/* Print mips instructions for GDB, the GNU debugger, or for objdump. Copyright (C) 1989-2017 Free Software Foundation, Inc. Contributed by Nobuyuki Hikichi(hikichi@sra.co.jp). This file is part of the GNU opcodes library. This library is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3, or (at your option) any later version. It is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 51 Franklin Street - Fifth Floor, Boston, MA 02110-1301, USA. */ #include "sysdep.h" #include "disassemble.h" #include "libiberty.h" #include "opcode/mips.h" #include "opintl.h" /* FIXME: These are needed to figure out if the code is mips16 or not. The low bit of the address is often a good indicator. No symbol table is available when this code runs out in an embedded system as when it is used for disassembler support in a monitor. */ #if !defined(EMBEDDED_ENV) #define SYMTAB_AVAILABLE 1 #include "elf-bfd.h" #include "elf/mips.h" #endif /* Mips instructions are at maximum this many bytes long. */ #define INSNLEN 4 /* FIXME: These should be shared with gdb somehow. */ struct mips_cp0sel_name { unsigned int cp0reg; unsigned int sel; const char * const name; }; static const char * const mips_gpr_names_numeric[32] = { "$0", "$1", "$2", "$3", "$4", "$5", "$6", "$7", "$8", "$9", "$10", "$11", "$12", "$13", "$14", "$15", "$16", "$17", "$18", "$19", "$20", "$21", "$22", "$23", "$24", "$25", "$26", "$27", "$28", "$29", "$30", "$31" }; static const char * const mips_gpr_names_oldabi[32] = { "zero", "at", "v0", "v1", "a0", "a1", "a2", "a3", "t0", "t1", "t2", "t3", "t4", "t5", "t6", "t7", "s0", "s1", "s2", "s3", "s4", "s5", "s6", "s7", "t8", "t9", "k0", "k1", "gp", "sp", "s8", "ra" }; static const char * const mips_gpr_names_newabi[32] = { "zero", "at", "v0", "v1", "a0", "a1", "a2", "a3", "a4", "a5", "a6", "a7", "t0", "t1", "t2", "t3", "s0", "s1", "s2", "s3", "s4", "s5", "s6", "s7", "t8", "t9", "k0", "k1", "gp", "sp", "s8", "ra" }; static const char * const mips_fpr_names_numeric[32] = { "$f0", "$f1", "$f2", "$f3", "$f4", "$f5", "$f6", "$f7", "$f8", "$f9", "$f10", "$f11", "$f12", "$f13", "$f14", "$f15", "$f16", "$f17", "$f18", "$f19", "$f20", "$f21", "$f22", "$f23", "$f24", "$f25", "$f26", "$f27", "$f28", "$f29", "$f30", "$f31" }; static const char * const mips_fpr_names_32[32] = { "fv0", "fv0f", "fv1", "fv1f", "ft0", "ft0f", "ft1", "ft1f", "ft2", "ft2f", "ft3", "ft3f", "fa0", "fa0f", "fa1", "fa1f", "ft4", "ft4f", "ft5", "ft5f", "fs0", "fs0f", "fs1", "fs1f", "fs2", "fs2f", "fs3", "fs3f", "fs4", "fs4f", "fs5", "fs5f" }; static const char * const mips_fpr_names_n32[32] = { "fv0", "ft14", "fv1", "ft15", "ft0", "ft1", "ft2", "ft3", "ft4", "ft5", "ft6", "ft7", "fa0", "fa1", "fa2", "fa3", "fa4", "fa5", "fa6", "fa7", "fs0", "ft8", "fs1", "ft9", "fs2", "ft10", "fs3", "ft11", "fs4", "ft12", "fs5", "ft13" }; static const char * const mips_fpr_names_64[32] = { "fv0", "ft12", "fv1", "ft13", "ft0", "ft1", "ft2", "ft3", "ft4", "ft5", "ft6", "ft7", "fa0", "fa1", "fa2", "fa3", "fa4", "fa5", "fa6", "fa7", "ft8", "ft9", "ft10", "ft11", "fs0", "fs1", "fs2", "fs3", "fs4", "fs5", "fs6", "fs7" }; static const char * const mips_cp0_names_numeric[32] = { "$0", "$1", "$2", "$3", "$4", "$5", "$6", "$7", "$8", "$9", "$10", "$11", "$12", "$13", "$14", "$15", "$16", "$17", "$18", "$19", "$20", "$21", "$22", "$23", "$24", "$25", "$26", "$27", "$28", "$29", "$30", "$31" }; static const char * const mips_cp1_names_numeric[32] = { "$0", "$1", "$2", "$3", "$4", "$5", "$6", "$7", "$8", "$9", "$10", "$11", "$12", "$13", "$14", "$15", "$16", "$17", "$18", "$19", "$20", "$21", "$22", "$23", "$24", "$25", "$26", "$27", "$28", "$29", "$30", "$31" }; static const char * const mips_cp0_names_r3000[32] = { "c0_index", "c0_random", "c0_entrylo", "$3", "c0_context", "$5", "$6", "$7", "c0_badvaddr", "$9", "c0_entryhi", "$11", "c0_sr", "c0_cause", "c0_epc", "c0_prid", "$16", "$17", "$18", "$19", "$20", "$21", "$22", "$23", "$24", "$25", "$26", "$27", "$28", "$29", "$30", "$31", }; static const char * const mips_cp0_names_r4000[32] = { "c0_index", "c0_random", "c0_entrylo0", "c0_entrylo1", "c0_context", "c0_pagemask", "c0_wired", "$7", "c0_badvaddr", "c0_count", "c0_entryhi", "c0_compare", "c0_sr", "c0_cause", "c0_epc", "c0_prid", "c0_config", "c0_lladdr", "c0_watchlo", "c0_watchhi", "c0_xcontext", "$21", "$22", "$23", "$24", "$25", "c0_ecc", "c0_cacheerr", "c0_taglo", "c0_taghi", "c0_errorepc", "$31", }; static const char * const mips_cp0_names_r5900[32] = { "c0_index", "c0_random", "c0_entrylo0", "c0_entrylo1", "c0_context", "c0_pagemask", "c0_wired", "$7", "c0_badvaddr", "c0_count", "c0_entryhi", "c0_compare", "c0_sr", "c0_cause", "c0_epc", "c0_prid", "c0_config", "$17", "$18", "$19", "$20", "$21", "$22", "c0_badpaddr", "c0_depc", "c0_perfcnt", "$26", "$27", "c0_taglo", "c0_taghi", "c0_errorepc", "$31" }; static const char * const mips_cp0_names_mips3264[32] = { "c0_index", "c0_random", "c0_entrylo0", "c0_entrylo1", "c0_context", "c0_pagemask", "c0_wired", "$7", "c0_badvaddr", "c0_count", "c0_entryhi", "c0_compare", "c0_status", "c0_cause", "c0_epc", "c0_prid", "c0_config", "c0_lladdr", "c0_watchlo", "c0_watchhi", "c0_xcontext", "$21", "$22", "c0_debug", "c0_depc", "c0_perfcnt", "c0_errctl", "c0_cacheerr", "c0_taglo", "c0_taghi", "c0_errorepc", "c0_desave", }; static const char * const mips_cp1_names_mips3264[32] = { "c1_fir", "c1_ufr", "$2", "$3", "c1_unfr", "$5", "$6", "$7", "$8", "$9", "$10", "$11", "$12", "$13", "$14", "$15", "$16", "$17", "$18", "$19", "$20", "$21", "$22", "$23", "$24", "c1_fccr", "c1_fexr", "$27", "c1_fenr", "$29", "$30", "c1_fcsr" }; static const struct mips_cp0sel_name mips_cp0sel_names_mips3264[] = { { 16, 1, "c0_config1" }, { 16, 2, "c0_config2" }, { 16, 3, "c0_config3" }, { 18, 1, "c0_watchlo,1" }, { 18, 2, "c0_watchlo,2" }, { 18, 3, "c0_watchlo,3" }, { 18, 4, "c0_watchlo,4" }, { 18, 5, "c0_watchlo,5" }, { 18, 6, "c0_watchlo,6" }, { 18, 7, "c0_watchlo,7" }, { 19, 1, "c0_watchhi,1" }, { 19, 2, "c0_watchhi,2" }, { 19, 3, "c0_watchhi,3" }, { 19, 4, "c0_watchhi,4" }, { 19, 5, "c0_watchhi,5" }, { 19, 6, "c0_watchhi,6" }, { 19, 7, "c0_watchhi,7" }, { 25, 1, "c0_perfcnt,1" }, { 25, 2, "c0_perfcnt,2" }, { 25, 3, "c0_perfcnt,3" }, { 25, 4, "c0_perfcnt,4" }, { 25, 5, "c0_perfcnt,5" }, { 25, 6, "c0_perfcnt,6" }, { 25, 7, "c0_perfcnt,7" }, { 27, 1, "c0_cacheerr,1" }, { 27, 2, "c0_cacheerr,2" }, { 27, 3, "c0_cacheerr,3" }, { 28, 1, "c0_datalo" }, { 29, 1, "c0_datahi" } }; static const char * const mips_cp0_names_mips3264r2[32] = { "c0_index", "c0_random", "c0_entrylo0", "c0_entrylo1", "c0_context", "c0_pagemask", "c0_wired", "c0_hwrena", "c0_badvaddr", "c0_count", "c0_entryhi", "c0_compare", "c0_status", "c0_cause", "c0_epc", "c0_prid", "c0_config", "c0_lladdr", "c0_watchlo", "c0_watchhi", "c0_xcontext", "$21", "$22", "c0_debug", "c0_depc", "c0_perfcnt", "c0_errctl", "c0_cacheerr", "c0_taglo", "c0_taghi", "c0_errorepc", "c0_desave", }; static const struct mips_cp0sel_name mips_cp0sel_names_mips3264r2[] = { { 4, 1, "c0_contextconfig" }, { 0, 1, "c0_mvpcontrol" }, { 0, 2, "c0_mvpconf0" }, { 0, 3, "c0_mvpconf1" }, { 1, 1, "c0_vpecontrol" }, { 1, 2, "c0_vpeconf0" }, { 1, 3, "c0_vpeconf1" }, { 1, 4, "c0_yqmask" }, { 1, 5, "c0_vpeschedule" }, { 1, 6, "c0_vpeschefback" }, { 2, 1, "c0_tcstatus" }, { 2, 2, "c0_tcbind" }, { 2, 3, "c0_tcrestart" }, { 2, 4, "c0_tchalt" }, { 2, 5, "c0_tccontext" }, { 2, 6, "c0_tcschedule" }, { 2, 7, "c0_tcschefback" }, { 5, 1, "c0_pagegrain" }, { 6, 1, "c0_srsconf0" }, { 6, 2, "c0_srsconf1" }, { 6, 3, "c0_srsconf2" }, { 6, 4, "c0_srsconf3" }, { 6, 5, "c0_srsconf4" }, { 12, 1, "c0_intctl" }, { 12, 2, "c0_srsctl" }, { 12, 3, "c0_srsmap" }, { 15, 1, "c0_ebase" }, { 16, 1, "c0_config1" }, { 16, 2, "c0_config2" }, { 16, 3, "c0_config3" }, { 18, 1, "c0_watchlo,1" }, { 18, 2, "c0_watchlo,2" }, { 18, 3, "c0_watchlo,3" }, { 18, 4, "c0_watchlo,4" }, { 18, 5, "c0_watchlo,5" }, { 18, 6, "c0_watchlo,6" }, { 18, 7, "c0_watchlo,7" }, { 19, 1, "c0_watchhi,1" }, { 19, 2, "c0_watchhi,2" }, { 19, 3, "c0_watchhi,3" }, { 19, 4, "c0_watchhi,4" }, { 19, 5, "c0_watchhi,5" }, { 19, 6, "c0_watchhi,6" }, { 19, 7, "c0_watchhi,7" }, { 23, 1, "c0_tracecontrol" }, { 23, 2, "c0_tracecontrol2" }, { 23, 3, "c0_usertracedata" }, { 23, 4, "c0_tracebpc" }, { 25, 1, "c0_perfcnt,1" }, { 25, 2, "c0_perfcnt,2" }, { 25, 3, "c0_perfcnt,3" }, { 25, 4, "c0_perfcnt,4" }, { 25, 5, "c0_perfcnt,5" }, { 25, 6, "c0_perfcnt,6" }, { 25, 7, "c0_perfcnt,7" }, { 27, 1, "c0_cacheerr,1" }, { 27, 2, "c0_cacheerr,2" }, { 27, 3, "c0_cacheerr,3" }, { 28, 1, "c0_datalo" }, { 28, 2, "c0_taglo1" }, { 28, 3, "c0_datalo1" }, { 28, 4, "c0_taglo2" }, { 28, 5, "c0_datalo2" }, { 28, 6, "c0_taglo3" }, { 28, 7, "c0_datalo3" }, { 29, 1, "c0_datahi" }, { 29, 2, "c0_taghi1" }, { 29, 3, "c0_datahi1" }, { 29, 4, "c0_taghi2" }, { 29, 5, "c0_datahi2" }, { 29, 6, "c0_taghi3" }, { 29, 7, "c0_datahi3" }, }; /* SB-1: MIPS64 (mips_cp0_names_mips3264) with minor mods. */ static const char * const mips_cp0_names_sb1[32] = { "c0_index", "c0_random", "c0_entrylo0", "c0_entrylo1", "c0_context", "c0_pagemask", "c0_wired", "$7", "c0_badvaddr", "c0_count", "c0_entryhi", "c0_compare", "c0_status", "c0_cause", "c0_epc", "c0_prid", "c0_config", "c0_lladdr", "c0_watchlo", "c0_watchhi", "c0_xcontext", "$21", "$22", "c0_debug", "c0_depc", "c0_perfcnt", "c0_errctl", "c0_cacheerr_i", "c0_taglo_i", "c0_taghi_i", "c0_errorepc", "c0_desave", }; static const struct mips_cp0sel_name mips_cp0sel_names_sb1[] = { { 16, 1, "c0_config1" }, { 18, 1, "c0_watchlo,1" }, { 19, 1, "c0_watchhi,1" }, { 22, 0, "c0_perftrace" }, { 23, 3, "c0_edebug" }, { 25, 1, "c0_perfcnt,1" }, { 25, 2, "c0_perfcnt,2" }, { 25, 3, "c0_perfcnt,3" }, { 25, 4, "c0_perfcnt,4" }, { 25, 5, "c0_perfcnt,5" }, { 25, 6, "c0_perfcnt,6" }, { 25, 7, "c0_perfcnt,7" }, { 26, 1, "c0_buserr_pa" }, { 27, 1, "c0_cacheerr_d" }, { 27, 3, "c0_cacheerr_d_pa" }, { 28, 1, "c0_datalo_i" }, { 28, 2, "c0_taglo_d" }, { 28, 3, "c0_datalo_d" }, { 29, 1, "c0_datahi_i" }, { 29, 2, "c0_taghi_d" }, { 29, 3, "c0_datahi_d" }, }; /* Xlr cop0 register names. */ static const char * const mips_cp0_names_xlr[32] = { "c0_index", "c0_random", "c0_entrylo0", "c0_entrylo1", "c0_context", "c0_pagemask", "c0_wired", "$7", "c0_badvaddr", "c0_count", "c0_entryhi", "c0_compare", "c0_status", "c0_cause", "c0_epc", "c0_prid", "c0_config", "c0_lladdr", "c0_watchlo", "c0_watchhi", "c0_xcontext", "$21", "$22", "c0_debug", "c0_depc", "c0_perfcnt", "c0_errctl", "c0_cacheerr_i", "c0_taglo_i", "c0_taghi_i", "c0_errorepc", "c0_desave", }; /* XLR's CP0 Select Registers. */ static const struct mips_cp0sel_name mips_cp0sel_names_xlr[] = { { 9, 6, "c0_extintreq" }, { 9, 7, "c0_extintmask" }, { 15, 1, "c0_ebase" }, { 16, 1, "c0_config1" }, { 16, 2, "c0_config2" }, { 16, 3, "c0_config3" }, { 16, 7, "c0_procid2" }, { 18, 1, "c0_watchlo,1" }, { 18, 2, "c0_watchlo,2" }, { 18, 3, "c0_watchlo,3" }, { 18, 4, "c0_watchlo,4" }, { 18, 5, "c0_watchlo,5" }, { 18, 6, "c0_watchlo,6" }, { 18, 7, "c0_watchlo,7" }, { 19, 1, "c0_watchhi,1" }, { 19, 2, "c0_watchhi,2" }, { 19, 3, "c0_watchhi,3" }, { 19, 4, "c0_watchhi,4" }, { 19, 5, "c0_watchhi,5" }, { 19, 6, "c0_watchhi,6" }, { 19, 7, "c0_watchhi,7" }, { 25, 1, "c0_perfcnt,1" }, { 25, 2, "c0_perfcnt,2" }, { 25, 3, "c0_perfcnt,3" }, { 25, 4, "c0_perfcnt,4" }, { 25, 5, "c0_perfcnt,5" }, { 25, 6, "c0_perfcnt,6" }, { 25, 7, "c0_perfcnt,7" }, { 27, 1, "c0_cacheerr,1" }, { 27, 2, "c0_cacheerr,2" }, { 27, 3, "c0_cacheerr,3" }, { 28, 1, "c0_datalo" }, { 29, 1, "c0_datahi" } }; static const char * const mips_hwr_names_numeric[32] = { "$0", "$1", "$2", "$3", "$4", "$5", "$6", "$7", "$8", "$9", "$10", "$11", "$12", "$13", "$14", "$15", "$16", "$17", "$18", "$19", "$20", "$21", "$22", "$23", "$24", "$25", "$26", "$27", "$28", "$29", "$30", "$31" }; static const char * const mips_hwr_names_mips3264r2[32] = { "hwr_cpunum", "hwr_synci_step", "hwr_cc", "hwr_ccres", "$4", "$5", "$6", "$7", "$8", "$9", "$10", "$11", "$12", "$13", "$14", "$15", "$16", "$17", "$18", "$19", "$20", "$21", "$22", "$23", "$24", "$25", "$26", "$27", "$28", "$29", "$30", "$31" }; static const char * const msa_control_names[32] = { "msa_ir", "msa_csr", "msa_access", "msa_save", "msa_modify", "msa_request", "msa_map", "msa_unmap", "$8", "$9", "$10", "$11", "$12", "$13", "$14", "$15", "$16", "$17", "$18", "$19", "$20", "$21", "$22", "$23", "$24", "$25", "$26", "$27", "$28", "$29", "$30", "$31" }; struct mips_abi_choice { const char * name; const char * const *gpr_names; const char * const *fpr_names; }; struct mips_abi_choice mips_abi_choices[] = { { "numeric", mips_gpr_names_numeric, mips_fpr_names_numeric }, { "32", mips_gpr_names_oldabi, mips_fpr_names_32 }, { "n32", mips_gpr_names_newabi, mips_fpr_names_n32 }, { "64", mips_gpr_names_newabi, mips_fpr_names_64 }, }; struct mips_arch_choice { const char *name; int bfd_mach_valid; unsigned long bfd_mach; int processor; int isa; int ase; const char * const *cp0_names; const struct mips_cp0sel_name *cp0sel_names; unsigned int cp0sel_names_len; const char * const *cp1_names; const char * const *hwr_names; }; const struct mips_arch_choice mips_arch_choices[] = { { "numeric", 0, 0, 0, 0, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "r3000", 1, bfd_mach_mips3000, CPU_R3000, ISA_MIPS1, 0, mips_cp0_names_r3000, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "r3900", 1, bfd_mach_mips3900, CPU_R3900, ISA_MIPS1, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "r4000", 1, bfd_mach_mips4000, CPU_R4000, ISA_MIPS3, 0, mips_cp0_names_r4000, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "r4010", 1, bfd_mach_mips4010, CPU_R4010, ISA_MIPS2, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "vr4100", 1, bfd_mach_mips4100, CPU_VR4100, ISA_MIPS3, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "vr4111", 1, bfd_mach_mips4111, CPU_R4111, ISA_MIPS3, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "vr4120", 1, bfd_mach_mips4120, CPU_VR4120, ISA_MIPS3, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "r4300", 1, bfd_mach_mips4300, CPU_R4300, ISA_MIPS3, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "r4400", 1, bfd_mach_mips4400, CPU_R4400, ISA_MIPS3, 0, mips_cp0_names_r4000, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "r4600", 1, bfd_mach_mips4600, CPU_R4600, ISA_MIPS3, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "r4650", 1, bfd_mach_mips4650, CPU_R4650, ISA_MIPS3, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "r5000", 1, bfd_mach_mips5000, CPU_R5000, ISA_MIPS4, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "vr5400", 1, bfd_mach_mips5400, CPU_VR5400, ISA_MIPS4, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "vr5500", 1, bfd_mach_mips5500, CPU_VR5500, ISA_MIPS4, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "r5900", 1, bfd_mach_mips5900, CPU_R5900, ISA_MIPS3, 0, mips_cp0_names_r5900, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "r6000", 1, bfd_mach_mips6000, CPU_R6000, ISA_MIPS2, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "rm7000", 1, bfd_mach_mips7000, CPU_RM7000, ISA_MIPS4, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "rm9000", 1, bfd_mach_mips7000, CPU_RM7000, ISA_MIPS4, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "r8000", 1, bfd_mach_mips8000, CPU_R8000, ISA_MIPS4, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "r10000", 1, bfd_mach_mips10000, CPU_R10000, ISA_MIPS4, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "r12000", 1, bfd_mach_mips12000, CPU_R12000, ISA_MIPS4, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "r14000", 1, bfd_mach_mips14000, CPU_R14000, ISA_MIPS4, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "r16000", 1, bfd_mach_mips16000, CPU_R16000, ISA_MIPS4, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "mips5", 1, bfd_mach_mips5, CPU_MIPS5, ISA_MIPS5, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, /* For stock MIPS32, disassemble all applicable MIPS-specified ASEs. Note that MIPS-3D and MDMX are not applicable to MIPS32. (See _MIPS32 Architecture For Programmers Volume I: Introduction to the MIPS32 Architecture_ (MIPS Document Number MD00082, Revision 0.95), page 1. */ { "mips32", 1, bfd_mach_mipsisa32, CPU_MIPS32, ISA_MIPS32, ASE_SMARTMIPS, mips_cp0_names_mips3264, mips_cp0sel_names_mips3264, ARRAY_SIZE (mips_cp0sel_names_mips3264), mips_cp1_names_mips3264, mips_hwr_names_numeric }, { "mips32r2", 1, bfd_mach_mipsisa32r2, CPU_MIPS32R2, ISA_MIPS32R2, (ASE_SMARTMIPS | ASE_DSP | ASE_DSPR2 | ASE_EVA | ASE_MIPS3D | ASE_MT | ASE_MCU | ASE_VIRT | ASE_MSA | ASE_XPA), mips_cp0_names_mips3264r2, mips_cp0sel_names_mips3264r2, ARRAY_SIZE (mips_cp0sel_names_mips3264r2), mips_cp1_names_mips3264, mips_hwr_names_mips3264r2 }, { "mips32r3", 1, bfd_mach_mipsisa32r3, CPU_MIPS32R3, ISA_MIPS32R3, (ASE_SMARTMIPS | ASE_DSP | ASE_DSPR2 | ASE_EVA | ASE_MIPS3D | ASE_MT | ASE_MCU | ASE_VIRT | ASE_MSA | ASE_XPA), mips_cp0_names_mips3264r2, mips_cp0sel_names_mips3264r2, ARRAY_SIZE (mips_cp0sel_names_mips3264r2), mips_cp1_names_mips3264, mips_hwr_names_mips3264r2 }, { "mips32r5", 1, bfd_mach_mipsisa32r5, CPU_MIPS32R5, ISA_MIPS32R5, (ASE_SMARTMIPS | ASE_DSP | ASE_DSPR2 | ASE_EVA | ASE_MIPS3D | ASE_MT | ASE_MCU | ASE_VIRT | ASE_MSA | ASE_XPA), mips_cp0_names_mips3264r2, mips_cp0sel_names_mips3264r2, ARRAY_SIZE (mips_cp0sel_names_mips3264r2), mips_cp1_names_mips3264, mips_hwr_names_mips3264r2 }, { "mips32r6", 1, bfd_mach_mipsisa32r6, CPU_MIPS32R6, ISA_MIPS32R6, (ASE_EVA | ASE_MSA | ASE_VIRT | ASE_XPA | ASE_MCU | ASE_MT | ASE_DSP | ASE_DSPR2 | ASE_DSPR3), mips_cp0_names_mips3264r2, mips_cp0sel_names_mips3264r2, ARRAY_SIZE (mips_cp0sel_names_mips3264r2), mips_cp1_names_mips3264, mips_hwr_names_mips3264r2 }, /* For stock MIPS64, disassemble all applicable MIPS-specified ASEs. */ { "mips64", 1, bfd_mach_mipsisa64, CPU_MIPS64, ISA_MIPS64, ASE_MIPS3D | ASE_MDMX, mips_cp0_names_mips3264, mips_cp0sel_names_mips3264, ARRAY_SIZE (mips_cp0sel_names_mips3264), mips_cp1_names_mips3264, mips_hwr_names_numeric }, { "mips64r2", 1, bfd_mach_mipsisa64r2, CPU_MIPS64R2, ISA_MIPS64R2, (ASE_MIPS3D | ASE_DSP | ASE_DSPR2 | ASE_DSP64 | ASE_EVA | ASE_MT | ASE_MCU | ASE_VIRT | ASE_VIRT64 | ASE_MSA | ASE_MSA64 | ASE_XPA), mips_cp0_names_mips3264r2, mips_cp0sel_names_mips3264r2, ARRAY_SIZE (mips_cp0sel_names_mips3264r2), mips_cp1_names_mips3264, mips_hwr_names_mips3264r2 }, { "mips64r3", 1, bfd_mach_mipsisa64r3, CPU_MIPS64R3, ISA_MIPS64R3, (ASE_MIPS3D | ASE_DSP | ASE_DSPR2 | ASE_DSP64 | ASE_EVA | ASE_MT | ASE_MCU | ASE_VIRT | ASE_VIRT64 | ASE_MSA | ASE_MSA64 | ASE_XPA), mips_cp0_names_mips3264r2, mips_cp0sel_names_mips3264r2, ARRAY_SIZE (mips_cp0sel_names_mips3264r2), mips_cp1_names_mips3264, mips_hwr_names_mips3264r2 }, { "mips64r5", 1, bfd_mach_mipsisa64r5, CPU_MIPS64R5, ISA_MIPS64R5, (ASE_MIPS3D | ASE_DSP | ASE_DSPR2 | ASE_DSP64 | ASE_EVA | ASE_MT | ASE_MCU | ASE_VIRT | ASE_VIRT64 | ASE_MSA | ASE_MSA64 | ASE_XPA), mips_cp0_names_mips3264r2, mips_cp0sel_names_mips3264r2, ARRAY_SIZE (mips_cp0sel_names_mips3264r2), mips_cp1_names_mips3264, mips_hwr_names_mips3264r2 }, { "mips64r6", 1, bfd_mach_mipsisa64r6, CPU_MIPS64R6, ISA_MIPS64R6, (ASE_EVA | ASE_MSA | ASE_MSA64 | ASE_XPA | ASE_VIRT | ASE_VIRT64 | ASE_MCU | ASE_MT | ASE_DSP | ASE_DSPR2 | ASE_DSPR3), mips_cp0_names_mips3264r2, mips_cp0sel_names_mips3264r2, ARRAY_SIZE (mips_cp0sel_names_mips3264r2), mips_cp1_names_mips3264, mips_hwr_names_mips3264r2 }, { "interaptiv-mr2", 1, bfd_mach_mips_interaptiv_mr2, CPU_INTERAPTIV_MR2, ISA_MIPS32R3, ASE_MT | ASE_EVA | ASE_DSP | ASE_DSPR2 | ASE_MIPS16E2 | ASE_MIPS16E2_MT, mips_cp0_names_mips3264r2, mips_cp0sel_names_mips3264r2, ARRAY_SIZE (mips_cp0sel_names_mips3264r2), mips_cp1_names_mips3264, mips_hwr_names_mips3264r2 }, { "sb1", 1, bfd_mach_mips_sb1, CPU_SB1, ISA_MIPS64 | INSN_SB1, ASE_MIPS3D, mips_cp0_names_sb1, mips_cp0sel_names_sb1, ARRAY_SIZE (mips_cp0sel_names_sb1), mips_cp1_names_mips3264, mips_hwr_names_numeric }, { "loongson2e", 1, bfd_mach_mips_loongson_2e, CPU_LOONGSON_2E, ISA_MIPS3 | INSN_LOONGSON_2E, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "loongson2f", 1, bfd_mach_mips_loongson_2f, CPU_LOONGSON_2F, ISA_MIPS3 | INSN_LOONGSON_2F, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, { "loongson3a", 1, bfd_mach_mips_loongson_3a, CPU_LOONGSON_3A, ISA_MIPS64R2 | INSN_LOONGSON_3A, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_mips3264, mips_hwr_names_numeric }, { "octeon", 1, bfd_mach_mips_octeon, CPU_OCTEON, ISA_MIPS64R2 | INSN_OCTEON, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_mips3264, mips_hwr_names_numeric }, { "octeon+", 1, bfd_mach_mips_octeonp, CPU_OCTEONP, ISA_MIPS64R2 | INSN_OCTEONP, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_mips3264, mips_hwr_names_numeric }, { "octeon2", 1, bfd_mach_mips_octeon2, CPU_OCTEON2, ISA_MIPS64R2 | INSN_OCTEON2, 0, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_mips3264, mips_hwr_names_numeric }, { "octeon3", 1, bfd_mach_mips_octeon3, CPU_OCTEON3, ISA_MIPS64R5 | INSN_OCTEON3, ASE_VIRT | ASE_VIRT64, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_mips3264, mips_hwr_names_numeric }, { "xlr", 1, bfd_mach_mips_xlr, CPU_XLR, ISA_MIPS64 | INSN_XLR, 0, mips_cp0_names_xlr, mips_cp0sel_names_xlr, ARRAY_SIZE (mips_cp0sel_names_xlr), mips_cp1_names_mips3264, mips_hwr_names_numeric }, /* XLP is mostly like XLR, with the prominent exception it is being MIPS64R2. */ { "xlp", 1, bfd_mach_mips_xlr, CPU_XLR, ISA_MIPS64R2 | INSN_XLR, 0, mips_cp0_names_xlr, mips_cp0sel_names_xlr, ARRAY_SIZE (mips_cp0sel_names_xlr), mips_cp1_names_mips3264, mips_hwr_names_numeric }, /* This entry, mips16, is here only for ISA/processor selection; do not print its name. */ { "", 1, bfd_mach_mips16, CPU_MIPS16, ISA_MIPS64, ASE_MIPS16E2 | ASE_MIPS16E2_MT, mips_cp0_names_numeric, NULL, 0, mips_cp1_names_numeric, mips_hwr_names_numeric }, }; /* ISA and processor type to disassemble for, and register names to use. set_default_mips_dis_options and parse_mips_dis_options fill in these values. */ static int mips_processor; static int mips_isa; static int mips_ase; static int micromips_ase; static const char * const *mips_gpr_names; static const char * const *mips_fpr_names; static const char * const *mips_cp0_names; static const struct mips_cp0sel_name *mips_cp0sel_names; static int mips_cp0sel_names_len; static const char * const *mips_cp1_names; static const char * const *mips_hwr_names; /* Other options */ static int no_aliases; /* If set disassemble as most general inst. */ static const struct mips_abi_choice * choose_abi_by_name (const char *name, unsigned int namelen) { const struct mips_abi_choice *c; unsigned int i; for (i = 0, c = NULL; i < ARRAY_SIZE (mips_abi_choices) && c == NULL; i++) if (strncmp (mips_abi_choices[i].name, name, namelen) == 0 && strlen (mips_abi_choices[i].name) == namelen) c = &mips_abi_choices[i]; return c; } static const struct mips_arch_choice * choose_arch_by_name (const char *name, unsigned int namelen) { const struct mips_arch_choice *c = NULL; unsigned int i; for (i = 0, c = NULL; i < ARRAY_SIZE (mips_arch_choices) && c == NULL; i++) if (strncmp (mips_arch_choices[i].name, name, namelen) == 0 && strlen (mips_arch_choices[i].name) == namelen) c = &mips_arch_choices[i]; return c; } static const struct mips_arch_choice * choose_arch_by_number (unsigned long mach) { static unsigned long hint_bfd_mach; static const struct mips_arch_choice *hint_arch_choice; const struct mips_arch_choice *c; unsigned int i; /* We optimize this because even if the user specifies no flags, this will be done for every instruction! */ if (hint_bfd_mach == mach && hint_arch_choice != NULL && hint_arch_choice->bfd_mach == hint_bfd_mach) return hint_arch_choice; for (i = 0, c = NULL; i < ARRAY_SIZE (mips_arch_choices) && c == NULL; i++) { if (mips_arch_choices[i].bfd_mach_valid && mips_arch_choices[i].bfd_mach == mach) { c = &mips_arch_choices[i]; hint_bfd_mach = mach; hint_arch_choice = c; } } return c; } /* Check if the object uses NewABI conventions. */ static int is_newabi (Elf_Internal_Ehdr *header) { /* There are no old-style ABIs which use 64-bit ELF. */ if (header->e_ident[EI_CLASS] == ELFCLASS64) return 1; /* If a 32-bit ELF file, n32 is a new-style ABI. */ if ((header->e_flags & EF_MIPS_ABI2) != 0) return 1; return 0; } /* Check if the object has microMIPS ASE code. */ static int is_micromips (Elf_Internal_Ehdr *header) { if ((header->e_flags & EF_MIPS_ARCH_ASE_MICROMIPS) != 0) return 1; return 0; } /* Convert ASE flags from .MIPS.abiflags to internal values. */ static unsigned long mips_convert_abiflags_ases (unsigned long afl_ases) { unsigned long opcode_ases = 0; if (afl_ases & AFL_ASE_DSP) opcode_ases |= ASE_DSP; if (afl_ases & AFL_ASE_DSPR2) opcode_ases |= ASE_DSPR2; if (afl_ases & AFL_ASE_EVA) opcode_ases |= ASE_EVA; if (afl_ases & AFL_ASE_MCU) opcode_ases |= ASE_MCU; if (afl_ases & AFL_ASE_MDMX) opcode_ases |= ASE_MDMX; if (afl_ases & AFL_ASE_MIPS3D) opcode_ases |= ASE_MIPS3D; if (afl_ases & AFL_ASE_MT) opcode_ases |= ASE_MT; if (afl_ases & AFL_ASE_SMARTMIPS) opcode_ases |= ASE_SMARTMIPS; if (afl_ases & AFL_ASE_VIRT) opcode_ases |= ASE_VIRT; if (afl_ases & AFL_ASE_MSA) opcode_ases |= ASE_MSA; if (afl_ases & AFL_ASE_XPA) opcode_ases |= ASE_XPA; if (afl_ases & AFL_ASE_DSPR3) opcode_ases |= ASE_DSPR3; if (afl_ases & AFL_ASE_MIPS16E2) opcode_ases |= ASE_MIPS16E2; if ((afl_ases & (AFL_ASE_MIPS16E2 | AFL_ASE_MT)) == (AFL_ASE_MIPS16E2 | AFL_ASE_MT)) opcode_ases |= ASE_MIPS16E2_MT; return opcode_ases; } static void set_default_mips_dis_options (struct disassemble_info *info) { const struct mips_arch_choice *chosen_arch; /* Defaults: mipsIII/r3000 (?!), no microMIPS ASE (any compressed code is MIPS16 ASE) (o)32-style ("oldabi") GPR names, and numeric FPR, CP0 register, and HWR names. */ mips_isa = ISA_MIPS3; mips_processor = CPU_R3000; micromips_ase = 0; mips_ase = 0; mips_gpr_names = mips_gpr_names_oldabi; mips_fpr_names = mips_fpr_names_numeric; mips_cp0_names = mips_cp0_names_numeric; mips_cp0sel_names = NULL; mips_cp0sel_names_len = 0; mips_cp1_names = mips_cp1_names_numeric; mips_hwr_names = mips_hwr_names_numeric; no_aliases = 0; /* Set ISA, architecture, and cp0 register names as best we can. */ #if ! SYMTAB_AVAILABLE /* This is running out on a target machine, not in a host tool. FIXME: Where does mips_target_info come from? */ target_processor = mips_target_info.processor; mips_isa = mips_target_info.isa; mips_ase = mips_target_info.ase; #else chosen_arch = choose_arch_by_number (info->mach); if (chosen_arch != NULL) { mips_processor = chosen_arch->processor; mips_isa = chosen_arch->isa; mips_ase = chosen_arch->ase; mips_cp0_names = chosen_arch->cp0_names; mips_cp0sel_names = chosen_arch->cp0sel_names; mips_cp0sel_names_len = chosen_arch->cp0sel_names_len; mips_cp1_names = chosen_arch->cp1_names; mips_hwr_names = chosen_arch->hwr_names; } /* Update settings according to the ELF file header flags. */ if (info->flavour == bfd_target_elf_flavour && info->section != NULL) { struct bfd *abfd = info->section->owner; Elf_Internal_Ehdr *header = elf_elfheader (abfd); Elf_Internal_ABIFlags_v0 *abiflags = NULL; /* We won't ever get here if !HAVE_BFD_MIPS_ELF_GET_ABIFLAGS, because we won't then have a MIPS/ELF BFD, however we need to guard against a link error in a `--enable-targets=...' configuration with a 32-bit host where the MIPS target is a secondary, or with MIPS/ECOFF configurations. */ #ifdef HAVE_BFD_MIPS_ELF_GET_ABIFLAGS abiflags = bfd_mips_elf_get_abiflags (abfd); #endif /* If an ELF "newabi" binary, use the n32/(n)64 GPR names. */ if (is_newabi (header)) mips_gpr_names = mips_gpr_names_newabi; /* If a microMIPS binary, then don't use MIPS16 bindings. */ micromips_ase = is_micromips (header); /* OR in any extra ASE flags set in ELF file structures. */ if (abiflags) mips_ase |= mips_convert_abiflags_ases (abiflags->ases); else if (header->e_flags & EF_MIPS_ARCH_ASE_MDMX) mips_ase |= ASE_MDMX; } #endif } static void parse_mips_dis_option (const char *option, unsigned int len) { unsigned int i, optionlen, vallen; const char *val; const struct mips_abi_choice *chosen_abi; const struct mips_arch_choice *chosen_arch; /* Try to match options that are simple flags */ if (CONST_STRNEQ (option, "no-aliases")) { no_aliases = 1; return; } if (CONST_STRNEQ (option, "msa")) { mips_ase |= ASE_MSA; if ((mips_isa & INSN_ISA_MASK) == ISA_MIPS64R2 || (mips_isa & INSN_ISA_MASK) == ISA_MIPS64R3 || (mips_isa & INSN_ISA_MASK) == ISA_MIPS64R5 || (mips_isa & INSN_ISA_MASK) == ISA_MIPS64R6) mips_ase |= ASE_MSA64; return; } if (CONST_STRNEQ (option, "virt")) { mips_ase |= ASE_VIRT; if (mips_isa & ISA_MIPS64R2 || mips_isa & ISA_MIPS64R3 || mips_isa & ISA_MIPS64R5 || mips_isa & ISA_MIPS64R6) mips_ase |= ASE_VIRT64; return; } if (CONST_STRNEQ (option, "xpa")) { mips_ase |= ASE_XPA; return; } /* Look for the = that delimits the end of the option name. */ for (i = 0; i < len; i++) if (option[i] == '=') break; if (i == 0) /* Invalid option: no name before '='. */ return; if (i == len) /* Invalid option: no '='. */ return; if (i == (len - 1)) /* Invalid option: no value after '='. */ return; optionlen = i; val = option + (optionlen + 1); vallen = len - (optionlen + 1); if (strncmp ("gpr-names", option, optionlen) == 0 && strlen ("gpr-names") == optionlen) { chosen_abi = choose_abi_by_name (val, vallen); if (chosen_abi != NULL) mips_gpr_names = chosen_abi->gpr_names; return; } if (strncmp ("fpr-names", option, optionlen) == 0 && strlen ("fpr-names") == optionlen) { chosen_abi = choose_abi_by_name (val, vallen); if (chosen_abi != NULL) mips_fpr_names = chosen_abi->fpr_names; return; } if (strncmp ("cp0-names", option, optionlen) == 0 && strlen ("cp0-names") == optionlen) { chosen_arch = choose_arch_by_name (val, vallen); if (chosen_arch != NULL) { mips_cp0_names = chosen_arch->cp0_names; mips_cp0sel_names = chosen_arch->cp0sel_names; mips_cp0sel_names_len = chosen_arch->cp0sel_names_len; } return; } if (strncmp ("cp1-names", option, optionlen) == 0 && strlen ("cp1-names") == optionlen) { chosen_arch = choose_arch_by_name (val, vallen); if (chosen_arch != NULL) mips_cp1_names = chosen_arch->cp1_names; return; } if (strncmp ("hwr-names", option, optionlen) == 0 && strlen ("hwr-names") == optionlen) { chosen_arch = choose_arch_by_name (val, vallen); if (chosen_arch != NULL) mips_hwr_names = chosen_arch->hwr_names; return; } if (strncmp ("reg-names", option, optionlen) == 0 && strlen ("reg-names") == optionlen) { /* We check both ABI and ARCH here unconditionally, so that "numeric" will do the desirable thing: select numeric register names for all registers. Other than that, a given name probably won't match both. */ chosen_abi = choose_abi_by_name (val, vallen); if (chosen_abi != NULL) { mips_gpr_names = chosen_abi->gpr_names; mips_fpr_names = chosen_abi->fpr_names; } chosen_arch = choose_arch_by_name (val, vallen); if (chosen_arch != NULL) { mips_cp0_names = chosen_arch->cp0_names; mips_cp0sel_names = chosen_arch->cp0sel_names; mips_cp0sel_names_len = chosen_arch->cp0sel_names_len; mips_cp1_names = chosen_arch->cp1_names; mips_hwr_names = chosen_arch->hwr_names; } return; } /* Invalid option. */ } static void parse_mips_dis_options (const char *options) { const char *option_end; if (options == NULL) return; while (*options != '\0') { /* Skip empty options. */ if (*options == ',') { options++; continue; } /* We know that *options is neither NUL or a comma. */ option_end = options + 1; while (*option_end != ',' && *option_end != '\0') option_end++; parse_mips_dis_option (options, option_end - options); /* Go on to the next one. If option_end points to a comma, it will be skipped above. */ options = option_end; } } static const struct mips_cp0sel_name * lookup_mips_cp0sel_name (const struct mips_cp0sel_name *names, unsigned int len, unsigned int cp0reg, unsigned int sel) { unsigned int i; for (i = 0; i < len; i++) if (names[i].cp0reg == cp0reg && names[i].sel == sel) return &names[i]; return NULL; } /* Print register REGNO, of type TYPE, for instruction OPCODE. */ static void print_reg (struct disassemble_info *info, const struct mips_opcode *opcode, enum mips_reg_operand_type type, int regno) { switch (type) { case OP_REG_GP: info->fprintf_func (info->stream, "%s", mips_gpr_names[regno]); break; case OP_REG_FP: info->fprintf_func (info->stream, "%s", mips_fpr_names[regno]); break; case OP_REG_CCC: if (opcode->pinfo & (FP_D | FP_S)) info->fprintf_func (info->stream, "$fcc%d", regno); else info->fprintf_func (info->stream, "$cc%d", regno); break; case OP_REG_VEC: if (opcode->membership & INSN_5400) info->fprintf_func (info->stream, "$f%d", regno); else info->fprintf_func (info->stream, "$v%d", regno); break; case OP_REG_ACC: info->fprintf_func (info->stream, "$ac%d", regno); break; case OP_REG_COPRO: if (opcode->name[strlen (opcode->name) - 1] == '0') info->fprintf_func (info->stream, "%s", mips_cp0_names[regno]); else if (opcode->name[strlen (opcode->name) - 1] == '1') info->fprintf_func (info->stream, "%s", mips_cp1_names[regno]); else info->fprintf_func (info->stream, "$%d", regno); break; case OP_REG_HW: info->fprintf_func (info->stream, "%s", mips_hwr_names[regno]); break; case OP_REG_VF: info->fprintf_func (info->stream, "$vf%d", regno); break; case OP_REG_VI: info->fprintf_func (info->stream, "$vi%d", regno); break; case OP_REG_R5900_I: info->fprintf_func (info->stream, "$I"); break; case OP_REG_R5900_Q: info->fprintf_func (info->stream, "$Q"); break; case OP_REG_R5900_R: info->fprintf_func (info->stream, "$R"); break; case OP_REG_R5900_ACC: info->fprintf_func (info->stream, "$ACC"); break; case OP_REG_MSA: info->fprintf_func (info->stream, "$w%d", regno); break; case OP_REG_MSA_CTRL: info->fprintf_func (info->stream, "%s", msa_control_names[regno]); break; } } /* Used to track the state carried over from previous operands in an instruction. */ struct mips_print_arg_state { /* The value of the last OP_INT seen. We only use this for OP_MSB, where the value is known to be unsigned and small. */ unsigned int last_int; /* The type and number of the last OP_REG seen. We only use this for OP_REPEAT_DEST_REG and OP_REPEAT_PREV_REG. */ enum mips_reg_operand_type last_reg_type; unsigned int last_regno; unsigned int dest_regno; unsigned int seen_dest; }; /* Initialize STATE for the start of an instruction. */ static inline void init_print_arg_state (struct mips_print_arg_state *state) { memset (state, 0, sizeof (*state)); } /* Print OP_VU0_SUFFIX or OP_VU0_MATCH_SUFFIX operand OPERAND, whose value is given by UVAL. */ static void print_vu0_channel (struct disassemble_info *info, const struct mips_operand *operand, unsigned int uval) { if (operand->size == 4) info->fprintf_func (info->stream, "%s%s%s%s", uval & 8 ? "x" : "", uval & 4 ? "y" : "", uval & 2 ? "z" : "", uval & 1 ? "w" : ""); else if (operand->size == 2) info->fprintf_func (info->stream, "%c", "xyzw"[uval]); else abort (); } /* Record information about a register operand. */ static void mips_seen_register (struct mips_print_arg_state *state, unsigned int regno, enum mips_reg_operand_type reg_type) { state->last_reg_type = reg_type; state->last_regno = regno; if (!state->seen_dest) { state->seen_dest = 1; state->dest_regno = regno; } } /* Print SAVE/RESTORE instruction operands according to the argument register mask AMASK, the number of static registers saved NSREG, the $ra, $s0 and $s1 register specifiers RA, S0 and S1 respectively, and the frame size FRAME_SIZE. */ static void mips_print_save_restore (struct disassemble_info *info, unsigned int amask, unsigned int nsreg, unsigned int ra, unsigned int s0, unsigned int s1, unsigned int frame_size) { const fprintf_ftype infprintf = info->fprintf_func; unsigned int nargs, nstatics, smask, i, j; void *is = info->stream; const char *sep; if (amask == MIPS_SVRS_ALL_ARGS) { nargs = 4; nstatics = 0; } else if (amask == MIPS_SVRS_ALL_STATICS) { nargs = 0; nstatics = 4; } else { nargs = amask >> 2; nstatics = amask & 3; } sep = ""; if (nargs > 0) { infprintf (is, "%s", mips_gpr_names[4]); if (nargs > 1) infprintf (is, "-%s", mips_gpr_names[4 + nargs - 1]); sep = ","; } infprintf (is, "%s%d", sep, frame_size); if (ra) /* $ra */ infprintf (is, ",%s", mips_gpr_names[31]); smask = 0; if (s0) /* $s0 */ smask |= 1 << 0; if (s1) /* $s1 */ smask |= 1 << 1; if (nsreg > 0) /* $s2-$s8 */ smask |= ((1 << nsreg) - 1) << 2; for (i = 0; i < 9; i++) if (smask & (1 << i)) { infprintf (is, ",%s", mips_gpr_names[i == 8 ? 30 : (16 + i)]); /* Skip over string of set bits. */ for (j = i; smask & (2 << j); j++) continue; if (j > i) infprintf (is, "-%s", mips_gpr_names[j == 8 ? 30 : (16 + j)]); i = j + 1; } /* Statics $ax - $a3. */ if (nstatics == 1) infprintf (is, ",%s", mips_gpr_names[7]); else if (nstatics > 0) infprintf (is, ",%s-%s", mips_gpr_names[7 - nstatics + 1], mips_gpr_names[7]); } /* Print operand OPERAND of OPCODE, using STATE to track inter-operand state. UVAL is the encoding of the operand (shifted into bit 0) and BASE_PC is the base address for OP_PCREL operands. */ static void print_insn_arg (struct disassemble_info *info, struct mips_print_arg_state *state, const struct mips_opcode *opcode, const struct mips_operand *operand, bfd_vma base_pc, unsigned int uval) { const fprintf_ftype infprintf = info->fprintf_func; void *is = info->stream; switch (operand->type) { case OP_INT: { const struct mips_int_operand *int_op; int_op = (const struct mips_int_operand *) operand; uval = mips_decode_int_operand (int_op, uval); state->last_int = uval; if (int_op->print_hex) infprintf (is, "0x%x", uval); else infprintf (is, "%d", uval); } break; case OP_MAPPED_INT: { const struct mips_mapped_int_operand *mint_op; mint_op = (const struct mips_mapped_int_operand *) operand; uval = mint_op->int_map[uval]; state->last_int = uval; if (mint_op->print_hex) infprintf (is, "0x%x", uval); else infprintf (is, "%d", uval); } break; case OP_MSB: { const struct mips_msb_operand *msb_op; msb_op = (const struct mips_msb_operand *) operand; uval += msb_op->bias; if (msb_op->add_lsb) uval -= state->last_int; infprintf (is, "0x%x", uval); } break; case OP_REG: case OP_OPTIONAL_REG: { const struct mips_reg_operand *reg_op; reg_op = (const struct mips_reg_operand *) operand; uval = mips_decode_reg_operand (reg_op, uval); print_reg (info, opcode, reg_op->reg_type, uval); mips_seen_register (state, uval, reg_op->reg_type); } break; case OP_REG_PAIR: { const struct mips_reg_pair_operand *pair_op; pair_op = (const struct mips_reg_pair_operand *) operand; print_reg (info, opcode, pair_op->reg_type, pair_op->reg1_map[uval]); infprintf (is, ","); print_reg (info, opcode, pair_op->reg_type, pair_op->reg2_map[uval]); } break; case OP_PCREL: { const struct mips_pcrel_operand *pcrel_op; pcrel_op = (const struct mips_pcrel_operand *) operand; info->target = mips_decode_pcrel_operand (pcrel_op, base_pc, uval); /* For jumps and branches clear the ISA bit except for the GDB disassembler. */ if (pcrel_op->include_isa_bit && info->flavour != bfd_target_unknown_flavour) info->target &= -2; (*info->print_address_func) (info->target, info); } break; case OP_PERF_REG: infprintf (is, "%d", uval); break; case OP_ADDIUSP_INT: { int sval; sval = mips_signed_operand (operand, uval) * 4; if (sval >= -8 && sval < 8) sval ^= 0x400; infprintf (is, "%d", sval); break; } case OP_CLO_CLZ_DEST: { unsigned int reg1, reg2; reg1 = uval & 31; reg2 = uval >> 5; /* If one is zero use the other. */ if (reg1 == reg2 || reg2 == 0) infprintf (is, "%s", mips_gpr_names[reg1]); else if (reg1 == 0) infprintf (is, "%s", mips_gpr_names[reg2]); else /* Bogus, result depends on processor. */ infprintf (is, "%s or %s", mips_gpr_names[reg1], mips_gpr_names[reg2]); } break; case OP_SAME_RS_RT: case OP_CHECK_PREV: case OP_NON_ZERO_REG: { print_reg (info, opcode, OP_REG_GP, uval & 31); mips_seen_register (state, uval, OP_REG_GP); } break; case OP_LWM_SWM_LIST: if (operand->size == 2) { if (uval == 0) infprintf (is, "%s,%s", mips_gpr_names[16], mips_gpr_names[31]); else infprintf (is, "%s-%s,%s", mips_gpr_names[16], mips_gpr_names[16 + uval], mips_gpr_names[31]); } else { int s_reg_encode; s_reg_encode = uval & 0xf; if (s_reg_encode != 0) { if (s_reg_encode == 1) infprintf (is, "%s", mips_gpr_names[16]); else if (s_reg_encode < 9) infprintf (is, "%s-%s", mips_gpr_names[16], mips_gpr_names[15 + s_reg_encode]); else if (s_reg_encode == 9) infprintf (is, "%s-%s,%s", mips_gpr_names[16], mips_gpr_names[23], mips_gpr_names[30]); else infprintf (is, "UNKNOWN"); } if (uval & 0x10) /* For ra. */ { if (s_reg_encode == 0) infprintf (is, "%s", mips_gpr_names[31]); else infprintf (is, ",%s", mips_gpr_names[31]); } } break; case OP_ENTRY_EXIT_LIST: { const char *sep; unsigned int amask, smask; sep = ""; amask = (uval >> 3) & 7; if (amask > 0 && amask < 5) { infprintf (is, "%s", mips_gpr_names[4]); if (amask > 1) infprintf (is, "-%s", mips_gpr_names[amask + 3]); sep = ","; } smask = (uval >> 1) & 3; if (smask == 3) { infprintf (is, "%s??", sep); sep = ","; } else if (smask > 0) { infprintf (is, "%s%s", sep, mips_gpr_names[16]); if (smask > 1) infprintf (is, "-%s", mips_gpr_names[smask + 15]); sep = ","; } if (uval & 1) { infprintf (is, "%s%s", sep, mips_gpr_names[31]); sep = ","; } if (amask == 5 || amask == 6) { infprintf (is, "%s%s", sep, mips_fpr_names[0]); if (amask == 6) infprintf (is, "-%s", mips_fpr_names[1]); } } break; case OP_SAVE_RESTORE_LIST: /* Should be handled by the caller due to complex behavior. */ abort (); case OP_MDMX_IMM_REG: { unsigned int vsel; vsel = uval >> 5; uval &= 31; if ((vsel & 0x10) == 0) { int fmt; vsel &= 0x0f; for (fmt = 0; fmt < 3; fmt++, vsel >>= 1) if ((vsel & 1) == 0) break; print_reg (info, opcode, OP_REG_VEC, uval); infprintf (is, "[%d]", vsel >> 1); } else if ((vsel & 0x08) == 0) print_reg (info, opcode, OP_REG_VEC, uval); else infprintf (is, "0x%x", uval); } break; case OP_REPEAT_PREV_REG: print_reg (info, opcode, state->last_reg_type, state->last_regno); break; case OP_REPEAT_DEST_REG: print_reg (info, opcode, state->last_reg_type, state->dest_regno); break; case OP_PC: infprintf (is, "$pc"); break; case OP_REG28: print_reg (info, opcode, OP_REG_GP, 28); break; case OP_VU0_SUFFIX: case OP_VU0_MATCH_SUFFIX: print_vu0_channel (info, operand, uval); break; case OP_IMM_INDEX: infprintf (is, "[%d]", uval); break; case OP_REG_INDEX: infprintf (is, "["); print_reg (info, opcode, OP_REG_GP, uval); infprintf (is, "]"); break; } } /* Validate the arguments for INSN, which is described by OPCODE. Use DECODE_OPERAND to get the encoding of each operand. */ static bfd_boolean validate_insn_args (const struct mips_opcode *opcode, const struct mips_operand *(*decode_operand) (const char *), unsigned int insn) { struct mips_print_arg_state state; const struct mips_operand *operand; const char *s; unsigned int uval; init_print_arg_state (&state); for (s = opcode->args; *s; ++s) { switch (*s) { case ',': case '(': case ')': break; case '#': ++s; break; default: operand = decode_operand (s); if (operand) { uval = mips_extract_operand (operand, insn); switch (operand->type) { case OP_REG: case OP_OPTIONAL_REG: { const struct mips_reg_operand *reg_op; reg_op = (const struct mips_reg_operand *) operand; uval = mips_decode_reg_operand (reg_op, uval); mips_seen_register (&state, uval, reg_op->reg_type); } break; case OP_SAME_RS_RT: { unsigned int reg1, reg2; reg1 = uval & 31; reg2 = uval >> 5; if (reg1 != reg2 || reg1 == 0) return FALSE; } break; case OP_CHECK_PREV: { const struct mips_check_prev_operand *prev_op; prev_op = (const struct mips_check_prev_operand *) operand; if (!prev_op->zero_ok && uval == 0) return FALSE; if (((prev_op->less_than_ok && uval < state.last_regno) || (prev_op->greater_than_ok && uval > state.last_regno) || (prev_op->equal_ok && uval == state.last_regno))) break; return FALSE; } case OP_NON_ZERO_REG: { if (uval == 0) return FALSE; } break; case OP_INT: case OP_MAPPED_INT: case OP_MSB: case OP_REG_PAIR: case OP_PCREL: case OP_PERF_REG: case OP_ADDIUSP_INT: case OP_CLO_CLZ_DEST: case OP_LWM_SWM_LIST: case OP_ENTRY_EXIT_LIST: case OP_MDMX_IMM_REG: case OP_REPEAT_PREV_REG: case OP_REPEAT_DEST_REG: case OP_PC: case OP_REG28: case OP_VU0_SUFFIX: case OP_VU0_MATCH_SUFFIX: case OP_IMM_INDEX: case OP_REG_INDEX: case OP_SAVE_RESTORE_LIST: break; } } if (*s == 'm' || *s == '+' || *s == '-') ++s; } } return TRUE; } /* Print the arguments for INSN, which is described by OPCODE. Use DECODE_OPERAND to get the encoding of each operand. Use BASE_PC as the base of OP_PCREL operands, adjusting by LENGTH if the OP_PCREL operand is for a branch or jump. */ static void print_insn_args (struct disassemble_info *info, const struct mips_opcode *opcode, const struct mips_operand *(*decode_operand) (const char *), unsigned int insn, bfd_vma insn_pc, unsigned int length) { const fprintf_ftype infprintf = info->fprintf_func; void *is = info->stream; struct mips_print_arg_state state; const struct mips_operand *operand; const char *s; init_print_arg_state (&state); for (s = opcode->args; *s; ++s) { switch (*s) { case ',': case '(': case ')': infprintf (is, "%c", *s); break; case '#': ++s; infprintf (is, "%c%c", *s, *s); break; default: operand = decode_operand (s); if (!operand) { /* xgettext:c-format */ infprintf (is, _("# internal error, undefined operand in `%s %s'"), opcode->name, opcode->args); return; } if (operand->type == OP_SAVE_RESTORE_LIST) { /* Handle this case here because of the complex behavior. */ unsigned int amask = (insn >> 15) & 0xf; unsigned int nsreg = (insn >> 23) & 0x7; unsigned int ra = insn & 0x1000; /* $ra */ unsigned int s0 = insn & 0x800; /* $s0 */ unsigned int s1 = insn & 0x400; /* $s1 */ unsigned int frame_size = (((insn >> 15) & 0xf0) | ((insn >> 6) & 0x0f)) * 8; mips_print_save_restore (info, amask, nsreg, ra, s0, s1, frame_size); } else if (operand->type == OP_REG && s[1] == ',' && s[2] == 'H' && opcode->name[strlen (opcode->name) - 1] == '0') { /* Coprocessor register 0 with sel field. */ const struct mips_cp0sel_name *n; unsigned int reg, sel; reg = mips_extract_operand (operand, insn); s += 2; operand = decode_operand (s); sel = mips_extract_operand (operand, insn); /* CP0 register including 'sel' code for mftc0, to be printed textually if known. If not known, print both CP0 register name and sel numerically since CP0 register with sel 0 may have a name unrelated to register being printed. */ n = lookup_mips_cp0sel_name (mips_cp0sel_names, mips_cp0sel_names_len, reg, sel); if (n != NULL) infprintf (is, "%s", n->name); else infprintf (is, "$%d,%d", reg, sel); } else { bfd_vma base_pc = insn_pc; /* Adjust the PC relative base so that branch/jump insns use the following PC as the base but genuinely PC relative operands use the current PC. */ if (operand->type == OP_PCREL) { const struct mips_pcrel_operand *pcrel_op; pcrel_op = (const struct mips_pcrel_operand *) operand; /* The include_isa_bit flag is sufficient to distinguish branch/jump from other PC relative operands. */ if (pcrel_op->include_isa_bit) base_pc += length; } print_insn_arg (info, &state, opcode, operand, base_pc, mips_extract_operand (operand, insn)); } if (*s == 'm' || *s == '+' || *s == '-') ++s; break; } } } /* Print the mips instruction at address MEMADDR in debugged memory, on using INFO. Returns length of the instruction, in bytes, which is always INSNLEN. BIGENDIAN must be 1 if this is big-endian code, 0 if this is little-endian code. */ static int print_insn_mips (bfd_vma memaddr, int word, struct disassemble_info *info) { #define GET_OP(insn, field) \ (((insn) >> OP_SH_##field) & OP_MASK_##field) static const struct mips_opcode *mips_hash[OP_MASK_OP + 1]; const fprintf_ftype infprintf = info->fprintf_func; const struct mips_opcode *op; static bfd_boolean init = 0; void *is = info->stream; /* Build a hash table to shorten the search time. */ if (! init) { unsigned int i; for (i = 0; i <= OP_MASK_OP; i++) { for (op = mips_opcodes; op < &mips_opcodes[NUMOPCODES]; op++) { if (op->pinfo == INSN_MACRO || (no_aliases && (op->pinfo2 & INSN2_ALIAS))) continue; if (i == GET_OP (op->match, OP)) { mips_hash[i] = op; break; } } } init = 1; } info->bytes_per_chunk = INSNLEN; info->display_endian = info->endian; info->insn_info_valid = 1; info->branch_delay_insns = 0; info->data_size = 0; info->insn_type = dis_nonbranch; info->target = 0; info->target2 = 0; op = mips_hash[GET_OP (word, OP)]; if (op != NULL) { for (; op < &mips_opcodes[NUMOPCODES]; op++) { if (op->pinfo != INSN_MACRO && !(no_aliases && (op->pinfo2 & INSN2_ALIAS)) && (word & op->mask) == op->match) { /* We always disassemble the jalx instruction, except for MIPS r6. */ if (!opcode_is_member (op, mips_isa, mips_ase, mips_processor) && (strcmp (op->name, "jalx") || (mips_isa & INSN_ISA_MASK) == ISA_MIPS32R6 || (mips_isa & INSN_ISA_MASK) == ISA_MIPS64R6)) continue; /* Figure out instruction type and branch delay information. */ if ((op->pinfo & INSN_UNCOND_BRANCH_DELAY) != 0) { if ((op->pinfo & (INSN_WRITE_GPR_31 | INSN_WRITE_1)) != 0) info->insn_type = dis_jsr; else info->insn_type = dis_branch; info->branch_delay_insns = 1; } else if ((op->pinfo & (INSN_COND_BRANCH_DELAY | INSN_COND_BRANCH_LIKELY)) != 0) { if ((op->pinfo & INSN_WRITE_GPR_31) != 0) info->insn_type = dis_condjsr; else info->insn_type = dis_condbranch; info->branch_delay_insns = 1; } else if ((op->pinfo & (INSN_STORE_MEMORY | INSN_LOAD_MEMORY)) != 0) info->insn_type = dis_dref; if (!validate_insn_args (op, decode_mips_operand, word)) continue; infprintf (is, "%s", op->name); if (op->pinfo2 & INSN2_VU0_CHANNEL_SUFFIX) { unsigned int uval; infprintf (is, "."); uval = mips_extract_operand (&mips_vu0_channel_mask, word); print_vu0_channel (info, &mips_vu0_channel_mask, uval); } if (op->args[0]) { infprintf (is, "\t"); print_insn_args (info, op, decode_mips_operand, word, memaddr, 4); } return INSNLEN; } } } #undef GET_OP /* Handle undefined instructions. */ info->insn_type = dis_noninsn; infprintf (is, "0x%x", word); return INSNLEN; } /* Disassemble an operand for a mips16 instruction. */ static void print_mips16_insn_arg (struct disassemble_info *info, struct mips_print_arg_state *state, const struct mips_opcode *opcode, char type, bfd_vma memaddr, unsigned insn, bfd_boolean use_extend, unsigned extend, bfd_boolean is_offset) { const fprintf_ftype infprintf = info->fprintf_func; void *is = info->stream; const struct mips_operand *operand, *ext_operand; unsigned short ext_size; unsigned int uval; bfd_vma baseaddr; if (!use_extend) extend = 0; switch (type) { case ',': case '(': case ')': infprintf (is, "%c", type); break; default: operand = decode_mips16_operand (type, FALSE); if (!operand) { /* xgettext:c-format */ infprintf (is, _("# internal error, undefined operand in `%s %s'"), opcode->name, opcode->args); return; } if (operand->type == OP_SAVE_RESTORE_LIST) { /* Handle this case here because of the complex interaction with the EXTEND opcode. */ unsigned int amask = extend & 0xf; unsigned int nsreg = (extend >> 8) & 0x7; unsigned int ra = insn & 0x40; /* $ra */ unsigned int s0 = insn & 0x20; /* $s0 */ unsigned int s1 = insn & 0x10; /* $s1 */ unsigned int frame_size = ((extend & 0xf0) | (insn & 0x0f)) * 8; if (frame_size == 0 && !use_extend) frame_size = 128; mips_print_save_restore (info, amask, nsreg, ra, s0, s1, frame_size); break; } if (is_offset && operand->type == OP_INT) { const struct mips_int_operand *int_op; int_op = (const struct mips_int_operand *) operand; info->insn_type = dis_dref; info->data_size = 1 << int_op->shift; } ext_size = 0; if (use_extend) { ext_operand = decode_mips16_operand (type, TRUE); if (ext_operand != operand || (operand->type == OP_INT && operand->lsb == 0 && mips_opcode_32bit_p (opcode))) { ext_size = ext_operand->size; operand = ext_operand; } } if (operand->size == 26) uval = ((extend & 0x1f) << 21) | ((extend & 0x3e0) << 11) | insn; else if (ext_size == 16 || ext_size == 9) uval = ((extend & 0x1f) << 11) | (extend & 0x7e0) | (insn & 0x1f); else if (ext_size == 15) uval = ((extend & 0xf) << 11) | (extend & 0x7f0) | (insn & 0xf); else if (ext_size == 6) uval = ((extend >> 6) & 0x1f) | (extend & 0x20); else uval = mips_extract_operand (operand, (extend << 16) | insn); if (ext_size == 9) uval &= (1U << ext_size) - 1; baseaddr = memaddr + 2; if (operand->type == OP_PCREL) { const struct mips_pcrel_operand *pcrel_op; pcrel_op = (const struct mips_pcrel_operand *) operand; if (!pcrel_op->include_isa_bit && use_extend) baseaddr = memaddr - 2; else if (!pcrel_op->include_isa_bit) { bfd_byte buffer[2]; /* If this instruction is in the delay slot of a JAL/JALX instruction, the base address is the address of the JAL/JALX instruction. If it is in the delay slot of a JR/JALR instruction, the base address is the address of the JR/JALR instruction. This test is unreliable: we have no way of knowing whether the previous word is instruction or data. */ if (info->read_memory_func (memaddr - 4, buffer, 2, info) == 0 && (((info->endian == BFD_ENDIAN_BIG ? bfd_getb16 (buffer) : bfd_getl16 (buffer)) & 0xf800) == 0x1800)) baseaddr = memaddr - 4; else if (info->read_memory_func (memaddr - 2, buffer, 2, info) == 0 && (((info->endian == BFD_ENDIAN_BIG ? bfd_getb16 (buffer) : bfd_getl16 (buffer)) & 0xf89f) == 0xe800) && (((info->endian == BFD_ENDIAN_BIG ? bfd_getb16 (buffer) : bfd_getl16 (buffer)) & 0x0060) != 0x0060)) baseaddr = memaddr - 2; else baseaddr = memaddr; } } print_insn_arg (info, state, opcode, operand, baseaddr + 1, uval); break; } } /* Check if the given address is the last word of a MIPS16 PLT entry. This word is data and depending on the value it may interfere with disassembly of further PLT entries. We make use of the fact PLT symbols are marked BSF_SYNTHETIC. */ static bfd_boolean is_mips16_plt_tail (struct disassemble_info *info, bfd_vma addr) { if (info->symbols && info->symbols[0] && (info->symbols[0]->flags & BSF_SYNTHETIC) && addr == bfd_asymbol_value (info->symbols[0]) + 12) return TRUE; return FALSE; } /* Whether none, a 32-bit or a 16-bit instruction match has been done. */ enum match_kind { MATCH_NONE, MATCH_FULL, MATCH_SHORT }; /* Disassemble mips16 instructions. */ static int print_insn_mips16 (bfd_vma memaddr, struct disassemble_info *info) { const fprintf_ftype infprintf = info->fprintf_func; int status; bfd_byte buffer[4]; const struct mips_opcode *op, *opend; struct mips_print_arg_state state; void *is = info->stream; bfd_boolean have_second; bfd_boolean extend_only; unsigned int second; unsigned int first; unsigned int full; info->bytes_per_chunk = 2; info->display_endian = info->endian; info->insn_info_valid = 1; info->branch_delay_insns = 0; info->data_size = 0; info->target = 0; info->target2 = 0; #define GET_OP(insn, field) \ (((insn) >> MIPS16OP_SH_##field) & MIPS16OP_MASK_##field) /* Decode PLT entry's GOT slot address word. */ if (is_mips16_plt_tail (info, memaddr)) { info->insn_type = dis_noninsn; status = (*info->read_memory_func) (memaddr, buffer, 4, info); if (status == 0) { unsigned int gotslot; if (info->endian == BFD_ENDIAN_BIG) gotslot = bfd_getb32 (buffer); else gotslot = bfd_getl32 (buffer); infprintf (is, ".word\t0x%x", gotslot); return 4; } } else { info->insn_type = dis_nonbranch; status = (*info->read_memory_func) (memaddr, buffer, 2, info); } if (status != 0) { (*info->memory_error_func) (status, memaddr, info); return -1; } extend_only = FALSE; if (info->endian == BFD_ENDIAN_BIG) first = bfd_getb16 (buffer); else first = bfd_getl16 (buffer); status = (*info->read_memory_func) (memaddr + 2, buffer, 2, info); if (status == 0) { have_second = TRUE; if (info->endian == BFD_ENDIAN_BIG) second = bfd_getb16 (buffer); else second = bfd_getl16 (buffer); full = (first << 16) | second; } else { have_second = FALSE; second = 0; full = first; } /* FIXME: Should probably use a hash table on the major opcode here. */ opend = mips16_opcodes + bfd_mips16_num_opcodes; for (op = mips16_opcodes; op < opend; op++) { enum match_kind match; if (!opcode_is_member (op, mips_isa, mips_ase, mips_processor)) continue; if (op->pinfo == INSN_MACRO || (no_aliases && (op->pinfo2 & INSN2_ALIAS))) match = MATCH_NONE; else if (mips_opcode_32bit_p (op)) { if (have_second && (full & op->mask) == op->match) match = MATCH_FULL; else match = MATCH_NONE; } else if ((first & op->mask) == op->match) { match = MATCH_SHORT; second = 0; full = first; } else if ((first & 0xf800) == 0xf000 && have_second && !extend_only && (second & op->mask) == op->match) { if (op->pinfo2 & INSN2_SHORT_ONLY) { match = MATCH_NONE; extend_only = TRUE; } else match = MATCH_FULL; } else match = MATCH_NONE; if (match != MATCH_NONE) { const char *s; infprintf (is, "%s", op->name); if (op->args[0] != '\0') infprintf (is, "\t"); init_print_arg_state (&state); for (s = op->args; *s != '\0'; s++) { if (*s == ',' && s[1] == 'w' && GET_OP (full, RX) == GET_OP (full, RY)) { /* Skip the register and the comma. */ ++s; continue; } if (*s == ',' && s[1] == 'v' && GET_OP (full, RZ) == GET_OP (full, RX)) { /* Skip the register and the comma. */ ++s; continue; } if (s[0] == 'N' && s[1] == ',' && s[2] == 'O' && op->name[strlen (op->name) - 1] == '0') { /* Coprocessor register 0 with sel field. */ const struct mips_cp0sel_name *n; const struct mips_operand *operand; unsigned int reg, sel; operand = decode_mips16_operand (*s, TRUE); reg = mips_extract_operand (operand, (first << 16) | second); s += 2; operand = decode_mips16_operand (*s, TRUE); sel = mips_extract_operand (operand, (first << 16) | second); /* CP0 register including 'sel' code for mftc0, to be printed textually if known. If not known, print both CP0 register name and sel numerically since CP0 register with sel 0 may have a name unrelated to register being printed. */ n = lookup_mips_cp0sel_name (mips_cp0sel_names, mips_cp0sel_names_len, reg, sel); if (n != NULL) infprintf (is, "%s", n->name); else infprintf (is, "$%d,%d", reg, sel); } else switch (match) { case MATCH_FULL: print_mips16_insn_arg (info, &state, op, *s, memaddr + 2, second, TRUE, first, s[1] == '('); break; case MATCH_SHORT: print_mips16_insn_arg (info, &state, op, *s, memaddr, first, FALSE, 0, s[1] == '('); break; case MATCH_NONE: /* Stop the compiler complaining. */ break; } } /* Figure out branch instruction type and delay slot information. */ if ((op->pinfo & INSN_UNCOND_BRANCH_DELAY) != 0) info->branch_delay_insns = 1; if ((op->pinfo & INSN_UNCOND_BRANCH_DELAY) != 0 || (op->pinfo2 & INSN2_UNCOND_BRANCH) != 0) { if ((op->pinfo & INSN_WRITE_GPR_31) != 0) info->insn_type = dis_jsr; else info->insn_type = dis_branch; } else if ((op->pinfo2 & INSN2_COND_BRANCH) != 0) info->insn_type = dis_condbranch; return match == MATCH_FULL ? 4 : 2; } } #undef GET_OP infprintf (is, "0x%x", first); info->insn_type = dis_noninsn; return 2; } /* Disassemble microMIPS instructions. */ static int print_insn_micromips (bfd_vma memaddr, struct disassemble_info *info) { const fprintf_ftype infprintf = info->fprintf_func; const struct mips_opcode *op, *opend; void *is = info->stream; bfd_byte buffer[2]; unsigned int higher; unsigned int length; int status; unsigned int insn; info->bytes_per_chunk = 2; info->display_endian = info->endian; info->insn_info_valid = 1; info->branch_delay_insns = 0; info->data_size = 0; info->insn_type = dis_nonbranch; info->target = 0; info->target2 = 0; status = (*info->read_memory_func) (memaddr, buffer, 2, info); if (status != 0) { (*info->memory_error_func) (status, memaddr, info); return -1; } length = 2; if (info->endian == BFD_ENDIAN_BIG) insn = bfd_getb16 (buffer); else insn = bfd_getl16 (buffer); if ((insn & 0x1c00) == 0x0000 || (insn & 0x1000) == 0x1000) { /* This is a 32-bit microMIPS instruction. */ higher = insn; status = (*info->read_memory_func) (memaddr + 2, buffer, 2, info); if (status != 0) { infprintf (is, "micromips 0x%x", higher); (*info->memory_error_func) (status, memaddr + 2, info); return -1; } if (info->endian == BFD_ENDIAN_BIG) insn = bfd_getb16 (buffer); else insn = bfd_getl16 (buffer); insn = insn | (higher << 16); length += 2; } /* FIXME: Should probably use a hash table on the major opcode here. */ opend = micromips_opcodes + bfd_micromips_num_opcodes; for (op = micromips_opcodes; op < opend; op++) { if (op->pinfo != INSN_MACRO && !(no_aliases && (op->pinfo2 & INSN2_ALIAS)) && (insn & op->mask) == op->match && ((length == 2 && (op->mask & 0xffff0000) == 0) || (length == 4 && (op->mask & 0xffff0000) != 0))) { if (!validate_insn_args (op, decode_micromips_operand, insn)) continue; infprintf (is, "%s", op->name); if (op->args[0]) { infprintf (is, "\t"); print_insn_args (info, op, decode_micromips_operand, insn, memaddr + 1, length); } /* Figure out instruction type and branch delay information. */ if ((op->pinfo & (INSN_UNCOND_BRANCH_DELAY | INSN_COND_BRANCH_DELAY)) != 0) info->branch_delay_insns = 1; if (((op->pinfo & INSN_UNCOND_BRANCH_DELAY) | (op->pinfo2 & INSN2_UNCOND_BRANCH)) != 0) { if ((op->pinfo & (INSN_WRITE_GPR_31 | INSN_WRITE_1)) != 0) info->insn_type = dis_jsr; else info->insn_type = dis_branch; } else if (((op->pinfo & INSN_COND_BRANCH_DELAY) | (op->pinfo2 & INSN2_COND_BRANCH)) != 0) { if ((op->pinfo & INSN_WRITE_GPR_31) != 0) info->insn_type = dis_condjsr; else info->insn_type = dis_condbranch; } else if ((op->pinfo & (INSN_STORE_MEMORY | INSN_LOAD_MEMORY)) != 0) info->insn_type = dis_dref; return length; } } infprintf (is, "0x%x", insn); info->insn_type = dis_noninsn; return length; } /* Return 1 if a symbol associated with the location being disassembled indicates a compressed mode, either MIPS16 or microMIPS, according to MICROMIPS_P. We iterate over all the symbols at the address being considered assuming if at least one of them indicates code compression, then such code has been genuinely produced here (other symbols could have been derived from function symbols defined elsewhere or could define data). Otherwise, return 0. */ static bfd_boolean is_compressed_mode_p (struct disassemble_info *info, bfd_boolean micromips_p) { int i; int l; for (i = info->symtab_pos, l = i + info->num_symbols; i < l; i++) if (((info->symtab[i])->flags & BSF_SYNTHETIC) != 0 && ((!micromips_p && ELF_ST_IS_MIPS16 ((*info->symbols)->udata.i)) || (micromips_p && ELF_ST_IS_MICROMIPS ((*info->symbols)->udata.i)))) return 1; else if (bfd_asymbol_flavour (info->symtab[i]) == bfd_target_elf_flavour && info->symtab[i]->section == info->section) { elf_symbol_type *symbol = (elf_symbol_type *) info->symtab[i]; if ((!micromips_p && ELF_ST_IS_MIPS16 (symbol->internal_elf_sym.st_other)) || (micromips_p && ELF_ST_IS_MICROMIPS (symbol->internal_elf_sym.st_other))) return 1; } return 0; } /* In an environment where we do not know the symbol type of the instruction we are forced to assume that the low order bit of the instructions' address may mark it as a mips16 instruction. If we are single stepping, or the pc is within the disassembled function, this works. Otherwise, we need a clue. Sometimes. */ static int _print_insn_mips (bfd_vma memaddr, struct disassemble_info *info, enum bfd_endian endianness) { bfd_byte buffer[INSNLEN]; int status; set_default_mips_dis_options (info); parse_mips_dis_options (info->disassembler_options); if (info->mach == bfd_mach_mips16) return print_insn_mips16 (memaddr, info); if (info->mach == bfd_mach_mips_micromips) return print_insn_micromips (memaddr, info); #if 1 /* FIXME: If odd address, this is CLEARLY a compressed instruction. */ /* Only a few tools will work this way. */ if (memaddr & 0x01) { if (micromips_ase) return print_insn_micromips (memaddr, info); else return print_insn_mips16 (memaddr, info); } #endif #if SYMTAB_AVAILABLE if (is_compressed_mode_p (info, TRUE)) return print_insn_micromips (memaddr, info); if (is_compressed_mode_p (info, FALSE)) return print_insn_mips16 (memaddr, info); #endif status = (*info->read_memory_func) (memaddr, buffer, INSNLEN, info); if (status == 0) { int insn; if (endianness == BFD_ENDIAN_BIG) insn = bfd_getb32 (buffer); else insn = bfd_getl32 (buffer); return print_insn_mips (memaddr, insn, info); } else { (*info->memory_error_func) (status, memaddr, info); return -1; } } int print_insn_big_mips (bfd_vma memaddr, struct disassemble_info *info) { return _print_insn_mips (memaddr, info, BFD_ENDIAN_BIG); } int print_insn_little_mips (bfd_vma memaddr, struct disassemble_info *info) { return _print_insn_mips (memaddr, info, BFD_ENDIAN_LITTLE); } void print_mips_disassembler_options (FILE *stream) { unsigned int i; fprintf (stream, _("\n\ The following MIPS specific disassembler options are supported for use\n\ with the -M switch (multiple options should be separated by commas):\n")); fprintf (stream, _("\n\ no-aliases Use canonical instruction forms.\n")); fprintf (stream, _("\n\ msa Recognize MSA instructions.\n")); fprintf (stream, _("\n\ virt Recognize the virtualization ASE instructions.\n")); fprintf (stream, _("\n\ xpa Recognize the eXtended Physical Address (XPA)\n\ ASE instructions.\n")); fprintf (stream, _("\n\ gpr-names=ABI Print GPR names according to specified ABI.\n\ Default: based on binary being disassembled.\n")); fprintf (stream, _("\n\ fpr-names=ABI Print FPR names according to specified ABI.\n\ Default: numeric.\n")); fprintf (stream, _("\n\ cp0-names=ARCH Print CP0 register names according to\n\ specified architecture.\n\ Default: based on binary being disassembled.\n")); fprintf (stream, _("\n\ hwr-names=ARCH Print HWR names according to specified \n\ architecture.\n\ Default: based on binary being disassembled.\n")); fprintf (stream, _("\n\ reg-names=ABI Print GPR and FPR names according to\n\ specified ABI.\n")); fprintf (stream, _("\n\ reg-names=ARCH Print CP0 register and HWR names according to\n\ specified architecture.\n")); fprintf (stream, _("\n\ For the options above, the following values are supported for \"ABI\":\n\ ")); for (i = 0; i < ARRAY_SIZE (mips_abi_choices); i++) fprintf (stream, " %s", mips_abi_choices[i].name); fprintf (stream, _("\n")); fprintf (stream, _("\n\ For the options above, The following values are supported for \"ARCH\":\n\ ")); for (i = 0; i < ARRAY_SIZE (mips_arch_choices); i++) if (*mips_arch_choices[i].name != '\0') fprintf (stream, " %s", mips_arch_choices[i].name); fprintf (stream, _("\n")); fprintf (stream, _("\n")); }