sim/ppc/hw_init.c - third_party/binutils-gdb - Git at Google

 /*  This file is part of the program psim.

     Copyright 1994, 1997, 2003, 2004 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 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 _HW_INIT_C_
 #define _HW_INIT_C_

 #include "device_table.h"
 #include "bfd.h"
 #include "psim.h"


 /* DMA a file into memory */
 static int
 dma_file(device *me,
 	 const char *file_name,
 	 unsigned_word addr)
 {
   int count;
   int inc;
   FILE *image;
   char buf[1024];

   /* get it open */
   image = fopen(file_name, "r");
   if (image == NULL)
     return -1;

   /* read it in slowly */
   count = 0;
   while (1) {
     inc = fread(buf, 1, sizeof(buf), image);
     if (inc <= 0)
       break;
     if (device_dma_write_buffer(device_parent(me),
 				buf,
 				0 /*address-space*/,
 				addr+count,
 				inc /*nr-bytes*/,
 				1 /*violate ro*/) != inc) {
       fclose(image);
       return -1;
     }
     count += inc;
   }

   /* close down again */
   fclose(image);

   return count;
 }


 /* DEVICE

    file - load a file into memory

    DESCRIPTION

    Loads the entire contents of <file-name> into memory at starting at
    <<real-address>>.  Assumes that memory exists for the load.

    PROPERTIES

    file-name = <string>

    Name of the file to be loaded into memory

    real-address = <integer>

    Real address at which the file is to be loaded */

 static void
 hw_file_init_data_callback(device *me)
 {
   int count;
   const char *file_name = device_find_string_property(me, "file-name");
   unsigned_word addr = device_find_integer_property(me, "real-address");
   /* load the file */
   count = dma_file(me, file_name, addr);
   if (count < 0)
     device_error(me, "Problem loading file %s\n", file_name);
 }


 static device_callbacks const hw_file_callbacks = {
   { NULL, hw_file_init_data_callback, },
   { NULL, }, /* address */
   { NULL, }, /* IO */
   { NULL, }, /* DMA */
   { NULL, }, /* interrupt */
   { NULL, }, /* unit */
 };


 /* DEVICE


    data - initialize a memory location with specified data


    DESCRIPTION


    The pseudo device <<data>> provides a mechanism specifying the
    initialization of a small section of memory.

    Normally, the data would be written using a dma operation.
    However, for some addresses this will not result in the desired
    result.  For instance, to initialize an address in an eeprom,
    instead of a simple dma of the data, a sequence of writes (and then
    real delays) that program the eeprom would be required.

    For dma write initialization, the data device will write the
    specified <<data>> to <<real-address>> using a normal dma.

    For instance write initialization, the specified <<instance>> is
    opened.  Then a seek to the <<real-address>> is performed followed
    by a write of the data.


    Integer properties are stored using the target's endian mode.


    PROPERTIES


    data = <any-valid-property> (required)

    Data to be loaded into memory.  The property type determines how it
    is loaded.


    real-address = <integer> (required)

    Start address at which the data is to be stored.


    instance = <string> (optional)

    Instance specification of the device that is to be opened so that
    the specified data can be written to it.


    EXAMPLES


    The examples below illustrate the two alternative mechanisms that
    can be used to store the value 0x12345678 at address 0xfff00c00,
    which is normally part of the 512k system eeprom.


    If the eeprom is being modeled by ram (<<memory>> device) then the
    standard dma initialization can be used.  By convention: the data
    devices are uniquely identified by argumenting them with the
    destinations real address; and all data devices are put under the
    node <</openprom/init>>.

    | /openprom/memory@0xfff00000/reg 0xfff00000 0x80000
    | /openprom/init/data@0x1000/data 0x12345678
    | /openprom/init/data@0x1000/real-address 0x1000


    If instead a real eeprom was being used the instance write method
    would instead need to be used (storing just a single byte in an
    eeprom requires a complex sequence of accesses).  The
    <<real-address>> is specified as <<0x0c00>> which is the offset
    into the eeprom.  For brevity, most of the eeprom properties have
    been omited.

    | /iobus/eeprom@0xfff00000/reg 0xfff00000 0x80000
    | /openprom/init/data@0xfff00c00/real-address 0x0c00
    | /openprom/init/data@0xfff00c00/data 0x12345667
    | /openprom/init/data@0xfff00c00/instance /iobus/eeprom@0xfff00000/reg


    BUGS


    At present, only <<integer>> properties can be specified for an
    initial data value.

    */


 static void
 hw_data_init_data_callback(device *me)
 {
   unsigned_word addr = device_find_integer_property(me, "real-address");
   const device_property *data = device_find_property(me, "data");
   const char *instance_spec = (device_find_property(me, "instance") != NULL
 			       ? device_find_string_property(me, "instance")
 			       : NULL);
   device_instance *instance = NULL;
   if (data == NULL)
     device_error(me, "missing property <data>\n");
   if (instance_spec != NULL)
     instance = tree_instance(me, instance_spec);
   switch (data->type) {
   case integer_property:
     {
       unsigned_cell buf = device_find_integer_property(me, "data");
       H2T(buf);
       if (instance == NULL) {
 	if (device_dma_write_buffer(device_parent(me),
 				    &buf,
 				    0 /*address-space*/,
 				    addr,
 				    sizeof(buf), /*nr-bytes*/
 				    1 /*violate ro*/) != sizeof(buf))
 	  device_error(me, "Problem storing integer 0x%x at 0x%lx\n",
 		       (unsigned)buf, (unsigned long)addr);
       }
       else {
 	if (device_instance_seek(instance, 0, addr) < 0
 	    || device_instance_write(instance, &buf, sizeof(buf)) != sizeof(buf))
 	  device_error(me, "Problem storing integer 0x%x at 0x%lx of instance %s\n",
 		       (unsigned)buf, (unsigned long)addr, instance_spec);
       }
     }
     break;
   default:
     device_error(me, "Write of this data is not yet implemented\n");
     break;
   }
   if (instance != NULL)
     device_instance_delete(instance);
 }


 static device_callbacks const hw_data_callbacks = {
   { NULL, hw_data_init_data_callback, },
   { NULL, }, /* address */
   { NULL, }, /* IO */
   { NULL, }, /* DMA */
   { NULL, }, /* interrupt */
   { NULL, }, /* unit */
 };


 /* DEVICE


    load-binary - load binary segments into memory


    DESCRIPTION

    Each loadable segment of the specified binary is loaded into memory
    at its required address.  It is assumed that the memory at those
    addresses already exists.

    This device is normally used to load an executable into memory as
    part of real mode simulation.


    PROPERTIES


    file-name = <string>

    Name of the binary to be loaded.


    claim = <anything> (optional)

    If this property is present, the real memory that is to be used by
    the image being loaded will be claimed from the memory node
    (specified by the ihandle <</chosen/memory>>).


    BUGS


    When loading the binary the bfd virtual-address is used.  It should
    be using the bfd load-address.

    */

 /* DEVICE

    map-binary - map the binary into the users address space

    DESCRIPTION

    Similar to load-binary except that memory for each segment is
    created before the corresponding data for the segment is loaded.

    This device is normally used to load an executable into a user mode
    simulation.

    PROPERTIES

    file-name = <string>

    Name of the binary to be loaded.

    */

 static void
 update_for_binary_section(bfd *abfd,
 			  asection *the_section,
 			  PTR obj)
 {
   unsigned_word section_vma;
   unsigned_word section_size;
   access_type access;
   device *me = (device*)obj;

   /* skip the section if no memory to allocate */
   if (! (bfd_get_section_flags(abfd, the_section) & SEC_ALLOC))
     return;

   /* check/ignore any sections of size zero */
   section_size = bfd_get_section_size (the_section);
   if (section_size == 0)
     return;

   /* find where it is to go */
   section_vma = bfd_get_section_vma(abfd, the_section);

   DTRACE(binary,
 	 ("name=%-7s, vma=0x%.8lx, size=%6ld, flags=%3lx(%s%s%s%s%s )\n",
 	  bfd_get_section_name(abfd, the_section),
 	  (long)section_vma,
 	  (long)section_size,
 	  (long)bfd_get_section_flags(abfd, the_section),
 	  bfd_get_section_flags(abfd, the_section) & SEC_LOAD ? " LOAD" : "",
 	  bfd_get_section_flags(abfd, the_section) & SEC_CODE ? " CODE" : "",
 	  bfd_get_section_flags(abfd, the_section) & SEC_DATA ? " DATA" : "",
 	  bfd_get_section_flags(abfd, the_section) & SEC_ALLOC ? " ALLOC" : "",
 	  bfd_get_section_flags(abfd, the_section) & SEC_READONLY ? " READONLY" : ""
 	  ));

   /* If there is an .interp section, it means it needs a shared library interpreter.  */
   if (strcmp(".interp", bfd_get_section_name(abfd, the_section)) == 0)
     error("Shared libraries are not yet supported.\n");

   /* determine the devices access */
   access = access_read;
   if (bfd_get_section_flags(abfd, the_section) & SEC_CODE)
     access |= access_exec;
   if (!(bfd_get_section_flags(abfd, the_section) & SEC_READONLY))
     access |= access_write;

   /* if claim specified, allocate region from the memory device */
   if (device_find_property(me, "claim") != NULL) {
     device_instance *memory = tree_find_ihandle_property(me, "/chosen/memory");
     unsigned_cell mem_in[3];
     unsigned_cell mem_out[1];
     mem_in[0] = 0; /*alignment - top-of-stack*/
     mem_in[1] = section_size;
     mem_in[2] = section_vma;
     if (device_instance_call_method(memory, "claim", 3, mem_in, 1, mem_out) < 0)
       device_error(me, "failed to claim memory for section at 0x%lx (0x%lx",
 		   section_vma,
 		   section_size);
     if (mem_out[0] != section_vma)
       device_error(me, "section address not as requested");
   }

   /* if a map, pass up a request to create the memory in core */
   if (strncmp(device_name(me), "map-binary", strlen("map-binary")) == 0)
     device_attach_address(device_parent(me),
 			  attach_raw_memory,
 			  0 /*address space*/,
 			  section_vma,
 			  section_size,
 			  access,
 			  me);

   /* if a load dma in the required data */
   if (bfd_get_section_flags(abfd, the_section) & SEC_LOAD) {
     void *section_init = zalloc(section_size);
     if (!bfd_get_section_contents(abfd,
 				  the_section,
 				  section_init, 0,
 				  section_size)) {
       bfd_perror("binary");
       device_error(me, "load of data failed");
       return;
     }
     if (device_dma_write_buffer(device_parent(me),
 				section_init,
 				0 /*space*/,
 				section_vma,
 				section_size,
 				1 /*violate_read_only*/)
 	!= section_size)
       device_error(me, "broken transfer\n");
     free(section_init); /* only free if load */
   }
 }

 static void
 hw_binary_init_data_callback(device *me)
 {
   /* get the file name */
   const char *file_name = device_find_string_property(me, "file-name");
   bfd *image;

   /* open the file */
   image = bfd_openr(file_name, NULL);
   if (image == NULL) {
     bfd_perror("binary");
     device_error(me, "Failed to open file %s\n", file_name);
   }

   /* check it is valid */
   if (!bfd_check_format(image, bfd_object)) {
     bfd_close(image);
     device_error(me, "The file %s has an invalid binary format\n", file_name);
   }

   /* and the data sections */
   bfd_map_over_sections(image,
 			update_for_binary_section,
 			(PTR)me);

   bfd_close(image);
 }


 static device_callbacks const hw_binary_callbacks = {
   { NULL, hw_binary_init_data_callback, },
   { NULL, }, /* address */
   { NULL, }, /* IO */
   { NULL, }, /* DMA */
   { NULL, }, /* interrupt */
   { NULL, }, /* unit */
 };


 /* DEVICE

    stack - create an initial stack frame in memory

    DESCRIPTION

    Creates a stack frame of the specified type in memory.

    Due to the startup sequence gdb uses when commencing a simulation,
    it is not possible for the data to be placed on the stack to be
    specified as part of the device tree.  Instead the arguments to be
    pushed onto the stack are specified using an IOCTL call.

    The IOCTL takes the additional arguments:

    | unsigned_word stack_end -- where the stack should come down from
    | char **argv -- ...
    | char **envp -- ...

    PROPERTIES

    stack-type = <string>

    The form of the stack frame that is to be created.

    */

 static int
 sizeof_argument_strings(char **arg)
 {
   int sizeof_strings = 0;

   /* robust */
   if (arg == NULL)
     return 0;

   /* add up all the string sizes (padding as we go) */
   for (; *arg != NULL; arg++) {
     int len = strlen(*arg) + 1;
     sizeof_strings += ALIGN_8(len);
   }

   return sizeof_strings;
 }

 static int
 number_of_arguments(char **arg)
 {
   int nr;
   if (arg == NULL)
     return 0;
   for (nr = 0; *arg != NULL; arg++, nr++);
   return nr;
 }

 static int
 sizeof_arguments(char **arg)
 {
   return ALIGN_8((number_of_arguments(arg) + 1) * sizeof(unsigned_word));
 }

 static void
 write_stack_arguments(device *me,
 		      char **arg,
 		      unsigned_word start_block,
 		      unsigned_word end_block,
 		      unsigned_word start_arg,
 		      unsigned_word end_arg)
 {
   DTRACE(stack,
 	("write_stack_arguments(device=%s, arg=0x%lx, start_block=0x%lx, end_block=0x%lx, start_arg=0x%lx, end_arg=0x%lx)\n",
 	 device_name(me), (long)arg, (long)start_block, (long)end_block, (long)start_arg, (long)end_arg));
   if (arg == NULL)
     device_error(me, "Attempt to write a null array onto the stack\n");
   /* only copy in arguments, memory is already zero */
   for (; *arg != NULL; arg++) {
     int len = strlen(*arg)+1;
     unsigned_word target_start_block;
     DTRACE(stack,
 	  ("write_stack_arguments() write %s=%s at %s=0x%lx %s=0x%lx %s=0x%lx\n",
 	   "**arg", *arg, "start_block", (long)start_block,
 	   "len", (long)len, "start_arg", (long)start_arg));
     if (psim_write_memory(device_system(me), 0, *arg,
 			  start_block, len,
 			  0/*violate_readonly*/) != len)
       device_error(me, "Write of **arg (%s) at 0x%lx of stack failed\n",
 		   *arg, (unsigned long)start_block);
     target_start_block = H2T_word(start_block);
     if (psim_write_memory(device_system(me), 0, &target_start_block,
 			  start_arg, sizeof(target_start_block),
 			  0) != sizeof(target_start_block))
       device_error(me, "Write of *arg onto stack failed\n");
     start_block += ALIGN_8(len);
     start_arg += sizeof(start_block);
   }
   start_arg += sizeof(start_block); /*the null at the end*/
   if (start_block != end_block
       || ALIGN_8(start_arg) != end_arg)
     device_error(me, "Probable corrpution of stack arguments\n");
   DTRACE(stack, ("write_stack_arguments() = void\n"));
 }

 static void
 create_ppc_elf_stack_frame(device *me,
 			   unsigned_word bottom_of_stack,
 			   char **argv,
 			   char **envp)
 {
   /* fixme - this is over aligned */

   /* information block */
   const unsigned sizeof_envp_block = sizeof_argument_strings(envp);
   const unsigned_word start_envp_block = bottom_of_stack - sizeof_envp_block;
   const unsigned sizeof_argv_block = sizeof_argument_strings(argv);
   const unsigned_word start_argv_block = start_envp_block - sizeof_argv_block;

   /* auxiliary vector - contains only one entry */
   const unsigned sizeof_aux_entry = 2*sizeof(unsigned_word); /* magic */
   const unsigned_word start_aux = start_argv_block - ALIGN_8(sizeof_aux_entry);

   /* environment points (including null sentinal) */
   const unsigned sizeof_envp = sizeof_arguments(envp);
   const unsigned_word start_envp = start_aux - sizeof_envp;

   /* argument pointers (including null sentinal) */
   const int argc = number_of_arguments(argv);
   const unsigned sizeof_argv = sizeof_arguments(argv);
   const unsigned_word start_argv = start_envp - sizeof_argv;

   /* link register save address - alligned to a 16byte boundary */
   const unsigned_word top_of_stack = ((start_argv
 				       - 2 * sizeof(unsigned_word))
 				      & ~0xf);

   /* install arguments on stack */
   write_stack_arguments(me, envp,
 			start_envp_block, bottom_of_stack,
 			start_envp, start_aux);
   write_stack_arguments(me, argv,
 			start_argv_block, start_envp_block,
 			start_argv, start_envp);

   /* set up the registers */
   ASSERT (psim_write_register(device_system(me), -1,
 			      &top_of_stack, "sp", cooked_transfer) > 0);
   ASSERT (psim_write_register(device_system(me), -1,
 			      &argc, "r3", cooked_transfer) > 0);
   ASSERT (psim_write_register(device_system(me), -1,
 			      &start_argv, "r4", cooked_transfer) > 0);
   ASSERT (psim_write_register(device_system(me), -1,
 			      &start_envp, "r5", cooked_transfer) > 0);
   ASSERT (psim_write_register(device_system(me), -1,
 			      &start_aux, "r6", cooked_transfer) > 0);
 }

 static void
 create_ppc_aix_stack_frame(device *me,
 			   unsigned_word bottom_of_stack,
 			   char **argv,
 			   char **envp)
 {
   unsigned_word core_envp;
   unsigned_word core_argv;
   unsigned_word core_argc;
   unsigned_word core_aux;
   unsigned_word top_of_stack;

   /* cheat - create an elf stack frame */
   create_ppc_elf_stack_frame(me, bottom_of_stack, argv, envp);

   /* extract argument addresses from registers */
   ASSERT (psim_read_register(device_system(me), 0,
 			     &top_of_stack, "r1", cooked_transfer) > 0);
   ASSERT (psim_read_register(device_system(me), 0,
 			     &core_argc, "r3", cooked_transfer) > 0);
   ASSERT (psim_read_register(device_system(me), 0,
 			     &core_argv, "r4", cooked_transfer) > 0);
   ASSERT (psim_read_register(device_system(me), 0,
 			     &core_envp, "r5", cooked_transfer) > 0);
   ASSERT (psim_read_register(device_system(me), 0,
 			     &core_aux, "r6", cooked_transfer) > 0);

   /* extract arguments from registers */
   device_error(me, "Unfinished procedure create_ppc_aix_stack_frame\n");
 }


 static void
 create_ppc_chirp_bootargs(device *me,
 			  char **argv)
 {
   /* concat the arguments */
   char args[1024];
   char **chp = argv + 1;
   args[0] = '\0';
   while (*chp != NULL) {
     if (strlen(args) > 0)
       strcat(args, " ");
     if (strlen(args) + strlen(*chp) >= sizeof(args))
       device_error(me, "buffer overflow");
     strcat(args, *chp);
     chp++;
   }

   /* set the arguments property */
   tree_parse(me, "/chosen/bootargs \"%s", args);
 }


 static int
 hw_stack_ioctl(device *me,
 	       cpu *processor,
 	       unsigned_word cia,
 	       device_ioctl_request request,
 	       va_list ap)
 {
   switch (request) {
   case device_ioctl_create_stack:
     {
       unsigned_word stack_pointer = va_arg(ap, unsigned_word);
       char **argv = va_arg(ap, char **);
       char **envp = va_arg(ap, char **);
       const char *stack_type;
       DTRACE(stack,
 	     ("stack_ioctl_callback(me=0x%lx:%s processor=0x%lx cia=0x%lx argv=0x%lx envp=0x%lx)\n",
 	      (long)me, device_name(me),
 	      (long)processor,
 	      (long)cia,
 	      (long)argv,
 	      (long)envp));
       stack_type = device_find_string_property(me, "stack-type");
       if (strcmp(stack_type, "ppc-elf") == 0)
 	create_ppc_elf_stack_frame(me, stack_pointer, argv, envp);
       else if (strcmp(stack_type, "ppc-xcoff") == 0)
 	create_ppc_aix_stack_frame(me, stack_pointer, argv, envp);
       else if (strcmp(stack_type, "chirp") == 0)
 	create_ppc_chirp_bootargs(me, argv);
       else if (strcmp(stack_type, "none") != 0)
 	device_error(me, "Unknown initial stack frame type %s", stack_type);
       DTRACE(stack,
 	     ("stack_ioctl_callback() = void\n"));
       break;
     }
   default:
     device_error(me, "Unsupported ioctl requested");
     break;
   }
   return 0;
 }

 static device_callbacks const hw_stack_callbacks = {
   { NULL, },
   { NULL, }, /* address */
   { NULL, }, /* IO */
   { NULL, }, /* DMA */
   { NULL, }, /* interrupt */
   { NULL, }, /* unit */
   NULL, /* instance */
   hw_stack_ioctl,
 };

 const device_descriptor hw_init_device_descriptor[] = {
   { "file", NULL, &hw_file_callbacks },
   { "data", NULL, &hw_data_callbacks },
   { "load-binary", NULL, &hw_binary_callbacks },
   { "map-binary", NULL, &hw_binary_callbacks },
   { "stack", NULL, &hw_stack_callbacks },
   { NULL },
 };

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

	Copyright 1994, 1997, 2003, 2004 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 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 _HW_INIT_C_
	#define _HW_INIT_C_

	#include "device_table.h"
	#include "bfd.h"
	#include "psim.h"


	/* DMA a file into memory */
	static int
	dma_file(device *me,
	const char *file_name,
	unsigned_word addr)
	{
	int count;
	int inc;
	FILE *image;
	char buf[1024];

	/* get it open */
	image = fopen(file_name, "r");
	if (image == NULL)
	return -1;

	/* read it in slowly */
	count = 0;
	while (1) {
	inc = fread(buf, 1, sizeof(buf), image);
	if (inc <= 0)
	break;
	if (device_dma_write_buffer(device_parent(me),
	buf,
	0 /address-space/,
	addr+count,
	inc /nr-bytes/,
	1 /violate ro/) != inc) {
	fclose(image);
	return -1;
	}
	count += inc;
	}

	/* close down again */
	fclose(image);

	return count;
	}


	/* DEVICE

	file - load a file into memory

	DESCRIPTION

	Loads the entire contents of <file-name> into memory at starting at
	<<real-address>>. Assumes that memory exists for the load.

	PROPERTIES

	file-name = <string>

	Name of the file to be loaded into memory

	real-address = <integer>

	Real address at which the file is to be loaded */

	static void
	hw_file_init_data_callback(device *me)
	{
	int count;
	const char *file_name = device_find_string_property(me, "file-name");
	unsigned_word addr = device_find_integer_property(me, "real-address");
	/* load the file */
	count = dma_file(me, file_name, addr);
	if (count < 0)
	device_error(me, "Problem loading file %s\n", file_name);
	}


	static device_callbacks const hw_file_callbacks = {
	{ NULL, hw_file_init_data_callback, },
	{ NULL, }, /* address */
	{ NULL, }, /* IO */
	{ NULL, }, /* DMA */
	{ NULL, }, /* interrupt */
	{ NULL, }, /* unit */
	};


	/* DEVICE


	data - initialize a memory location with specified data


	DESCRIPTION


	The pseudo device <<data>> provides a mechanism specifying the
	initialization of a small section of memory.

	Normally, the data would be written using a dma operation.
	However, for some addresses this will not result in the desired
	result. For instance, to initialize an address in an eeprom,
	instead of a simple dma of the data, a sequence of writes (and then
	real delays) that program the eeprom would be required.

	For dma write initialization, the data device will write the
	specified <<data>> to <<real-address>> using a normal dma.

	For instance write initialization, the specified <<instance>> is
	opened. Then a seek to the <<real-address>> is performed followed
	by a write of the data.


	Integer properties are stored using the target's endian mode.


	PROPERTIES


	data = <any-valid-property> (required)

	Data to be loaded into memory. The property type determines how it
	is loaded.


	real-address = <integer> (required)

	Start address at which the data is to be stored.


	instance = <string> (optional)

	Instance specification of the device that is to be opened so that
	the specified data can be written to it.


	EXAMPLES


	The examples below illustrate the two alternative mechanisms that
	can be used to store the value 0x12345678 at address 0xfff00c00,
	which is normally part of the 512k system eeprom.


	If the eeprom is being modeled by ram (<<memory>> device) then the
	standard dma initialization can be used. By convention: the data
	devices are uniquely identified by argumenting them with the
	destinations real address; and all data devices are put under the
	node <</openprom/init>>.

	\| /openprom/memory@0xfff00000/reg 0xfff00000 0x80000
	\| /openprom/init/data@0x1000/data 0x12345678
	\| /openprom/init/data@0x1000/real-address 0x1000


	If instead a real eeprom was being used the instance write method
	would instead need to be used (storing just a single byte in an
	eeprom requires a complex sequence of accesses). The
	<<real-address>> is specified as <<0x0c00>> which is the offset
	into the eeprom. For brevity, most of the eeprom properties have
	been omited.

	\| /iobus/eeprom@0xfff00000/reg 0xfff00000 0x80000
	\| /openprom/init/data@0xfff00c00/real-address 0x0c00
	\| /openprom/init/data@0xfff00c00/data 0x12345667
	\| /openprom/init/data@0xfff00c00/instance /iobus/eeprom@0xfff00000/reg


	BUGS


	At present, only <<integer>> properties can be specified for an
	initial data value.

	*/


	static void
	hw_data_init_data_callback(device *me)
	{
	unsigned_word addr = device_find_integer_property(me, "real-address");
	const device_property *data = device_find_property(me, "data");
	const char *instance_spec = (device_find_property(me, "instance") != NULL
	? device_find_string_property(me, "instance")
	: NULL);
	device_instance *instance = NULL;
	if (data == NULL)
	device_error(me, "missing property <data>\n");
	if (instance_spec != NULL)
	instance = tree_instance(me, instance_spec);
	switch (data->type) {
	case integer_property:
	{
	unsigned_cell buf = device_find_integer_property(me, "data");
	H2T(buf);
	if (instance == NULL) {
	if (device_dma_write_buffer(device_parent(me),
	&buf,
	0 /address-space/,
	addr,
	sizeof(buf), /nr-bytes/
	1 /violate ro/) != sizeof(buf))
	device_error(me, "Problem storing integer 0x%x at 0x%lx\n",
	(unsigned)buf, (unsigned long)addr);
	}
	else {
	if (device_instance_seek(instance, 0, addr) < 0
	\|\| device_instance_write(instance, &buf, sizeof(buf)) != sizeof(buf))
	device_error(me, "Problem storing integer 0x%x at 0x%lx of instance %s\n",
	(unsigned)buf, (unsigned long)addr, instance_spec);
	}
	}
	break;
	default:
	device_error(me, "Write of this data is not yet implemented\n");
	break;
	}
	if (instance != NULL)
	device_instance_delete(instance);
	}


	static device_callbacks const hw_data_callbacks = {
	{ NULL, hw_data_init_data_callback, },
	{ NULL, }, /* address */
	{ NULL, }, /* IO */
	{ NULL, }, /* DMA */
	{ NULL, }, /* interrupt */
	{ NULL, }, /* unit */
	};


	/* DEVICE


	load-binary - load binary segments into memory


	DESCRIPTION

	Each loadable segment of the specified binary is loaded into memory
	at its required address. It is assumed that the memory at those
	addresses already exists.

	This device is normally used to load an executable into memory as
	part of real mode simulation.


	PROPERTIES


	file-name = <string>

	Name of the binary to be loaded.


	claim = <anything> (optional)

	If this property is present, the real memory that is to be used by
	the image being loaded will be claimed from the memory node
	(specified by the ihandle <</chosen/memory>>).


	BUGS


	When loading the binary the bfd virtual-address is used. It should
	be using the bfd load-address.

	*/

	/* DEVICE

	map-binary - map the binary into the users address space

	DESCRIPTION

	Similar to load-binary except that memory for each segment is
	created before the corresponding data for the segment is loaded.

	This device is normally used to load an executable into a user mode
	simulation.

	PROPERTIES

	file-name = <string>

	Name of the binary to be loaded.

	*/

	static void
	update_for_binary_section(bfd *abfd,
	asection *the_section,
	PTR obj)
	{
	unsigned_word section_vma;
	unsigned_word section_size;
	access_type access;
	device me = (device)obj;

	/* skip the section if no memory to allocate */
	if (! (bfd_get_section_flags(abfd, the_section) & SEC_ALLOC))
	return;

	/* check/ignore any sections of size zero */
	section_size = bfd_get_section_size (the_section);
	if (section_size == 0)
	return;

	/* find where it is to go */
	section_vma = bfd_get_section_vma(abfd, the_section);

	DTRACE(binary,
	("name=%-7s, vma=0x%.8lx, size=%6ld, flags=%3lx(%s%s%s%s%s )\n",
	bfd_get_section_name(abfd, the_section),
	(long)section_vma,
	(long)section_size,
	(long)bfd_get_section_flags(abfd, the_section),
	bfd_get_section_flags(abfd, the_section) & SEC_LOAD ? " LOAD" : "",
	bfd_get_section_flags(abfd, the_section) & SEC_CODE ? " CODE" : "",
	bfd_get_section_flags(abfd, the_section) & SEC_DATA ? " DATA" : "",
	bfd_get_section_flags(abfd, the_section) & SEC_ALLOC ? " ALLOC" : "",
	bfd_get_section_flags(abfd, the_section) & SEC_READONLY ? " READONLY" : ""
	));

	/* If there is an .interp section, it means it needs a shared library interpreter. */
	if (strcmp(".interp", bfd_get_section_name(abfd, the_section)) == 0)
	error("Shared libraries are not yet supported.\n");

	/* determine the devices access */
	access = access_read;
	if (bfd_get_section_flags(abfd, the_section) & SEC_CODE)
	access \|= access_exec;
	if (!(bfd_get_section_flags(abfd, the_section) & SEC_READONLY))
	access \|= access_write;

	/* if claim specified, allocate region from the memory device */
	if (device_find_property(me, "claim") != NULL) {
	device_instance *memory = tree_find_ihandle_property(me, "/chosen/memory");
	unsigned_cell mem_in[3];
	unsigned_cell mem_out[1];
	mem_in[0] = 0; /alignment - top-of-stack/
	mem_in[1] = section_size;
	mem_in[2] = section_vma;
	if (device_instance_call_method(memory, "claim", 3, mem_in, 1, mem_out) < 0)
	device_error(me, "failed to claim memory for section at 0x%lx (0x%lx",
	section_vma,
	section_size);
	if (mem_out[0] != section_vma)
	device_error(me, "section address not as requested");
	}

	/* if a map, pass up a request to create the memory in core */
	if (strncmp(device_name(me), "map-binary", strlen("map-binary")) == 0)
	device_attach_address(device_parent(me),
	attach_raw_memory,
	0 /address space/,
	section_vma,
	section_size,
	access,
	me);

	/* if a load dma in the required data */
	if (bfd_get_section_flags(abfd, the_section) & SEC_LOAD) {
	void *section_init = zalloc(section_size);
	if (!bfd_get_section_contents(abfd,
	the_section,
	section_init, 0,
	section_size)) {
	bfd_perror("binary");
	device_error(me, "load of data failed");
	return;
	}
	if (device_dma_write_buffer(device_parent(me),
	section_init,
	0 /space/,
	section_vma,
	section_size,
	1 /violate_read_only/)
	!= section_size)
	device_error(me, "broken transfer\n");
	free(section_init); /* only free if load */
	}
	}

	static void
	hw_binary_init_data_callback(device *me)
	{
	/* get the file name */
	const char *file_name = device_find_string_property(me, "file-name");
	bfd *image;

	/* open the file */
	image = bfd_openr(file_name, NULL);
	if (image == NULL) {
	bfd_perror("binary");
	device_error(me, "Failed to open file %s\n", file_name);
	}

	/* check it is valid */
	if (!bfd_check_format(image, bfd_object)) {
	bfd_close(image);
	device_error(me, "The file %s has an invalid binary format\n", file_name);
	}

	/* and the data sections */
	bfd_map_over_sections(image,
	update_for_binary_section,
	(PTR)me);

	bfd_close(image);
	}


	static device_callbacks const hw_binary_callbacks = {
	{ NULL, hw_binary_init_data_callback, },
	{ NULL, }, /* address */
	{ NULL, }, /* IO */
	{ NULL, }, /* DMA */
	{ NULL, }, /* interrupt */
	{ NULL, }, /* unit */
	};


	/* DEVICE

	stack - create an initial stack frame in memory

	DESCRIPTION

	Creates a stack frame of the specified type in memory.

	Due to the startup sequence gdb uses when commencing a simulation,
	it is not possible for the data to be placed on the stack to be
	specified as part of the device tree. Instead the arguments to be
	pushed onto the stack are specified using an IOCTL call.

	The IOCTL takes the additional arguments:

	\| unsigned_word stack_end -- where the stack should come down from
	\| char **argv -- ...
	\| char **envp -- ...

	PROPERTIES

	stack-type = <string>

	The form of the stack frame that is to be created.

	*/

	static int
	sizeof_argument_strings(char **arg)
	{
	int sizeof_strings = 0;

	/* robust */
	if (arg == NULL)
	return 0;

	/* add up all the string sizes (padding as we go) */
	for (; *arg != NULL; arg++) {
	int len = strlen(*arg) + 1;
	sizeof_strings += ALIGN_8(len);
	}

	return sizeof_strings;
	}

	static int
	number_of_arguments(char **arg)
	{
	int nr;
	if (arg == NULL)
	return 0;
	for (nr = 0; *arg != NULL; arg++, nr++);
	return nr;
	}

	static int
	sizeof_arguments(char **arg)
	{
	return ALIGN_8((number_of_arguments(arg) + 1) * sizeof(unsigned_word));
	}

	static void
	write_stack_arguments(device *me,
	char **arg,
	unsigned_word start_block,
	unsigned_word end_block,
	unsigned_word start_arg,
	unsigned_word end_arg)
	{
	DTRACE(stack,
	("write_stack_arguments(device=%s, arg=0x%lx, start_block=0x%lx, end_block=0x%lx, start_arg=0x%lx, end_arg=0x%lx)\n",
	device_name(me), (long)arg, (long)start_block, (long)end_block, (long)start_arg, (long)end_arg));
	if (arg == NULL)
	device_error(me, "Attempt to write a null array onto the stack\n");
	/* only copy in arguments, memory is already zero */
	for (; *arg != NULL; arg++) {
	int len = strlen(*arg)+1;
	unsigned_word target_start_block;
	DTRACE(stack,
	("write_stack_arguments() write %s=%s at %s=0x%lx %s=0x%lx %s=0x%lx\n",
	"*arg", arg, "start_block", (long)start_block,
	"len", (long)len, "start_arg", (long)start_arg));
	if (psim_write_memory(device_system(me), 0, *arg,
	start_block, len,
	0/violate_readonly/) != len)
	device_error(me, "Write of **arg (%s) at 0x%lx of stack failed\n",
	*arg, (unsigned long)start_block);
	target_start_block = H2T_word(start_block);
	if (psim_write_memory(device_system(me), 0, &target_start_block,
	start_arg, sizeof(target_start_block),
	0) != sizeof(target_start_block))
	device_error(me, "Write of *arg onto stack failed\n");
	start_block += ALIGN_8(len);
	start_arg += sizeof(start_block);
	}
	start_arg += sizeof(start_block); /the null at the end/
	if (start_block != end_block
	\|\| ALIGN_8(start_arg) != end_arg)
	device_error(me, "Probable corrpution of stack arguments\n");
	DTRACE(stack, ("write_stack_arguments() = void\n"));
	}

	static void
	create_ppc_elf_stack_frame(device *me,
	unsigned_word bottom_of_stack,
	char **argv,
	char **envp)
	{
	/* fixme - this is over aligned */

	/* information block */
	const unsigned sizeof_envp_block = sizeof_argument_strings(envp);
	const unsigned_word start_envp_block = bottom_of_stack - sizeof_envp_block;
	const unsigned sizeof_argv_block = sizeof_argument_strings(argv);
	const unsigned_word start_argv_block = start_envp_block - sizeof_argv_block;

	/* auxiliary vector - contains only one entry */
	const unsigned sizeof_aux_entry = 2sizeof(unsigned_word); / magic */
	const unsigned_word start_aux = start_argv_block - ALIGN_8(sizeof_aux_entry);

	/* environment points (including null sentinal) */
	const unsigned sizeof_envp = sizeof_arguments(envp);
	const unsigned_word start_envp = start_aux - sizeof_envp;

	/* argument pointers (including null sentinal) */
	const int argc = number_of_arguments(argv);
	const unsigned sizeof_argv = sizeof_arguments(argv);
	const unsigned_word start_argv = start_envp - sizeof_argv;

	/* link register save address - alligned to a 16byte boundary */
	const unsigned_word top_of_stack = ((start_argv
	- 2 * sizeof(unsigned_word))
	& ~0xf);

	/* install arguments on stack */
	write_stack_arguments(me, envp,
	start_envp_block, bottom_of_stack,
	start_envp, start_aux);
	write_stack_arguments(me, argv,
	start_argv_block, start_envp_block,
	start_argv, start_envp);

	/* set up the registers */
	ASSERT (psim_write_register(device_system(me), -1,
	&top_of_stack, "sp", cooked_transfer) > 0);
	ASSERT (psim_write_register(device_system(me), -1,
	&argc, "r3", cooked_transfer) > 0);
	ASSERT (psim_write_register(device_system(me), -1,
	&start_argv, "r4", cooked_transfer) > 0);
	ASSERT (psim_write_register(device_system(me), -1,
	&start_envp, "r5", cooked_transfer) > 0);
	ASSERT (psim_write_register(device_system(me), -1,
	&start_aux, "r6", cooked_transfer) > 0);
	}

	static void
	create_ppc_aix_stack_frame(device *me,
	unsigned_word bottom_of_stack,
	char **argv,
	char **envp)
	{
	unsigned_word core_envp;
	unsigned_word core_argv;
	unsigned_word core_argc;
	unsigned_word core_aux;
	unsigned_word top_of_stack;

	/* cheat - create an elf stack frame */
	create_ppc_elf_stack_frame(me, bottom_of_stack, argv, envp);

	/* extract argument addresses from registers */
	ASSERT (psim_read_register(device_system(me), 0,
	&top_of_stack, "r1", cooked_transfer) > 0);
	ASSERT (psim_read_register(device_system(me), 0,
	&core_argc, "r3", cooked_transfer) > 0);
	ASSERT (psim_read_register(device_system(me), 0,
	&core_argv, "r4", cooked_transfer) > 0);
	ASSERT (psim_read_register(device_system(me), 0,
	&core_envp, "r5", cooked_transfer) > 0);
	ASSERT (psim_read_register(device_system(me), 0,
	&core_aux, "r6", cooked_transfer) > 0);

	/* extract arguments from registers */
	device_error(me, "Unfinished procedure create_ppc_aix_stack_frame\n");
	}


	static void
	create_ppc_chirp_bootargs(device *me,
	char **argv)
	{
	/* concat the arguments */
	char args[1024];
	char **chp = argv + 1;
	args[0] = '\0';
	while (*chp != NULL) {
	if (strlen(args) > 0)
	strcat(args, " ");
	if (strlen(args) + strlen(*chp) >= sizeof(args))
	device_error(me, "buffer overflow");
	strcat(args, *chp);
	chp++;
	}

	/* set the arguments property */
	tree_parse(me, "/chosen/bootargs \"%s", args);
	}


	static int
	hw_stack_ioctl(device *me,
	cpu *processor,
	unsigned_word cia,
	device_ioctl_request request,
	va_list ap)
	{
	switch (request) {
	case device_ioctl_create_stack:
	{
	unsigned_word stack_pointer = va_arg(ap, unsigned_word);
	char argv = va_arg(ap, char );
	char envp = va_arg(ap, char );
	const char *stack_type;
	DTRACE(stack,
	("stack_ioctl_callback(me=0x%lx:%s processor=0x%lx cia=0x%lx argv=0x%lx envp=0x%lx)\n",
	(long)me, device_name(me),
	(long)processor,
	(long)cia,
	(long)argv,
	(long)envp));
	stack_type = device_find_string_property(me, "stack-type");
	if (strcmp(stack_type, "ppc-elf") == 0)
	create_ppc_elf_stack_frame(me, stack_pointer, argv, envp);
	else if (strcmp(stack_type, "ppc-xcoff") == 0)
	create_ppc_aix_stack_frame(me, stack_pointer, argv, envp);
	else if (strcmp(stack_type, "chirp") == 0)
	create_ppc_chirp_bootargs(me, argv);
	else if (strcmp(stack_type, "none") != 0)
	device_error(me, "Unknown initial stack frame type %s", stack_type);
	DTRACE(stack,
	("stack_ioctl_callback() = void\n"));
	break;
	}
	default:
	device_error(me, "Unsupported ioctl requested");
	break;
	}
	return 0;
	}

	static device_callbacks const hw_stack_callbacks = {
	{ NULL, },
	{ NULL, }, /* address */
	{ NULL, }, /* IO */
	{ NULL, }, /* DMA */
	{ NULL, }, /* interrupt */
	{ NULL, }, /* unit */
	NULL, /* instance */
	hw_stack_ioctl,
	};

	const device_descriptor hw_init_device_descriptor[] = {
	{ "file", NULL, &hw_file_callbacks },
	{ "data", NULL, &hw_data_callbacks },
	{ "load-binary", NULL, &hw_binary_callbacks },
	{ "map-binary", NULL, &hw_binary_callbacks },
	{ "stack", NULL, &hw_stack_callbacks },
	{ NULL },
	};

	#endif /* _HW_INIT_C_ */