Subversion Repositories openrisc_2011-10-31

/* CPU family header for crisv32f.

/* CPU family header for crisv32f.

THIS FILE IS MACHINE GENERATED WITH CGEN.

THIS FILE IS MACHINE GENERATED WITH CGEN.

Copyright 1996-2007 Free Software Foundation, Inc.

Copyright 1996-2007 Free Software Foundation, Inc.

This file is part of the GNU simulators.

This file is part of the GNU simulators.

   This file is free software; you can redistribute it and/or modify

   This file is free software; you can redistribute it and/or modify

   it under the terms of the GNU General Public License as published by

   it under the terms of the GNU General Public License as published by

   the Free Software Foundation; either version 3, or (at your option)

   the Free Software Foundation; either version 3, or (at your option)

   any later version.

   any later version.

   It is distributed in the hope that it will be useful, but WITHOUT

   It is distributed in the hope that it will be useful, but WITHOUT

   ANY WARRANTY; without even the implied warranty of MERCHANTABILITY

   ANY WARRANTY; without even the implied warranty of MERCHANTABILITY

   or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public

   or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public

   License for more details.

   License for more details.

   You should have received a copy of the GNU General Public License along

   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.,

   with this program; if not, write to the Free Software Foundation, Inc.,

   51 Franklin Street - Fifth Floor, Boston, MA 02110-1301, USA.

   51 Franklin Street - Fifth Floor, Boston, MA 02110-1301, USA.

*/

*/

#ifndef CPU_CRISV32F_H

#ifndef CPU_CRISV32F_H

#define CPU_CRISV32F_H

#define CPU_CRISV32F_H

/* Maximum number of instructions that are fetched at a time.

/* Maximum number of instructions that are fetched at a time.

   This is for LIW type instructions sets (e.g. m32r).  */

   This is for LIW type instructions sets (e.g. m32r).  */

#define MAX_LIW_INSNS 1

#define MAX_LIW_INSNS 1

/* Maximum number of instructions that can be executed in parallel.  */

/* Maximum number of instructions that can be executed in parallel.  */

#define MAX_PARALLEL_INSNS 1

#define MAX_PARALLEL_INSNS 1

/* CPU state information.  */

/* CPU state information.  */

typedef struct {

typedef struct {

  /* Hardware elements.  */

  /* Hardware elements.  */

  struct {

  struct {

  /* program counter */

  /* program counter */

  USI h_pc;

  USI h_pc;

#define GET_H_PC() CPU (h_pc)

#define GET_H_PC() CPU (h_pc)

#define SET_H_PC(x) \

#define SET_H_PC(x) \

do { \

do { \

CPU (h_pc) = ANDSI ((x), (~ (1)));\

CPU (h_pc) = ANDSI ((x), (~ (1)));\

;} while (0)

;} while (0)

  /* General purpose registers */

  /* General purpose registers */

  SI h_gr_acr[16];

  SI h_gr_acr[16];

#define GET_H_GR_ACR(a1) CPU (h_gr_acr)[a1]

#define GET_H_GR_ACR(a1) CPU (h_gr_acr)[a1]

#define SET_H_GR_ACR(a1, x) (CPU (h_gr_acr)[a1] = (x))

#define SET_H_GR_ACR(a1, x) (CPU (h_gr_acr)[a1] = (x))

  /* Special registers for v32 */

  /* Special registers for v32 */

  SI h_sr_v32[16];

  SI h_sr_v32[16];

#define GET_H_SR_V32(index) (ORIF (ORIF (((index) == (((UINT) 0))), ((index) == (((UINT) 4)))), ((index) == (((UINT) 8))))) ? (0) : (((index) == (((UINT) 1)))) ? (32) : (((index) == (((UINT) 13)))) ? (ORSI (ANDSI (CPU (h_sr_v32[((UINT) 13)]), 1073740800), ORSI (ZEXTBISI (CPU (h_cbit)), ORSI (SLLSI (ZEXTBISI (CPU (h_vbit)), 1), ORSI (SLLSI (ZEXTBISI (CPU (h_zbit)), 2), ORSI (SLLSI (ZEXTBISI (CPU (h_nbit)), 3), ORSI (SLLSI (ZEXTBISI (CPU (h_xbit)), 4), ORSI (SLLSI (ZEXTBISI (GET_H_IBIT ()), 5), ORSI (SLLSI (ZEXTBISI (GET_H_UBIT ()), 6), ORSI (SLLSI (ZEXTBISI (CPU (h_pbit)), 7), ORSI (SLLSI (ZEXTBISI (CPU (h_rbit)), 8), ORSI (SLLSI (ZEXTBISI (CPU (h_sbit)), 9), ORSI (SLLSI (ZEXTBISI (CPU (h_mbit)), 30), ORSI (SLLSI (ZEXTBISI (CPU (h_qbit)), 31), 0)))))))))))))) : (((index) == (((UINT) 14)))) ? (((GET_H_UBIT ()) ? (CPU (h_gr_acr[((UINT) 14)])) : (CPU (h_sr_v32[((UINT) 14)])))) : (CPU (h_sr_v32[index]))

#define GET_H_SR_V32(index) (ORIF (ORIF (((index) == (((UINT) 0))), ((index) == (((UINT) 4)))), ((index) == (((UINT) 8))))) ? (0) : (((index) == (((UINT) 1)))) ? (32) : (((index) == (((UINT) 13)))) ? (ORSI (ANDSI (CPU (h_sr_v32[((UINT) 13)]), 1073740800), ORSI (ZEXTBISI (CPU (h_cbit)), ORSI (SLLSI (ZEXTBISI (CPU (h_vbit)), 1), ORSI (SLLSI (ZEXTBISI (CPU (h_zbit)), 2), ORSI (SLLSI (ZEXTBISI (CPU (h_nbit)), 3), ORSI (SLLSI (ZEXTBISI (CPU (h_xbit)), 4), ORSI (SLLSI (ZEXTBISI (GET_H_IBIT ()), 5), ORSI (SLLSI (ZEXTBISI (GET_H_UBIT ()), 6), ORSI (SLLSI (ZEXTBISI (CPU (h_pbit)), 7), ORSI (SLLSI (ZEXTBISI (CPU (h_rbit)), 8), ORSI (SLLSI (ZEXTBISI (CPU (h_sbit)), 9), ORSI (SLLSI (ZEXTBISI (CPU (h_mbit)), 30), ORSI (SLLSI (ZEXTBISI (CPU (h_qbit)), 31), 0)))))))))))))) : (((index) == (((UINT) 14)))) ? (((GET_H_UBIT ()) ? (CPU (h_gr_acr[((UINT) 14)])) : (CPU (h_sr_v32[((UINT) 14)])))) : (CPU (h_sr_v32[index]))

#define SET_H_SR_V32(index, x) \

#define SET_H_SR_V32(index, x) \

do { \

do { \

if (ORIF (ORIF ((((index)) == (((UINT) 0))), (((index)) == (((UINT) 4)))), ORIF ((((index)) == (((UINT) 8))), (((index)) == (((UINT) 1)))))) {\

if (ORIF (ORIF ((((index)) == (((UINT) 0))), (((index)) == (((UINT) 4)))), ORIF ((((index)) == (((UINT) 8))), (((index)) == (((UINT) 1)))))) {\

((void) 0); /*nop*/\

((void) 0); /*nop*/\

}\

}\

 else if ((((index)) == (((UINT) 13)))) {\

 else if ((((index)) == (((UINT) 13)))) {\

{\

{\

CPU (h_cbit) = ((NESI (ANDSI ((x), ((1) << (0))), 0)) ? (1) : (0));\

CPU (h_cbit) = ((NESI (ANDSI ((x), ((1) << (0))), 0)) ? (1) : (0));\

CPU (h_vbit) = ((NESI (ANDSI ((x), ((1) << (1))), 0)) ? (1) : (0));\

CPU (h_vbit) = ((NESI (ANDSI ((x), ((1) << (1))), 0)) ? (1) : (0));\

CPU (h_zbit) = ((NESI (ANDSI ((x), ((1) << (2))), 0)) ? (1) : (0));\

CPU (h_zbit) = ((NESI (ANDSI ((x), ((1) << (2))), 0)) ? (1) : (0));\

CPU (h_nbit) = ((NESI (ANDSI ((x), ((1) << (3))), 0)) ? (1) : (0));\

CPU (h_nbit) = ((NESI (ANDSI ((x), ((1) << (3))), 0)) ? (1) : (0));\

CPU (h_xbit) = ((NESI (ANDSI ((x), ((1) << (4))), 0)) ? (1) : (0));\

CPU (h_xbit) = ((NESI (ANDSI ((x), ((1) << (4))), 0)) ? (1) : (0));\

SET_H_IBIT (((NESI (ANDSI ((x), ((1) << (5))), 0)) ? (1) : (0)));\

SET_H_IBIT (((NESI (ANDSI ((x), ((1) << (5))), 0)) ? (1) : (0)));\

SET_H_SBIT (((NESI (ANDSI ((x), ((1) << (9))), 0)) ? (1) : (0)));\

SET_H_SBIT (((NESI (ANDSI ((x), ((1) << (9))), 0)) ? (1) : (0)));\

SET_H_MBIT (((NESI (ANDSI ((x), ((1) << (30))), 0)) ? (1) : (0)));\

SET_H_MBIT (((NESI (ANDSI ((x), ((1) << (30))), 0)) ? (1) : (0)));\

CPU (h_pbit) = ((NESI (ANDSI ((x), ((1) << (7))), 0)) ? (1) : (0));\

CPU (h_pbit) = ((NESI (ANDSI ((x), ((1) << (7))), 0)) ? (1) : (0));\

CPU (h_rbit) = ((NESI (ANDSI ((x), ((1) << (8))), 0)) ? (1) : (0));\

CPU (h_rbit) = ((NESI (ANDSI ((x), ((1) << (8))), 0)) ? (1) : (0));\

SET_H_QBIT (((NESI (ANDSI ((x), ((1) << (31))), 0)) ? (1) : (0)));\

SET_H_QBIT (((NESI (ANDSI ((x), ((1) << (31))), 0)) ? (1) : (0)));\

SET_H_UBIT (((NESI (ANDSI ((x), ((1) << (6))), 0)) ? (1) : (0)));\

SET_H_UBIT (((NESI (ANDSI ((x), ((1) << (6))), 0)) ? (1) : (0)));\

CPU (h_sr_v32[(index)]) = (x);\

CPU (h_sr_v32[(index)]) = (x);\

}\

}\

}\

}\

 else if ((((index)) == (((UINT) 14)))) {\

 else if ((((index)) == (((UINT) 14)))) {\

{\

{\

if (GET_H_UBIT ()) {\

if (GET_H_UBIT ()) {\

CPU (h_gr_acr[((UINT) 14)]) = (x);\

CPU (h_gr_acr[((UINT) 14)]) = (x);\

}\

}\

CPU (h_sr_v32[((UINT) 14)]) = (x);\

CPU (h_sr_v32[((UINT) 14)]) = (x);\

}\

}\

}\

}\

 else if ((((index)) == (((UINT) 3)))) {\

 else if ((((index)) == (((UINT) 3)))) {\

if (NOTBI (GET_H_UBIT ())) {\

if (NOTBI (GET_H_UBIT ())) {\

CPU (h_sr_v32[((UINT) 3)]) = (x);\

CPU (h_sr_v32[((UINT) 3)]) = (x);\

}\

}\

}\

}\

 else if ((((index)) == (((UINT) 9)))) {\

 else if ((((index)) == (((UINT) 9)))) {\

if (NOTBI (GET_H_UBIT ())) {\

if (NOTBI (GET_H_UBIT ())) {\

CPU (h_sr_v32[((UINT) 9)]) = (x);\

CPU (h_sr_v32[((UINT) 9)]) = (x);\

}\

}\

}\

}\

 else if ((((index)) == (((UINT) 2)))) {\

 else if ((((index)) == (((UINT) 2)))) {\

if (NOTBI (GET_H_UBIT ())) {\

if (NOTBI (GET_H_UBIT ())) {\

{\

{\

crisv32f_write_pid_handler (current_cpu, (x));\

crisv32f_write_pid_handler (current_cpu, (x));\

CPU (h_sr_v32[((UINT) 2)]) = (x);\

CPU (h_sr_v32[((UINT) 2)]) = (x);\

}\

}\

}\

}\

}\

}\

 else if ((((index)) == (((UINT) 15)))) {\

 else if ((((index)) == (((UINT) 15)))) {\

if (NOTBI (GET_H_UBIT ())) {\

if (NOTBI (GET_H_UBIT ())) {\

CPU (h_sr_v32[((UINT) 15)]) = (x);\

CPU (h_sr_v32[((UINT) 15)]) = (x);\

}\

}\

}\

}\

 else {\

 else {\

CPU (h_sr_v32[(index)]) = (x);\

CPU (h_sr_v32[(index)]) = (x);\

}\

}\

;} while (0)

;} while (0)

  /* carry bit */

  /* carry bit */

  BI h_cbit;

  BI h_cbit;

#define GET_H_CBIT() CPU (h_cbit)

#define GET_H_CBIT() CPU (h_cbit)

#define SET_H_CBIT(x) (CPU (h_cbit) = (x))

#define SET_H_CBIT(x) (CPU (h_cbit) = (x))

  /* overflow bit */

  /* overflow bit */

  BI h_vbit;

  BI h_vbit;

#define GET_H_VBIT() CPU (h_vbit)

#define GET_H_VBIT() CPU (h_vbit)

#define SET_H_VBIT(x) (CPU (h_vbit) = (x))

#define SET_H_VBIT(x) (CPU (h_vbit) = (x))

  /* zero bit */

  /* zero bit */

  BI h_zbit;

  BI h_zbit;

#define GET_H_ZBIT() CPU (h_zbit)

#define GET_H_ZBIT() CPU (h_zbit)

#define SET_H_ZBIT(x) (CPU (h_zbit) = (x))

#define SET_H_ZBIT(x) (CPU (h_zbit) = (x))

  /* sign bit */

  /* sign bit */

  BI h_nbit;

  BI h_nbit;

#define GET_H_NBIT() CPU (h_nbit)

#define GET_H_NBIT() CPU (h_nbit)

#define SET_H_NBIT(x) (CPU (h_nbit) = (x))

#define SET_H_NBIT(x) (CPU (h_nbit) = (x))

  /* extended-arithmetic bit */

  /* extended-arithmetic bit */

  BI h_xbit;

  BI h_xbit;

#define GET_H_XBIT() CPU (h_xbit)

#define GET_H_XBIT() CPU (h_xbit)

#define SET_H_XBIT(x) (CPU (h_xbit) = (x))

#define SET_H_XBIT(x) (CPU (h_xbit) = (x))

  /* sequence-broken bit */

  /* sequence-broken bit */

  BI h_pbit;

  BI h_pbit;

#define GET_H_PBIT() CPU (h_pbit)

#define GET_H_PBIT() CPU (h_pbit)

#define SET_H_PBIT(x) (CPU (h_pbit) = (x))

#define SET_H_PBIT(x) (CPU (h_pbit) = (x))

  /* carry bit for MCP+restore-p bit */

  /* carry bit for MCP+restore-p bit */

  BI h_rbit;

  BI h_rbit;

#define GET_H_RBIT() CPU (h_rbit)

#define GET_H_RBIT() CPU (h_rbit)

#define SET_H_RBIT(x) (CPU (h_rbit) = (x))

#define SET_H_RBIT(x) (CPU (h_rbit) = (x))

  /* guru mode bit */

  /* guru mode bit */

  BI h_gbit;

  BI h_gbit;

#define GET_H_GBIT() CPU (h_gbit)

#define GET_H_GBIT() CPU (h_gbit)

#define SET_H_GBIT(x) (CPU (h_gbit) = (x))

#define SET_H_GBIT(x) (CPU (h_gbit) = (x))

  /* Kernel stack pointer during user mode */

  /* Kernel stack pointer during user mode */

  SI h_kernel_sp;

  SI h_kernel_sp;

#define GET_H_KERNEL_SP() CPU (h_kernel_sp)

#define GET_H_KERNEL_SP() CPU (h_kernel_sp)

#define SET_H_KERNEL_SP(x) (CPU (h_kernel_sp) = (x))

#define SET_H_KERNEL_SP(x) (CPU (h_kernel_sp) = (x))

  /* User mode bit */

  /* User mode bit */

  BI h_ubit_v32;

  BI h_ubit_v32;

#define GET_H_UBIT_V32() CPU (h_ubit_v32)

#define GET_H_UBIT_V32() CPU (h_ubit_v32)

#define SET_H_UBIT_V32(x) \

#define SET_H_UBIT_V32(x) \

do { \

do { \

{\

{\

if (ANDIF ((x), NOTBI (CPU (h_ubit_v32)))) {\

if (ANDIF ((x), NOTBI (CPU (h_ubit_v32)))) {\

{\

{\

CPU (h_kernel_sp) = CPU (h_gr_acr[((UINT) 14)]);\

CPU (h_kernel_sp) = CPU (h_gr_acr[((UINT) 14)]);\

CPU (h_gr_acr[((UINT) 14)]) = CPU (h_sr_v32[((UINT) 14)]);\

CPU (h_gr_acr[((UINT) 14)]) = CPU (h_sr_v32[((UINT) 14)]);\

CPU (h_ubit_v32) = (x);\

CPU (h_ubit_v32) = (x);\

crisv32f_usermode_enabled (current_cpu);\

crisv32f_usermode_enabled (current_cpu);\

}\

}\

}\

}\

}\

}\

;} while (0)

;} while (0)

  /* Interrupt-enable bit */

  /* Interrupt-enable bit */

  BI h_ibit_v32;

  BI h_ibit_v32;

#define GET_H_IBIT_V32() CPU (h_ibit_v32)

#define GET_H_IBIT_V32() CPU (h_ibit_v32)

#define SET_H_IBIT_V32(x) \

#define SET_H_IBIT_V32(x) \

do { \

do { \

{\

{\

if (NOTBI (GET_H_UBIT ())) {\

if (NOTBI (GET_H_UBIT ())) {\

{\

{\

  BI tmp_enabled;\

  BI tmp_enabled;\

  tmp_enabled = ANDIF ((x), NOTBI (CPU (h_ibit_v32)));\

  tmp_enabled = ANDIF ((x), NOTBI (CPU (h_ibit_v32)));\

CPU (h_ibit_v32) = (x);\

CPU (h_ibit_v32) = (x);\

if (tmp_enabled) {\

if (tmp_enabled) {\

crisv32f_interrupts_enabled (current_cpu);\

crisv32f_interrupts_enabled (current_cpu);\

}\

}\

}\

}\

}\

}\

}\

}\

;} while (0)

;} while (0)

  /* NMI enable bit */

  /* NMI enable bit */

  BI h_mbit;

  BI h_mbit;

#define GET_H_MBIT() CPU (h_mbit)

#define GET_H_MBIT() CPU (h_mbit)

#define SET_H_MBIT(x) \

#define SET_H_MBIT(x) \

do { \

do { \

{\

{\

if (ANDIF ((x), ANDIF (NOTBI (CPU (h_mbit)), NOTBI (GET_H_UBIT ())))) {\

if (ANDIF ((x), ANDIF (NOTBI (CPU (h_mbit)), NOTBI (GET_H_UBIT ())))) {\

{\

{\

CPU (h_mbit) = 1;\

CPU (h_mbit) = 1;\

crisv32f_nmi_enabled (current_cpu);\

crisv32f_nmi_enabled (current_cpu);\

}\

}\

}\

}\

}\

}\

;} while (0)

;} while (0)

  /* Pending single-step bit */

  /* Pending single-step bit */

  BI h_qbit;

  BI h_qbit;

#define GET_H_QBIT() CPU (h_qbit)

#define GET_H_QBIT() CPU (h_qbit)

#define SET_H_QBIT(x) \

#define SET_H_QBIT(x) \

do { \

do { \

{\

{\

if (NOTBI (GET_H_UBIT ())) {\

if (NOTBI (GET_H_UBIT ())) {\

CPU (h_qbit) = (x);\

CPU (h_qbit) = (x);\

}\

}\

}\

}\

;} while (0)

;} while (0)

  /* Cause single step exception on ... [see CRISv32 ref] bit */

  /* Cause single step exception on ... [see CRISv32 ref] bit */

  BI h_sbit;

  BI h_sbit;

#define GET_H_SBIT() CPU (h_sbit)

#define GET_H_SBIT() CPU (h_sbit)

#define SET_H_SBIT(x) \

#define SET_H_SBIT(x) \

do { \

do { \

{\

{\

if (NOTBI (GET_H_UBIT ())) {\

if (NOTBI (GET_H_UBIT ())) {\

{\

{\

  BI tmp_enabled;\

  BI tmp_enabled;\

  tmp_enabled = ANDIF ((x), NOTBI (CPU (h_sbit)));\

  tmp_enabled = ANDIF ((x), NOTBI (CPU (h_sbit)));\

CPU (h_sbit) = (x);\

CPU (h_sbit) = (x);\

if (tmp_enabled) {\

if (tmp_enabled) {\

crisv32f_single_step_enabled (current_cpu);\

crisv32f_single_step_enabled (current_cpu);\

}\

}\

}\

}\

}\

}\

}\

}\

;} while (0)

;} while (0)

  } hardware;

  } hardware;

#define CPU_CGEN_HW(cpu) (& (cpu)->cpu_data.hardware)

#define CPU_CGEN_HW(cpu) (& (cpu)->cpu_data.hardware)

} CRISV32F_CPU_DATA;

} CRISV32F_CPU_DATA;

/* Virtual regs.  */

/* Virtual regs.  */

#define GET_H_V32_V32() 1

#define GET_H_V32_V32() 1

#define SET_H_V32_V32(x) \

#define SET_H_V32_V32(x) \

do { \

do { \

cgen_rtx_error (current_cpu, "Can't set h-v32");\

cgen_rtx_error (current_cpu, "Can't set h-v32");\

;} while (0)

;} while (0)

#define GET_H_GR(index) CPU (h_gr_acr[index])

#define GET_H_GR(index) CPU (h_gr_acr[index])

#define SET_H_GR(index, x) \

#define SET_H_GR(index, x) \

do { \

do { \

CPU (h_gr_acr[(index)]) = (x);\

CPU (h_gr_acr[(index)]) = (x);\

;} while (0)

;} while (0)

#define GET_H_RAW_GR_ACR(index) CPU (h_gr_acr[index])

#define GET_H_RAW_GR_ACR(index) CPU (h_gr_acr[index])

#define SET_H_RAW_GR_ACR(index, x) \

#define SET_H_RAW_GR_ACR(index, x) \

do { \

do { \

CPU (h_gr_acr[(index)]) = (x);\

CPU (h_gr_acr[(index)]) = (x);\

;} while (0)

;} while (0)

#define GET_H_SR(index) GET_H_SR_V32 (index)

#define GET_H_SR(index) GET_H_SR_V32 (index)

#define SET_H_SR(index, x) \

#define SET_H_SR(index, x) \

do { \

do { \

SET_H_SR_V32 ((index), (x));\

SET_H_SR_V32 ((index), (x));\

;} while (0)

;} while (0)

#define GET_H_SUPR(index) crisv32f_read_supr (current_cpu, index)

#define GET_H_SUPR(index) crisv32f_read_supr (current_cpu, index)

#define SET_H_SUPR(index, x) \

#define SET_H_SUPR(index, x) \

do { \

do { \

crisv32f_write_supr (current_cpu, (index), (x));\

crisv32f_write_supr (current_cpu, (index), (x));\

;} while (0)

;} while (0)

#define GET_H_CBIT_MOVE() GET_H_CBIT_MOVE_V32 ()

#define GET_H_CBIT_MOVE() GET_H_CBIT_MOVE_V32 ()

#define SET_H_CBIT_MOVE(x) \

#define SET_H_CBIT_MOVE(x) \

do { \

do { \

SET_H_CBIT_MOVE_V32 ((x));\

SET_H_CBIT_MOVE_V32 ((x));\

;} while (0)

;} while (0)

#define GET_H_CBIT_MOVE_V32() (cgen_rtx_error (current_cpu, "Can't get h-cbit-move on CRISv32"), 0)

#define GET_H_CBIT_MOVE_V32() (cgen_rtx_error (current_cpu, "Can't get h-cbit-move on CRISv32"), 0)

#define SET_H_CBIT_MOVE_V32(x) \

#define SET_H_CBIT_MOVE_V32(x) \

do { \

do { \

((void) 0); /*nop*/\

((void) 0); /*nop*/\

;} while (0)

;} while (0)

#define GET_H_VBIT_MOVE() GET_H_VBIT_MOVE_V32 ()

#define GET_H_VBIT_MOVE() GET_H_VBIT_MOVE_V32 ()

#define SET_H_VBIT_MOVE(x) \

#define SET_H_VBIT_MOVE(x) \

do { \

do { \

SET_H_VBIT_MOVE_V32 ((x));\

SET_H_VBIT_MOVE_V32 ((x));\

;} while (0)

;} while (0)

#define GET_H_VBIT_MOVE_V32() (cgen_rtx_error (current_cpu, "Can't get h-vbit-move on CRISv32"), 0)

#define GET_H_VBIT_MOVE_V32() (cgen_rtx_error (current_cpu, "Can't get h-vbit-move on CRISv32"), 0)

#define SET_H_VBIT_MOVE_V32(x) \

#define SET_H_VBIT_MOVE_V32(x) \

do { \

do { \

((void) 0); /*nop*/\

((void) 0); /*nop*/\

;} while (0)

;} while (0)

#define GET_H_ZBIT_MOVE() GET_H_ZBIT_MOVE_V32 ()

#define GET_H_ZBIT_MOVE() GET_H_ZBIT_MOVE_V32 ()

#define SET_H_ZBIT_MOVE(x) \

#define SET_H_ZBIT_MOVE(x) \

do { \

do { \

SET_H_ZBIT_MOVE_V32 ((x));\

SET_H_ZBIT_MOVE_V32 ((x));\

;} while (0)

;} while (0)

#define GET_H_ZBIT_MOVE_V32() (cgen_rtx_error (current_cpu, "Can't get h-zbit-move on CRISv32"), 0)

#define GET_H_ZBIT_MOVE_V32() (cgen_rtx_error (current_cpu, "Can't get h-zbit-move on CRISv32"), 0)

#define SET_H_ZBIT_MOVE_V32(x) \

#define SET_H_ZBIT_MOVE_V32(x) \

do { \

do { \

((void) 0); /*nop*/\

((void) 0); /*nop*/\

;} while (0)

;} while (0)

#define GET_H_NBIT_MOVE() GET_H_NBIT_MOVE_V32 ()

#define GET_H_NBIT_MOVE() GET_H_NBIT_MOVE_V32 ()

#define SET_H_NBIT_MOVE(x) \

#define SET_H_NBIT_MOVE(x) \

do { \

do { \

SET_H_NBIT_MOVE_V32 ((x));\

SET_H_NBIT_MOVE_V32 ((x));\

;} while (0)

;} while (0)

#define GET_H_NBIT_MOVE_V32() (cgen_rtx_error (current_cpu, "Can't get h-nbit-move on CRISv32"), 0)

#define GET_H_NBIT_MOVE_V32() (cgen_rtx_error (current_cpu, "Can't get h-nbit-move on CRISv32"), 0)

#define SET_H_NBIT_MOVE_V32(x) \

#define SET_H_NBIT_MOVE_V32(x) \

do { \

do { \

((void) 0); /*nop*/\

((void) 0); /*nop*/\

;} while (0)

;} while (0)

#define GET_H_IBIT() CPU (h_ibit_v32)

#define GET_H_IBIT() CPU (h_ibit_v32)

#define SET_H_IBIT(x) \

#define SET_H_IBIT(x) \

do { \

do { \

SET_H_IBIT_V32 ((x));\

SET_H_IBIT_V32 ((x));\

;} while (0)

;} while (0)

#define GET_H_UBIT() CPU (h_ubit_v32)

#define GET_H_UBIT() CPU (h_ubit_v32)

#define SET_H_UBIT(x) \

#define SET_H_UBIT(x) \

do { \

do { \

SET_H_UBIT_V32 ((x));\

SET_H_UBIT_V32 ((x));\

;} while (0)

;} while (0)

#define GET_H_INSN_PREFIXED_P() GET_H_INSN_PREFIXED_P_V32 ()

#define GET_H_INSN_PREFIXED_P() GET_H_INSN_PREFIXED_P_V32 ()

#define SET_H_INSN_PREFIXED_P(x) \

#define SET_H_INSN_PREFIXED_P(x) \

do { \

do { \

SET_H_INSN_PREFIXED_P_V32 ((x));\

SET_H_INSN_PREFIXED_P_V32 ((x));\

;} while (0)

;} while (0)

#define GET_H_INSN_PREFIXED_P_V32() 0

#define GET_H_INSN_PREFIXED_P_V32() 0

#define SET_H_INSN_PREFIXED_P_V32(x) \

#define SET_H_INSN_PREFIXED_P_V32(x) \

do { \

do { \

((void) 0); /*nop*/\

((void) 0); /*nop*/\

;} while (0)

;} while (0)

#define GET_H_PREFIXREG_V32() GET_H_GR (((UINT) 15))

#define GET_H_PREFIXREG_V32() GET_H_GR (((UINT) 15))

#define SET_H_PREFIXREG_V32(x) \

#define SET_H_PREFIXREG_V32(x) \

do { \

do { \

SET_H_GR (((UINT) 15), (x));\

SET_H_GR (((UINT) 15), (x));\

;} while (0)

;} while (0)

/* Cover fns for register access.  */

/* Cover fns for register access.  */

BI crisv32f_h_v32_v32_get (SIM_CPU *);

BI crisv32f_h_v32_v32_get (SIM_CPU *);

void crisv32f_h_v32_v32_set (SIM_CPU *, BI);

void crisv32f_h_v32_v32_set (SIM_CPU *, BI);

USI crisv32f_h_pc_get (SIM_CPU *);

USI crisv32f_h_pc_get (SIM_CPU *);

void crisv32f_h_pc_set (SIM_CPU *, USI);

void crisv32f_h_pc_set (SIM_CPU *, USI);

SI crisv32f_h_gr_get (SIM_CPU *, UINT);

SI crisv32f_h_gr_get (SIM_CPU *, UINT);

void crisv32f_h_gr_set (SIM_CPU *, UINT, SI);

void crisv32f_h_gr_set (SIM_CPU *, UINT, SI);

SI crisv32f_h_gr_acr_get (SIM_CPU *, UINT);

SI crisv32f_h_gr_acr_get (SIM_CPU *, UINT);

void crisv32f_h_gr_acr_set (SIM_CPU *, UINT, SI);

void crisv32f_h_gr_acr_set (SIM_CPU *, UINT, SI);

SI crisv32f_h_raw_gr_acr_get (SIM_CPU *, UINT);

SI crisv32f_h_raw_gr_acr_get (SIM_CPU *, UINT);

void crisv32f_h_raw_gr_acr_set (SIM_CPU *, UINT, SI);

void crisv32f_h_raw_gr_acr_set (SIM_CPU *, UINT, SI);

SI crisv32f_h_sr_get (SIM_CPU *, UINT);

SI crisv32f_h_sr_get (SIM_CPU *, UINT);

void crisv32f_h_sr_set (SIM_CPU *, UINT, SI);

void crisv32f_h_sr_set (SIM_CPU *, UINT, SI);

SI crisv32f_h_sr_v32_get (SIM_CPU *, UINT);

SI crisv32f_h_sr_v32_get (SIM_CPU *, UINT);

void crisv32f_h_sr_v32_set (SIM_CPU *, UINT, SI);

void crisv32f_h_sr_v32_set (SIM_CPU *, UINT, SI);

SI crisv32f_h_supr_get (SIM_CPU *, UINT);

SI crisv32f_h_supr_get (SIM_CPU *, UINT);

void crisv32f_h_supr_set (SIM_CPU *, UINT, SI);

void crisv32f_h_supr_set (SIM_CPU *, UINT, SI);

BI crisv32f_h_cbit_get (SIM_CPU *);

BI crisv32f_h_cbit_get (SIM_CPU *);

void crisv32f_h_cbit_set (SIM_CPU *, BI);

void crisv32f_h_cbit_set (SIM_CPU *, BI);

BI crisv32f_h_cbit_move_get (SIM_CPU *);

BI crisv32f_h_cbit_move_get (SIM_CPU *);

void crisv32f_h_cbit_move_set (SIM_CPU *, BI);

void crisv32f_h_cbit_move_set (SIM_CPU *, BI);

BI crisv32f_h_cbit_move_v32_get (SIM_CPU *);

BI crisv32f_h_cbit_move_v32_get (SIM_CPU *);

void crisv32f_h_cbit_move_v32_set (SIM_CPU *, BI);

void crisv32f_h_cbit_move_v32_set (SIM_CPU *, BI);

BI crisv32f_h_vbit_get (SIM_CPU *);

BI crisv32f_h_vbit_get (SIM_CPU *);

void crisv32f_h_vbit_set (SIM_CPU *, BI);

void crisv32f_h_vbit_set (SIM_CPU *, BI);

BI crisv32f_h_vbit_move_get (SIM_CPU *);

BI crisv32f_h_vbit_move_get (SIM_CPU *);

void crisv32f_h_vbit_move_set (SIM_CPU *, BI);

void crisv32f_h_vbit_move_set (SIM_CPU *, BI);

BI crisv32f_h_vbit_move_v32_get (SIM_CPU *);

BI crisv32f_h_vbit_move_v32_get (SIM_CPU *);

void crisv32f_h_vbit_move_v32_set (SIM_CPU *, BI);

void crisv32f_h_vbit_move_v32_set (SIM_CPU *, BI);

BI crisv32f_h_zbit_get (SIM_CPU *);

BI crisv32f_h_zbit_get (SIM_CPU *);

void crisv32f_h_zbit_set (SIM_CPU *, BI);

void crisv32f_h_zbit_set (SIM_CPU *, BI);

BI crisv32f_h_zbit_move_get (SIM_CPU *);

BI crisv32f_h_zbit_move_get (SIM_CPU *);

void crisv32f_h_zbit_move_set (SIM_CPU *, BI);

void crisv32f_h_zbit_move_set (SIM_CPU *, BI);

BI crisv32f_h_zbit_move_v32_get (SIM_CPU *);

BI crisv32f_h_zbit_move_v32_get (SIM_CPU *);

void crisv32f_h_zbit_move_v32_set (SIM_CPU *, BI);

void crisv32f_h_zbit_move_v32_set (SIM_CPU *, BI);

BI crisv32f_h_nbit_get (SIM_CPU *);

BI crisv32f_h_nbit_get (SIM_CPU *);

void crisv32f_h_nbit_set (SIM_CPU *, BI);

void crisv32f_h_nbit_set (SIM_CPU *, BI);

BI crisv32f_h_nbit_move_get (SIM_CPU *);

BI crisv32f_h_nbit_move_get (SIM_CPU *);

void crisv32f_h_nbit_move_set (SIM_CPU *, BI);

void crisv32f_h_nbit_move_set (SIM_CPU *, BI);

BI crisv32f_h_nbit_move_v32_get (SIM_CPU *);

BI crisv32f_h_nbit_move_v32_get (SIM_CPU *);

void crisv32f_h_nbit_move_v32_set (SIM_CPU *, BI);

void crisv32f_h_nbit_move_v32_set (SIM_CPU *, BI);

BI crisv32f_h_xbit_get (SIM_CPU *);

BI crisv32f_h_xbit_get (SIM_CPU *);

void crisv32f_h_xbit_set (SIM_CPU *, BI);

void crisv32f_h_xbit_set (SIM_CPU *, BI);

BI crisv32f_h_ibit_get (SIM_CPU *);

BI crisv32f_h_ibit_get (SIM_CPU *);

void crisv32f_h_ibit_set (SIM_CPU *, BI);

void crisv32f_h_ibit_set (SIM_CPU *, BI);

BI crisv32f_h_pbit_get (SIM_CPU *);

BI crisv32f_h_pbit_get (SIM_CPU *);

void crisv32f_h_pbit_set (SIM_CPU *, BI);

void crisv32f_h_pbit_set (SIM_CPU *, BI);

BI crisv32f_h_rbit_get (SIM_CPU *);

BI crisv32f_h_rbit_get (SIM_CPU *);

void crisv32f_h_rbit_set (SIM_CPU *, BI);

void crisv32f_h_rbit_set (SIM_CPU *, BI);

BI crisv32f_h_ubit_get (SIM_CPU *);

BI crisv32f_h_ubit_get (SIM_CPU *);

void crisv32f_h_ubit_set (SIM_CPU *, BI);

void crisv32f_h_ubit_set (SIM_CPU *, BI);

BI crisv32f_h_gbit_get (SIM_CPU *);

BI crisv32f_h_gbit_get (SIM_CPU *);

void crisv32f_h_gbit_set (SIM_CPU *, BI);

void crisv32f_h_gbit_set (SIM_CPU *, BI);

SI crisv32f_h_kernel_sp_get (SIM_CPU *);

SI crisv32f_h_kernel_sp_get (SIM_CPU *);

void crisv32f_h_kernel_sp_set (SIM_CPU *, SI);

void crisv32f_h_kernel_sp_set (SIM_CPU *, SI);

BI crisv32f_h_ubit_v32_get (SIM_CPU *);

BI crisv32f_h_ubit_v32_get (SIM_CPU *);

void crisv32f_h_ubit_v32_set (SIM_CPU *, BI);

void crisv32f_h_ubit_v32_set (SIM_CPU *, BI);

BI crisv32f_h_ibit_v32_get (SIM_CPU *);

BI crisv32f_h_ibit_v32_get (SIM_CPU *);

void crisv32f_h_ibit_v32_set (SIM_CPU *, BI);

void crisv32f_h_ibit_v32_set (SIM_CPU *, BI);

BI crisv32f_h_mbit_get (SIM_CPU *);

BI crisv32f_h_mbit_get (SIM_CPU *);

void crisv32f_h_mbit_set (SIM_CPU *, BI);

void crisv32f_h_mbit_set (SIM_CPU *, BI);

BI crisv32f_h_qbit_get (SIM_CPU *);

BI crisv32f_h_qbit_get (SIM_CPU *);

void crisv32f_h_qbit_set (SIM_CPU *, BI);

void crisv32f_h_qbit_set (SIM_CPU *, BI);

BI crisv32f_h_sbit_get (SIM_CPU *);

BI crisv32f_h_sbit_get (SIM_CPU *);

void crisv32f_h_sbit_set (SIM_CPU *, BI);

void crisv32f_h_sbit_set (SIM_CPU *, BI);

BI crisv32f_h_insn_prefixed_p_get (SIM_CPU *);

BI crisv32f_h_insn_prefixed_p_get (SIM_CPU *);

void crisv32f_h_insn_prefixed_p_set (SIM_CPU *, BI);

void crisv32f_h_insn_prefixed_p_set (SIM_CPU *, BI);

BI crisv32f_h_insn_prefixed_p_v32_get (SIM_CPU *);

BI crisv32f_h_insn_prefixed_p_v32_get (SIM_CPU *);

void crisv32f_h_insn_prefixed_p_v32_set (SIM_CPU *, BI);

void crisv32f_h_insn_prefixed_p_v32_set (SIM_CPU *, BI);

SI crisv32f_h_prefixreg_v32_get (SIM_CPU *);

SI crisv32f_h_prefixreg_v32_get (SIM_CPU *);

void crisv32f_h_prefixreg_v32_set (SIM_CPU *, SI);

void crisv32f_h_prefixreg_v32_set (SIM_CPU *, SI);

/* These must be hand-written.  */

/* These must be hand-written.  */

extern CPUREG_FETCH_FN crisv32f_fetch_register;

extern CPUREG_FETCH_FN crisv32f_fetch_register;

extern CPUREG_STORE_FN crisv32f_store_register;

extern CPUREG_STORE_FN crisv32f_store_register;

typedef struct {

typedef struct {

  UINT prev_prev_prev_modf_regs;

  UINT prev_prev_prev_modf_regs;

  UINT prev_prev_modf_regs;

  UINT prev_prev_modf_regs;

  UINT prev_modf_regs;

  UINT prev_modf_regs;

  UINT modf_regs;

  UINT modf_regs;

  UINT prev_prev_prev_movem_dest_regs;

  UINT prev_prev_prev_movem_dest_regs;

  UINT prev_prev_movem_dest_regs;

  UINT prev_prev_movem_dest_regs;

  UINT prev_movem_dest_regs;

  UINT prev_movem_dest_regs;

  UINT movem_dest_regs;

  UINT movem_dest_regs;

} MODEL_CRISV32_DATA;

} MODEL_CRISV32_DATA;

/* Instruction argument buffer.  */

/* Instruction argument buffer.  */

union sem_fields {

union sem_fields {

  struct { /* no operands */

  struct { /* no operands */

    int empty;

    int empty;

  } fmt_empty;

  } fmt_empty;

  struct { /*  */

  struct { /*  */

    UINT f_u4;

    UINT f_u4;

  } sfmt_break;

  } sfmt_break;

  struct { /*  */

  struct { /*  */

    UINT f_dstsrc;

    UINT f_dstsrc;

  } sfmt_setf;

  } sfmt_setf;

  struct { /*  */

  struct { /*  */

    IADDR i_o_word_pcrel;

    IADDR i_o_word_pcrel;

    UINT f_operand2;

    UINT f_operand2;

  } sfmt_bcc_w;

  } sfmt_bcc_w;

  struct { /*  */

  struct { /*  */

    IADDR i_o_pcrel;

    IADDR i_o_pcrel;

    UINT f_operand2;

    UINT f_operand2;

  } sfmt_bcc_b;

  } sfmt_bcc_b;

  struct { /*  */

  struct { /*  */