1995-08-23 21:06:36 +00:00
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/* This file is part of the program psim.
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Copyright (C) 1994-1995, Andrew Cagney <cagney@highland.com.au>
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This program is free software; you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation; either version 2 of the License, or
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(at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program; if not, write to the Free Software
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Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
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*/
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#ifndef _CORE_C_
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#define _CORE_C_
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#ifndef STATIC_INLINE_CORE
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#define STATIC_INLINE_CORE STATIC_INLINE
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#endif
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#include "basics.h"
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#include "device_tree.h"
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#include "memory_map.h"
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#include "core.h"
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struct _core {
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/* attached devices */
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device_node *device_tree;
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/* different memory maps */
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memory_map *readable; /* really everything */
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memory_map *writeable;
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memory_map *executable;
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/* VEA model requires additional memory information */
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unsigned_word data_upper_bound;
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unsigned_word data_high_water;
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unsigned_word stack_upper_bound;
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unsigned_word stack_lower_bound;
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unsigned_word stack_low_water;
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/* misc */
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int trace;
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};
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STATIC_INLINE_CORE void
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create_core_from_addresses(device_node *device,
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void *data)
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{
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core *memory = (core*)data;
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device_address *address;
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for (address = device->addresses;
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address != NULL;
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address = address->next_address) {
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switch (device->type) {
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case memory_device:
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{
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void *ram = zalloc(address->size);
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TRACE(trace_core,
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("create_core_from_addresses() adding memory at 0x%.8x-0x%.8x, size %8d\n",
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address->lower_bound, address->lower_bound + address->size - 1, address->size));
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core_add_raw_memory(memory,
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ram,
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address->lower_bound,
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address->size,
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address->access);
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}
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break;
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case sequential_device:
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case block_device:
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case bus_device:
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case other_device:
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{
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TRACE(trace_core,
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("create_core_from_addresses() adding device at 0x%.8x-0x%.8x, size %8d\n",
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address->lower_bound, address->lower_bound + address->size - 1, address->size));
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ASSERT(device->callbacks != NULL);
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core_add_callback_memory(memory,
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device,
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device->callbacks->read_callback,
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device->callbacks->write_callback,
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address->lower_bound,
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address->size,
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address->access);
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}
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break;
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default:
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TRACE(trace_core,
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("create_core_from_addresses() unknown type %d\n", (int)device->type));
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break;
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/* nothing happens here */
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}
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}
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}
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INLINE_CORE core *
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core_create(device_node *root,
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int trace)
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{
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core *memory;
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/* Initialize things */
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memory = ZALLOC(core);
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memory->trace = trace;
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memory->device_tree = root;
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/* allocate space for the separate virtual to physical maps */
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memory->executable = new_memory_map();
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memory->readable = new_memory_map();
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memory->writeable = new_memory_map();
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/* initial values for the water marks */
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memory->data_high_water = 0;
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memory->stack_low_water = memory->data_high_water - sizeof(unsigned_word);
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/* go over the device tree looking for address ranges to add to
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memory */
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device_tree_traverse(root,
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create_core_from_addresses,
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NULL,
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memory);
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/* return the created core object */
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return memory;
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}
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STATIC_INLINE_CORE void
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zero_core_from_addresses(device_node *device,
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void *data)
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{
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core *memory = (core*)data;
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device_address *address;
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/* for memory nodes, copy or zero any data */
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if (device->type == memory_device) {
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for (address = device->addresses;
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address != NULL;
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address = address->next_address) {
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if (memory_map_zero(memory->readable,
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address->lower_bound,
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address->size) != address->size)
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error("init_core_from_addresses() - zero failed\n");
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/* adjust high water mark (sbrk) */
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if (memory->data_upper_bound < address->upper_bound)
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memory->data_upper_bound = address->upper_bound;
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}
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}
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}
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STATIC_INLINE_CORE void
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load_core_from_addresses(device_node *device,
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void *data)
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{
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core *memory = (core*)data;
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device_address *address;
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/* initialize the address range with the value attached to the
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address. Even works for devices! */
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for (address = device->addresses;
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address != NULL;
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address = address->next_address) {
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/* (re)init the address range. I don't want to think about what
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this is doing to callback devices! */
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if (address->init) {
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if (memory_map_write_buffer(memory->readable,
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address->init,
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address->lower_bound,
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address->size,
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raw_transfer) != address->size)
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error("init_core_from_addresses() - write failed\n");
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}
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}
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}
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INLINE_CORE void
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core_init(core *memory)
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{
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unsigned nr_cleared;
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unsigned_word clear_base;
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unsigned_word clear_bound;
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/* for vea, several memory break points */
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memory->data_upper_bound = 0;
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memory->stack_upper_bound = device_tree_find_int(memory->device_tree,
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"/options/stack-pointer");;
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memory->stack_lower_bound = memory->stack_upper_bound;
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/* (re) clear all of memory that is specified by memory-address
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entries. While we're at it determine the upper bound for memory
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areas */
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device_tree_traverse(memory->device_tree,
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NULL,
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zero_core_from_addresses,
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memory);
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/* May have grown the data sectioin (vea model), zero that too if
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present */
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clear_base = memory->data_upper_bound;
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clear_bound = memory->data_high_water;
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if (clear_bound > clear_base) {
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while ((nr_cleared = memory_map_zero(memory->readable,
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clear_base,
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clear_bound - clear_base)) > 0) {
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clear_base += nr_cleared;
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}
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}
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/* clear any part of the stack that was dynamically allocated */
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clear_base = memory->stack_low_water;
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clear_bound = memory->stack_upper_bound;
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if (clear_bound > clear_base) {
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while ((nr_cleared = memory_map_zero(memory->readable,
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clear_base,
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clear_bound - clear_base)) > 0) {
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clear_base += nr_cleared;
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}
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}
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/* with everything zero'ed, now (re) load any data sections */
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device_tree_traverse(memory->device_tree,
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NULL,
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load_core_from_addresses,
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memory);
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}
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INLINE_CORE void
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core_add_raw_memory(core *memory,
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void *buffer,
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unsigned_word base,
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unsigned size,
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device_access access)
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{
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if (access & device_is_readable)
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memory_map_add_raw_memory(memory->readable,
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buffer, base, size);
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if (access & device_is_writeable)
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memory_map_add_raw_memory(memory->writeable,
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buffer, base, size);
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if (access & device_is_executable)
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memory_map_add_raw_memory(memory->executable,
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buffer, base, size);
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}
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INLINE_CORE void
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core_add_callback_memory(core *memory,
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device_node *device,
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device_reader_callback *reader,
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device_writer_callback *writer,
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unsigned_word base,
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unsigned size,
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device_access access)
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{
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if (access & device_is_readable)
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memory_map_add_callback_memory(memory->readable,
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device, reader, writer,
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base, size);
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if (access & device_is_writeable)
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memory_map_add_callback_memory(memory->writeable,
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device, reader, writer,
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base, size);
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if (access & device_is_executable)
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memory_map_add_callback_memory(memory->executable,
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device, reader, writer,
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base, size);
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}
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STATIC_INLINE_CORE void
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malloc_core_memory(core *memory,
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unsigned_word base,
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unsigned size,
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device_access access)
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{
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void *buffer = (void*)zalloc(size);
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core_add_raw_memory(memory, buffer, base, size, access);
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}
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INLINE_CORE unsigned_word
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core_data_upper_bound(core *memory)
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{
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return memory->data_upper_bound;
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}
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INLINE_CORE unsigned_word
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core_stack_lower_bound(core *memory)
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{
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return memory->stack_lower_bound;
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}
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INLINE_CORE unsigned_word
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core_stack_size(core *memory)
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{
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return (memory->stack_upper_bound - memory->stack_lower_bound);
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}
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INLINE_CORE void
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core_add_data(core *memory, unsigned_word incr)
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{
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1995-09-06 14:00:16 +00:00
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unsigned_word new_upper_bound = memory->data_upper_bound + incr;
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if (new_upper_bound > memory->data_high_water) {
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if (memory->data_upper_bound >= memory->data_high_water)
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/* all the memory is new */
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malloc_core_memory(memory,
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memory->data_upper_bound,
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incr,
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device_is_readable | device_is_writeable);
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else
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/* some of the memory was already allocated, only need to add
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missing bit */
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malloc_core_memory(memory,
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memory->data_high_water,
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new_upper_bound - memory->data_high_water,
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device_is_readable | device_is_writeable);
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memory->data_high_water = new_upper_bound;
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1995-08-23 21:06:36 +00:00
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}
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1995-09-06 14:00:16 +00:00
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memory->data_upper_bound = new_upper_bound;
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1995-08-23 21:06:36 +00:00
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}
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INLINE_CORE void
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core_add_stack(core *memory, unsigned_word incr)
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{
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1995-09-06 14:00:16 +00:00
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unsigned_word new_lower_bound = memory->stack_lower_bound - incr;
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if (new_lower_bound < memory->stack_low_water) {
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if (memory->stack_lower_bound <= memory->stack_low_water)
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/* all the memory is new */
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malloc_core_memory(memory,
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new_lower_bound,
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incr,
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device_is_readable | device_is_writeable);
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else
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/* allocate only the extra bit */
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malloc_core_memory(memory,
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new_lower_bound,
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memory->stack_low_water - new_lower_bound,
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device_is_readable | device_is_writeable);
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memory->stack_low_water = new_lower_bound;
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1995-08-23 21:06:36 +00:00
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}
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1995-09-06 14:00:16 +00:00
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memory->stack_lower_bound = new_lower_bound;
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1995-08-23 21:06:36 +00:00
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}
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INLINE_CORE memory_map *
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core_readable(core *core)
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{
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return core->readable;
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}
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INLINE_CORE memory_map *
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core_writeable(core *core)
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{
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return core->writeable;
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}
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INLINE_CORE memory_map *
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core_executable(core *core)
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{
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return core->executable;
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}
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#endif /* _CORE_ */
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