437 lines
13 KiB
C
437 lines
13 KiB
C
/* Parts of target interface that deal with accessing memory and memory-like
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objects.
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Copyright (C) 2006, 2007 Free Software Foundation, Inc.
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This file is part of GDB.
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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., 51 Franklin Street, Fifth Floor,
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Boston, MA 02110-1301, USA. */
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#include "defs.h"
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#include "vec.h"
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#include "target.h"
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#include "memory-map.h"
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#include "gdb_assert.h"
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#include <stdio.h>
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#include <sys/time.h>
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static int
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compare_block_starting_address (const void *a, const void *b)
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{
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const struct memory_write_request *a_req = a;
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const struct memory_write_request *b_req = b;
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if (a_req->begin < b_req->begin)
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return -1;
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else if (a_req->begin == b_req->begin)
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return 0;
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else
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return 1;
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}
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/* Adds to RESULT all memory write requests from BLOCK that are
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in [BEGIN, END) range.
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If any memory request is only partially in the specified range,
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that part of the memory request will be added. */
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static void
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claim_memory (VEC(memory_write_request_s) *blocks,
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VEC(memory_write_request_s) **result,
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ULONGEST begin,
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ULONGEST end)
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{
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int i;
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ULONGEST claimed_begin;
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ULONGEST claimed_end;
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struct memory_write_request *r;
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for (i = 0; VEC_iterate (memory_write_request_s, blocks, i, r); ++i)
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{
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/* If the request doesn't overlap [BEGIN, END), skip it. We
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must handle END == 0 meaning the top of memory; we don't yet
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check for R->end == 0, which would also mean the top of
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memory, but there's an assertion in
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target_write_memory_blocks which checks for that. */
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if (begin >= r->end)
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continue;
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if (end != 0 && end <= r->begin)
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continue;
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claimed_begin = max (begin, r->begin);
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if (end == 0)
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claimed_end = r->end;
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else
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claimed_end = min (end, r->end);
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if (claimed_begin == r->begin && claimed_end == r->end)
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VEC_safe_push (memory_write_request_s, *result, r);
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else
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{
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struct memory_write_request *n =
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VEC_safe_push (memory_write_request_s, *result, NULL);
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memset (n, 0, sizeof (struct memory_write_request));
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n->begin = claimed_begin;
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n->end = claimed_end;
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n->data = r->data + (claimed_begin - r->begin);
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}
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}
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}
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/* Given a vector of struct memory_write_request objects in BLOCKS,
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add memory requests for flash memory into FLASH_BLOCKS, and for
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regular memory to REGULAR_BLOCKS. */
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static void
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split_regular_and_flash_blocks (VEC(memory_write_request_s) *blocks,
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VEC(memory_write_request_s) **regular_blocks,
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VEC(memory_write_request_s) **flash_blocks)
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{
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struct mem_region *region;
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CORE_ADDR cur_address;
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/* This implementation runs in O(length(regions)*length(blocks)) time.
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However, in most cases the number of blocks will be small, so this does
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not matter.
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Note also that it's extremely unlikely that a memory write request
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will span more than one memory region, however for safety we handle
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such situations. */
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cur_address = 0;
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while (1)
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{
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VEC(memory_write_request_s) **r;
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region = lookup_mem_region (cur_address);
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r = region->attrib.mode == MEM_FLASH ? flash_blocks : regular_blocks;
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cur_address = region->hi;
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claim_memory (blocks, r, region->lo, region->hi);
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if (cur_address == 0)
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break;
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}
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}
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/* Given an ADDRESS, if BEGIN is non-NULL this function sets *BEGIN
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to the start of the flash block containing the address. Similarly,
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if END is non-NULL *END will be set to the address one past the end
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of the block containing the address. */
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static void
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block_boundaries (CORE_ADDR address, CORE_ADDR *begin, CORE_ADDR *end)
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{
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struct mem_region *region;
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unsigned blocksize;
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region = lookup_mem_region (address);
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gdb_assert (region->attrib.mode == MEM_FLASH);
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blocksize = region->attrib.blocksize;
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if (begin)
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*begin = address / blocksize * blocksize;
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if (end)
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*end = (address + blocksize - 1) / blocksize * blocksize;
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}
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/* Given the list of memory requests to be WRITTEN, this function
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returns write requests covering each group of flash blocks which must
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be erased. */
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static VEC(memory_write_request_s) *
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blocks_to_erase (VEC(memory_write_request_s) *written)
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{
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unsigned i;
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struct memory_write_request *ptr;
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VEC(memory_write_request_s) *result = NULL;
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for (i = 0; VEC_iterate (memory_write_request_s, written, i, ptr); ++i)
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{
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CORE_ADDR begin, end;
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block_boundaries (ptr->begin, &begin, 0);
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block_boundaries (ptr->end - 1, 0, &end);
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if (!VEC_empty (memory_write_request_s, result)
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&& VEC_last (memory_write_request_s, result)->end >= begin)
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{
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VEC_last (memory_write_request_s, result)->end = end;
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}
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else
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{
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struct memory_write_request *n =
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VEC_safe_push (memory_write_request_s, result, NULL);
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memset (n, 0, sizeof (struct memory_write_request));
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n->begin = begin;
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n->end = end;
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}
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}
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return result;
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}
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/* Given ERASED_BLOCKS, a list of blocks that will be erased with
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flash erase commands, and WRITTEN_BLOCKS, the list of memory
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addresses that will be written, compute the set of memory addresses
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that will be erased but not rewritten (e.g. padding within a block
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which is only partially filled by "load"). */
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static VEC(memory_write_request_s) *
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compute_garbled_blocks (VEC(memory_write_request_s) *erased_blocks,
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VEC(memory_write_request_s) *written_blocks)
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{
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VEC(memory_write_request_s) *result = NULL;
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unsigned i, j;
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unsigned je = VEC_length (memory_write_request_s, written_blocks);
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struct memory_write_request *erased_p;
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/* Look at each erased memory_write_request in turn, and
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see what part of it is subsequently written to.
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This implementation is O(length(erased) * length(written)). If
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the lists are sorted at this point it could be rewritten more
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efficiently, but the complexity is not generally worthwhile. */
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for (i = 0;
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VEC_iterate (memory_write_request_s, erased_blocks, i, erased_p);
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++i)
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{
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/* Make a deep copy -- it will be modified inside the loop, but
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we don't want to modify original vector. */
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struct memory_write_request erased = *erased_p;
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for (j = 0; j != je;)
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{
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struct memory_write_request *written
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= VEC_index (memory_write_request_s,
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written_blocks, j);
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/* Now try various cases. */
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/* If WRITTEN is fully to the left of ERASED, check the next
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written memory_write_request. */
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if (written->end <= erased.begin)
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{
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++j;
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continue;
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}
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/* If WRITTEN is fully to the right of ERASED, then ERASED
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is not written at all. WRITTEN might affect other
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blocks. */
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if (written->begin >= erased.end)
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{
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VEC_safe_push (memory_write_request_s, result, &erased);
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goto next_erased;
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}
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/* If all of ERASED is completely written, we can move on to
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the next erased region. */
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if (written->begin <= erased.begin
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&& written->end >= erased.end)
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{
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goto next_erased;
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}
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/* If there is an unwritten part at the beginning of ERASED,
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then we should record that part and try this inner loop
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again for the remainder. */
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if (written->begin > erased.begin)
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{
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struct memory_write_request *n =
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VEC_safe_push (memory_write_request_s, result, NULL);
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memset (n, 0, sizeof (struct memory_write_request));
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n->begin = erased.begin;
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n->end = written->begin;
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erased.begin = written->begin;
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continue;
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}
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/* If there is an unwritten part at the end of ERASED, we
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forget about the part that was written to and wait to see
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if the next write request writes more of ERASED. We can't
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push it yet. */
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if (written->end < erased.end)
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{
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erased.begin = written->end;
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++j;
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continue;
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}
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}
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/* If we ran out of write requests without doing anything about
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ERASED, then that means it's really erased. */
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VEC_safe_push (memory_write_request_s, result, &erased);
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next_erased:
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;
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}
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return result;
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}
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static void
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cleanup_request_data (void *p)
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{
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VEC(memory_write_request_s) **v = p;
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struct memory_write_request *r;
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int i;
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for (i = 0; VEC_iterate (memory_write_request_s, *v, i, r); ++i)
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xfree (r->data);
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}
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static void
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cleanup_write_requests_vector (void *p)
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{
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VEC(memory_write_request_s) **v = p;
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VEC_free (memory_write_request_s, *v);
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}
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int
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target_write_memory_blocks (VEC(memory_write_request_s) *requests,
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enum flash_preserve_mode preserve_flash_p,
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void (*progress_cb) (ULONGEST, void *))
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{
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struct cleanup *back_to = make_cleanup (null_cleanup, NULL);
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VEC(memory_write_request_s) *blocks = VEC_copy (memory_write_request_s,
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requests);
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unsigned i;
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int err = 0;
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struct memory_write_request *r;
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VEC(memory_write_request_s) *regular = NULL;
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VEC(memory_write_request_s) *flash = NULL;
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VEC(memory_write_request_s) *erased, *garbled;
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/* END == 0 would represent wraparound: a write to the very last
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byte of the address space. This file was not written with that
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possibility in mind. This is fixable, but a lot of work for a
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rare problem; so for now, fail noisily here instead of obscurely
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later. */
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for (i = 0; VEC_iterate (memory_write_request_s, requests, i, r); ++i)
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gdb_assert (r->end != 0);
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make_cleanup (cleanup_write_requests_vector, &blocks);
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/* Sort the blocks by their start address. */
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qsort (VEC_address (memory_write_request_s, blocks),
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VEC_length (memory_write_request_s, blocks),
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sizeof (struct memory_write_request), compare_block_starting_address);
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/* Split blocks into list of regular memory blocks,
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and list of flash memory blocks. */
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make_cleanup (cleanup_write_requests_vector, ®ular);
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make_cleanup (cleanup_write_requests_vector, &flash);
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split_regular_and_flash_blocks (blocks, ®ular, &flash);
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/* If a variable is added to forbid flash write, even during "load",
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it should be checked here. Similarly, if this function is used
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for other situations besides "load" in which writing to flash
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is undesirable, that should be checked here. */
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/* Find flash blocks to erase. */
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erased = blocks_to_erase (flash);
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make_cleanup (cleanup_write_requests_vector, &erased);
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/* Find what flash regions will be erased, and not overwritten; then
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either preserve or discard the old contents. */
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garbled = compute_garbled_blocks (erased, flash);
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make_cleanup (cleanup_request_data, &garbled);
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make_cleanup (cleanup_write_requests_vector, &garbled);
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if (!VEC_empty (memory_write_request_s, garbled))
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{
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if (preserve_flash_p == flash_preserve)
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{
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struct memory_write_request *r;
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/* Read in regions that must be preserved and add them to
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the list of blocks we read. */
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for (i = 0; VEC_iterate (memory_write_request_s, garbled, i, r); ++i)
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{
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gdb_assert (r->data == NULL);
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r->data = xmalloc (r->end - r->begin);
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err = target_read_memory (r->begin, r->data, r->end - r->begin);
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if (err != 0)
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goto out;
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VEC_safe_push (memory_write_request_s, flash, r);
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}
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qsort (VEC_address (memory_write_request_s, flash),
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VEC_length (memory_write_request_s, flash),
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sizeof (struct memory_write_request), compare_block_starting_address);
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}
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}
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/* We could coalesce adjacent memory blocks here, to reduce the
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number of write requests for small sections. However, we would
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have to reallocate and copy the data pointers, which could be
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large; large sections are more common in loadable objects than
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large numbers of small sections (although the reverse can be true
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in object files). So, we issue at least one write request per
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passed struct memory_write_request. The remote stub will still
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have the opportunity to batch flash requests. */
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/* Write regular blocks. */
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for (i = 0; VEC_iterate (memory_write_request_s, regular, i, r); ++i)
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{
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LONGEST len;
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len = target_write_with_progress (¤t_target,
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TARGET_OBJECT_MEMORY, NULL,
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r->data, r->begin, r->end - r->begin,
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progress_cb, r->baton);
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if (len < (LONGEST) (r->end - r->begin))
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{
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/* Call error? */
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err = -1;
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goto out;
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}
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}
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if (!VEC_empty (memory_write_request_s, erased))
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{
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/* Erase all pages. */
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for (i = 0; VEC_iterate (memory_write_request_s, erased, i, r); ++i)
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target_flash_erase (r->begin, r->end - r->begin);
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/* Write flash data. */
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for (i = 0; VEC_iterate (memory_write_request_s, flash, i, r); ++i)
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{
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LONGEST len;
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len = target_write_with_progress (¤t_target,
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TARGET_OBJECT_FLASH, NULL,
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r->data, r->begin, r->end - r->begin,
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progress_cb, r->baton);
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if (len < (LONGEST) (r->end - r->begin))
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error (_("Error writing data to flash"));
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}
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target_flash_done ();
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}
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out:
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do_cleanups (back_to);
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return err;
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}
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