1 /* Parts of target interface that deal with accessing memory and memory-like
4 Copyright (C) 2006-2018 Free Software Foundation, Inc.
6 This file is part of GDB.
8 This program is free software; you can redistribute it and/or modify
9 it under the terms of the GNU General Public License as published by
10 the Free Software Foundation; either version 3 of the License, or
11 (at your option) any later version.
13 This program is distributed in the hope that it will be useful,
14 but WITHOUT ANY WARRANTY; without even the implied warranty of
15 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
16 GNU General Public License for more details.
18 You should have received a copy of the GNU General Public License
19 along with this program. If not, see <http://www.gnu.org/licenses/>. */
24 #include "memory-map.h"
26 #include "gdb_sys_time.h"
30 compare_block_starting_address (const memory_write_request &a_req,
31 const memory_write_request &b_req)
33 return a_req.begin < b_req.begin;
36 /* Adds to RESULT all memory write requests from BLOCK that are
37 in [BEGIN, END) range.
39 If any memory request is only partially in the specified range,
40 that part of the memory request will be added. */
43 claim_memory (const std::vector<memory_write_request> &blocks,
44 std::vector<memory_write_request> *result,
48 ULONGEST claimed_begin;
51 for (const memory_write_request &r : blocks)
53 /* If the request doesn't overlap [BEGIN, END), skip it. We
54 must handle END == 0 meaning the top of memory; we don't yet
55 check for R->end == 0, which would also mean the top of
56 memory, but there's an assertion in
57 target_write_memory_blocks which checks for that. */
61 if (end != 0 && end <= r.begin)
64 claimed_begin = std::max (begin, r.begin);
68 claimed_end = std::min (end, r.end);
70 if (claimed_begin == r.begin && claimed_end == r.end)
71 result->push_back (r);
74 struct memory_write_request n = r;
76 n.begin = claimed_begin;
78 n.data += claimed_begin - r.begin;
80 result->push_back (n);
85 /* Given a vector of struct memory_write_request objects in BLOCKS,
86 add memory requests for flash memory into FLASH_BLOCKS, and for
87 regular memory to REGULAR_BLOCKS. */
90 split_regular_and_flash_blocks (const std::vector<memory_write_request> &blocks,
91 std::vector<memory_write_request> *regular_blocks,
92 std::vector<memory_write_request> *flash_blocks)
94 struct mem_region *region;
95 CORE_ADDR cur_address;
97 /* This implementation runs in O(length(regions)*length(blocks)) time.
98 However, in most cases the number of blocks will be small, so this does
101 Note also that it's extremely unlikely that a memory write request
102 will span more than one memory region, however for safety we handle
108 std::vector<memory_write_request> *r;
110 region = lookup_mem_region (cur_address);
111 r = region->attrib.mode == MEM_FLASH ? flash_blocks : regular_blocks;
112 cur_address = region->hi;
113 claim_memory (blocks, r, region->lo, region->hi);
115 if (cur_address == 0)
120 /* Given an ADDRESS, if BEGIN is non-NULL this function sets *BEGIN
121 to the start of the flash block containing the address. Similarly,
122 if END is non-NULL *END will be set to the address one past the end
123 of the block containing the address. */
126 block_boundaries (CORE_ADDR address, CORE_ADDR *begin, CORE_ADDR *end)
128 struct mem_region *region;
130 CORE_ADDR offset_in_region;
132 region = lookup_mem_region (address);
133 gdb_assert (region->attrib.mode == MEM_FLASH);
134 blocksize = region->attrib.blocksize;
136 offset_in_region = address - region->lo;
139 *begin = region->lo + offset_in_region / blocksize * blocksize;
141 *end = region->lo + (offset_in_region + blocksize - 1) / blocksize * blocksize;
144 /* Given the list of memory requests to be WRITTEN, this function
145 returns write requests covering each group of flash blocks which must
148 static std::vector<memory_write_request>
149 blocks_to_erase (const std::vector<memory_write_request> &written)
151 std::vector<memory_write_request> result;
153 for (const memory_write_request &request : written)
155 CORE_ADDR begin, end;
157 block_boundaries (request.begin, &begin, 0);
158 block_boundaries (request.end - 1, 0, &end);
160 if (!result.empty () && result.back ().end >= begin)
161 result.back ().end = end;
163 result.emplace_back (begin, end);
169 /* Given ERASED_BLOCKS, a list of blocks that will be erased with
170 flash erase commands, and WRITTEN_BLOCKS, the list of memory
171 addresses that will be written, compute the set of memory addresses
172 that will be erased but not rewritten (e.g. padding within a block
173 which is only partially filled by "load"). */
175 static std::vector<memory_write_request>
176 compute_garbled_blocks (const std::vector<memory_write_request> &erased_blocks,
177 const std::vector<memory_write_request> &written_blocks)
179 std::vector<memory_write_request> result;
182 unsigned je = written_blocks.size ();
184 /* Look at each erased memory_write_request in turn, and
185 see what part of it is subsequently written to.
187 This implementation is O(length(erased) * length(written)). If
188 the lists are sorted at this point it could be rewritten more
189 efficiently, but the complexity is not generally worthwhile. */
191 for (const memory_write_request &erased_iter : erased_blocks)
193 /* Make a deep copy -- it will be modified inside the loop, but
194 we don't want to modify original vector. */
195 struct memory_write_request erased = erased_iter;
197 for (j = 0; j != je;)
199 const memory_write_request *written = &written_blocks[j];
201 /* Now try various cases. */
203 /* If WRITTEN is fully to the left of ERASED, check the next
204 written memory_write_request. */
205 if (written->end <= erased.begin)
211 /* If WRITTEN is fully to the right of ERASED, then ERASED
212 is not written at all. WRITTEN might affect other
214 if (written->begin >= erased.end)
216 result.push_back (erased);
220 /* If all of ERASED is completely written, we can move on to
221 the next erased region. */
222 if (written->begin <= erased.begin
223 && written->end >= erased.end)
228 /* If there is an unwritten part at the beginning of ERASED,
229 then we should record that part and try this inner loop
230 again for the remainder. */
231 if (written->begin > erased.begin)
233 result.emplace_back (erased.begin, written->begin);
234 erased.begin = written->begin;
238 /* If there is an unwritten part at the end of ERASED, we
239 forget about the part that was written to and wait to see
240 if the next write request writes more of ERASED. We can't
242 if (written->end < erased.end)
244 erased.begin = written->end;
250 /* If we ran out of write requests without doing anything about
251 ERASED, then that means it's really erased. */
252 result.push_back (erased);
262 target_write_memory_blocks (const std::vector<memory_write_request> &requests,
263 enum flash_preserve_mode preserve_flash_p,
264 void (*progress_cb) (ULONGEST, void *))
266 std::vector<memory_write_request> blocks = requests;
267 std::vector<memory_write_request> regular;
268 std::vector<memory_write_request> flash;
269 std::vector<memory_write_request> erased, garbled;
271 /* END == 0 would represent wraparound: a write to the very last
272 byte of the address space. This file was not written with that
273 possibility in mind. This is fixable, but a lot of work for a
274 rare problem; so for now, fail noisily here instead of obscurely
276 for (const memory_write_request &iter : requests)
277 gdb_assert (iter.end != 0);
279 /* Sort the blocks by their start address. */
280 std::sort (blocks.begin (), blocks.end (), compare_block_starting_address);
282 /* Split blocks into list of regular memory blocks,
283 and list of flash memory blocks. */
284 split_regular_and_flash_blocks (blocks, ®ular, &flash);
286 /* If a variable is added to forbid flash write, even during "load",
287 it should be checked here. Similarly, if this function is used
288 for other situations besides "load" in which writing to flash
289 is undesirable, that should be checked here. */
291 /* Find flash blocks to erase. */
292 erased = blocks_to_erase (flash);
294 /* Find what flash regions will be erased, and not overwritten; then
295 either preserve or discard the old contents. */
296 garbled = compute_garbled_blocks (erased, flash);
298 std::vector<gdb::unique_xmalloc_ptr<gdb_byte>> mem_holders;
299 if (!garbled.empty ())
301 if (preserve_flash_p == flash_preserve)
303 /* Read in regions that must be preserved and add them to
304 the list of blocks we read. */
305 for (memory_write_request &iter : garbled)
307 gdb_assert (iter.data == NULL);
308 gdb::unique_xmalloc_ptr<gdb_byte> holder
309 ((gdb_byte *) xmalloc (iter.end - iter.begin));
310 iter.data = holder.get ();
311 mem_holders.push_back (std::move (holder));
312 int err = target_read_memory (iter.begin, iter.data,
313 iter.end - iter.begin);
317 flash.push_back (iter);
320 std::sort (flash.begin (), flash.end (),
321 compare_block_starting_address);
325 /* We could coalesce adjacent memory blocks here, to reduce the
326 number of write requests for small sections. However, we would
327 have to reallocate and copy the data pointers, which could be
328 large; large sections are more common in loadable objects than
329 large numbers of small sections (although the reverse can be true
330 in object files). So, we issue at least one write request per
331 passed struct memory_write_request. The remote stub will still
332 have the opportunity to batch flash requests. */
334 /* Write regular blocks. */
335 for (const memory_write_request &iter : regular)
339 len = target_write_with_progress (current_top_target (),
340 TARGET_OBJECT_MEMORY, NULL,
341 iter.data, iter.begin,
342 iter.end - iter.begin,
343 progress_cb, iter.baton);
344 if (len < (LONGEST) (iter.end - iter.begin))
351 if (!erased.empty ())
353 /* Erase all pages. */
354 for (const memory_write_request &iter : erased)
355 target_flash_erase (iter.begin, iter.end - iter.begin);
357 /* Write flash data. */
358 for (const memory_write_request &iter : flash)
362 len = target_write_with_progress (current_top_target (),
363 TARGET_OBJECT_FLASH, NULL,
364 iter.data, iter.begin,
365 iter.end - iter.begin,
366 progress_cb, iter.baton);
367 if (len < (LONGEST) (iter.end - iter.begin))
368 error (_("Error writing data to flash"));
371 target_flash_done ();