sim/ppc/interrupts.h - binutils-gdb - Git at Google

 /*  This file is part of the program psim.

     Copyright (C) 1994-1995, Andrew Cagney <cagney@highland.com.au>

     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 3 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, see <http://www.gnu.org/licenses/>.

     */


 #ifndef _INTERRUPTS_H_
 #define _INTERRUPTS_H_

 /* Interrupts:

    The code below handles two different types of interrupts.
    Synchronous and Asynchronous.

    Synchronous:

    Interrupts that must immediately force either an abort or restart
    of a current instruction are implemented by forcing an instruction
    restart. (or to put it another way, long jump).  In looking at the
    code it may occure to you that, for some interrupts, they could
    return instead of restarting the cpu (eg system_call).  While true
    (it once was like that) I've decided to make the behavour of all
    interrupt routines roughly identical.

    Because, a cpu's recorded state (ie what is in the cpu structure)
    is allowed to lag behind the cpu's true current state (eg PC not
    updated) sycnronous interrupt handers are parameterized with the
    the cpu being interrupted so that, as part of moddeling the
    interrupt, the cpu's state can be updated.

    Asynchronous:

    Interrupts such as reset or external exception are delivered using
    more normal (returning) functions.  It is assumed that these
    functions are called out side of the normal processor execution
    cycle. */


 /* Software generated interrupts.

    The below are generated by software driven events.  For instance,
    an invalid instruction or access (virtual or physical) to an
    invalid address */

 typedef enum {
   direct_store_storage_interrupt,
   hash_table_miss_storage_interrupt,
   protection_violation_storage_interrupt,
   earwax_violation_storage_interrupt,
   segment_table_miss_storage_interrupt,
   earwax_disabled_storage_interrupt,
   vea_storage_interrupt,
 } storage_interrupt_reasons;


 INLINE_INTERRUPTS\
 (void) data_storage_interrupt
 (cpu *processor,
  unsigned_word cia,
  unsigned_word ea,
  storage_interrupt_reasons reason,
  int is_store);

 INLINE_INTERRUPTS\
 (void) instruction_storage_interrupt
 (cpu *processor,
  unsigned_word cia,
  storage_interrupt_reasons reason);

 INLINE_INTERRUPTS\
 (void) alignment_interrupt
 (cpu *processor,
  unsigned_word cia,
  unsigned_word ra);

 typedef enum {
   floating_point_enabled_program_interrupt,
   illegal_instruction_program_interrupt,
   privileged_instruction_program_interrupt,
   trap_program_interrupt,
   optional_instruction_program_interrupt, /* subset of illegal instruction */
   mpc860c0_instruction_program_interrupt, /* fwd br, taken but not predicted, near EO page */
   nr_program_interrupt_reasons
 } program_interrupt_reasons;

 INLINE_INTERRUPTS\
 (void) program_interrupt
 (cpu *processor,
  unsigned_word cia,
  program_interrupt_reasons reason);

 INLINE_INTERRUPTS\
 (void) floating_point_unavailable_interrupt
 (cpu *processor,
  unsigned_word cia);

 INLINE_INTERRUPTS\
 (void) system_call_interrupt
 (cpu *processor,
  unsigned_word cia);

 INLINE_INTERRUPTS\
 (void) floating_point_assist_interrupt
 (cpu *processor,
  unsigned_word cia);

 INLINE_INTERRUPTS\
 (void) machine_check_interrupt
 (cpu *processor,
  unsigned_word cia);

 /* Hardware generated interrupts:

    These asynchronous hardware generated interrupts may be called at
    any time.  It is the responsibility of this (the interrupts) module
    to ensure that interrupts are delivered correctly (when possible).
    The delivery of these interrupts is controlled by the MSR's
    external interrupt enable bit.  When ever the MSR's value is
    changed, the processor must call the check_masked_interrupts()
    function in case delivery has been made possible.

    decrementer_interrupt is `edge' sensitive.  Multiple edges arriving
    before the first edge has been delivered result in only one
    interrupt.

    external_interrupt is `level' sensitive.  An external interrupt
    will only be delivered when the external interrupt port is
    `asserted'. While interrupts are disabled, the external interrupt
    can be asserted and then de-asserted without an interrupt
    eventually being delivered. */

 enum {
   external_interrupt_pending = 1,
   decrementer_interrupt_pending = 2,
 };

 typedef struct _interrupts {
   event_entry_tag delivery_scheduled;
   int pending_interrupts;
 } interrupts;

 INLINE_INTERRUPTS\
 (void) check_masked_interrupts
 (cpu *processor);

 INLINE_INTERRUPTS\
 (void) decrementer_interrupt
 (cpu *processor);

 INLINE_INTERRUPTS\
 (void) external_interrupt
 (cpu *processor,
  int is_asserted);

 #endif /* _INTERRUPTS_H_ */
	/* This file is part of the program psim.

	Copyright (C) 1994-1995, Andrew Cagney <cagney@highland.com.au>

	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 3 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, see <http://www.gnu.org/licenses/>.

	*/


	#ifndef _INTERRUPTS_H_
	#define _INTERRUPTS_H_

	/* Interrupts:

	The code below handles two different types of interrupts.
	Synchronous and Asynchronous.

	Synchronous:

	Interrupts that must immediately force either an abort or restart
	of a current instruction are implemented by forcing an instruction
	restart. (or to put it another way, long jump). In looking at the
	code it may occure to you that, for some interrupts, they could
	return instead of restarting the cpu (eg system_call). While true
	(it once was like that) I've decided to make the behavour of all
	interrupt routines roughly identical.

	Because, a cpu's recorded state (ie what is in the cpu structure)
	is allowed to lag behind the cpu's true current state (eg PC not
	updated) sycnronous interrupt handers are parameterized with the
	the cpu being interrupted so that, as part of moddeling the
	interrupt, the cpu's state can be updated.

	Asynchronous:

	Interrupts such as reset or external exception are delivered using
	more normal (returning) functions. It is assumed that these
	functions are called out side of the normal processor execution
	cycle. */


	/* Software generated interrupts.

	The below are generated by software driven events. For instance,
	an invalid instruction or access (virtual or physical) to an
	invalid address */

	typedef enum {
	direct_store_storage_interrupt,
	hash_table_miss_storage_interrupt,
	protection_violation_storage_interrupt,
	earwax_violation_storage_interrupt,
	segment_table_miss_storage_interrupt,
	earwax_disabled_storage_interrupt,
	vea_storage_interrupt,
	} storage_interrupt_reasons;


	INLINE_INTERRUPTS\
	(void) data_storage_interrupt
	(cpu *processor,
	unsigned_word cia,
	unsigned_word ea,
	storage_interrupt_reasons reason,
	int is_store);

	INLINE_INTERRUPTS\
	(void) instruction_storage_interrupt
	(cpu *processor,
	unsigned_word cia,
	storage_interrupt_reasons reason);

	INLINE_INTERRUPTS\
	(void) alignment_interrupt
	(cpu *processor,
	unsigned_word cia,
	unsigned_word ra);

	typedef enum {
	floating_point_enabled_program_interrupt,
	illegal_instruction_program_interrupt,
	privileged_instruction_program_interrupt,
	trap_program_interrupt,
	optional_instruction_program_interrupt, /* subset of illegal instruction */
	mpc860c0_instruction_program_interrupt, /* fwd br, taken but not predicted, near EO page */
	nr_program_interrupt_reasons
	} program_interrupt_reasons;

	INLINE_INTERRUPTS\
	(void) program_interrupt
	(cpu *processor,
	unsigned_word cia,
	program_interrupt_reasons reason);

	INLINE_INTERRUPTS\
	(void) floating_point_unavailable_interrupt
	(cpu *processor,
	unsigned_word cia);

	INLINE_INTERRUPTS\
	(void) system_call_interrupt
	(cpu *processor,
	unsigned_word cia);

	INLINE_INTERRUPTS\
	(void) floating_point_assist_interrupt
	(cpu *processor,
	unsigned_word cia);

	INLINE_INTERRUPTS\
	(void) machine_check_interrupt
	(cpu *processor,
	unsigned_word cia);

	/* Hardware generated interrupts:

	These asynchronous hardware generated interrupts may be called at
	any time. It is the responsibility of this (the interrupts) module
	to ensure that interrupts are delivered correctly (when possible).
	The delivery of these interrupts is controlled by the MSR's
	external interrupt enable bit. When ever the MSR's value is
	changed, the processor must call the check_masked_interrupts()
	function in case delivery has been made possible.

	decrementer_interrupt is `edge' sensitive. Multiple edges arriving
	before the first edge has been delivered result in only one
	interrupt.

	external_interrupt is `level' sensitive. An external interrupt
	will only be delivered when the external interrupt port is
	`asserted'. While interrupts are disabled, the external interrupt
	can be asserted and then de-asserted without an interrupt
	eventually being delivered. */

	enum {
	external_interrupt_pending = 1,
	decrementer_interrupt_pending = 2,
	};

	typedef struct _interrupts {
	event_entry_tag delivery_scheduled;
	int pending_interrupts;
	} interrupts;

	INLINE_INTERRUPTS\
	(void) check_masked_interrupts
	(cpu *processor);

	INLINE_INTERRUPTS\
	(void) decrementer_interrupt
	(cpu *processor);

	INLINE_INTERRUPTS\
	(void) external_interrupt
	(cpu *processor,
	int is_asserted);

	#endif /* _INTERRUPTS_H_ */