[deliverable/binutils-gdb.git] / sim / ppc / registers.h

/*  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_ */
Commit	Line	Data
c906108c SS	1	/* This file is part of the program psim.
c906108c SS	2
345d88d9	3	Copyright 1994, 1997, 2003 Andrew Cagney
c906108c SS	4
	5	This program is free software; you can redistribute it and/or modify
	6	it under the terms of the GNU General Public License as published by
	7	the Free Software Foundation; either version 2 of the License, or
	8	(at your option) any later version.
	9
	10	This program is distributed in the hope that it will be useful,
	11	but WITHOUT ANY WARRANTY; without even the implied warranty of
	12	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	13	GNU General Public License for more details.
	14
	15	You should have received a copy of the GNU General Public License
	16	along with this program; if not, write to the Free Software
	17	Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
	18
	19	*/
	20
	21
	22	#ifndef _REGISTERS_H_
	23	#define _REGISTERS_H_
	24
	25
	26	/*
	27	* The PowerPC registers
	28	*
	29	*/
	30
345d88d9 AC	31	/* FIXME:
	32
	33	For the moment use macro's to determine if the E500 or Altivec
	34	registers should be included. IGEN should instead of a :register:
	35	field to facilitate the specification and generation of per ISA
	36	registers. */
	37
	38	#ifdef WITH_E500
	39	#include "e500_registers.h"
	40	#endif
	41	#if WITH_ALTIVEC
	42	#include "altivec_registers.h"
	43	#endif
c906108c SS	44
	45	/**
	46	** General Purpose Registers
	47	**/
	48
	49	typedef signed_word gpreg;
	50
	51
	52
	53	/**
	54	** Floating Point Registers
	55	**/
	56
	57	typedef unsigned64 fpreg;
	58
	59
	60
	61	/**
	62	** The condition register
	63	**
	64	**/
	65
	66	typedef unsigned32 creg;
	67
	68	/* The following sub bits are defined for the condition register */
	69	enum {
	70	cr_i_negative = BIT4(0),
	71	cr_i_positive = BIT4(1),
	72	cr_i_zero = BIT4(2),
	73	cr_i_summary_overflow = BIT4(3),
	74	#if 0
	75	/* cr0 - integer status */
	76	cr0_i_summary_overflow_bit = 3,
	77	cr0_i_negative = BIT32(0),
	78	cr0_i_positive = BIT32(1),
	79	cr0_i_zero = BIT32(2),
	80	cr0_i_summary_overflow = BIT32(3),
	81	cr0_i_mask = MASK32(0,3),
	82	#endif
	83	/* cr1 - floating-point status */
	84	cr1_i_floating_point_exception_summary_bit = 4,
	85	cr1_i_floating_point_enabled_exception_summary_bit = 5,
	86	cr1_i_floating_point_invalid_operation_exception_summary_bit = 6,
	87	cr1_i_floating_point_overflow_exception_bit = 7,
	88	cr1_i_floating_point_exception_summary = BIT32(4),
	89	cr1_i_floating_point_enabled_exception_summary = BIT32(5),
	90	cr1_i_floating_point_invalid_operation_exception_summary = BIT32(6),
	91	cr1_i_floating_point_overflow_exception = BIT32(7),
	92	cr1_i_mask = MASK32(4,7),
	93	};
	94
	95
	96	/* Condition register 1 contains the result of floating point arithmetic */
	97	enum {
	98	cr_fp_exception = BIT4(0),
	99	cr_fp_enabled_exception = BIT4(1),
	100	cr_fp_invalid_exception = BIT4(2),
	101	cr_fp_overflow_exception = BIT4(3),
	102	};
	103
	104
	105
	106	/**
	107	** Floating-Point Status and Control Register
108	**/
109
110	typedef unsigned32 fpscreg;
111	enum {
112	fpscr_fx_bit = 0,
113	fpscr_fx = BIT32(0),
114	fpscr_fex_bit = 1,
115	fpscr_fex = BIT32(1),
116	fpscr_vx_bit = 2,
117	fpscr_vx = BIT32(2),
118	fpscr_ox_bit = 3,
119	fpscr_ox = BIT32(3),
120	fpscr_ux = BIT32(4),
121	fpscr_zx = BIT32(5),
122	fpscr_xx = BIT32(6),
123	fpscr_vxsnan = BIT32(7), /* SNAN */
124	fpscr_vxisi = BIT32(8), /* INF - INF */
125	fpscr_vxidi = BIT32(9), /* INF / INF */
126	fpscr_vxzdz = BIT32(10), /* 0 / 0 */
127	fpscr_vximz = BIT32(11), /* INF * 0 */
128	fpscr_vxvc = BIT32(12),
129	fpscr_fr = BIT32(13),
130	fpscr_fi = BIT32(14),
131	fpscr_fprf = MASK32(15, 19),
132	fpscr_c = BIT32(15),
133	fpscr_fpcc_bit = 16, /* well sort of */
134	fpscr_fpcc = MASK32(16, 19),
135	fpscr_fl = BIT32(16),
136	fpscr_fg = BIT32(17),
137	fpscr_fe = BIT32(18),
138	fpscr_fu = BIT32(19),
139	fpscr_rf_quiet_nan = fpscr_c \| fpscr_fu,
140	fpscr_rf_neg_infinity = fpscr_fl \| fpscr_fu,
141	fpscr_rf_neg_normal_number = fpscr_fl,
142	fpscr_rf_neg_denormalized_number = fpscr_c \| fpscr_fl,
143	fpscr_rf_neg_zero = fpscr_c \| fpscr_fe,
144	fpscr_rf_pos_zero = fpscr_fe,
145	fpscr_rf_pos_denormalized_number = fpscr_c \| fpscr_fg,
146	fpscr_rf_pos_normal_number = fpscr_fg,
147	fpscr_rf_pos_infinity = fpscr_fg \| fpscr_fu,
148	fpscr_reserved_20 = BIT32(20),
149	fpscr_vxsoft = BIT32(21),
150	fpscr_vxsqrt = BIT32(22),
151	fpscr_vxcvi = BIT32(23),
152	fpscr_ve = BIT32(24),
153	fpscr_oe = BIT32(25),
154	fpscr_ue = BIT32(26),
155	fpscr_ze = BIT32(27),
156	fpscr_xe = BIT32(28),
157	fpscr_ni = BIT32(29),
158	fpscr_rn = MASK32(30, 31),
159	fpscr_rn_round_to_nearest = 0,
160	fpscr_rn_round_towards_zero = MASK32(31,31),
161	fpscr_rn_round_towards_pos_infinity = MASK32(30,30),
162	fpscr_rn_round_towards_neg_infinity = MASK32(30,31),
163	fpscr_vx_bits = (fpscr_vxsnan \| fpscr_vxisi \| fpscr_vxidi
164	\| fpscr_vxzdz \| fpscr_vximz \| fpscr_vxvc
165	\| fpscr_vxsoft \| fpscr_vxsqrt \| fpscr_vxcvi),
166	};
167
168
169
170	/**
171	** XER Register
172	**/
173
174	typedef unsigned32 xereg;
175
176	enum {
177	xer_summary_overflow = BIT32(0), xer_summary_overflow_bit = 0,
178	xer_carry = BIT32(2), xer_carry_bit = 2,
179	xer_overflow = BIT32(1),
180	xer_reserved_3_24 = MASK32(3,24),
181	xer_byte_count_mask = MASK32(25,31)
182	};
183
184
185	/**
186	** SPR's
187	**/
188
189	#include "spreg.h"
190
191
192	/**
193	** Segment Registers
194	**/
195
196	typedef unsigned32 sreg;
197	enum {
198	nr_of_srs = 16
199	};
200
201
202	/**
203	** Machine state register
204	**/
205	typedef unsigned_word msreg; /* 32 or 64 bits */
206
207	enum {
208	#if (WITH_TARGET_WORD_BITSIZE == 64)
209	msr_64bit_mode = BIT(0),
210	#endif
211	#if (WITH_TARGET_WORD_BITSIZE == 32)
212	msr_64bit_mode = 0,
213	#endif
214	msr_power_management_enable = BIT(45),
215	msr_tempoary_gpr_remapping = BIT(46), /* 603 specific */
216	msr_interrupt_little_endian_mode = BIT(47),
217	msr_external_interrupt_enable = BIT(48),
218	msr_problem_state = BIT(49),
219	msr_floating_point_available = BIT(50),
220	msr_machine_check_enable = BIT(51),
221	msr_floating_point_exception_mode_0 = BIT(52),
222	msr_single_step_trace_enable = BIT(53),
223	msr_branch_trace_enable = BIT(54),
224	msr_floating_point_exception_mode_1 = BIT(55),
225	msr_interrupt_prefix = BIT(57),
226	msr_instruction_relocate = BIT(58),
227	msr_data_relocate = BIT(59),
228	msr_recoverable_interrupt = BIT(62),
229	msr_little_endian_mode = BIT(63)
230	};
231
232	enum {
233	srr1_hash_table_or_ibat_miss = BIT(33),
234	srr1_direct_store_error_exception = BIT(35),
235	srr1_protection_violation = BIT(36),
236	srr1_segment_table_miss = BIT(42),
237	srr1_floating_point_enabled = BIT(43),
238	srr1_illegal_instruction = BIT(44),
239	srr1_priviliged_instruction = BIT(45),
240	srr1_trap = BIT(46),
241	srr1_subsequent_instruction = BIT(47)
242	};
243
c906108c SS	244	/**
	245	** storage interrupt registers
	246	**/
	247
	248	typedef enum {
	249	dsisr_direct_store_error_exception = BIT32(0),
	250	dsisr_hash_table_or_dbat_miss = BIT32(1),
	251	dsisr_protection_violation = BIT32(4),
	252	dsisr_earwax_violation = BIT32(5),
	253	dsisr_store_operation = BIT32(6),
	254	dsisr_segment_table_miss = BIT32(10),
	255	dsisr_earwax_disabled = BIT32(11)
	256	} dsisr_status;
	257
	258
	259
	260	/**
	261	** And the registers proper
	262	**/
	263	typedef struct _registers {
	264
	265	gpreg gpr[32];
	266	fpreg fpr[32];
	267	creg cr;
	268	fpscreg fpscr;
	269
	270	/* Machine state register */
	271	msreg msr;
	272
	273	/* Spr's */
	274	spreg spr[nr_of_sprs];
	275
	276	/* Segment Registers */
	277	sreg sr[nr_of_srs];
	278
345d88d9 AC	279	#if WITH_ALTIVEC
	280	struct altivec_regs altivec;
	281	#endif
	282	#if WITH_E500
	283	struct e500_regs e500;
	284	#endif
c906108c	285
345d88d9	286	} registers;
c906108c SS	287
	288	/* dump out all the registers */
	289
	290	INLINE_REGISTERS\
	291	(void) registers_dump
	292	(registers *regs);
	293
	294
	295	/* return information on a register based on name */
	296
	297	typedef enum {
	298	reg_invalid,
	299	reg_gpr, reg_fpr, reg_spr, reg_msr,
	300	reg_cr, reg_fpscr, reg_pc, reg_sr,
	301	reg_insns, reg_stalls, reg_cycles,
345d88d9 AC	302	#ifdef WITH_ALTIVEC
	303	reg_vr, reg_vscr,
	304	#endif
	305	#ifdef WITH_E500
	306	reg_acc, reg_gprh, reg_evr,
	307	#endif
c906108c SS	308	nr_register_types
	309	} register_types;
	310
	311	typedef struct {
	312	register_types type;
	313	int index;
	314	int size;
	315	} register_descriptions;
	316
	317	INLINE_REGISTERS\
	318	(register_descriptions) register_description
	319	(const char reg[]);
	320
	321
	322	/* Special purpose registers by their more common names */
	323
	324	#define SPREG(N) cpu_registers(processor)->spr[N]
	325	#define XER SPREG(spr_xer)
	326	#define LR SPREG(spr_lr)
	327	#define CTR SPREG(spr_ctr)
	328	#define SRR0 SPREG(spr_srr0)
	329	#define SRR1 SPREG(spr_srr1)
	330	#define DAR SPREG(spr_dar)
	331	#define DSISR SPREG(spr_dsisr)
	332
	333	/* general purpose registers - indexed access */
	334	#define GPR(N) cpu_registers(processor)->gpr[N]
	335
	336	/* segment registers */
	337	#define SEGREG(N) cpu_registers(processor)->sr[N]
	338
	339	/* condition register */
	340	#define CR cpu_registers(processor)->cr
	341
	342	/* machine status register */
	343	#define MSR cpu_registers(processor)->msr
	344
	345	/* floating-point status condition register */
	346	#define FPSCR cpu_registers(processor)->fpscr
	347
	348	#endif /* _REGISTERS_H_ */