sim/cris/dv-cris.c - binutils-gdb - Git at Google

 /* The CRIS interrupt framework for GDB, the GNU Debugger.

    Copyright 2006-2021 Free Software Foundation, Inc.

    This file is part of GDB.

    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/>.  */

 /* This must come before any other includes.  */
 #include "defs.h"

 #include "sim-main.h"
 #include "hw-main.h"

 /* DEVICE

    CRIS cpu virtual device (very rudimental; generic enough for all
    currently used CRIS versions).


    DESCRIPTION

    Implements the external CRIS functionality.  This includes the
    delivery of interrupts generated from other devices.


    PROPERTIES

    vec-for-int = <int-a> <vec-a> <int-b> <vec-b> ...
    These are the translations to interrupt vector for values appearing
    on the "int" port, as pairs of the value and the corresponding
    vector.  Defaults to no translation.  All values that may appear on
    the "int" port must be defined, or the device aborts.

    multiple-int = ("abort" | "ignore_previous" | <vector>)
    If multiple interrupt values are dispatched, this property decides
    what to do.  The value is either a number corresponding to the
    vector to use, or the string "abort" to cause a hard abort, or the
    string "ignore_previous", to silently use the new vector instead.
    The default is "abort".


    PORTS

    int (input)
    Interrupt port.  An event with a non-zero value on this port causes
    an interrupt.  If, after an event but before the interrupt has been
    properly dispatched, a non-zero value appears that is different
    after mapping than the previous, then the property multiple_int
    decides what to do.

    FIXME: reg port so internal registers can be read.  Requires
    chip-specific versions, though.  Ports "nmi" and "reset".


    BUGS
    When delivering an interrupt, this code assumes that there is only
    one processor (number 0).

    This code does not attempt to be efficient at handling pending
    interrupts.  It simply schedules the interrupt delivery handler
    every instruction cycle until all pending interrupts go away.
    It also works around a bug in sim_events_process when doing so.
    */

 /* Keep this an enum for simple addition of "reset" and "nmi".  */
 enum
  {
    INT_PORT,
  };

 static const struct hw_port_descriptor cris_ports[] =
  {
    { "int", INT_PORT, 0, input_port },
    { NULL, 0, 0, 0 }
  };

 struct cris_vec_tr
  {
    unsigned32 portval, vec;
  };

 enum cris_multiple_ints
   {
     cris_multint_abort,
     cris_multint_ignore_previous,
     cris_multint_vector
   };

 struct cris_hw
  {
    struct hw_event *pending_handler;
    unsigned32 pending_vector;
    struct cris_vec_tr *int_to_vec;
    enum cris_multiple_ints multi_int_action;
    unsigned32 multiple_int_vector;
  };

 /* An event function, calling the actual CPU-model-specific
    interrupt-delivery function.  */

 static void
 deliver_cris_interrupt (struct hw *me, void *data)
 {
   struct cris_hw *crishw = hw_data (me);
   SIM_DESC simulator = hw_system (me);
   sim_cpu *cpu = STATE_CPU (simulator, 0);
   unsigned int intno = crishw->pending_vector;

  if (CPU_CRIS_DELIVER_INTERRUPT (cpu) (cpu, CRIS_INT_INT, intno))
     {
       crishw->pending_vector = 0;
       crishw->pending_handler = NULL;
       return;
     }

  {
    /* Bug workaround: at time T with a pending number of cycles N to
       process, if re-scheduling an event at time T+M, M < N,
       sim_events_process gets stuck at T (updating the "time" to
       before the event rather than after the event, or somesuch).

       Hacking this locally is thankfully easy: if we see the same
       simulation time, increase the number of cycles.  Do this every
       time we get here, until a new time is seen (supposedly unstuck
       re-delivery).  (Fixing in SIM/GDB source will hopefully then
       also be easier, having a tangible test-case.)  */
    static signed64 last_events_time = 0;
    static signed64 delta = 1;
    signed64 this_events_time = hw_event_queue_time (me);

    if (this_events_time == last_events_time)
      delta++;
    else
      {
        delta = 1;
        last_events_time = this_events_time;
      }

    crishw->pending_handler
      = hw_event_queue_schedule (me, delta, deliver_cris_interrupt, NULL);
  }
 }


 /* A port-event function for events arriving to an interrupt port.  */

 static void
 cris_port_event (struct hw *me,
 		 int my_port,
 		 struct hw *source,
 		 int source_port,
 		 int intparam)
 {
   struct cris_hw *crishw = hw_data (me);
   unsigned32 vec;

   /* A few placeholders; only the INT port is implemented.  */
   switch (my_port)
     {
     case INT_PORT:
       HW_TRACE ((me, "INT value=0x%x", intparam));
       break;

     default:
       hw_abort (me, "bad switch");
       break;
     }

   if (intparam == 0)
     return;

   if (crishw->int_to_vec != NULL)
     {
       unsigned int i;
       for (i = 0; crishw->int_to_vec[i].portval != 0; i++)
 	if (crishw->int_to_vec[i].portval == intparam)
 	  break;

       if (crishw->int_to_vec[i].portval == 0)
 	hw_abort (me, "unsupported value for int port: 0x%x", intparam);

       vec = crishw->int_to_vec[i].vec;
     }
   else
     vec = (unsigned32) intparam;

   if (crishw->pending_vector != 0)
     {
       if (vec == crishw->pending_vector)
 	return;

       switch (crishw->multi_int_action)
 	{
 	case cris_multint_abort:
 	  hw_abort (me, "int 0x%x (0x%x) while int 0x%x hasn't been delivered",
 		    vec, intparam, crishw->pending_vector);
 	  break;

 	case cris_multint_ignore_previous:
 	  break;

 	case cris_multint_vector:
 	  vec = crishw->multiple_int_vector;
 	  break;

 	default:
 	  hw_abort (me, "bad switch");
 	}
     }

   crishw->pending_vector = vec;

   /* Schedule our event handler *now*.  */
   if (crishw->pending_handler == NULL)
     crishw->pending_handler
       = hw_event_queue_schedule (me, 0, deliver_cris_interrupt, NULL);
 }

 /* Instance initializer function.  */

 static void
 cris_finish (struct hw *me)
 {
   struct cris_hw *crishw;
   const struct hw_property *vec_for_int;
   const struct hw_property *multiple_int;

   crishw = HW_ZALLOC (me, struct cris_hw);
   set_hw_data (me, crishw);
   set_hw_ports (me, cris_ports);
   set_hw_port_event (me, cris_port_event);

   vec_for_int = hw_find_property (me, "vec-for-int");
   if (vec_for_int != NULL)
     {
       unsigned32 vecsize;
       unsigned32 i;

       if (hw_property_type (vec_for_int) != array_property)
 	hw_abort (me, "property \"vec-for-int\" has the wrong type");

       vecsize = hw_property_sizeof_array (vec_for_int) / sizeof (signed_cell);

       if ((vecsize % 2) != 0)
 	hw_abort (me, "translation vector does not consist of even pairs");

       crishw->int_to_vec
 	= hw_malloc (me, (vecsize/2 + 1) * sizeof (crishw->int_to_vec[0]));

       for (i = 0; i < vecsize/2; i++)
 	{
 	  signed_cell portval_sc;
 	  signed_cell vec_sc;

 	  if (!hw_find_integer_array_property (me, "vec-for-int", i*2,
 					       &portval_sc)
 	      || !hw_find_integer_array_property (me, "vec-for-int", i*2 + 1,
 						  &vec_sc)
 	      || portval_sc < 0
 	      || vec_sc < 0)
 	    hw_abort (me, "no valid vector translation pair %u", i);

 	  crishw->int_to_vec[i].portval = (unsigned32) portval_sc;
 	  crishw->int_to_vec[i].vec = (unsigned32) vec_sc;
 	}

       crishw->int_to_vec[i].portval = 0;
       crishw->int_to_vec[i].vec = 0;
     }

   multiple_int = hw_find_property (me, "multiple-int");
   if (multiple_int != NULL)
     {
       if (hw_property_type (multiple_int) == integer_property)
 	{
 	  crishw->multiple_int_vector
 	    = hw_find_integer_property (me, "multiple-int");
 	  crishw->multi_int_action = cris_multint_vector;
 	}
       else
 	{
 	  const char *action = hw_find_string_property (me, "multiple-int");

 	  if (action == NULL)
 	    hw_abort (me, "property \"multiple-int\" has the wrong type");

 	  if (strcmp (action, "abort") == 0)
 	    crishw->multi_int_action = cris_multint_abort;
 	  else if (strcmp (action, "ignore_previous") == 0)
 	    crishw->multi_int_action = cris_multint_ignore_previous;
 	  else
 	    hw_abort (me, "property \"multiple-int\" must be one of <vector number>\n"
 		      "\"abort\" and \"ignore_previous\", not \"%s\"", action);
 	}
     }
   else
     crishw->multi_int_action = cris_multint_abort;
 }

 const struct hw_descriptor dv_cris_descriptor[] = {
   { "cris", cris_finish, },
   { NULL },
 };
	/* The CRIS interrupt framework for GDB, the GNU Debugger.

	Copyright 2006-2021 Free Software Foundation, Inc.

	This file is part of GDB.

	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/>. */

	/* This must come before any other includes. */
	#include "defs.h"

	#include "sim-main.h"
	#include "hw-main.h"

	/* DEVICE

	CRIS cpu virtual device (very rudimental; generic enough for all
	currently used CRIS versions).


	DESCRIPTION

	Implements the external CRIS functionality. This includes the
	delivery of interrupts generated from other devices.


	PROPERTIES

	vec-for-int = <int-a> <vec-a> <int-b> <vec-b> ...
	These are the translations to interrupt vector for values appearing
	on the "int" port, as pairs of the value and the corresponding
	vector. Defaults to no translation. All values that may appear on
	the "int" port must be defined, or the device aborts.

	multiple-int = ("abort" \| "ignore_previous" \| <vector>)
	If multiple interrupt values are dispatched, this property decides
	what to do. The value is either a number corresponding to the
	vector to use, or the string "abort" to cause a hard abort, or the
	string "ignore_previous", to silently use the new vector instead.
	The default is "abort".


	PORTS

	int (input)
	Interrupt port. An event with a non-zero value on this port causes
	an interrupt. If, after an event but before the interrupt has been
	properly dispatched, a non-zero value appears that is different
	after mapping than the previous, then the property multiple_int
	decides what to do.

	FIXME: reg port so internal registers can be read. Requires
	chip-specific versions, though. Ports "nmi" and "reset".


	BUGS
	When delivering an interrupt, this code assumes that there is only
	one processor (number 0).

	This code does not attempt to be efficient at handling pending
	interrupts. It simply schedules the interrupt delivery handler
	every instruction cycle until all pending interrupts go away.
	It also works around a bug in sim_events_process when doing so.
	*/

	/* Keep this an enum for simple addition of "reset" and "nmi". */
	enum
	{
	INT_PORT,
	};

	static const struct hw_port_descriptor cris_ports[] =
	{
	{ "int", INT_PORT, 0, input_port },
	{ NULL, 0, 0, 0 }
	};

	struct cris_vec_tr
	{
	unsigned32 portval, vec;
	};

	enum cris_multiple_ints
	{
	cris_multint_abort,
	cris_multint_ignore_previous,
	cris_multint_vector
	};

	struct cris_hw
	{
	struct hw_event *pending_handler;
	unsigned32 pending_vector;
	struct cris_vec_tr *int_to_vec;
	enum cris_multiple_ints multi_int_action;
	unsigned32 multiple_int_vector;
	};

	/* An event function, calling the actual CPU-model-specific
	interrupt-delivery function. */

	static void
	deliver_cris_interrupt (struct hw me, void data)
	{
	struct cris_hw *crishw = hw_data (me);
	SIM_DESC simulator = hw_system (me);
	sim_cpu *cpu = STATE_CPU (simulator, 0);
	unsigned int intno = crishw->pending_vector;

	if (CPU_CRIS_DELIVER_INTERRUPT (cpu) (cpu, CRIS_INT_INT, intno))
	{
	crishw->pending_vector = 0;
	crishw->pending_handler = NULL;
	return;
	}

	{
	/* Bug workaround: at time T with a pending number of cycles N to
	process, if re-scheduling an event at time T+M, M < N,
	sim_events_process gets stuck at T (updating the "time" to
	before the event rather than after the event, or somesuch).

	Hacking this locally is thankfully easy: if we see the same
	simulation time, increase the number of cycles. Do this every
	time we get here, until a new time is seen (supposedly unstuck
	re-delivery). (Fixing in SIM/GDB source will hopefully then
	also be easier, having a tangible test-case.) */
	static signed64 last_events_time = 0;
	static signed64 delta = 1;
	signed64 this_events_time = hw_event_queue_time (me);

	if (this_events_time == last_events_time)
	delta++;
	else
	{
	delta = 1;
	last_events_time = this_events_time;
	}

	crishw->pending_handler
	= hw_event_queue_schedule (me, delta, deliver_cris_interrupt, NULL);
	}
	}


	/* A port-event function for events arriving to an interrupt port. */

	static void
	cris_port_event (struct hw *me,
	int my_port,
	struct hw *source,
	int source_port,
	int intparam)
	{
	struct cris_hw *crishw = hw_data (me);
	unsigned32 vec;

	/* A few placeholders; only the INT port is implemented. */
	switch (my_port)
	{
	case INT_PORT:
	HW_TRACE ((me, "INT value=0x%x", intparam));
	break;

	default:
	hw_abort (me, "bad switch");
	break;
	}

	if (intparam == 0)
	return;

	if (crishw->int_to_vec != NULL)
	{
	unsigned int i;
	for (i = 0; crishw->int_to_vec[i].portval != 0; i++)
	if (crishw->int_to_vec[i].portval == intparam)
	break;

	if (crishw->int_to_vec[i].portval == 0)
	hw_abort (me, "unsupported value for int port: 0x%x", intparam);

	vec = crishw->int_to_vec[i].vec;
	}
	else
	vec = (unsigned32) intparam;

	if (crishw->pending_vector != 0)
	{
	if (vec == crishw->pending_vector)
	return;

	switch (crishw->multi_int_action)
	{
	case cris_multint_abort:
	hw_abort (me, "int 0x%x (0x%x) while int 0x%x hasn't been delivered",
	vec, intparam, crishw->pending_vector);
	break;

	case cris_multint_ignore_previous:
	break;

	case cris_multint_vector:
	vec = crishw->multiple_int_vector;
	break;

	default:
	hw_abort (me, "bad switch");
	}
	}

	crishw->pending_vector = vec;

	/* Schedule our event handler now. */
	if (crishw->pending_handler == NULL)
	crishw->pending_handler
	= hw_event_queue_schedule (me, 0, deliver_cris_interrupt, NULL);
	}

	/* Instance initializer function. */

	static void
	cris_finish (struct hw *me)
	{
	struct cris_hw *crishw;
	const struct hw_property *vec_for_int;
	const struct hw_property *multiple_int;

	crishw = HW_ZALLOC (me, struct cris_hw);
	set_hw_data (me, crishw);
	set_hw_ports (me, cris_ports);
	set_hw_port_event (me, cris_port_event);

	vec_for_int = hw_find_property (me, "vec-for-int");
	if (vec_for_int != NULL)
	{
	unsigned32 vecsize;
	unsigned32 i;

	if (hw_property_type (vec_for_int) != array_property)
	hw_abort (me, "property \"vec-for-int\" has the wrong type");

	vecsize = hw_property_sizeof_array (vec_for_int) / sizeof (signed_cell);

	if ((vecsize % 2) != 0)
	hw_abort (me, "translation vector does not consist of even pairs");

	crishw->int_to_vec
	= hw_malloc (me, (vecsize/2 + 1) * sizeof (crishw->int_to_vec[0]));

	for (i = 0; i < vecsize/2; i++)
	{
	signed_cell portval_sc;
	signed_cell vec_sc;

	if (!hw_find_integer_array_property (me, "vec-for-int", i*2,
	&portval_sc)
	\|\| !hw_find_integer_array_property (me, "vec-for-int", i*2 + 1,
	&vec_sc)
	\|\| portval_sc < 0
	\|\| vec_sc < 0)
	hw_abort (me, "no valid vector translation pair %u", i);

	crishw->int_to_vec[i].portval = (unsigned32) portval_sc;
	crishw->int_to_vec[i].vec = (unsigned32) vec_sc;
	}

	crishw->int_to_vec[i].portval = 0;
	crishw->int_to_vec[i].vec = 0;
	}

	multiple_int = hw_find_property (me, "multiple-int");
	if (multiple_int != NULL)
	{
	if (hw_property_type (multiple_int) == integer_property)
	{
	crishw->multiple_int_vector
	= hw_find_integer_property (me, "multiple-int");
	crishw->multi_int_action = cris_multint_vector;
	}
	else
	{
	const char *action = hw_find_string_property (me, "multiple-int");

	if (action == NULL)
	hw_abort (me, "property \"multiple-int\" has the wrong type");

	if (strcmp (action, "abort") == 0)
	crishw->multi_int_action = cris_multint_abort;
	else if (strcmp (action, "ignore_previous") == 0)
	crishw->multi_int_action = cris_multint_ignore_previous;
	else
	hw_abort (me, "property \"multiple-int\" must be one of <vector number>\n"
	"\"abort\" and \"ignore_previous\", not \"%s\"", action);
	}
	}
	else
	crishw->multi_int_action = cris_multint_abort;
	}

	const struct hw_descriptor dv_cris_descriptor[] = {
	{ "cris", cris_finish, },
	{ NULL },
	};