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[/] [openrisc/] [trunk/] [gnu-src/] [gdb-6.8/] [sim/] [ppc/] [registers.h] - Rev 157
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/* This file is part of the program psim. Copyright 1994, 1997, 2003 Andrew Cagney This program 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 2 of the License, or (at your option) any later version. This program 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., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ #ifndef _REGISTERS_H_ #define _REGISTERS_H_ /* * The PowerPC registers * */ /* FIXME: For the moment use macro's to determine if the E500 or Altivec registers should be included. IGEN should instead of a :register: field to facilitate the specification and generation of per ISA registers. */ #ifdef WITH_E500 #include "e500_registers.h" #endif #if WITH_ALTIVEC #include "altivec_registers.h" #endif /** ** General Purpose Registers **/ typedef signed_word gpreg; /** ** Floating Point Registers **/ typedef unsigned64 fpreg; /** ** The condition register ** **/ typedef unsigned32 creg; /* The following sub bits are defined for the condition register */ enum { cr_i_negative = BIT4(0), cr_i_positive = BIT4(1), cr_i_zero = BIT4(2), cr_i_summary_overflow = BIT4(3), #if 0 /* cr0 - integer status */ cr0_i_summary_overflow_bit = 3, cr0_i_negative = BIT32(0), cr0_i_positive = BIT32(1), cr0_i_zero = BIT32(2), cr0_i_summary_overflow = BIT32(3), cr0_i_mask = MASK32(0,3), #endif /* cr1 - floating-point status */ cr1_i_floating_point_exception_summary_bit = 4, cr1_i_floating_point_enabled_exception_summary_bit = 5, cr1_i_floating_point_invalid_operation_exception_summary_bit = 6, cr1_i_floating_point_overflow_exception_bit = 7, cr1_i_floating_point_exception_summary = BIT32(4), cr1_i_floating_point_enabled_exception_summary = BIT32(5), cr1_i_floating_point_invalid_operation_exception_summary = BIT32(6), cr1_i_floating_point_overflow_exception = BIT32(7), cr1_i_mask = MASK32(4,7), }; /* Condition register 1 contains the result of floating point arithmetic */ enum { cr_fp_exception = BIT4(0), cr_fp_enabled_exception = BIT4(1), cr_fp_invalid_exception = BIT4(2), cr_fp_overflow_exception = BIT4(3), }; /** ** Floating-Point Status and Control Register **/ typedef unsigned32 fpscreg; enum { fpscr_fx_bit = 0, fpscr_fx = BIT32(0), fpscr_fex_bit = 1, fpscr_fex = BIT32(1), fpscr_vx_bit = 2, fpscr_vx = BIT32(2), fpscr_ox_bit = 3, fpscr_ox = BIT32(3), fpscr_ux = BIT32(4), fpscr_zx = BIT32(5), fpscr_xx = BIT32(6), fpscr_vxsnan = BIT32(7), /* SNAN */ fpscr_vxisi = BIT32(8), /* INF - INF */ fpscr_vxidi = BIT32(9), /* INF / INF */ fpscr_vxzdz = BIT32(10), /* 0 / 0 */ fpscr_vximz = BIT32(11), /* INF * 0 */ fpscr_vxvc = BIT32(12), fpscr_fr = BIT32(13), fpscr_fi = BIT32(14), fpscr_fprf = MASK32(15, 19), fpscr_c = BIT32(15), fpscr_fpcc_bit = 16, /* well sort of */ fpscr_fpcc = MASK32(16, 19), fpscr_fl = BIT32(16), fpscr_fg = BIT32(17), fpscr_fe = BIT32(18), fpscr_fu = BIT32(19), fpscr_rf_quiet_nan = fpscr_c | fpscr_fu, fpscr_rf_neg_infinity = fpscr_fl | fpscr_fu, fpscr_rf_neg_normal_number = fpscr_fl, fpscr_rf_neg_denormalized_number = fpscr_c | fpscr_fl, fpscr_rf_neg_zero = fpscr_c | fpscr_fe, fpscr_rf_pos_zero = fpscr_fe, fpscr_rf_pos_denormalized_number = fpscr_c | fpscr_fg, fpscr_rf_pos_normal_number = fpscr_fg, fpscr_rf_pos_infinity = fpscr_fg | fpscr_fu, fpscr_reserved_20 = BIT32(20), fpscr_vxsoft = BIT32(21), fpscr_vxsqrt = BIT32(22), fpscr_vxcvi = BIT32(23), fpscr_ve = BIT32(24), fpscr_oe = BIT32(25), fpscr_ue = BIT32(26), fpscr_ze = BIT32(27), fpscr_xe = BIT32(28), fpscr_ni = BIT32(29), fpscr_rn = MASK32(30, 31), fpscr_rn_round_to_nearest = 0, fpscr_rn_round_towards_zero = MASK32(31,31), fpscr_rn_round_towards_pos_infinity = MASK32(30,30), fpscr_rn_round_towards_neg_infinity = MASK32(30,31), fpscr_vx_bits = (fpscr_vxsnan | fpscr_vxisi | fpscr_vxidi | fpscr_vxzdz | fpscr_vximz | fpscr_vxvc | fpscr_vxsoft | fpscr_vxsqrt | fpscr_vxcvi), }; /** ** XER Register **/ typedef unsigned32 xereg; enum { xer_summary_overflow = BIT32(0), xer_summary_overflow_bit = 0, xer_carry = BIT32(2), xer_carry_bit = 2, xer_overflow = BIT32(1), xer_reserved_3_24 = MASK32(3,24), xer_byte_count_mask = MASK32(25,31) }; /** ** SPR's **/ #include "spreg.h" /** ** Segment Registers **/ typedef unsigned32 sreg; enum { nr_of_srs = 16 }; /** ** Machine state register **/ typedef unsigned_word msreg; /* 32 or 64 bits */ enum { #if (WITH_TARGET_WORD_BITSIZE == 64) msr_64bit_mode = BIT(0), #endif #if (WITH_TARGET_WORD_BITSIZE == 32) msr_64bit_mode = 0, #endif msr_power_management_enable = BIT(45), msr_tempoary_gpr_remapping = BIT(46), /* 603 specific */ msr_interrupt_little_endian_mode = BIT(47), msr_external_interrupt_enable = BIT(48), msr_problem_state = BIT(49), msr_floating_point_available = BIT(50), msr_machine_check_enable = BIT(51), msr_floating_point_exception_mode_0 = BIT(52), msr_single_step_trace_enable = BIT(53), msr_branch_trace_enable = BIT(54), msr_floating_point_exception_mode_1 = BIT(55), msr_interrupt_prefix = BIT(57), msr_instruction_relocate = BIT(58), msr_data_relocate = BIT(59), msr_recoverable_interrupt = BIT(62), msr_little_endian_mode = BIT(63) }; enum { srr1_hash_table_or_ibat_miss = BIT(33), srr1_direct_store_error_exception = BIT(35), srr1_protection_violation = BIT(36), srr1_segment_table_miss = BIT(42), srr1_floating_point_enabled = BIT(43), srr1_illegal_instruction = BIT(44), srr1_priviliged_instruction = BIT(45), srr1_trap = BIT(46), srr1_subsequent_instruction = BIT(47) }; /** ** storage interrupt registers **/ typedef enum { dsisr_direct_store_error_exception = BIT32(0), dsisr_hash_table_or_dbat_miss = BIT32(1), dsisr_protection_violation = BIT32(4), dsisr_earwax_violation = BIT32(5), dsisr_store_operation = BIT32(6), dsisr_segment_table_miss = BIT32(10), dsisr_earwax_disabled = BIT32(11) } dsisr_status; /** ** And the registers proper **/ typedef struct _registers { gpreg gpr[32]; fpreg fpr[32]; creg cr; fpscreg fpscr; /* Machine state register */ msreg msr; /* Spr's */ spreg spr[nr_of_sprs]; /* Segment Registers */ sreg sr[nr_of_srs]; #if WITH_ALTIVEC struct altivec_regs altivec; #endif #if WITH_E500 struct e500_regs e500; #endif } registers; /* dump out all the registers */ INLINE_REGISTERS\ (void) registers_dump (registers *regs); /* return information on a register based on name */ typedef enum { reg_invalid, reg_gpr, reg_fpr, reg_spr, reg_msr, reg_cr, reg_fpscr, reg_pc, reg_sr, reg_insns, reg_stalls, reg_cycles, #ifdef WITH_ALTIVEC reg_vr, reg_vscr, #endif #ifdef WITH_E500 reg_acc, reg_gprh, reg_evr, #endif nr_register_types } register_types; typedef struct { register_types type; int index; int size; } register_descriptions; INLINE_REGISTERS\ (register_descriptions) register_description (const char reg[]); /* Special purpose registers by their more common names */ #define SPREG(N) cpu_registers(processor)->spr[N] #define XER SPREG(spr_xer) #define LR SPREG(spr_lr) #define CTR SPREG(spr_ctr) #define SRR0 SPREG(spr_srr0) #define SRR1 SPREG(spr_srr1) #define DAR SPREG(spr_dar) #define DSISR SPREG(spr_dsisr) /* general purpose registers - indexed access */ #define GPR(N) cpu_registers(processor)->gpr[N] /* segment registers */ #define SEGREG(N) cpu_registers(processor)->sr[N] /* condition register */ #define CR cpu_registers(processor)->cr /* machine status register */ #define MSR cpu_registers(processor)->msr /* floating-point status condition register */ #define FPSCR cpu_registers(processor)->fpscr #endif /* _REGISTERS_H_ */