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binutils-gdb/sim/ppc/emul_chirp.c

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/* 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 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 _EMUL_CHIRP_C_
#define _EMUL_CHIRP_C_
/* Note: this module is called via a table. There is no benefit in
making it inline */
#include "emul_generic.h"
#include "emul_chirp.h"
#include "cap.h"
#ifdef HAVE_STRING_H
#include <string.h>
#else
#ifdef HAVE_STRINGS_H
#include <strings.h>
#endif
#endif
#include <unistd.h>
#ifndef STATIC_INLINE_EMUL_CHIRP
#define STATIC_INLINE_EMUL_CHIRP STATIC_INLINE
#endif
/* Descriptor of the open boot services being emulated */
typedef int (chirp_handler)
(os_emul_data *data,
cpu *processor,
unsigned_word cia);
typedef struct _chirp_services {
const char *name;
chirp_handler *handler;
} chirp_services;
/* The OpenBoot emulation is, at any time either waiting for a client
request or waiting on a client callback */
typedef enum {
serving,
faulting,
catching,
} chirp_emul_state;
struct _os_emul_data {
chirp_emul_state state;
unsigned_word return_address;
unsigned_word arguments;
chirp_services *service;
unsigned_word serving_instruction_ea;
unsigned_word catching_instruction_ea;
cap *phandles;
device *root;
chirp_services *services;
};
/* Read in the argument list and make the most basic check that number
of argumnets are consistent with what was expected */
static int
chirp_read_args(void *args,
int sizeof_args,
int n_args,
int n_returns,
os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
struct base_args {
unsigned32 service;
unsigned32 n_args;
unsigned32 n_returns;
} *base;
emul_read_buffer(args, data->arguments,
sizeof_args,
processor, cia);
base = (struct base_args*)args;
if (T2H_4(base->n_args) != n_args || T2H_4(base->n_returns) != n_returns) {
TRACE(trace_os_emul, ("invalid nr of args - n_args=%ld, n_returns=%ld\n",
(long)T2H_4(base->n_args),
(long)T2H_4(base->n_returns)));
return -1;
}
return 0;
}
/* OpenBoot emulation functions */
/* client interface */
static int
chirp_emul_test(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
struct test_args {
unsigned32 service;
unsigned32 n_args;
unsigned32 n_returns;
/*in*/
unsigned32 name; /*string*/
/*out*/
unsigned32 missing;
} args;
char name[32];
chirp_services *service = data->services;
/* read in the arguments */
if (chirp_read_args(&args, sizeof(args), 1, 1, data, processor, cia))
return -1;
emul_read_string(name, T2H_4(args.name), sizeof(name),
processor, cia);
TRACE(trace_os_emul, ("test - in - name=`%s'\n", name));
/* see if we know about the service */
while (service->name != NULL && strcmp(service->name, name) != 0) {
service++;
}
if (service->name == NULL)
args.missing = -1;
else
args.missing = 0;
/* write the arguments back out */
TRACE(trace_os_emul, ("test - out - missing=%ld\n",
(long)args.missing));
emul_write_buffer(&args, data->arguments,
sizeof(args),
processor, cia);
return 0;
}
/* Device tree */
static int
chirp_emul_peer(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
struct peer_args {
unsigned32 service;
unsigned32 n_args;
unsigned32 n_returns;
/*in*/
unsigned32 phandle;
/*out*/
unsigned32 sibling_phandle;
} args;
device *dev;
device *sibling_dev = NULL;
/* read in the arguments */
if (chirp_read_args(&args, sizeof(args), 1, 1, data, processor, cia))
return -1;
dev = cap_internal(data->phandles, args.phandle);
TRACE(trace_os_emul, ("peer - in - phandle=0x%lx(0x%lx`%s')\n",
(unsigned long)T2H_4(args.phandle),
(unsigned long)dev,
(dev == NULL ? "" : device_name(dev))));
/* find the peer */
if (dev == NULL && args.phandle != 0)
return -1;
if (args.phandle == 0)
sibling_dev = data->root;
else
sibling_dev = device_sibling(dev);
if (sibling_dev == NULL)
args.sibling_phandle = 0;
else
args.sibling_phandle = cap_external(data->phandles, sibling_dev);
/* write the arguments back out */
TRACE(trace_os_emul, ("peer - out - sibling_phandle=0x%lx(0x%lx`%s')\n",
(unsigned long)T2H_4(args.sibling_phandle),
(unsigned long)sibling_dev,
(sibling_dev == NULL
? ""
: device_name(sibling_dev))));
emul_write_buffer(&args, data->arguments,
sizeof(args),
processor, cia);
return 0;
}
static int
chirp_emul_child(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
struct child_args {
unsigned32 service;
unsigned32 n_args;
unsigned32 n_returns;
/*in*/
unsigned32 phandle;
/*out*/
unsigned32 child_phandle;
} args;
device *dev;
device *child_dev;
/* read the arguments in */
if (chirp_read_args(&args, sizeof(args), 1, 1, data, processor, cia))
return -1;
dev = cap_internal(data->phandles, args.phandle);
TRACE(trace_os_emul, ("child - in - phandle=0x%lx(0x%lx`%s')\n",
(unsigned long)T2H_4(args.phandle),
(unsigned long)dev,
(dev == NULL ? "" : device_name(dev))));
/* find a child */
if (dev == (device*)0)
return -1;
child_dev = device_child(dev);
if (child_dev == NULL)
args.child_phandle = 0;
else
args.child_phandle = cap_external(data->phandles, child_dev);
/* write the result out */
TRACE(trace_os_emul, ("child - out - child_phandle=0x%lx(0x%lx`%s')\n",
(unsigned long)T2H_4(args.child_phandle),
(unsigned long)child_dev,
(child_dev == NULL ? "" : device_name(child_dev))));
emul_write_buffer(&args, data->arguments,
sizeof(args),
processor, cia);
return 0;
}
static int
chirp_emul_parent(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
struct parent_args {
unsigned32 service;
unsigned32 n_args;
unsigned32 n_returns;
/*in*/
unsigned32 phandle;
/*out*/
unsigned32 parent_phandle;
} args;
device *dev;
device *parent_dev;
/* read the args in */
if (chirp_read_args(&args, sizeof(args), 1, 1, data, processor, cia))
return -1;
dev = cap_internal(data->phandles, args.phandle);
TRACE(trace_os_emul, ("parent - in - phandle=0x%lx(0x%lx`%s')\n",
(unsigned long)T2H_4(args.phandle),
(unsigned long)dev,
(dev == NULL ? "" : device_name(dev))));
/* find a parent */
if (dev == (device*)0)
return -1;
parent_dev = device_parent(dev);
if (parent_dev == NULL)
args.parent_phandle = 0;
else
args.parent_phandle = cap_external(data->phandles, parent_dev);
/* return the result */
TRACE(trace_os_emul, ("parent - out - parent_phandle=0x%lx(0x%lx`%s')\n",
(unsigned long)T2H_4(args.parent_phandle),
(unsigned long)parent_dev,
(parent_dev == NULL ? "" : device_name(parent_dev))));
emul_write_buffer(&args, data->arguments,
sizeof(args),
processor, cia);
return 0;
}
static int
chirp_emul_instance_to_package(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
error("chirp: instance-to-package unimplemented\n");
return 0;
}
static int
chirp_emul_getproplen(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
struct getproplen_args {
unsigned32 service;
unsigned32 n_args;
unsigned32 n_returns;
/*in*/
unsigned32 phandle;
unsigned32 name;
/*out*/
unsigned32 proplen;
} args;
char name[32];
device *dev;
const device_property *prop;
/* read the args in */
if (chirp_read_args(&args, sizeof(args), 2, 1, data, processor, cia))
return -1;
dev = cap_internal(data->phandles, args.phandle);
/* find our prop and get its length */
if (dev == (device*)0)
return -1;
emul_read_string(name,
T2H_4(args.name),
sizeof(name),
processor, cia);
TRACE(trace_os_emul, ("getproplen - in - phandle=0x%lx(0x%lx`%s') name=`%s'\n",
(unsigned long)T2H_4(args.phandle),
(unsigned long)dev,
(dev == NULL ? "" : device_name(dev)),
name));
prop = device_find_property(dev, name);
if (prop == (device_property*)0) {
args.proplen = -1;
}
else {
args.proplen = H2T_4(prop->sizeof_array);
}
/* return the result */
TRACE(trace_os_emul, ("getproplen - out - proplen=%ld\n",
(unsigned long)T2H_4(args.proplen)));
emul_write_buffer(&args, data->arguments,
sizeof(args),
processor, cia);
return 0;
}
static int
chirp_emul_getprop(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
struct getprop_args {
unsigned32 service;
unsigned32 n_args;
unsigned32 n_returns;
/*in*/
unsigned32 phandle;
unsigned32 name;
unsigned32 buf;
unsigned32 buflen;
/*out*/
unsigned32 size;
} args;
char name[32];
device *dev;
const device_property *prop;
/* read in the args */
if (chirp_read_args(&args, sizeof(args), 4, 1, data, processor, cia))
return -1;
dev = cap_internal(data->phandles, args.phandle);
emul_read_string(name,
T2H_4(args.name),
sizeof(name),
processor, cia);
TRACE(trace_os_emul, ("getprop - in - phandle=0x%lx(0x%lx`%s') name=`%s' buf=0x%lx buflen=%ld\n",
(unsigned long)T2H_4(args.phandle),
(unsigned long)dev,
(dev == NULL ? "" : device_name(dev)),
name,
(unsigned long)T2H_4(args.buf),
(unsigned long)T2H_4(args.buflen)));
/* get the property */
if (dev == (device*)0)
return -1;
prop = device_find_property(dev, name);
if (prop == (device_property*)0) {
args.size = -1;
}
else {
int size = T2H_4(args.buflen);
if (size > prop->sizeof_array)
size = prop->sizeof_array;
emul_write_buffer(prop->array, T2H_4(args.buf),
size,
processor, cia);
args.size = H2T_4(size);
}
switch (prop->type) {
case string_property:
TRACE(trace_os_emul, ("getprop - value=`%s' (string)\n",
(char*)prop->array));
break;
default:
break;
}
/* write back the result */
TRACE(trace_os_emul, ("getprop - out - size=%ld\n",
(unsigned long)T2H_4(args.size)));
emul_write_buffer(&args, data->arguments,
sizeof(args),
processor, cia);
return 0;
}
static int
chirp_emul_nextprop(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
error("chirp: nextprop not implemented\n");
return 0;
}
static int
chirp_emul_setprop(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
error("chirp: setprop not implemented\n");
return 0;
}
static int
chirp_emul_canon(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
error("chirp: canon not implemented\n");
return 0;
}
static int
chirp_emul_finddevice(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
struct finddevice_args {
unsigned32 service;
unsigned32 n_args;
unsigned32 n_returns;
/*in*/
unsigned32 device_specifier;
/*out*/
unsigned32 phandle;
} args;
char device_specifier[1024];
device *dev;
/* get the args */
if (chirp_read_args(&args, sizeof(args), 1, 1, data, processor, cia))
return -1;
emul_read_string(device_specifier,
T2H_4(args.device_specifier),
sizeof(device_specifier),
processor, cia);
TRACE(trace_os_emul, ("finddevice - in - device_specifier=`%s'\n",
device_specifier));
/* find the device */
dev = device_tree_find_device(data->root,
device_specifier);
if (dev == (device*)0)
args.phandle = -1;
else
args.phandle = cap_external(data->phandles, dev);
/* return its phandle */
TRACE(trace_os_emul, ("finddevice - out - phandle=0x%lx(0x%lx`%s')\n",
(unsigned long)T2H_4(args.phandle),
(unsigned long)dev,
(dev == NULL ? "" : device_name(dev))));
emul_write_buffer(&args, data->arguments,
sizeof(args),
processor, cia);
return 0;
}
static int
chirp_emul_instance_to_path(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
error("chirp: instance_to_path not implemented\n");
return 0;
}
static int
chirp_emul_package_to_path(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
error("chirp: package_to_path not implemented\n");
return 0;
}
static int
chirp_emul_call_method(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
error("chirp: call-method implemented\n");
return 0;
}
/* Device I/O */
static int
chirp_emul_open(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
struct open_args {
unsigned32 service;
unsigned32 n_args;
unsigned32 n_returns;
/*in*/
unsigned32 device_specifier;
/*out*/
unsigned32 ihandle;
} args;
char name[1024];
/* read the args */
if (chirp_read_args(&args, sizeof(args), 1, 1, data, processor, cia))
return -1;
emul_read_string(name,
T2H_4(args.device_specifier),
sizeof(name),
processor, cia);
TRACE(trace_os_emul, ("open - in - device_specifier=`%s'\n",
name));
/* open the device */
printf_filtered("OpenBoot - open unimplemented for %s\n", name);
args.ihandle = -1;
/* return the ihandle result */
TRACE(trace_os_emul, ("open - out - ihandle=0x%lx\n",
(unsigned long)T2H_4(args.ihandle)));
emul_write_buffer(&args, data->arguments,
sizeof(args),
processor, cia);
return 0;
}
static int
chirp_emul_close(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
error("chirp: close not implemented\n");
return 0;
}
static int
chirp_emul_read(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
struct read_args {
unsigned32 service;
unsigned32 n_args;
unsigned32 n_returns;
/*in*/
unsigned32 ihandle;
unsigned32 addr;
unsigned32 len;
/*out*/
unsigned32 actual;
} args;
char buf[1024];
int actual;
/* read the args */
if (chirp_read_args(&args, sizeof(args), 3, 1, data, processor, cia))
return -1;
TRACE(trace_os_emul, ("read - in - ihandle=0x%lx addr=0x%lx len=%ld\n",
(unsigned long)args.ihandle,
(unsigned long)T2H_4(args.addr),
(unsigned long)T2H_4(args.len)));
/* do the read */
actual = T2H_4(args.len);
if (actual >= sizeof(buf))
actual = sizeof(buf) - 1;
actual = read(BE2H_4(args.ihandle), buf, actual);
if (actual >= 0) {
emul_write_buffer(buf,
T2H_4(args.addr),
actual,
processor, cia);
args.actual = H2T_4(actual);
buf[actual] = '\0';
}
else {
args.actual = 0;
}
/* return the result */
TRACE(trace_os_emul, ("read - out - actual=%ld `%s'\n",
(long)T2H_4(args.actual),
(actual >= 0 ? buf : "")));
emul_write_buffer(&args, data->arguments,
sizeof(args),
processor, cia);
return 0;
}
static int
chirp_emul_write(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
struct write_args {
unsigned32 service;
unsigned32 n_args;
unsigned32 n_returns;
/*in*/
unsigned32 ihandle;
unsigned32 addr;
unsigned32 len;
/*out*/
unsigned32 actual;
} args;
char buf[1024];
int actual;
/* get the args */
if (chirp_read_args(&args, sizeof(args), 3, 1, data, processor, cia))
return -1;
actual = T2H_4(args.len);
if (actual >= sizeof(buf))
actual = sizeof(buf) - 1;
emul_read_buffer(buf,
T2H_4(args.addr),
actual,
processor, cia);
buf[actual] = '\0';
TRACE(trace_os_emul, ("write - in - ihandle=0x%lx `%s' (%ld)\n",
(unsigned long)args.ihandle, buf, (long)actual));
/* write it out */
actual = write(BE2H_4(args.ihandle), buf, actual);
if (actual < 0)
args.actual = 0;
else
args.actual = H2T_4(actual);
/* return the result */
TRACE(trace_os_emul, ("write - out - actual=%ld\n",
(long)T2H_4(args.actual)));
emul_write_buffer(&args, data->arguments,
sizeof(args),
processor, cia);
return 0;
}
static int
chirp_emul_seek(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
error("chirp: seek not implemented\n");
return 0;
}
/* memory */
static int
chirp_emul_claim(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
error("chirp: claim not implemented\n");
return 0;
}
static int
chirp_emul_release(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
error("chirp: release not implemented\n");
return 0;
}
/* Control transfer */
static int
chirp_emul_boot(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
error("chirp: boot not implemented\n");
return 0;
}
static int
chirp_emul_enter(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
error("chirp: enter not implemented\n");
return 0;
}
static int
chirp_emul_exit(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
cpu_halt(processor, cia, was_exited, 0); /* always succeeds */
return 0;
}
static int
chirp_emul_chain(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
error("chirp: chain not implemented\n");
return 0;
}
/* user interface */
static int
chirp_emul_interpret(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
error("chirp: interpret not implemented\n");
return 0;
}
static int
chirp_emul_set_callback(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
error("chirp: set_callback not implemented\n");
return 0;
}
static int
chirp_emul_set_symbol_lookup(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
error("chirp: set_symbol_lookup not implemented\n");
return 0;
}
/* Time */
static int
chirp_emul_milliseconds(os_emul_data *data,
cpu *processor,
unsigned_word cia)
{
struct test_args {
unsigned32 service;
unsigned32 n_args;
unsigned32 n_returns;
/*in*/
/*out*/
unsigned32 ms;
} args;
unsigned64 time;
/* read in the arguments */
if (chirp_read_args(&args, sizeof(args), 1, 1, data, processor, cia))
return -1;
/* make up a number */
time = event_queue_time(cpu_event_queue(processor)) / 1000000;
args.ms = H2T_4(time);
/* write the arguments back out */
TRACE(trace_os_emul, ("milliseconds - out - ms=%ld\n",
(unsigned long)T2H_4(args.ms)));
emul_write_buffer(&args, data->arguments,
sizeof(args),
processor, cia);
return 0;
}
static chirp_services services[] = {
/* client interface */
{ "test", chirp_emul_test },
/* device tree */
{ "peer", chirp_emul_peer },
{ "child", chirp_emul_child },
{ "parent", chirp_emul_parent },
{ "instance-to-package", chirp_emul_instance_to_package },
{ "getproplen", chirp_emul_getproplen },
{ "getprop", chirp_emul_getprop },
{ "nextprop", chirp_emul_nextprop },
{ "setprop", chirp_emul_setprop },
{ "canon", chirp_emul_canon },
{ "finddevice", chirp_emul_finddevice },
{ "instance-to-path", chirp_emul_instance_to_path },
{ "package-to-path", chirp_emul_package_to_path },
{ "call-method", chirp_emul_call_method },
/* device I/O */
{ "open", chirp_emul_open },
{ "close", chirp_emul_close },
{ "read", chirp_emul_read },
{ "write", chirp_emul_write },
{ "seek", chirp_emul_seek },
{ "write", chirp_emul_write },
/* memory */
{ "claim", chirp_emul_claim },
{ "release", chirp_emul_release },
/* control transfer */
{ "boot", chirp_emul_boot },
{ "enter", chirp_emul_enter },
{ "exit", chirp_emul_exit },
{ "chain", chirp_emul_chain },
/* user interface */
{ "interpret", chirp_emul_interpret },
{ "set_callback", chirp_emul_set_callback },
{ "set_symbol_lookup", chirp_emul_set_symbol_lookup },
/* time */
{ "milliseconds", chirp_emul_milliseconds },
{ 0, /* sentinal */ },
};
/* main handlers */
/* Any starting address greater than this is assumed to be an Chirp
rather than VEA */
#ifndef CHIRP_START_ADDRESS
#define CHIRP_START_ADDRESS 0x80000000
#endif
typedef struct _chirp_note_desc {
signed32 real_mode;
signed32 real_base;
signed32 real_size;
signed32 virt_base;
signed32 virt_size;
} chirp_note_desc;
typedef struct _chirp_note {
chirp_note_desc desc;
int found;
} chirp_note;
typedef struct _chirp_note_head {
unsigned32 namesz;
unsigned32 descsz;
unsigned32 type;
} chirp_note_head;
static void
map_over_chirp_note(bfd *image,
asection *sect,
PTR obj)
{
chirp_note *note = (chirp_note*)obj;
if (strcmp(sect->name, ".note") == 0) {
chirp_note_head head;
char name[16];
/* check the head */
if (!bfd_get_section_contents(image, sect,
&head, 0, sizeof(head)))
return;
head.namesz = bfd_get_32(image, (void*)&head.namesz);
head.descsz = bfd_get_32(image, (void*)&head.descsz);
head.type = bfd_get_32(image, (void*)&head.type);
if (head.type != 0x1275)
return;
note->found = 1;
/* check the name field */
if (head.namesz > sizeof(name)) {
printf_filtered("open-boot warning: note name too long (%ld)\n",
(long)head.namesz);
return;
}
if (!bfd_get_section_contents(image, sect,
name, sizeof(head), head.namesz)) {
printf_filtered("open-boot warning: note name unreadable\n");
return;
}
if (strcmp(name, "PowerPC") != 0) {
printf_filtered("open-boot warning: note name (%s) not `PowerPC'\n",
name);
return;
}
/* get the contents */
if (head.descsz != sizeof(note->desc)) {
printf_filtered("open-boot warning: note descriptor of wrong size\n");
return;
}
if (!bfd_get_section_contents(image, sect,
&note->desc, /* page align start */
((sizeof(head) + head.namesz) + 3) & ~3,
head.descsz)) {
printf_filtered("open-boot warning: note descriptor unreadable\n");
return;
}
note->desc.real_mode = bfd_get_32(image, (void*)&note->desc.real_mode);
note->desc.real_base = bfd_get_32(image, (void*)&note->desc.real_base);
note->desc.real_size = bfd_get_32(image, (void*)&note->desc.real_size);
note->desc.virt_base = bfd_get_32(image, (void*)&note->desc.virt_base);
note->desc.virt_size = bfd_get_32(image, (void*)&note->desc.virt_size);
note->found = 2;
}
}
static os_emul_data *
emul_chirp_create(device *root,
bfd *image,
const char *name)
{
os_emul_data *data;
chirp_note note;
int big_endian;
/* Sanity check that this really is the chosen emulation */
if (name == NULL && image == NULL)
return NULL;
if (name != NULL
&& strcmp(name, "ob") != 0
&& strcmp(name, "ieee1274") != 0
&& strcmp(name, "chrp") != 0
&& strcmp(name, "chirp") != 0
&& strcmp(name, "openboot") != 0)
return NULL;
/* look for an elf note section */
memset(&note, 0, sizeof(note));
if (image != NULL)
bfd_map_over_sections(image, map_over_chirp_note, &note);
if (name == NULL && image != NULL && !note.found)
return NULL;
/* the root node */
device_add_string_property(root,
"name",
"gpl,clayton");
{
const unsigned_word memory_size = 0x200000;
/* the hash table */
const unsigned nr_page_table_entry_groups = (memory_size < 0x800000
? 1024 /* min allowed */
: (memory_size / 4096 / 2));
const unsigned sizeof_htab = nr_page_table_entry_groups * 64;
const unsigned_word htab_ra = memory_size - sizeof_htab;
/* a page for firmware calls */
const unsigned_word sizeof_code = 4096;
const unsigned_word code_ra = htab_ra - sizeof_code;
/* the stack */
const unsigned sizeof_stack = 32 * 1024;
const unsigned_word stack_ra = code_ra - sizeof_stack;
/* the firmware's home */
const int real_mode = 0;
/* const unsigned_word real_base = stack_ra; */
/* const unsigned real_size = memory_size - real_base; */
const unsigned_word virt_base = CHIRP_START_ADDRESS;
/* const unsigned virt_size = real_size;*/
/* the virtual addresses */
const unsigned_word stack_va = virt_base;
const unsigned_word code_va = stack_va + sizeof_stack;
const unsigned_word code_client_va = code_va;
const unsigned_word code_callback_va = code_client_va + 16;
const unsigned_word code_loop_va = code_callback_va + 16;
const unsigned_word htab_va = code_va + sizeof_code;
#ifdef bfd_big_endian /* new bfd */
big_endian = bfd_big_endian(image);
#else
big_endian = image->xvec->byteorder_big_p;
#endif
/* options */
{
device *options = device_tree_add_found(root, "/", "options");
device_add_integer_property(options,
"smp",
MAX_NR_PROCESSORS);
device_add_boolean_property(options,
"little-endian?",
!big_endian);
device_add_string_property(options,
"env",
"operating");
device_add_boolean_property(options,
"strict-alignment?",
(WITH_ALIGNMENT == STRICT_ALIGNMENT
|| !big_endian));
device_add_boolean_property(options,
"floating-point?",
WITH_FLOATING_POINT);
device_add_string_property(options,
"os-emul",
"chirp");
}
/* hardware */
device_tree_add_found_uw_u_u(root, "/", "memory",
0, memory_size, access_read_write_exec);
/* initialization */
{
device *init = device_tree_add_found(root, "/", "init");
{
device *init_register = device_tree_add_found(init, "", "register");
device_add_integer_property(init_register,
"pc",
code_loop_va);
device_add_integer_property(init_register,
"0.pc",
bfd_get_start_address(image));
device_add_integer_property(init_register,
"sp",
stack_va + sizeof_stack - 16);
/* init the code callback along with a loop for the unused cpu's */
device_add_integer_property(init_register,
"r5",
code_client_va);
/* client interface */
device_tree_add_found_uw_u_u(init, "",
"data",
code_ra + (code_client_va - code_va),
4, emul_call_instruction);
device_tree_add_found_uw_u_u(init, "",
"data",
code_ra + (code_client_va - code_va) + 4,
4, emul_blr_instruction);
/* callback return address */
device_tree_add_found_uw_u_u(init, "",
"data",
code_ra + (code_callback_va - code_va),
4, emul_call_instruction);
/* loop to keep other processors busy */
device_tree_add_found_uw_u_u(init, "",
"data",
code_ra + (code_loop_va - code_va),
4, emul_loop_instruction);
device_add_integer_property(init_register,
"msr",
(msr_machine_check_enable
| (real_mode
? 0
: (msr_instruction_relocate
| msr_data_relocate))
| (big_endian
? 0
: (msr_little_endian_mode
| msr_interrupt_little_endian_mode
))));
device_add_integer_property(init_register,
"sdr1",
(htab_ra
| MASK32(16, 22)
| ((sizeof_htab - 1) >> 16)));
/* FIXME */
device_add_integer_property(init_register,
"sr8",
0x00fffff8);
device_add_integer_property(init_register,
"sr9",
0x00fffff9);
{ /* hash table and vm */
device *htab_root = device_tree_add_found_uw_u(init, "", "htab",
htab_ra, sizeof_htab);
device_tree_add_found_uw_uw_u_u_u(htab_root, "", "pte",
stack_ra, stack_va, sizeof_stack,
0x7/*wimg*/, 0x2/*pp*/);
device_tree_add_found_uw_uw_u_u_u(htab_root, "", "pte",
code_ra, code_va, sizeof_code,
0x7/*wimg*/, 0x2/*pp*/);
device_tree_add_found_uw_uw_u_u_u(htab_root, "", "pte",
htab_ra, htab_va, sizeof_htab,
0x7/*wimg*/, 0x2/*pp*/);
device_tree_add_found_uw_u_u_c(htab_root, "", "pte",
0x4000, /*magic*/
0x7/*wimg*/, 0x2/*pp*/,
bfd_get_filename (image));
}
}
}
{ /* chosen options */
device *chosen = device_tree_add_found(root, "/", "chosen");
device_add_string_property(chosen,
"name",
"chosen");
device_add_integer_property(chosen,
"stdin",
0); /* FIXME: ihandle of stdin */
device_add_integer_property(chosen,
"stdout",
1); /* FIXME: ihandle of stdout */
device_add_string_property(chosen,
"bootpath",
"/disk@0:\\boot");
device_add_string_property(chosen,
"bootargs",
"");
#if 0
device_add_integer_property(chosen,
"memory",
0); /* FIXME: ihandle of memory */
device_add_integer_property(chosen,
"mmu",
0);
#endif
}
/* FIXME - should come from the device tree */
data = ZALLOC(os_emul_data);
data->serving_instruction_ea = code_client_va;
data->catching_instruction_ea = code_callback_va;
data->phandles = cap_create("chirp");
data->root = root;
data->services = services;
return data;
}
}
static void
emul_chirp_init(os_emul_data *emul_data,
int nr_cpus)
{
emul_data->state = serving;
cap_init(emul_data->phandles);
}
static int
emul_chirp_instruction_call(cpu *processor,
unsigned_word cia,
unsigned_word ra,
os_emul_data *emul_data)
{
unsigned_word service_name_addr;
unsigned_word result;
char service_buf[32];
char *service_name;
chirp_services *service;
switch (emul_data->state) {
case serving:
/* we are waiting on an OpenBoot request from the client program
via the client interface */
if (cia != emul_data->serving_instruction_ea)
return 0;
emul_data->return_address = LR;
emul_data->arguments = cpu_registers(processor)->gpr[3];
/* try to determine what to do */
service_name_addr = emul_read_word(cpu_registers(processor)->gpr[3],
processor, cia);
service_name = emul_read_string(service_buf, service_name_addr,
sizeof(service_buf), processor, cia);
TRACE(trace_os_emul, ("%s called from 0x%lx with args 0x%lx\n",
service_name,
(unsigned long)emul_data->return_address,
(unsigned long)emul_data->arguments));
/* look it up */
service = services;
while (service->name != NULL && strcmp(service->name, service_name) != 0)
service++;
if (service->name == NULL) {
error("OpenBoot service `%s' not found\n", service_name);
TRACE(trace_os_emul, ("%s not found\n", service_name));
cpu_registers(processor)->gpr[3] = 0;
cpu_restart(processor, emul_data->return_address);
}
emul_data->service = service;
/* call upon it */
result = service->handler(emul_data, processor, cia);
break;
case faulting:
/* We were handling a client request but encountered a page fault
(or other exception). The fault needs to be passed back to the
client using the the client suplied call back interface */
error("emul_chirp_instruction_call() faulting unimplemented\n");
result = -1;
break;
case catching:
/* Have called the client (via the callback interface) because
some fault (hash table miss) occured. The client has finished
handling this and is now returning */
error("emul_chirp_instruction_call() catching unimplemented\n");
result = -1;
break;
default:
error("emul_chirp_instruction_call() unknown internal state\n");
result = -1;
break;
}
/* return to caller - instruction following this is a function return */
return 1;
}
const os_emul emul_chirp = {
"chirp",
emul_chirp_create,
emul_chirp_init,
NULL, /*system_call*/
emul_chirp_instruction_call,
0 /*data*/
};
#endif
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