 	      sec = call_fun->sec;
1.1.1.2  christos 	      if (fprintf (script, "   %s%c%s (%s)\n",
1.1.1.2  christos 			   (sec->owner->my_archive != NULL
1.1.1.2  christos 			    ? sec->owner->my_archive->filename : ""),
1.1.1.2  christos 			   info->path_separator,
1.1.1.2  christos 			   sec->owner->filename,
1.1.1.2  christos 			   sec->name) <= 0)
1.1.1.2  christos 		return -1;
1.1.1.2  christos 	      for (call = call_fun->call_list; call; call = call->next)
1.1.1.2  christos 		if (call->is_pasted)
1.1.1.2  christos 		  break;
1.1.1.2  christos 	    }
1.1.1.2  christos 	}
1.1.1.2  christos     }
1.1.1.2  christos
1.1.1.2  christos   for (j = base; j < count && ovly_map[j] == ovlynum; j++)
1.1.1.2  christos     {
1.1.1.2  christos       asection *sec = ovly_sections[2 * j + 1];
1.1.1.2  christos       if (sec != NULL
1.1.1.2  christos 	  && fprintf (script, "   %s%c%s (%s)\n",
1.1.1.2  christos 		      (sec->owner->my_archive != NULL
1.1.1.2  christos 		       ? sec->owner->my_archive->filename : ""),
1.1.1.2  christos 		      info->path_separator,
1.1.1.2  christos 		      sec->owner->filename,
1.1.1.2  christos 		      sec->name) <= 0)
1.1.1.2  christos 	return -1;
1.1.1.2  christos
1.1.1.2  christos       sec = ovly_sections[2 * j];
1.1.1.2  christos       if (sec->segment_mark)
1.1.1.2  christos 	{
1.1.1.2  christos 	  struct call_info *call = find_pasted_call (sec);
1.1.1.2  christos 	  while (call != NULL)
1.1.1.2  christos 	    {
1.1.1.2  christos 	      struct function_info *call_fun = call->fun;
1.1.1.2  christos 	      sec = call_fun->rodata;
1.1.1.2  christos 	      if (sec != NULL
1.1.1.2  christos 		  && fprintf (script, "   %s%c%s (%s)\n",
1.1.1.2  christos 			      (sec->owner->my_archive != NULL
1.1.1.2  christos 			       ? sec->owner->my_archive->filename : ""),
1.1.1.2  christos 			      info->path_separator,
1.1.1.2  christos 			      sec->owner->filename,
1.1.1.2  christos 			      sec->name) <= 0)
1.1.1.2  christos 		return -1;
1.1.1.2  christos 	      for (call = call_fun->call_list; call; call = call->next)
1.1.1.2  christos 		if (call->is_pasted)
1.1.1.2  christos 		  break;
1.1.1.2  christos 	    }
1.1.1.2  christos 	}
1.1.1.2  christos     }
    1.1     skrll
1.1.1.2  christos   return j;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Handle --auto-overlay.  */
    1.1     skrll
    1.1     skrll static void
1.1.1.2  christos spu_elf_auto_overlay (struct bfd_link_info *info)
    1.1     skrll {
    1.1     skrll   bfd *ibfd;
    1.1     skrll   bfd **bfd_arr;
    1.1     skrll   struct elf_segment_map *m;
    1.1     skrll   unsigned int fixed_size, lo, hi;
1.1.1.2  christos   unsigned int reserved;
    1.1     skrll   struct spu_link_hash_table *htab;
    1.1     skrll   unsigned int base, i, count, bfd_count;
1.1.1.2  christos   unsigned int region, ovlynum;
    1.1     skrll   asection **ovly_sections, **ovly_p;
1.1.1.2  christos   unsigned int *ovly_map;
    1.1     skrll   FILE *script;
    1.1     skrll   unsigned int total_overlay_size, overlay_size;
1.1.1.2  christos   const char *ovly_mgr_entry;
    1.1     skrll   struct elf_link_hash_entry *h;
    1.1     skrll   struct _mos_param mos_param;
    1.1     skrll   struct _uos_param uos_param;
    1.1     skrll   struct function_info dummy_caller;
    1.1     skrll
    1.1     skrll   /* Find the extents of our loadable image.  */
    1.1     skrll   lo = (unsigned int) -1;
    1.1     skrll   hi = 0;
1.1.1.4  christos   for (m = elf_seg_map (info->output_bfd); m != NULL; m = m->next)
    1.1     skrll     if (m->p_type == PT_LOAD)
    1.1     skrll       for (i = 0; i < m->count; i++)
    1.1     skrll 	if (m->sections[i]->size != 0)
    1.1     skrll 	  {
    1.1     skrll 	    if (m->sections[i]->vma < lo)
    1.1     skrll 	      lo = m->sections[i]->vma;
    1.1     skrll 	    if (m->sections[i]->vma + m->sections[i]->size - 1 > hi)
    1.1     skrll 	      hi = m->sections[i]->vma + m->sections[i]->size - 1;
    1.1     skrll 	  }
    1.1     skrll   fixed_size = hi + 1 - lo;
    1.1     skrll
    1.1     skrll   if (!discover_functions (info))
    1.1     skrll     goto err_exit;
    1.1     skrll
    1.1     skrll   if (!build_call_tree (info))
    1.1     skrll     goto err_exit;
    1.1     skrll
1.1.1.2  christos   htab = spu_hash_table (info);
1.1.1.2  christos   reserved = htab->params->auto_overlay_reserved;
1.1.1.2  christos   if (reserved == 0)
1.1.1.2  christos     {
1.1.1.2  christos       struct _sum_stack_param sum_stack_param;
1.1.1.2  christos
1.1.1.2  christos       sum_stack_param.emit_stack_syms = 0;
1.1.1.2  christos       sum_stack_param.overall_stack = 0;
1.1.1.2  christos       if (!for_each_node (sum_stack, info, &sum_stack_param, TRUE))
1.1.1.2  christos 	goto err_exit;
1.1.1.2  christos       reserved = (sum_stack_param.overall_stack
1.1.1.2  christos 		  + htab->params->extra_stack_space);
1.1.1.2  christos     }
1.1.1.2  christos
1.1.1.2  christos   /* No need for overlays if everything already fits.  */
1.1.1.2  christos   if (fixed_size + reserved <= htab->local_store
1.1.1.2  christos       && htab->params->ovly_flavour != ovly_soft_icache)
1.1.1.2  christos     {
1.1.1.2  christos       htab->params->auto_overlay = 0;
1.1.1.2  christos       return;
1.1.1.2  christos     }
1.1.1.2  christos
    1.1     skrll   uos_param.exclude_input_section = 0;
    1.1     skrll   uos_param.exclude_output_section
    1.1     skrll     = bfd_get_section_by_name (info->output_bfd, ".interrupt");
    1.1     skrll
1.1.1.2  christos   ovly_mgr_entry = "__ovly_load";
1.1.1.2  christos   if (htab->params->ovly_flavour == ovly_soft_icache)
1.1.1.2  christos     ovly_mgr_entry = "__icache_br_handler";
1.1.1.2  christos   h = elf_link_hash_lookup (&htab->elf, ovly_mgr_entry,
    1.1     skrll 			    FALSE, FALSE, FALSE);
    1.1     skrll   if (h != NULL
    1.1     skrll       && (h->root.type == bfd_link_hash_defined
    1.1     skrll 	  || h->root.type == bfd_link_hash_defweak)
    1.1     skrll       && h->def_regular)
    1.1     skrll     {
    1.1     skrll       /* We have a user supplied overlay manager.  */
    1.1     skrll       uos_param.exclude_input_section = h->root.u.def.section;
    1.1     skrll     }
    1.1     skrll   else
    1.1     skrll     {
    1.1     skrll       /* If no user overlay manager, spu_elf_load_ovl_mgr will add our
    1.1     skrll 	 builtin version to .text, and will adjust .text size.  */
1.1.1.2  christos       fixed_size += (*htab->params->spu_elf_load_ovl_mgr) ();
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   /* Mark overlay sections, and find max overlay section size.  */
    1.1     skrll   mos_param.max_overlay_size = 0;
    1.1     skrll   if (!for_each_node (mark_overlay_section, info, &mos_param, TRUE))
    1.1     skrll     goto err_exit;
    1.1     skrll
    1.1     skrll   /* We can't put the overlay manager or interrupt routines in
    1.1     skrll      overlays.  */
    1.1     skrll   uos_param.clearing = 0;
    1.1     skrll   if ((uos_param.exclude_input_section
    1.1     skrll        || uos_param.exclude_output_section)
    1.1     skrll       && !for_each_node (unmark_overlay_section, info, &uos_param, TRUE))
    1.1     skrll     goto err_exit;
    1.1     skrll
    1.1     skrll   bfd_count = 0;
1.1.1.4  christos   for (ibfd = info->input_bfds; ibfd != NULL; ibfd = ibfd->link.next)
    1.1     skrll     ++bfd_count;
    1.1     skrll   bfd_arr = bfd_malloc (bfd_count * sizeof (*bfd_arr));
    1.1     skrll   if (bfd_arr == NULL)
    1.1     skrll     goto err_exit;
    1.1     skrll
    1.1     skrll   /* Count overlay sections, and subtract their sizes from "fixed_size".  */
    1.1     skrll   count = 0;
    1.1     skrll   bfd_count = 0;
    1.1     skrll   total_overlay_size = 0;
1.1.1.4  christos   for (ibfd = info->input_bfds; ibfd != NULL; ibfd = ibfd->link.next)
    1.1     skrll     {
1.1.1.4  christos       extern const bfd_target spu_elf32_vec;
    1.1     skrll       asection *sec;
    1.1     skrll       unsigned int old_count;
    1.1     skrll
1.1.1.4  christos       if (ibfd->xvec != &spu_elf32_vec)
    1.1     skrll 	continue;
    1.1     skrll
    1.1     skrll       old_count = count;
    1.1     skrll       for (sec = ibfd->sections; sec != NULL; sec = sec->next)
    1.1     skrll 	if (sec->linker_mark)
    1.1     skrll 	  {
    1.1     skrll 	    if ((sec->flags & SEC_CODE) != 0)
    1.1     skrll 	      count += 1;
    1.1     skrll 	    fixed_size -= sec->size;
    1.1     skrll 	    total_overlay_size += sec->size;
    1.1     skrll 	  }
1.1.1.2  christos 	else if ((sec->flags & (SEC_ALLOC | SEC_LOAD)) == (SEC_ALLOC | SEC_LOAD)
1.1.1.2  christos 		 && sec->output_section->owner == info->output_bfd
1.1.1.2  christos 		 && strncmp (sec->output_section->name, ".ovl.init", 9) == 0)
1.1.1.2  christos 	  fixed_size -= sec->size;
    1.1     skrll       if (count != old_count)
    1.1     skrll 	bfd_arr[bfd_count++] = ibfd;
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   /* Since the overlay link script selects sections by file name and
    1.1     skrll      section name, ensure that file names are unique.  */
    1.1     skrll   if (bfd_count > 1)
    1.1     skrll     {
    1.1     skrll       bfd_boolean ok = TRUE;
    1.1     skrll
    1.1     skrll       qsort (bfd_arr, bfd_count, sizeof (*bfd_arr), sort_bfds);
    1.1     skrll       for (i = 1; i < bfd_count; ++i)
1.1.1.3  christos 	if (filename_cmp (bfd_arr[i - 1]->filename, bfd_arr[i]->filename) == 0)
    1.1     skrll 	  {
    1.1     skrll 	    if (bfd_arr[i - 1]->my_archive == bfd_arr[i]->my_archive)
    1.1     skrll 	      {
    1.1     skrll 		if (bfd_arr[i - 1]->my_archive && bfd_arr[i]->my_archive)
    1.1     skrll 		  info->callbacks->einfo (_("%s duplicated in %s\n"),
    1.1     skrll 					  bfd_arr[i]->filename,
    1.1     skrll 					  bfd_arr[i]->my_archive->filename);
    1.1     skrll 		else
    1.1     skrll 		  info->callbacks->einfo (_("%s duplicated\n"),
    1.1     skrll 					  bfd_arr[i]->filename);
    1.1     skrll 		ok = FALSE;
    1.1     skrll 	      }
    1.1     skrll 	  }
    1.1     skrll       if (!ok)
    1.1     skrll 	{
    1.1     skrll 	  info->callbacks->einfo (_("sorry, no support for duplicate "
    1.1     skrll 				    "object files in auto-overlay script\n"));
    1.1     skrll 	  bfd_set_error (bfd_error_bad_value);
    1.1     skrll 	  goto err_exit;
    1.1     skrll 	}
    1.1     skrll     }
    1.1     skrll   free (bfd_arr);
    1.1     skrll
1.1.1.2  christos   fixed_size += reserved;
1.1.1.2  christos   fixed_size += htab->non_ovly_stub * ovl_stub_size (htab->params);
    1.1     skrll   if (fixed_size + mos_param.max_overlay_size <= htab->local_store)
    1.1     skrll     {
1.1.1.2  christos       if (htab->params->ovly_flavour == ovly_soft_icache)
1.1.1.2  christos 	{
1.1.1.2  christos 	  /* Stubs in the non-icache area are bigger.  */
1.1.1.2  christos 	  fixed_size += htab->non_ovly_stub * 16;
1.1.1.2  christos 	  /* Space for icache manager tables.
1.1.1.2  christos 	     a) Tag array, one quadword per cache line.
1.1.1.2  christos 	     - word 0: ia address of present line, init to zero.  */
1.1.1.2  christos 	  fixed_size += 16 << htab->num_lines_log2;
1.1.1.2  christos 	  /* b) Rewrite "to" list, one quadword per cache line.  */
1.1.1.2  christos 	  fixed_size += 16 << htab->num_lines_log2;
1.1.1.2  christos 	  /* c) Rewrite "from" list, one byte per outgoing branch (rounded up
1.1.1.2  christos 		to a power-of-two number of full quadwords) per cache line.  */
1.1.1.2  christos 	  fixed_size += 16 << (htab->fromelem_size_log2
1.1.1.2  christos 			       + htab->num_lines_log2);
1.1.1.2  christos 	  /* d) Pointer to __ea backing store (toe), 1 quadword.  */
1.1.1.2  christos 	  fixed_size += 16;
1.1.1.2  christos 	}
1.1.1.2  christos       else
1.1.1.2  christos 	{
1.1.1.2  christos 	  /* Guess number of overlays.  Assuming overlay buffer is on
1.1.1.2  christos 	     average only half full should be conservative.  */
1.1.1.2  christos 	  ovlynum = (total_overlay_size * 2 * htab->params->num_lines
1.1.1.2  christos 		     / (htab->local_store - fixed_size));
1.1.1.2  christos 	  /* Space for _ovly_table[], _ovly_buf_table[] and toe.  */
1.1.1.2  christos 	  fixed_size += ovlynum * 16 + 16 + 4 + 16;
1.1.1.2  christos 	}
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   if (fixed_size + mos_param.max_overlay_size > htab->local_store)
    1.1     skrll     info->callbacks->einfo (_("non-overlay size of 0x%v plus maximum overlay "
    1.1     skrll 			      "size of 0x%v exceeds local store\n"),
    1.1     skrll 			    (bfd_vma) fixed_size,
    1.1     skrll 			    (bfd_vma) mos_param.max_overlay_size);
    1.1     skrll
    1.1     skrll   /* Now see if we should put some functions in the non-overlay area.  */
1.1.1.2  christos   else if (fixed_size < htab->params->auto_overlay_fixed)
    1.1     skrll     {
    1.1     skrll       unsigned int max_fixed, lib_size;
    1.1     skrll
    1.1     skrll       max_fixed = htab->local_store - mos_param.max_overlay_size;
1.1.1.2  christos       if (max_fixed > htab->params->auto_overlay_fixed)
1.1.1.2  christos 	max_fixed = htab->params->auto_overlay_fixed;
    1.1     skrll       lib_size = max_fixed - fixed_size;
    1.1     skrll       lib_size = auto_ovl_lib_functions (info, lib_size);
    1.1     skrll       if (lib_size == (unsigned int) -1)
    1.1     skrll 	goto err_exit;
    1.1     skrll       fixed_size = max_fixed - lib_size;
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   /* Build an array of sections, suitably sorted to place into
    1.1     skrll      overlays.  */
    1.1     skrll   ovly_sections = bfd_malloc (2 * count * sizeof (*ovly_sections));
    1.1     skrll   if (ovly_sections == NULL)
    1.1     skrll     goto err_exit;
    1.1     skrll   ovly_p = ovly_sections;
    1.1     skrll   if (!for_each_node (collect_overlays, info, &ovly_p, TRUE))
    1.1     skrll     goto err_exit;
    1.1     skrll   count = (size_t) (ovly_p - ovly_sections) / 2;
1.1.1.2  christos   ovly_map = bfd_malloc (count * sizeof (*ovly_map));
1.1.1.2  christos   if (ovly_map == NULL)
1.1.1.2  christos     goto err_exit;
    1.1     skrll
    1.1     skrll   memset (&dummy_caller, 0, sizeof (dummy_caller));
1.1.1.2  christos   overlay_size = (htab->local_store - fixed_size) / htab->params->num_lines;
1.1.1.2  christos   if (htab->params->line_size != 0)
1.1.1.2  christos     overlay_size = htab->params->line_size;
    1.1     skrll   base = 0;
    1.1     skrll   ovlynum = 0;
    1.1     skrll   while (base < count)
    1.1     skrll     {
1.1.1.2  christos       unsigned int size = 0, rosize = 0, roalign = 0;
    1.1     skrll
    1.1     skrll       for (i = base; i < count; i++)
    1.1     skrll 	{
1.1.1.2  christos 	  asection *sec, *rosec;
1.1.1.2  christos 	  unsigned int tmp, rotmp;
1.1.1.2  christos 	  unsigned int num_stubs;
    1.1     skrll 	  struct call_info *call, *pasty;
    1.1     skrll 	  struct _spu_elf_section_data *sec_data;
    1.1     skrll 	  struct spu_elf_stack_info *sinfo;
1.1.1.2  christos 	  unsigned int k;
    1.1     skrll
    1.1     skrll 	  /* See whether we can add this section to the current
    1.1     skrll 	     overlay without overflowing our overlay buffer.  */
    1.1     skrll 	  sec = ovly_sections[2 * i];
1.1.1.2  christos 	  tmp = align_power (size, sec->alignment_power) + sec->size;
1.1.1.2  christos 	  rotmp = rosize;
1.1.1.2  christos 	  rosec = ovly_sections[2 * i + 1];
1.1.1.2  christos 	  if (rosec != NULL)
1.1.1.2  christos 	    {
1.1.1.2  christos 	      rotmp = align_power (rotmp, rosec->alignment_power) + rosec->size;
1.1.1.2  christos 	      if (roalign < rosec->alignment_power)
1.1.1.2  christos 		roalign = rosec->alignment_power;
1.1.1.2  christos 	    }
1.1.1.2  christos 	  if (align_power (tmp, roalign) + rotmp > overlay_size)
    1.1     skrll 	    break;
    1.1     skrll 	  if (sec->segment_mark)
    1.1     skrll 	    {
    1.1     skrll 	      /* Pasted sections must stay together, so add their
    1.1     skrll 		 sizes too.  */
1.1.1.2  christos 	      pasty = find_pasted_call (sec);
    1.1     skrll 	      while (pasty != NULL)
    1.1     skrll 		{
    1.1     skrll 		  struct function_info *call_fun = pasty->fun;
1.1.1.2  christos 		  tmp = (align_power (tmp, call_fun->sec->alignment_power)
1.1.1.2  christos 			 + call_fun->sec->size);
    1.1     skrll 		  if (call_fun->rodata)
1.1.1.2  christos 		    {
1.1.1.2  christos 		      rotmp = (align_power (rotmp,
1.1.1.2  christos 					    call_fun->rodata->alignment_power)
1.1.1.2  christos 			       + call_fun->rodata->size);
1.1.1.2  christos 		      if (roalign < rosec->alignment_power)
1.1.1.2  christos 			roalign = rosec->alignment_power;
1.1.1.2  christos 		    }
    1.1     skrll 		  for (pasty = call_fun->call_list; pasty; pasty = pasty->next)
    1.1     skrll 		    if (pasty->is_pasted)
    1.1     skrll 		      break;
    1.1     skrll 		}
    1.1     skrll 	    }
1.1.1.2  christos 	  if (align_power (tmp, roalign) + rotmp > overlay_size)
    1.1     skrll 	    break;
    1.1     skrll
    1.1     skrll 	  /* If we add this section, we might need new overlay call
    1.1     skrll 	     stubs.  Add any overlay section calls to dummy_call.  */
    1.1     skrll 	  pasty = NULL;
    1.1     skrll 	  sec_data = spu_elf_section_data (sec);
    1.1     skrll 	  sinfo = sec_data->u.i.stack_info;
1.1.1.2  christos 	  for (k = 0; k < (unsigned) sinfo->num_fun; ++k)
    1.1     skrll 	    for (call = sinfo->fun[k].call_list; call; call = call->next)
    1.1     skrll 	      if (call->is_pasted)
    1.1     skrll 		{
    1.1     skrll 		  BFD_ASSERT (pasty == NULL);
    1.1     skrll 		  pasty = call;
    1.1     skrll 		}
    1.1     skrll 	      else if (call->fun->sec->linker_mark)
    1.1     skrll 		{
    1.1     skrll 		  if (!copy_callee (&dummy_caller, call))
    1.1     skrll 		    goto err_exit;
    1.1     skrll 		}
    1.1     skrll 	  while (pasty != NULL)
    1.1     skrll 	    {
    1.1     skrll 	      struct function_info *call_fun = pasty->fun;
    1.1     skrll 	      pasty = NULL;
    1.1     skrll 	      for (call = call_fun->call_list; call; call = call->next)
    1.1     skrll 		if (call->is_pasted)
    1.1     skrll 		  {
    1.1     skrll 		    BFD_ASSERT (pasty == NULL);
    1.1     skrll 		    pasty = call;
    1.1     skrll 		  }
    1.1     skrll 		else if (!copy_callee (&dummy_caller, call))
    1.1     skrll 		  goto err_exit;
    1.1     skrll 	    }
    1.1     skrll
    1.1     skrll 	  /* Calculate call stub size.  */
1.1.1.2  christos 	  num_stubs = 0;
    1.1     skrll 	  for (call = dummy_caller.call_list; call; call = call->next)
    1.1     skrll 	    {
1.1.1.2  christos 	      unsigned int stub_delta = 1;
1.1.1.2  christos
1.1.1.2  christos 	      if (htab->params->ovly_flavour == ovly_soft_icache)
1.1.1.2  christos 		stub_delta = call->count;
1.1.1.2  christos 	      num_stubs += stub_delta;
    1.1     skrll
    1.1     skrll 	      /* If the call is within this overlay, we won't need a
    1.1     skrll 		 stub.  */
    1.1     skrll 	      for (k = base; k < i + 1; k++)
    1.1     skrll 		if (call->fun->sec == ovly_sections[2 * k])
    1.1     skrll 		  {
1.1.1.2  christos 		    num_stubs -= stub_delta;
    1.1     skrll 		    break;
    1.1     skrll 		  }
    1.1     skrll 	    }
1.1.1.2  christos 	  if (htab->params->ovly_flavour == ovly_soft_icache
1.1.1.2  christos 	      && num_stubs > htab->params->max_branch)
1.1.1.2  christos 	    break;
1.1.1.2  christos 	  if (align_power (tmp, roalign) + rotmp
1.1.1.2  christos 	      + num_stubs * ovl_stub_size (htab->params) > overlay_size)
    1.1     skrll 	    break;
    1.1     skrll 	  size = tmp;
1.1.1.2  christos 	  rosize = rotmp;
    1.1     skrll 	}
    1.1     skrll
    1.1     skrll       if (i == base)
    1.1     skrll 	{
    1.1     skrll 	  info->callbacks->einfo (_("%B:%A%s exceeds overlay size\n"),
    1.1     skrll 				  ovly_sections[2 * i]->owner,
    1.1     skrll 				  ovly_sections[2 * i],
    1.1     skrll 				  ovly_sections[2 * i + 1] ? " + rodata" : "");
    1.1     skrll 	  bfd_set_error (bfd_error_bad_value);
    1.1     skrll 	  goto err_exit;
    1.1     skrll 	}
    1.1     skrll
1.1.1.2  christos       while (dummy_caller.call_list != NULL)
    1.1     skrll 	{
1.1.1.2  christos 	  struct call_info *call = dummy_caller.call_list;
1.1.1.2  christos 	  dummy_caller.call_list = call->next;
1.1.1.2  christos 	  free (call);
1.1.1.2  christos 	}
1.1.1.2  christos
1.1.1.2  christos       ++ovlynum;
1.1.1.2  christos       while (base < i)
1.1.1.2  christos 	ovly_map[base++] = ovlynum;
1.1.1.2  christos     }
1.1.1.2  christos
1.1.1.2  christos   script = htab->params->spu_elf_open_overlay_script ();
1.1.1.2  christos
1.1.1.2  christos   if (htab->params->ovly_flavour == ovly_soft_icache)
1.1.1.2  christos     {
1.1.1.2  christos       if (fprintf (script, "SECTIONS\n{\n") <= 0)
1.1.1.2  christos 	goto file_err;
1.1.1.2  christos
1.1.1.2  christos       if (fprintf (script,
1.1.1.2  christos 		   " . = ALIGN (%u);\n"
1.1.1.2  christos 		   " .ovl.init : { *(.ovl.init) }\n"
1.1.1.2  christos 		   " . = ABSOLUTE (ADDR (.ovl.init));\n",
1.1.1.2  christos 		   htab->params->line_size) <= 0)
1.1.1.2  christos 	goto file_err;
    1.1     skrll
1.1.1.2  christos       base = 0;
1.1.1.2  christos       ovlynum = 1;
1.1.1.2  christos       while (base < count)
1.1.1.2  christos 	{
1.1.1.2  christos 	  unsigned int indx = ovlynum - 1;
1.1.1.2  christos 	  unsigned int vma, lma;
1.1.1.2  christos
1.1.1.2  christos 	  vma = (indx & (htab->params->num_lines - 1)) << htab->line_size_log2;
1.1.1.2  christos 	  lma = vma + (((indx >> htab->num_lines_log2) + 1) << 18);
1.1.1.2  christos
1.1.1.2  christos 	  if (fprintf (script, " .ovly%u ABSOLUTE (ADDR (.ovl.init)) + %u "
1.1.1.2  christos 			       ": AT (LOADADDR (.ovl.init) + %u) {\n",
1.1.1.2  christos 		       ovlynum, vma, lma) <= 0)
    1.1     skrll 	    goto file_err;
    1.1     skrll
1.1.1.2  christos 	  base = print_one_overlay_section (script, base, count, ovlynum,
1.1.1.2  christos 					    ovly_map, ovly_sections, info);
1.1.1.2  christos 	  if (base == (unsigned) -1)
    1.1     skrll 	    goto file_err;
    1.1     skrll
1.1.1.2  christos 	  if (fprintf (script, "  }\n") <= 0)
1.1.1.2  christos 	    goto file_err;
1.1.1.2  christos
1.1.1.2  christos 	  ovlynum++;
    1.1     skrll 	}
    1.1     skrll
1.1.1.2  christos       if (fprintf (script, " . = ABSOLUTE (ADDR (.ovl.init)) + %u;\n",
1.1.1.2  christos 		   1 << (htab->num_lines_log2 + htab->line_size_log2)) <= 0)
    1.1     skrll 	goto file_err;
    1.1     skrll
1.1.1.2  christos       if (fprintf (script, "}\nINSERT AFTER .toe;\n") <= 0)
1.1.1.2  christos 	goto file_err;
1.1.1.2  christos     }
1.1.1.2  christos   else
1.1.1.2  christos     {
1.1.1.2  christos       if (fprintf (script, "SECTIONS\n{\n") <= 0)
1.1.1.2  christos 	goto file_err;
1.1.1.2  christos
1.1.1.2  christos       if (fprintf (script,
1.1.1.2  christos 		   " . = ALIGN (16);\n"
1.1.1.2  christos 		   " .ovl.init : { *(.ovl.init) }\n"
1.1.1.2  christos 		   " . = ABSOLUTE (ADDR (.ovl.init));\n") <= 0)
1.1.1.2  christos 	goto file_err;
1.1.1.2  christos
1.1.1.2  christos       for (region = 1; region <= htab->params->num_lines; region++)
    1.1     skrll 	{
1.1.1.2  christos 	  ovlynum = region;
1.1.1.2  christos 	  base = 0;
1.1.1.2  christos 	  while (base < count && ovly_map[base] < ovlynum)
1.1.1.2  christos 	    base++;
1.1.1.2  christos
1.1.1.2  christos 	  if (base == count)
1.1.1.2  christos 	    break;
1.1.1.2  christos
1.1.1.2  christos 	  if (region == 1)
1.1.1.2  christos 	    {
1.1.1.2  christos 	      /* We need to set lma since we are overlaying .ovl.init.  */
1.1.1.2  christos 	      if (fprintf (script,
1.1.1.2  christos 			   " OVERLAY : AT (ALIGN (LOADADDR (.ovl.init) + SIZEOF (.ovl.init), 16))\n {\n") <= 0)
1.1.1.2  christos 		goto file_err;
1.1.1.2  christos 	    }
1.1.1.2  christos 	  else
1.1.1.2  christos 	    {
1.1.1.2  christos 	      if (fprintf (script, " OVERLAY :\n {\n") <= 0)
1.1.1.2  christos 		goto file_err;
1.1.1.2  christos 	    }
1.1.1.2  christos
1.1.1.2  christos 	  while (base < count)
1.1.1.2  christos 	    {
1.1.1.2  christos 	      if (fprintf (script, "  .ovly%u {\n", ovlynum) <= 0)
1.1.1.2  christos 		goto file_err;
1.1.1.2  christos
1.1.1.2  christos 	      base = print_one_overlay_section (script, base, count, ovlynum,
1.1.1.2  christos 						ovly_map, ovly_sections, info);
1.1.1.2  christos 	      if (base == (unsigned) -1)
1.1.1.2  christos 		goto file_err;
1.1.1.2  christos
1.1.1.2  christos 	      if (fprintf (script, "  }\n") <= 0)
1.1.1.2  christos 		goto file_err;
1.1.1.2  christos
1.1.1.2  christos 	      ovlynum += htab->params->num_lines;
1.1.1.2  christos 	      while (base < count && ovly_map[base] < ovlynum)
1.1.1.2  christos 		base++;
1.1.1.2  christos 	    }
1.1.1.2  christos
1.1.1.2  christos 	  if (fprintf (script, " }\n") <= 0)
1.1.1.2  christos 	    goto file_err;
    1.1     skrll 	}
    1.1     skrll
1.1.1.2  christos       if (fprintf (script, "}\nINSERT BEFORE .text;\n") <= 0)
1.1.1.2  christos 	goto file_err;
    1.1     skrll     }
1.1.1.2  christos
1.1.1.2  christos   free (ovly_map);
    1.1     skrll   free (ovly_sections);
    1.1     skrll
    1.1     skrll   if (fclose (script) != 0)
    1.1     skrll     goto file_err;
    1.1     skrll
1.1.1.2  christos   if (htab->params->auto_overlay & AUTO_RELINK)
1.1.1.2  christos     (*htab->params->spu_elf_relink) ();
    1.1     skrll
    1.1     skrll   xexit (0);
    1.1     skrll
    1.1     skrll  file_err:
    1.1     skrll   bfd_set_error (bfd_error_system_call);
    1.1     skrll  err_exit:
    1.1     skrll   info->callbacks->einfo ("%F%P: auto overlay error: %E\n");
    1.1     skrll   xexit (1);
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Provide an estimate of total stack required.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
1.1.1.2  christos spu_elf_stack_analysis (struct bfd_link_info *info)
    1.1     skrll {
1.1.1.2  christos   struct spu_link_hash_table *htab;
    1.1     skrll   struct _sum_stack_param sum_stack_param;
    1.1     skrll
    1.1     skrll   if (!discover_functions (info))
    1.1     skrll     return FALSE;
    1.1     skrll
    1.1     skrll   if (!build_call_tree (info))
    1.1     skrll     return FALSE;
    1.1     skrll
1.1.1.2  christos   htab = spu_hash_table (info);
1.1.1.2  christos   if (htab->params->stack_analysis)
1.1.1.2  christos     {
1.1.1.2  christos       info->callbacks->info (_("Stack size for call graph root nodes.\n"));
1.1.1.2  christos       info->callbacks->minfo (_("\nStack size for functions.  "
1.1.1.2  christos 				"Annotations: '*' max stack, 't' tail call\n"));
1.1.1.2  christos     }
    1.1     skrll
1.1.1.2  christos   sum_stack_param.emit_stack_syms = htab->params->emit_stack_syms;
    1.1     skrll   sum_stack_param.overall_stack = 0;
    1.1     skrll   if (!for_each_node (sum_stack, info, &sum_stack_param, TRUE))
    1.1     skrll     return FALSE;
    1.1     skrll
1.1.1.2  christos   if (htab->params->stack_analysis)
1.1.1.2  christos     info->callbacks->info (_("Maximum stack required is 0x%v\n"),
1.1.1.2  christos 			   (bfd_vma) sum_stack_param.overall_stack);
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Perform a final link.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll spu_elf_final_link (bfd *output_bfd, struct bfd_link_info *info)
    1.1     skrll {
    1.1     skrll   struct spu_link_hash_table *htab = spu_hash_table (info);
    1.1     skrll
1.1.1.2  christos   if (htab->params->auto_overlay)
1.1.1.2  christos     spu_elf_auto_overlay (info);
    1.1     skrll
1.1.1.2  christos   if ((htab->params->stack_analysis
1.1.1.2  christos        || (htab->params->ovly_flavour == ovly_soft_icache
1.1.1.2  christos 	   && htab->params->lrlive_analysis))
1.1.1.2  christos       && !spu_elf_stack_analysis (info))
1.1.1.2  christos     info->callbacks->einfo ("%X%P: stack/lrlive analysis error: %E\n");
1.1.1.2  christos
1.1.1.2  christos   if (!spu_elf_build_stubs (info))
1.1.1.2  christos     info->callbacks->einfo ("%F%P: can not build overlay stubs: %E\n");
    1.1     skrll
    1.1     skrll   return bfd_elf_final_link (output_bfd, info);
    1.1     skrll }
    1.1     skrll
1.1.1.4  christos /* Called when not normally emitting relocs, ie. !bfd_link_relocatable (info)
    1.1     skrll    and !info->emitrelocations.  Returns a count of special relocs
    1.1     skrll    that need to be emitted.  */
    1.1     skrll
    1.1     skrll static unsigned int
1.1.1.2  christos spu_elf_count_relocs (struct bfd_link_info *info, asection *sec)
    1.1     skrll {
1.1.1.2  christos   Elf_Internal_Rela *relocs;
    1.1     skrll   unsigned int count = 0;
    1.1     skrll
1.1.1.2  christos   relocs = _bfd_elf_link_read_relocs (sec->owner, sec, NULL, NULL,
1.1.1.2  christos 				      info->keep_memory);
1.1.1.2  christos   if (relocs != NULL)
    1.1     skrll     {
1.1.1.2  christos       Elf_Internal_Rela *rel;
1.1.1.2  christos       Elf_Internal_Rela *relend = relocs + sec->reloc_count;
1.1.1.2  christos
1.1.1.2  christos       for (rel = relocs; rel < relend; rel++)
1.1.1.2  christos 	{
1.1.1.2  christos 	  int r_type = ELF32_R_TYPE (rel->r_info);
1.1.1.2  christos 	  if (r_type == R_SPU_PPU32 || r_type == R_SPU_PPU64)
1.1.1.2  christos 	    ++count;
1.1.1.2  christos 	}
1.1.1.2  christos
1.1.1.2  christos       if (elf_section_data (sec)->relocs != relocs)
1.1.1.2  christos 	free (relocs);
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   return count;
    1.1     skrll }
    1.1     skrll
1.1.1.2  christos /* Functions for adding fixup records to .fixup */
1.1.1.2  christos
1.1.1.2  christos #define FIXUP_RECORD_SIZE 4
1.1.1.2  christos
1.1.1.2  christos #define FIXUP_PUT(output_bfd,htab,index,addr) \
1.1.1.2  christos 	  bfd_put_32 (output_bfd, addr, \
1.1.1.2  christos 		      htab->sfixup->contents + FIXUP_RECORD_SIZE * (index))
1.1.1.2  christos #define FIXUP_GET(output_bfd,htab,index) \
1.1.1.2  christos 	  bfd_get_32 (output_bfd, \
1.1.1.2  christos 		      htab->sfixup->contents + FIXUP_RECORD_SIZE * (index))
1.1.1.2  christos
1.1.1.2  christos /* Store OFFSET in .fixup.  This assumes it will be called with an
1.1.1.2  christos    increasing OFFSET.  When this OFFSET fits with the last base offset,
1.1.1.2  christos    it just sets a bit, otherwise it adds a new fixup record.  */
1.1.1.2  christos static void
1.1.1.2  christos spu_elf_emit_fixup (bfd * output_bfd, struct bfd_link_info *info,
1.1.1.2  christos 		    bfd_vma offset)
1.1.1.2  christos {
1.1.1.2  christos   struct spu_link_hash_table *htab = spu_hash_table (info);
1.1.1.2  christos   asection *sfixup = htab->sfixup;
1.1.1.2  christos   bfd_vma qaddr = offset & ~(bfd_vma) 15;
1.1.1.2  christos   bfd_vma bit = ((bfd_vma) 8) >> ((offset & 15) >> 2);
1.1.1.2  christos   if (sfixup->reloc_count == 0)
1.1.1.2  christos     {
1.1.1.2  christos       FIXUP_PUT (output_bfd, htab, 0, qaddr | bit);
1.1.1.2  christos       sfixup->reloc_count++;
1.1.1.2  christos     }
1.1.1.2  christos   else
1.1.1.2  christos     {
1.1.1.2  christos       bfd_vma base = FIXUP_GET (output_bfd, htab, sfixup->reloc_count - 1);
1.1.1.2  christos       if (qaddr != (base & ~(bfd_vma) 15))
1.1.1.2  christos 	{
1.1.1.2  christos 	  if ((sfixup->reloc_count + 1) * FIXUP_RECORD_SIZE > sfixup->size)
1.1.1.2  christos 	    (*_bfd_error_handler) (_("fatal error while creating .fixup"));
1.1.1.2  christos 	  FIXUP_PUT (output_bfd, htab, sfixup->reloc_count, qaddr | bit);
1.1.1.2  christos 	  sfixup->reloc_count++;
1.1.1.2  christos 	}
1.1.1.2  christos       else
1.1.1.2  christos 	FIXUP_PUT (output_bfd, htab, sfixup->reloc_count - 1, base | bit);
1.1.1.2  christos     }
1.1.1.2  christos }
1.1.1.2  christos
    1.1     skrll /* Apply RELOCS to CONTENTS of INPUT_SECTION from INPUT_BFD.  */
    1.1     skrll
    1.1     skrll static int
    1.1     skrll spu_elf_relocate_section (bfd *output_bfd,
    1.1     skrll 			  struct bfd_link_info *info,
    1.1     skrll 			  bfd *input_bfd,
    1.1     skrll 			  asection *input_section,
    1.1     skrll 			  bfd_byte *contents,
    1.1     skrll 			  Elf_Internal_Rela *relocs,
    1.1     skrll 			  Elf_Internal_Sym *local_syms,
    1.1     skrll 			  asection **local_sections)
    1.1     skrll {
    1.1     skrll   Elf_Internal_Shdr *symtab_hdr;
    1.1     skrll   struct elf_link_hash_entry **sym_hashes;
    1.1     skrll   Elf_Internal_Rela *rel, *relend;
    1.1     skrll   struct spu_link_hash_table *htab;
1.1.1.2  christos   asection *ea;
    1.1     skrll   int ret = TRUE;
    1.1     skrll   bfd_boolean emit_these_relocs = FALSE;
    1.1     skrll   bfd_boolean is_ea_sym;
    1.1     skrll   bfd_boolean stubs;
1.1.1.2  christos   unsigned int iovl = 0;
    1.1     skrll
    1.1     skrll   htab = spu_hash_table (info);
    1.1     skrll   stubs = (htab->stub_sec != NULL
1.1.1.2  christos 	   && maybe_needs_stubs (input_section));
1.1.1.2  christos   iovl = overlay_index (input_section);
1.1.1.2  christos   ea = bfd_get_section_by_name (output_bfd, "._ea");
    1.1     skrll   symtab_hdr = &elf_tdata (input_bfd)->symtab_hdr;
    1.1     skrll   sym_hashes = (struct elf_link_hash_entry **) (elf_sym_hashes (input_bfd));
    1.1     skrll
    1.1     skrll   rel = relocs;
    1.1     skrll   relend = relocs + input_section->reloc_count;
    1.1     skrll   for (; rel < relend; rel++)
    1.1     skrll     {
    1.1     skrll       int r_type;
    1.1     skrll       reloc_howto_type *howto;
    1.1     skrll       unsigned int r_symndx;
    1.1     skrll       Elf_Internal_Sym *sym;
    1.1     skrll       asection *sec;
    1.1     skrll       struct elf_link_hash_entry *h;
    1.1     skrll       const char *sym_name;
    1.1     skrll       bfd_vma relocation;
    1.1     skrll       bfd_vma addend;
    1.1     skrll       bfd_reloc_status_type r;
    1.1     skrll       bfd_boolean unresolved_reloc;
    1.1     skrll       enum _stub_type stub_type;
    1.1     skrll
    1.1     skrll       r_symndx = ELF32_R_SYM (rel->r_info);
    1.1     skrll       r_type = ELF32_R_TYPE (rel->r_info);
    1.1     skrll       howto = elf_howto_table + r_type;
    1.1     skrll       unresolved_reloc = FALSE;
    1.1     skrll       h = NULL;
    1.1     skrll       sym = NULL;
    1.1     skrll       sec = NULL;
    1.1     skrll       if (r_symndx < symtab_hdr->sh_info)
    1.1     skrll 	{
    1.1     skrll 	  sym = local_syms + r_symndx;
    1.1     skrll 	  sec = local_sections[r_symndx];
    1.1     skrll 	  sym_name = bfd_elf_sym_name (input_bfd, symtab_hdr, sym, sec);
    1.1     skrll 	  relocation = _bfd_elf_rela_local_sym (output_bfd, sym, &sec, rel);
    1.1     skrll 	}
    1.1     skrll       else
    1.1     skrll 	{
    1.1     skrll 	  if (sym_hashes == NULL)
    1.1     skrll 	    return FALSE;
    1.1     skrll
    1.1     skrll 	  h = sym_hashes[r_symndx - symtab_hdr->sh_info];
    1.1     skrll
1.1.1.4  christos 	  if (info->wrap_hash != NULL
1.1.1.4  christos 	      && (input_section->flags & SEC_DEBUGGING) != 0)
1.1.1.4  christos 	    h = ((struct elf_link_hash_entry *)
1.1.1.4  christos 		 unwrap_hash_lookup (info, input_bfd, &h->root));
1.1.1.4  christos
    1.1     skrll 	  while (h->root.type == bfd_link_hash_indirect
    1.1     skrll 		 || h->root.type == bfd_link_hash_warning)
    1.1     skrll 	    h = (struct elf_link_hash_entry *) h->root.u.i.link;
    1.1     skrll
    1.1     skrll 	  relocation = 0;
    1.1     skrll 	  if (h->root.type == bfd_link_hash_defined
    1.1     skrll 	      || h->root.type == bfd_link_hash_defweak)
    1.1     skrll 	    {
    1.1     skrll 	      sec = h->root.u.def.section;
    1.1     skrll 	      if (sec == NULL
    1.1     skrll 		  || sec->output_section == NULL)
    1.1     skrll 		/* Set a flag that will be cleared later if we find a
    1.1     skrll 		   relocation value for this symbol.  output_section
    1.1     skrll 		   is typically NULL for symbols satisfied by a shared
    1.1     skrll 		   library.  */
    1.1     skrll 		unresolved_reloc = TRUE;
    1.1     skrll 	      else
    1.1     skrll 		relocation = (h->root.u.def.value
    1.1     skrll 			      + sec->output_section->vma
    1.1     skrll 			      + sec->output_offset);
    1.1     skrll 	    }
    1.1     skrll 	  else if (h->root.type == bfd_link_hash_undefweak)
    1.1     skrll 	    ;
    1.1     skrll 	  else if (info->unresolved_syms_in_objects == RM_IGNORE
    1.1     skrll 		   && ELF_ST_VISIBILITY (h->other) == STV_DEFAULT)
    1.1     skrll 	    ;
1.1.1.4  christos 	  else if (!bfd_link_relocatable (info)
    1.1     skrll 		   && !(r_type == R_SPU_PPU32 || r_type == R_SPU_PPU64))
    1.1     skrll 	    {
    1.1     skrll 	      bfd_boolean err;
    1.1     skrll 	      err = (info->unresolved_syms_in_objects == RM_GENERATE_ERROR
    1.1     skrll 		     || ELF_ST_VISIBILITY (h->other) != STV_DEFAULT);
    1.1     skrll 	      if (!info->callbacks->undefined_symbol (info,
    1.1     skrll 						      h->root.root.string,
    1.1     skrll 						      input_bfd,
    1.1     skrll 						      input_section,
    1.1     skrll 						      rel->r_offset, err))
    1.1     skrll 		return FALSE;
    1.1     skrll 	    }
    1.1     skrll 	  sym_name = h->root.root.string;
    1.1     skrll 	}
    1.1     skrll
1.1.1.3  christos       if (sec != NULL && discarded_section (sec))
1.1.1.2  christos 	RELOC_AGAINST_DISCARDED_SECTION (info, input_bfd, input_section,
1.1.1.3  christos 					 rel, 1, relend, howto, 0, contents);
    1.1     skrll
1.1.1.4  christos       if (bfd_link_relocatable (info))
    1.1     skrll 	continue;
    1.1     skrll
1.1.1.2  christos       /* Change "a rt,ra,rb" to "ai rt,ra,0". */
1.1.1.2  christos       if (r_type == R_SPU_ADD_PIC
1.1.1.2  christos 	  && h != NULL
1.1.1.2  christos 	  && !(h->def_regular || ELF_COMMON_DEF_P (h)))
1.1.1.2  christos 	{
1.1.1.2  christos 	  bfd_byte *loc = contents + rel->r_offset;
1.1.1.4  christos 	  loc[0] = 0x1c;
1.1.1.4  christos 	  loc[1] = 0x00;
1.1.1.2  christos 	  loc[2] &= 0x3f;
1.1.1.2  christos 	}
1.1.1.2  christos
    1.1     skrll       is_ea_sym = (ea != NULL
    1.1     skrll 		   && sec != NULL
    1.1     skrll 		   && sec->output_section == ea);
    1.1     skrll
1.1.1.2  christos       /* If this symbol is in an overlay area, we may need to relocate
1.1.1.2  christos 	 to the overlay stub.  */
1.1.1.2  christos       addend = rel->r_addend;
1.1.1.2  christos       if (stubs
1.1.1.2  christos 	  && !is_ea_sym
1.1.1.2  christos 	  && (stub_type = needs_ovl_stub (h, sym, sec, input_section, rel,
1.1.1.2  christos 					  contents, info)) != no_stub)
1.1.1.2  christos 	{
1.1.1.2  christos 	  unsigned int ovl = 0;
1.1.1.2  christos 	  struct got_entry *g, **head;
1.1.1.2  christos
1.1.1.2  christos 	  if (stub_type != nonovl_stub)
1.1.1.2  christos 	    ovl = iovl;
1.1.1.2  christos
1.1.1.2  christos 	  if (h != NULL)
1.1.1.2  christos 	    head = &h->got.glist;
1.1.1.2  christos 	  else
1.1.1.2  christos 	    head = elf_local_got_ents (input_bfd) + r_symndx;
1.1.1.2  christos
1.1.1.2  christos 	  for (g = *head; g != NULL; g = g->next)
1.1.1.2  christos 	    if (htab->params->ovly_flavour == ovly_soft_icache
1.1.1.2  christos 		? (g->ovl == ovl
1.1.1.2  christos 		   && g->br_addr == (rel->r_offset
1.1.1.2  christos 				     + input_section->output_offset
1.1.1.2  christos 				     + input_section->output_section->vma))
1.1.1.2  christos 		: g->addend == addend && (g->ovl == ovl || g->ovl == 0))
1.1.1.2  christos 	      break;
1.1.1.2  christos 	  if (g == NULL)
1.1.1.2  christos 	    abort ();
1.1.1.2  christos
1.1.1.2  christos 	  relocation = g->stub_addr;
1.1.1.2  christos 	  addend = 0;
1.1.1.2  christos 	}
1.1.1.2  christos       else
1.1.1.2  christos 	{
1.1.1.2  christos 	  /* For soft icache, encode the overlay index into addresses.  */
1.1.1.2  christos 	  if (htab->params->ovly_flavour == ovly_soft_icache
1.1.1.2  christos 	      && (r_type == R_SPU_ADDR16_HI
1.1.1.2  christos 		  || r_type == R_SPU_ADDR32 || r_type == R_SPU_REL32)
1.1.1.2  christos 	      && !is_ea_sym)
1.1.1.2  christos 	    {
1.1.1.2  christos 	      unsigned int ovl = overlay_index (sec);
1.1.1.2  christos 	      if (ovl != 0)
1.1.1.2  christos 		{
1.1.1.2  christos 		  unsigned int set_id = ((ovl - 1) >> htab->num_lines_log2) + 1;
1.1.1.2  christos 		  relocation += set_id << 18;
1.1.1.2  christos 		}
1.1.1.2  christos 	    }
1.1.1.2  christos 	}
1.1.1.2  christos
1.1.1.4  christos       if (htab->params->emit_fixups && !bfd_link_relocatable (info)
1.1.1.2  christos 	  && (input_section->flags & SEC_ALLOC) != 0
1.1.1.2  christos 	  && r_type == R_SPU_ADDR32)
1.1.1.2  christos 	{
1.1.1.2  christos 	  bfd_vma offset;
1.1.1.2  christos 	  offset = rel->r_offset + input_section->output_section->vma
1.1.1.2  christos 		   + input_section->output_offset;
1.1.1.2  christos 	  spu_elf_emit_fixup (output_bfd, info, offset);
1.1.1.2  christos 	}
1.1.1.2  christos
1.1.1.2  christos       if (unresolved_reloc)
1.1.1.2  christos 	;
1.1.1.2  christos       else if (r_type == R_SPU_PPU32 || r_type == R_SPU_PPU64)
    1.1     skrll 	{
    1.1     skrll 	  if (is_ea_sym)
    1.1     skrll 	    {
    1.1     skrll 	      /* ._ea is a special section that isn't allocated in SPU
    1.1     skrll 		 memory, but rather occupies space in PPU memory as
    1.1     skrll 		 part of an embedded ELF image.  If this reloc is
    1.1     skrll 		 against a symbol defined in ._ea, then transform the
    1.1     skrll 		 reloc into an equivalent one without a symbol
    1.1     skrll 		 relative to the start of the ELF image.  */
    1.1     skrll 	      rel->r_addend += (relocation
    1.1     skrll 				- ea->vma
    1.1     skrll 				+ elf_section_data (ea)->this_hdr.sh_offset);
    1.1     skrll 	      rel->r_info = ELF32_R_INFO (0, r_type);
    1.1     skrll 	    }
    1.1     skrll 	  emit_these_relocs = TRUE;
    1.1     skrll 	  continue;
    1.1     skrll 	}
1.1.1.2  christos       else if (is_ea_sym)
    1.1     skrll 	unresolved_reloc = TRUE;
    1.1     skrll
1.1.1.3  christos       if (unresolved_reloc
1.1.1.3  christos 	  && _bfd_elf_section_offset (output_bfd, info, input_section,
1.1.1.3  christos 				      rel->r_offset) != (bfd_vma) -1)
    1.1     skrll 	{
    1.1     skrll 	  (*_bfd_error_handler)
    1.1     skrll 	    (_("%B(%s+0x%lx): unresolvable %s relocation against symbol `%s'"),
    1.1     skrll 	     input_bfd,
    1.1     skrll 	     bfd_get_section_name (input_bfd, input_section),
    1.1     skrll 	     (long) rel->r_offset,
    1.1     skrll 	     howto->name,
    1.1     skrll 	     sym_name);
    1.1     skrll 	  ret = FALSE;
    1.1     skrll 	}
    1.1     skrll
    1.1     skrll       r = _bfd_final_link_relocate (howto,
    1.1     skrll 				    input_bfd,
    1.1     skrll 				    input_section,
    1.1     skrll 				    contents,
    1.1     skrll 				    rel->r_offset, relocation, addend);
    1.1     skrll
    1.1     skrll       if (r != bfd_reloc_ok)
    1.1     skrll 	{
    1.1     skrll 	  const char *msg = (const char *) 0;
    1.1     skrll
    1.1     skrll 	  switch (r)
    1.1     skrll 	    {
    1.1     skrll 	    case bfd_reloc_overflow:
    1.1     skrll 	      if (!((*info->callbacks->reloc_overflow)
    1.1     skrll 		    (info, (h ? &h->root : NULL), sym_name, howto->name,
    1.1     skrll 		     (bfd_vma) 0, input_bfd, input_section, rel->r_offset)))
    1.1     skrll 		return FALSE;
    1.1     skrll 	      break;
    1.1     skrll
    1.1     skrll 	    case bfd_reloc_undefined:
    1.1     skrll 	      if (!((*info->callbacks->undefined_symbol)
    1.1     skrll 		    (info, sym_name, input_bfd, input_section,
    1.1     skrll 		     rel->r_offset, TRUE)))
    1.1     skrll 		return FALSE;
    1.1     skrll 	      break;
    1.1     skrll
    1.1     skrll 	    case bfd_reloc_outofrange:
    1.1     skrll 	      msg = _("internal error: out of range error");
    1.1     skrll 	      goto common_error;
    1.1     skrll
    1.1     skrll 	    case bfd_reloc_notsupported:
    1.1     skrll 	      msg = _("internal error: unsupported relocation error");
    1.1     skrll 	      goto common_error;
    1.1     skrll
    1.1     skrll 	    case bfd_reloc_dangerous:
    1.1     skrll 	      msg = _("internal error: dangerous error");
    1.1     skrll 	      goto common_error;
    1.1     skrll
    1.1     skrll 	    default:
    1.1     skrll 	      msg = _("internal error: unknown error");
    1.1     skrll 	      /* fall through */
    1.1     skrll
    1.1     skrll 	    common_error:
    1.1     skrll 	      ret = FALSE;
    1.1     skrll 	      if (!((*info->callbacks->warning)
    1.1     skrll 		    (info, msg, sym_name, input_bfd, input_section,
    1.1     skrll 		     rel->r_offset)))
    1.1     skrll 		return FALSE;
    1.1     skrll 	      break;
    1.1     skrll 	    }
    1.1     skrll 	}
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   if (ret
    1.1     skrll       && emit_these_relocs
    1.1     skrll       && !info->emitrelocations)
    1.1     skrll     {
    1.1     skrll       Elf_Internal_Rela *wrel;
    1.1     skrll       Elf_Internal_Shdr *rel_hdr;
    1.1     skrll
    1.1     skrll       wrel = rel = relocs;
    1.1     skrll       relend = relocs + input_section->reloc_count;
    1.1     skrll       for (; rel < relend; rel++)
    1.1     skrll 	{
    1.1     skrll 	  int r_type;
    1.1     skrll
    1.1     skrll 	  r_type = ELF32_R_TYPE (rel->r_info);
    1.1     skrll 	  if (r_type == R_SPU_PPU32 || r_type == R_SPU_PPU64)
    1.1     skrll 	    *wrel++ = *rel;
    1.1     skrll 	}
    1.1     skrll       input_section->reloc_count = wrel - relocs;
    1.1     skrll       /* Backflips for _bfd_elf_link_output_relocs.  */
1.1.1.2  christos       rel_hdr = _bfd_elf_single_rel_hdr (input_section);
    1.1     skrll       rel_hdr->sh_size = input_section->reloc_count * rel_hdr->sh_entsize;
    1.1     skrll       ret = 2;
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   return ret;
    1.1     skrll }
    1.1     skrll
1.1.1.2  christos static bfd_boolean
1.1.1.2  christos spu_elf_finish_dynamic_sections (bfd *output_bfd ATTRIBUTE_UNUSED,
1.1.1.2  christos 				 struct bfd_link_info *info ATTRIBUTE_UNUSED)
1.1.1.2  christos {
1.1.1.2  christos   return TRUE;
1.1.1.2  christos }
1.1.1.2  christos
    1.1     skrll /* Adjust _SPUEAR_ syms to point at their overlay stubs.  */
    1.1     skrll
1.1.1.2  christos static int
    1.1     skrll spu_elf_output_symbol_hook (struct bfd_link_info *info,
    1.1     skrll 			    const char *sym_name ATTRIBUTE_UNUSED,
    1.1     skrll 			    Elf_Internal_Sym *sym,
    1.1     skrll 			    asection *sym_sec ATTRIBUTE_UNUSED,
    1.1     skrll 			    struct elf_link_hash_entry *h)
    1.1     skrll {
    1.1     skrll   struct spu_link_hash_table *htab = spu_hash_table (info);
    1.1     skrll
1.1.1.4  christos   if (!bfd_link_relocatable (info)
    1.1     skrll       && htab->stub_sec != NULL
    1.1     skrll       && h != NULL
    1.1     skrll       && (h->root.type == bfd_link_hash_defined
    1.1     skrll 	  || h->root.type == bfd_link_hash_defweak)
    1.1     skrll       && h->def_regular
    1.1     skrll       && strncmp (h->root.root.string, "_SPUEAR_", 8) == 0)
    1.1     skrll     {
    1.1     skrll       struct got_entry *g;
    1.1     skrll
    1.1     skrll       for (g = h->got.glist; g != NULL; g = g->next)
1.1.1.2  christos 	if (htab->params->ovly_flavour == ovly_soft_icache
1.1.1.2  christos 	    ? g->br_addr == g->stub_addr
1.1.1.2  christos 	    : g->addend == 0 && g->ovl == 0)
    1.1     skrll 	  {
    1.1     skrll 	    sym->st_shndx = (_bfd_elf_section_from_bfd_section
    1.1     skrll 			     (htab->stub_sec[0]->output_section->owner,
    1.1     skrll 			      htab->stub_sec[0]->output_section));
    1.1     skrll 	    sym->st_value = g->stub_addr;
    1.1     skrll 	    break;
    1.1     skrll 	  }
    1.1     skrll     }
    1.1     skrll
1.1.1.2  christos   return 1;
    1.1     skrll }
    1.1     skrll
    1.1     skrll static int spu_plugin = 0;
    1.1     skrll
    1.1     skrll void
    1.1     skrll spu_elf_plugin (int val)
    1.1     skrll {
    1.1     skrll   spu_plugin = val;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Set ELF header e_type for plugins.  */
    1.1     skrll
    1.1     skrll static void
1.1.1.4  christos spu_elf_post_process_headers (bfd *abfd, struct bfd_link_info *info)
    1.1     skrll {
    1.1     skrll   if (spu_plugin)
    1.1     skrll     {
    1.1     skrll       Elf_Internal_Ehdr *i_ehdrp = elf_elfheader (abfd);
    1.1     skrll
    1.1     skrll       i_ehdrp->e_type = ET_DYN;
    1.1     skrll     }
1.1.1.4  christos
1.1.1.4  christos   _bfd_elf_post_process_headers (abfd, info);
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* We may add an extra PT_LOAD segment for .toe.  We also need extra
    1.1     skrll    segments for overlays.  */
    1.1     skrll
    1.1     skrll static int
    1.1     skrll spu_elf_additional_program_headers (bfd *abfd, struct bfd_link_info *info)
    1.1     skrll {
    1.1     skrll   int extra = 0;
    1.1     skrll   asection *sec;
    1.1     skrll
    1.1     skrll   if (info != NULL)
    1.1     skrll     {
    1.1     skrll       struct spu_link_hash_table *htab = spu_hash_table (info);
    1.1     skrll       extra = htab->num_overlays;
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   if (extra)
    1.1     skrll     ++extra;
    1.1     skrll
    1.1     skrll   sec = bfd_get_section_by_name (abfd, ".toe");
    1.1     skrll   if (sec != NULL && (sec->flags & SEC_LOAD) != 0)
    1.1     skrll     ++extra;
    1.1     skrll
    1.1     skrll   return extra;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Remove .toe section from other PT_LOAD segments and put it in
    1.1     skrll    a segment of its own.  Put overlays in separate segments too.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll spu_elf_modify_segment_map (bfd *abfd, struct bfd_link_info *info)
    1.1     skrll {
    1.1     skrll   asection *toe, *s;
1.1.1.2  christos   struct elf_segment_map *m, *m_overlay;
1.1.1.2  christos   struct elf_segment_map **p, **p_overlay;
    1.1     skrll   unsigned int i;
    1.1     skrll
    1.1     skrll   if (info == NULL)
    1.1     skrll     return TRUE;
    1.1     skrll
    1.1     skrll   toe = bfd_get_section_by_name (abfd, ".toe");
1.1.1.4  christos   for (m = elf_seg_map (abfd); m != NULL; m = m->next)
    1.1     skrll     if (m->p_type == PT_LOAD && m->count > 1)
    1.1     skrll       for (i = 0; i < m->count; i++)
    1.1     skrll 	if ((s = m->sections[i]) == toe
    1.1     skrll 	    || spu_elf_section_data (s)->u.o.ovl_index != 0)
    1.1     skrll 	  {
    1.1     skrll 	    struct elf_segment_map *m2;
    1.1     skrll 	    bfd_vma amt;
    1.1     skrll
    1.1     skrll 	    if (i + 1 < m->count)
    1.1     skrll 	      {
    1.1     skrll 		amt = sizeof (struct elf_segment_map);
    1.1     skrll 		amt += (m->count - (i + 2)) * sizeof (m->sections[0]);
    1.1     skrll 		m2 = bfd_zalloc (abfd, amt);
    1.1     skrll 		if (m2 == NULL)
    1.1     skrll 		  return FALSE;
    1.1     skrll 		m2->count = m->count - (i + 1);
    1.1     skrll 		memcpy (m2->sections, m->sections + i + 1,
    1.1     skrll 			m2->count * sizeof (m->sections[0]));
    1.1     skrll 		m2->p_type = PT_LOAD;
    1.1     skrll 		m2->next = m->next;
    1.1     skrll 		m->next = m2;
    1.1     skrll 	      }
    1.1     skrll 	    m->count = 1;
    1.1     skrll 	    if (i != 0)
    1.1     skrll 	      {
    1.1     skrll 		m->count = i;
    1.1     skrll 		amt = sizeof (struct elf_segment_map);
    1.1     skrll 		m2 = bfd_zalloc (abfd, amt);
    1.1     skrll 		if (m2 == NULL)
    1.1     skrll 		  return FALSE;
    1.1     skrll 		m2->p_type = PT_LOAD;
    1.1     skrll 		m2->count = 1;
    1.1     skrll 		m2->sections[0] = s;
    1.1     skrll 		m2->next = m->next;
    1.1     skrll 		m->next = m2;
    1.1     skrll 	      }
    1.1     skrll 	    break;
    1.1     skrll 	  }
    1.1     skrll
1.1.1.2  christos
1.1.1.2  christos   /* Some SPU ELF loaders ignore the PF_OVERLAY flag and just load all
1.1.1.2  christos      PT_LOAD segments.  This can cause the .ovl.init section to be
1.1.1.2  christos      overwritten with the contents of some overlay segment.  To work
1.1.1.2  christos      around this issue, we ensure that all PF_OVERLAY segments are
1.1.1.2  christos      sorted first amongst the program headers; this ensures that even
1.1.1.2  christos      with a broken loader, the .ovl.init section (which is not marked
1.1.1.2  christos      as PF_OVERLAY) will be placed into SPU local store on startup.  */
1.1.1.2  christos
1.1.1.2  christos   /* Move all overlay segments onto a separate list.  */
1.1.1.4  christos   p = &elf_seg_map (abfd);
1.1.1.2  christos   p_overlay = &m_overlay;
1.1.1.2  christos   while (*p != NULL)
1.1.1.2  christos     {
1.1.1.2  christos       if ((*p)->p_type == PT_LOAD && (*p)->count == 1
1.1.1.2  christos 	  && spu_elf_section_data ((*p)->sections[0])->u.o.ovl_index != 0)
1.1.1.2  christos 	{
1.1.1.2  christos 	  m = *p;
1.1.1.2  christos 	  *p = m->next;
1.1.1.2  christos 	  *p_overlay = m;
1.1.1.2  christos 	  p_overlay = &m->next;
1.1.1.2  christos 	  continue;
1.1.1.2  christos 	}
1.1.1.2  christos
1.1.1.2  christos       p = &((*p)->next);
1.1.1.2  christos     }
1.1.1.2  christos
1.1.1.2  christos   /* Re-insert overlay segments at the head of the segment map.  */
1.1.1.4  christos   *p_overlay = elf_seg_map (abfd);
1.1.1.4  christos   elf_seg_map (abfd) = m_overlay;
1.1.1.2  christos
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Tweak the section type of .note.spu_name.  */
    1.1     skrll
    1.1     skrll static bfd_boolean
    1.1     skrll spu_elf_fake_sections (bfd *obfd ATTRIBUTE_UNUSED,
    1.1     skrll 		       Elf_Internal_Shdr *hdr,
    1.1     skrll 		       asection *sec)
    1.1     skrll {
    1.1     skrll   if (strcmp (sec->name, SPU_PTNOTE_SPUNAME) == 0)
    1.1     skrll     hdr->sh_type = SHT_NOTE;
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
    1.1     skrll /* Tweak phdrs before writing them out.  */
    1.1     skrll
    1.1     skrll static int
    1.1     skrll spu_elf_modify_program_headers (bfd *abfd, struct bfd_link_info *info)
    1.1     skrll {
    1.1     skrll   const struct elf_backend_data *bed;
    1.1     skrll   struct elf_obj_tdata *tdata;
    1.1     skrll   Elf_Internal_Phdr *phdr, *last;
    1.1     skrll   struct spu_link_hash_table *htab;
    1.1     skrll   unsigned int count;
    1.1     skrll   unsigned int i;
    1.1     skrll
    1.1     skrll   if (info == NULL)
    1.1     skrll     return TRUE;
    1.1     skrll
    1.1     skrll   bed = get_elf_backend_data (abfd);
    1.1     skrll   tdata = elf_tdata (abfd);
    1.1     skrll   phdr = tdata->phdr;
1.1.1.4  christos   count = elf_program_header_size (abfd) / bed->s->sizeof_phdr;
    1.1     skrll   htab = spu_hash_table (info);
    1.1     skrll   if (htab->num_overlays != 0)
    1.1     skrll     {
    1.1     skrll       struct elf_segment_map *m;
    1.1     skrll       unsigned int o;
    1.1     skrll
1.1.1.4  christos       for (i = 0, m = elf_seg_map (abfd); m; ++i, m = m->next)
    1.1     skrll 	if (m->count != 0
    1.1     skrll 	    && (o = spu_elf_section_data (m->sections[0])->u.o.ovl_index) != 0)
    1.1     skrll 	  {
    1.1     skrll 	    /* Mark this as an overlay header.  */
    1.1     skrll 	    phdr[i].p_flags |= PF_OVERLAY;
    1.1     skrll
1.1.1.2  christos 	    if (htab->ovtab != NULL && htab->ovtab->size != 0
1.1.1.2  christos 		&& htab->params->ovly_flavour != ovly_soft_icache)
    1.1     skrll 	      {
    1.1     skrll 		bfd_byte *p = htab->ovtab->contents;
    1.1     skrll 		unsigned int off = o * 16 + 8;
    1.1     skrll
    1.1     skrll 		/* Write file_off into _ovly_table.  */
    1.1     skrll 		bfd_put_32 (htab->ovtab->owner, phdr[i].p_offset, p + off);
    1.1     skrll 	      }
    1.1     skrll 	  }
1.1.1.2  christos       /* Soft-icache has its file offset put in .ovl.init.  */
1.1.1.2  christos       if (htab->init != NULL && htab->init->size != 0)
1.1.1.2  christos 	{
1.1.1.2  christos 	  bfd_vma val = elf_section_data (htab->ovl_sec[0])->this_hdr.sh_offset;
1.1.1.2  christos
1.1.1.2  christos 	  bfd_put_32 (htab->init->owner, val, htab->init->contents + 4);
1.1.1.2  christos 	}
    1.1     skrll     }
    1.1     skrll
    1.1     skrll   /* Round up p_filesz and p_memsz of PT_LOAD segments to multiples
    1.1     skrll      of 16.  This should always be possible when using the standard
    1.1     skrll      linker scripts, but don't create overlapping segments if
    1.1     skrll      someone is playing games with linker scripts.  */
    1.1     skrll   last = NULL;
    1.1     skrll   for (i = count; i-- != 0; )
    1.1     skrll     if (phdr[i].p_type == PT_LOAD)
    1.1     skrll       {
    1.1     skrll 	unsigned adjust;
    1.1     skrll
    1.1     skrll 	adjust = -phdr[i].p_filesz & 15;
    1.1     skrll 	if (adjust != 0
    1.1     skrll 	    && last != NULL
    1.1     skrll 	    && phdr[i].p_offset + phdr[i].p_filesz > last->p_offset - adjust)
    1.1     skrll 	  break;
    1.1     skrll
    1.1     skrll 	adjust = -phdr[i].p_memsz & 15;
    1.1     skrll 	if (adjust != 0
    1.1     skrll 	    && last != NULL
    1.1     skrll 	    && phdr[i].p_filesz != 0
    1.1     skrll 	    && phdr[i].p_vaddr + phdr[i].p_memsz > last->p_vaddr - adjust
    1.1     skrll 	    && phdr[i].p_vaddr + phdr[i].p_memsz <= last->p_vaddr)
    1.1     skrll 	  break;
    1.1     skrll
    1.1     skrll 	if (phdr[i].p_filesz != 0)
    1.1     skrll 	  last = &phdr[i];
    1.1     skrll       }
    1.1     skrll
    1.1     skrll   if (i == (unsigned int) -1)
    1.1     skrll     for (i = count; i-- != 0; )
    1.1     skrll       if (phdr[i].p_type == PT_LOAD)
    1.1     skrll 	{
    1.1     skrll 	unsigned adjust;
    1.1     skrll
    1.1     skrll 	adjust = -phdr[i].p_filesz & 15;
    1.1     skrll 	phdr[i].p_filesz += adjust;
    1.1     skrll
    1.1     skrll 	adjust = -phdr[i].p_memsz & 15;
    1.1     skrll 	phdr[i].p_memsz += adjust;
    1.1     skrll       }
    1.1     skrll
    1.1     skrll   return TRUE;
    1.1     skrll }
    1.1     skrll
1.1.1.2  christos bfd_boolean
1.1.1.2  christos spu_elf_size_sections (bfd * output_bfd, struct bfd_link_info *info)
1.1.1.2  christos {
1.1.1.2  christos   struct spu_link_hash_table *htab = spu_hash_table (info);
1.1.1.2  christos   if (htab->params->emit_fixups)
1.1.1.2  christos     {
1.1.1.2  christos       asection *sfixup = htab->sfixup;
1.1.1.2  christos       int fixup_count = 0;
1.1.1.2  christos       bfd *ibfd;
1.1.1.2  christos       size_t size;
1.1.1.2  christos
1.1.1.4  christos       for (ibfd = info->input_bfds; ibfd != NULL; ibfd = ibfd->link.next)
1.1.1.2  christos 	{
1.1.1.2  christos 	  asection *isec;
1.1.1.2  christos
1.1.1.2  christos 	  if (bfd_get_flavour (ibfd) != bfd_target_elf_flavour)
1.1.1.2  christos 	    continue;
1.1.1.2  christos
1.1.1.2  christos 	  /* Walk over each section attached to the input bfd.  */
1.1.1.2  christos 	  for (isec = ibfd->sections; isec != NULL; isec = isec->next)
1.1.1.2  christos 	    {
1.1.1.2  christos 	      Elf_Internal_Rela *internal_relocs, *irelaend, *irela;
1.1.1.2  christos 	      bfd_vma base_end;
1.1.1.2  christos
1.1.1.2  christos 	      /* If there aren't any relocs, then there's nothing more
1.1.1.2  christos 	         to do.  */
1.1.1.2  christos 	      if ((isec->flags & SEC_ALLOC) == 0
1.1.1.2  christos 		  || (isec->flags & SEC_RELOC) == 0
1.1.1.2  christos 		  || isec->reloc_count == 0)
1.1.1.2  christos 		continue;
1.1.1.2  christos
1.1.1.2  christos 	      /* Get the relocs.  */
1.1.1.2  christos 	      internal_relocs =
1.1.1.2  christos 		_bfd_elf_link_read_relocs (ibfd, isec, NULL, NULL,
1.1.1.2  christos 					   info->keep_memory);
1.1.1.2  christos 	      if (internal_relocs == NULL)
1.1.1.2  christos 		return FALSE;
1.1.1.2  christos
1.1.1.2  christos 	      /* 1 quadword can contain up to 4 R_SPU_ADDR32
1.1.1.2  christos 	         relocations.  They are stored in a single word by
1.1.1.2  christos 	         saving the upper 28 bits of the address and setting the
1.1.1.2  christos 	         lower 4 bits to a bit mask of the words that have the
1.1.1.2  christos 	         relocation.  BASE_END keeps track of the next quadword. */
1.1.1.2  christos 	      irela = internal_relocs;
1.1.1.2  christos 	      irelaend = irela + isec->reloc_count;
1.1.1.2  christos 	      base_end = 0;
1.1.1.2  christos 	      for (; irela < irelaend; irela++)
1.1.1.2  christos 		if (ELF32_R_TYPE (irela->r_info) == R_SPU_ADDR32
1.1.1.2  christos 		    && irela->r_offset >= base_end)
1.1.1.2  christos 		  {
1.1.1.2  christos 		    base_end = (irela->r_offset & ~(bfd_vma) 15) + 16;
1.1.1.2  christos 		    fixup_count++;
1.1.1.2  christos 		  }
1.1.1.2  christos 	    }
1.1.1.2  christos 	}
1.1.1.2  christos
1.1.1.2  christos       /* We always have a NULL fixup as a sentinel */
1.1.1.2  christos       size = (fixup_count + 1) * FIXUP_RECORD_SIZE;
1.1.1.2  christos       if (!bfd_set_section_size (output_bfd, sfixup, size))
1.1.1.2  christos 	return FALSE;
1.1.1.2  christos       sfixup->contents = (bfd_byte *) bfd_zalloc (info->input_bfds, size);
1.1.1.2  christos       if (sfixup->contents == NULL)
1.1.1.2  christos 	return FALSE;
1.1.1.2  christos     }
1.1.1.2  christos   return TRUE;
1.1.1.2  christos }
1.1.1.2  christos
1.1.1.4  christos #define TARGET_BIG_SYM		spu_elf32_vec
    1.1     skrll #define TARGET_BIG_NAME		"elf32-spu"
    1.1     skrll #define ELF_ARCH		bfd_arch_spu
1.1.1.2  christos #define ELF_TARGET_ID		SPU_ELF_DATA
    1.1     skrll #define ELF_MACHINE_CODE	EM_SPU
    1.1     skrll /* This matches the alignment need for DMA.  */
    1.1     skrll #define ELF_MAXPAGESIZE		0x80
    1.1     skrll #define elf_backend_rela_normal         1
    1.1     skrll #define elf_backend_can_gc_sections	1
    1.1     skrll
    1.1     skrll #define bfd_elf32_bfd_reloc_type_lookup		spu_elf_reloc_type_lookup
1.1.1.2  christos #define bfd_elf32_bfd_reloc_name_lookup		spu_elf_reloc_name_lookup
    1.1     skrll #define elf_info_to_howto			spu_elf_info_to_howto
    1.1     skrll #define elf_backend_count_relocs		spu_elf_count_relocs
    1.1     skrll #define elf_backend_relocate_section		spu_elf_relocate_section
1.1.1.2  christos #define elf_backend_finish_dynamic_sections	spu_elf_finish_dynamic_sections
    1.1     skrll #define elf_backend_symbol_processing		spu_elf_backend_symbol_processing
    1.1     skrll #define elf_backend_link_output_symbol_hook	spu_elf_output_symbol_hook
    1.1     skrll #define elf_backend_object_p			spu_elf_object_p
    1.1     skrll #define bfd_elf32_new_section_hook		spu_elf_new_section_hook
    1.1     skrll #define bfd_elf32_bfd_link_hash_table_create	spu_elf_link_hash_table_create
    1.1     skrll
    1.1     skrll #define elf_backend_additional_program_headers	spu_elf_additional_program_headers
    1.1     skrll #define elf_backend_modify_segment_map		spu_elf_modify_segment_map
    1.1     skrll #define elf_backend_modify_program_headers	spu_elf_modify_program_headers
    1.1     skrll #define elf_backend_post_process_headers        spu_elf_post_process_headers
    1.1     skrll #define elf_backend_fake_sections		spu_elf_fake_sections
    1.1     skrll #define elf_backend_special_sections		spu_elf_special_sections
    1.1     skrll #define bfd_elf32_bfd_final_link		spu_elf_final_link
    1.1     skrll
    1.1     skrll #include "elf32-target.h"