#ifndef ECOFF_H #define ECOFF_H /* Generic ECOFF support. This does not include symbol information, found in sym.h and symconst.h. */ /* Mips magic numbers used in filehdr. MIPS_MAGIC_LITTLE is used on little endian machines. MIPS_MAGIC_BIG is used on big endian machines. Where is MIPS_MAGIC_1 from? */ #define MIPS_MAGIC_1 0x0180 #define MIPS_MAGIC_LITTLE 0x0162 #define MIPS_MAGIC_BIG 0x0160 /* These are the magic numbers used for MIPS code compiled at ISA level 2. */ #define MIPS_MAGIC_LITTLE2 0x0166 #define MIPS_MAGIC_BIG2 0x0163 /* These are the magic numbers used for MIPS code compiled at ISA level 3. */ #define MIPS_MAGIC_LITTLE3 0x142 #define MIPS_MAGIC_BIG3 0x140 /* Alpha magic numbers used in filehdr. */ #define ALPHA_MAGIC 0x183 /* Magic numbers used in a.out header. */ #define ECOFF_AOUT_OMAGIC 0407 /* not demand paged (ld -N). */ #define ECOFF_AOUT_ZMAGIC 0413 /* demand load format, eg normal ld output */ /* Names of special sections. */ #define _TEXT ".text" #define _DATA ".data" #define _BSS ".bss" #define _RDATA ".rdata" #define _SDATA ".sdata" #define _SBSS ".sbss" #define _LITA ".lita" #define _LIT4 ".lit4" #define _LIT8 ".lit8" #define _LIB ".lib" #define _INIT ".init" #define _FINI ".fini" #define _PDATA ".pdata" #define _XDATA ".xdata" /* ECOFF uses some additional section flags. */ #define STYP_RDATA 0x100 #define STYP_SDATA 0x200 #define STYP_SBSS 0x400 #define STYP_ECOFF_FINI 0x1000000 #define STYP_LITA 0x4000000 #define STYP_LIT8 0x8000000 #define STYP_LIT4 0x10000000 #define STYP_ECOFF_INIT 0x80000000 #define STYP_OTHER_LOAD (STYP_ECOFF_INIT | STYP_ECOFF_FINI) /* The linker needs a section to hold small common variables while linking. There is no convenient way to create it when the linker needs it, so we always create one for each BFD. We then avoid writing it out. */ #define SCOMMON ".scommon" /* The ECOFF a.out header carries information about register masks and the gp value. The assembler needs to be able to write out this information, and objcopy needs to be able to copy it from one file to another. To handle this in BFD, we use a dummy section to hold the information. We call this section .reginfo, since MIPS ELF has a .reginfo section which serves a similar purpose. When BFD recognizes an ECOFF object, it copies the information into a private data structure. When the .reginfo section is read, the information is retrieved from the private data structure. When the .reginfo section is written, the information in the private data structure is updated. The contents of the .reginfo section, as seen by programs outside BFD, is a ecoff_reginfo structure. The contents of the structure are as seen on the host, so no swapping issues arise. The assembler used to update the private BFD data structures directly. With this approach, it instead just creates a .reginfo section and updates that. The real advantage of this approach is that objcopy works automatically. */ #define REGINFO ".reginfo" struct ecoff_reginfo { bfd_vma gp_value; /* GP register value. */ unsigned long gprmask; /* General registers used. */ unsigned long cprmask[4]; /* Coprocessor registers used. */ unsigned long fprmask; /* Floating pointer registers used. */ }; /* If the extern bit in a reloc is 1, then r_symndx is an index into the external symbol table. If the extern bit is 0, then r_symndx indicates a section, and is one of the following values. */ #define RELOC_SECTION_NONE 0 #define RELOC_SECTION_TEXT 1 #define RELOC_SECTION_RDATA 2 #define RELOC_SECTION_DATA 3 #define RELOC_SECTION_SDATA 4 #define RELOC_SECTION_SBSS 5 #define RELOC_SECTION_BSS 6 #define RELOC_SECTION_INIT 7 #define RELOC_SECTION_LIT8 8 #define RELOC_SECTION_LIT4 9 #define RELOC_SECTION_XDATA 10 #define RELOC_SECTION_PDATA 11 #define RELOC_SECTION_FINI 12 #define RELOC_SECTION_LITA 13 #define RELOC_SECTION_ABS 14 /********************** STABS **********************/ /* gcc uses mips-tfile to output type information in special stabs entries. These must match the corresponding definition in gcc/config/mips.h. At some point, these should probably go into a shared include file, but currently gcc and gdb do not share any directories. */ #define CODE_MASK 0x8F300 #define ECOFF_IS_STAB(sym) (((sym)->index & 0xFFF00) == CODE_MASK) #define ECOFF_MARK_STAB(code) ((code)+CODE_MASK) #define ECOFF_UNMARK_STAB(code) ((code)-CODE_MASK) #define STABS_SYMBOL "@stabs" /********************** COFF **********************/ /* gcc also uses mips-tfile to output COFF debugging information. These are the values it uses when outputting the .type directive. These should also be in a shared include file. */ #define N_BTMASK (017) #define N_TMASK (060) #define N_BTSHFT (4) #define N_TSHIFT (2) /********************** AUX **********************/ /* The auxiliary type information is the same on all known ECOFF targets. I can't see any reason that it would ever change, so I am going to gamble and define the external structures here, in the target independent ECOFF header file. The internal forms are defined in coff/sym.h, which was originally donated by MIPS Computer Systems. */ /* Type information external record */ struct tir_ext { unsigned char t_bits1[1]; unsigned char t_tq45[1]; unsigned char t_tq01[1]; unsigned char t_tq23[1]; }; #define TIR_BITS1_FBITFIELD_BIG 0x80 #define TIR_BITS1_FBITFIELD_LITTLE 0x01 #define TIR_BITS1_CONTINUED_BIG 0x40 #define TIR_BITS1_CONTINUED_LITTLE 0x02 #define TIR_BITS1_BT_BIG 0x3F #define TIR_BITS1_BT_SH_BIG 0 #define TIR_BITS1_BT_LITTLE 0xFC #define TIR_BITS1_BT_SH_LITTLE 2 #define TIR_BITS_TQ4_BIG 0xF0 #define TIR_BITS_TQ4_SH_BIG 4 #define TIR_BITS_TQ5_BIG 0x0F #define TIR_BITS_TQ5_SH_BIG 0 #define TIR_BITS_TQ4_LITTLE 0x0F #define TIR_BITS_TQ4_SH_LITTLE 0 #define TIR_BITS_TQ5_LITTLE 0xF0 #define TIR_BITS_TQ5_SH_LITTLE 4 #define TIR_BITS_TQ0_BIG 0xF0 #define TIR_BITS_TQ0_SH_BIG 4 #define TIR_BITS_TQ1_BIG 0x0F #define TIR_BITS_TQ1_SH_BIG 0 #define TIR_BITS_TQ0_LITTLE 0x0F #define TIR_BITS_TQ0_SH_LITTLE 0 #define TIR_BITS_TQ1_LITTLE 0xF0 #define TIR_BITS_TQ1_SH_LITTLE 4 #define TIR_BITS_TQ2_BIG 0xF0 #define TIR_BITS_TQ2_SH_BIG 4 #define TIR_BITS_TQ3_BIG 0x0F #define TIR_BITS_TQ3_SH_BIG 0 #define TIR_BITS_TQ2_LITTLE 0x0F #define TIR_BITS_TQ2_SH_LITTLE 0 #define TIR_BITS_TQ3_LITTLE 0xF0 #define TIR_BITS_TQ3_SH_LITTLE 4 /* Relative symbol external record */ struct rndx_ext { unsigned char r_bits[4]; }; #define RNDX_BITS0_RFD_SH_LEFT_BIG 4 #define RNDX_BITS1_RFD_BIG 0xF0 #define RNDX_BITS1_RFD_SH_BIG 4 #define RNDX_BITS0_RFD_SH_LEFT_LITTLE 0 #define RNDX_BITS1_RFD_LITTLE 0x0F #define RNDX_BITS1_RFD_SH_LEFT_LITTLE 8 #define RNDX_BITS1_INDEX_BIG 0x0F #define RNDX_BITS1_INDEX_SH_LEFT_BIG 16 #define RNDX_BITS2_INDEX_SH_LEFT_BIG 8 #define RNDX_BITS3_INDEX_SH_LEFT_BIG 0 #define RNDX_BITS1_INDEX_LITTLE 0xF0 #define RNDX_BITS1_INDEX_SH_LITTLE 4 #define RNDX_BITS2_INDEX_SH_LEFT_LITTLE 4 #define RNDX_BITS3_INDEX_SH_LEFT_LITTLE 12 /* Auxiliary symbol information external record */ union aux_ext { struct tir_ext a_ti; struct rndx_ext a_rndx; unsigned char a_dnLow[4]; unsigned char a_dnHigh[4]; unsigned char a_isym[4]; unsigned char a_iss[4]; unsigned char a_width[4]; unsigned char a_count[4]; }; #define AUX_GET_ANY(bigend, ax, field) \ ((bigend) ? bfd_getb32 ((ax)->field) : bfd_getl32 ((ax)->field)) #define AUX_GET_DNLOW(bigend, ax) AUX_GET_ANY ((bigend), (ax), a_dnLow) #define AUX_GET_DNHIGH(bigend, ax) AUX_GET_ANY ((bigend), (ax), a_dnHigh) #define AUX_GET_ISYM(bigend, ax) AUX_GET_ANY ((bigend), (ax), a_isym) #define AUX_GET_ISS(bigend, ax) AUX_GET_ANY ((bigend), (ax), a_iss) #define AUX_GET_WIDTH(bigend, ax) AUX_GET_ANY ((bigend), (ax), a_width) #define AUX_GET_COUNT(bigend, ax) AUX_GET_ANY ((bigend), (ax), a_count) #define AUX_PUT_ANY(bigend, val, ax, field) \ ((bigend) \ ? (bfd_putb32 ((bfd_vma) (val), (ax)->field), 0) \ : (bfd_putl32 ((bfd_vma) (val), (ax)->field), 0)) #define AUX_PUT_DNLOW(bigend, val, ax) \ AUX_PUT_ANY ((bigend), (val), (ax), a_dnLow) #define AUX_PUT_DNHIGH(bigend, val, ax) \ AUX_PUT_ANY ((bigend), (val), (ax), a_dnHigh) #define AUX_PUT_ISYM(bigend, val, ax) \ AUX_PUT_ANY ((bigend), (val), (ax), a_isym) #define AUX_PUT_ISS(bigend, val, ax) \ AUX_PUT_ANY ((bigend), (val), (ax), a_iss) #define AUX_PUT_WIDTH(bigend, val, ax) \ AUX_PUT_ANY ((bigend), (val), (ax), a_width) #define AUX_PUT_COUNT(bigend, val, ax) \ AUX_PUT_ANY ((bigend), (val), (ax), a_count) /* Prototypes for the swapping functions. These require that sym.h be included before this file. */ extern void ecoff_swap_tir_in PARAMS ((int bigend, struct tir_ext *, TIR *)); extern void ecoff_swap_tir_out PARAMS ((int bigend, TIR *, struct tir_ext *)); extern void ecoff_swap_rndx_in PARAMS ((int bigend, struct rndx_ext *, RNDXR *)); extern void ecoff_swap_rndx_out PARAMS ((int bigend, RNDXR *, struct rndx_ext *)); /********************** SWAPPING **********************/ /* The generic ECOFF code needs to be able to swap debugging information in and out in the specific format used by a particular ECOFF implementation. This structure provides the information needed to do this. */ struct ecoff_debug_swap { /* Symbol table magic number. */ int sym_magic; /* Alignment of debugging information. E.g., 4. */ bfd_size_type debug_align; /* Sizes of external symbolic information. */ bfd_size_type external_hdr_size; bfd_size_type external_dnr_size; bfd_size_type external_pdr_size; bfd_size_type external_sym_size; bfd_size_type external_opt_size; bfd_size_type external_fdr_size; bfd_size_type external_rfd_size; bfd_size_type external_ext_size; /* Functions to swap in external symbolic data. */ void (*swap_hdr_in) PARAMS ((bfd *, PTR, HDRR *)); void (*swap_dnr_in) PARAMS ((bfd *, PTR, DNR *)); void (*swap_pdr_in) PARAMS ((bfd *, PTR, PDR *)); void (*swap_sym_in) PARAMS ((bfd *, PTR, SYMR *)); void (*swap_opt_in) PARAMS ((bfd *, PTR, OPTR *)); void (*swap_fdr_in) PARAMS ((bfd *, PTR, FDR *)); void (*swap_rfd_in) PARAMS ((bfd *, PTR, RFDT *)); void (*swap_ext_in) PARAMS ((bfd *, PTR, EXTR *)); /* Functions to swap out external symbolic data. */ void (*swap_hdr_out) PARAMS ((bfd *, const HDRR *, PTR)); void (*swap_dnr_out) PARAMS ((bfd *, const DNR *, PTR)); void (*swap_pdr_out) PARAMS ((bfd *, const PDR *, PTR)); void (*swap_sym_out) PARAMS ((bfd *, const SYMR *, PTR)); void (*swap_opt_out) PARAMS ((bfd *, const OPTR *, PTR)); void (*swap_fdr_out) PARAMS ((bfd *, const FDR *, PTR)); void (*swap_rfd_out) PARAMS ((bfd *, const RFDT *, PTR)); void (*swap_ext_out) PARAMS ((bfd *, const EXTR *, PTR)); /* As noted above, it so happens that the auxiliary type information has the same type and format for all known ECOFF targets. I don't see any reason that that should change, so at least for now the auxiliary swapping information is not in this table. */ }; /********************** SYMBOLS **********************/ /* For efficiency, gdb deals directly with the unswapped symbolic information (that way it only takes the time to swap information that it really needs to read). gdb originally retrieved the information directly from the BFD backend information, but that strategy, besides being sort of ugly, does not work for MIPS ELF, which also uses ECOFF debugging information. This structure holds pointers to the (mostly) unswapped symbolic information. */ struct ecoff_debug_info { /* The swapped ECOFF symbolic header. */ HDRR symbolic_header; /* Pointers to the unswapped symbolic information. Note that the pointers to external structures point to different sorts of information on different ECOFF targets. The ecoff_debug_swap structure provides the sizes of the structures and the functions needed to swap the information in and out. These pointers are all pointers to arrays, not single structures. They will be NULL if there are no instances of the relevant structure. */ unsigned char *line; PTR external_dnr; /* struct dnr_ext */ PTR external_pdr; /* struct pdr_ext */ PTR external_sym; /* struct sym_ext */ PTR external_opt; /* struct opt_ext */ union aux_ext *external_aux; char *ss; char *ssext; PTR external_fdr; /* struct fdr_ext */ PTR external_rfd; /* struct rfd_ext */ PTR external_ext; /* struct ext_ext */ /* The swapped FDR information. Currently this is never NULL, but code using this structure should probably double-check in case this changes in the future. This is a pointer to an array, not a single structure. */ FDR *fdr; }; #endif /* ! defined (ECOFF_H) */