xref: /freebsd/contrib/llvm-project/lldb/source/Target/Memory.cpp (revision 06c3fb2749bda94cb5201f81ffdb8fa6c3161b2e)
1 //===-- Memory.cpp --------------------------------------------------------===//
2 //
3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4 // See https://llvm.org/LICENSE.txt for license information.
5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6 //
7 //===----------------------------------------------------------------------===//
8 
9 #include "lldb/Target/Memory.h"
10 #include "lldb/Target/Process.h"
11 #include "lldb/Utility/DataBufferHeap.h"
12 #include "lldb/Utility/LLDBLog.h"
13 #include "lldb/Utility/Log.h"
14 #include "lldb/Utility/RangeMap.h"
15 #include "lldb/Utility/State.h"
16 
17 #include <cinttypes>
18 #include <memory>
19 
20 using namespace lldb;
21 using namespace lldb_private;
22 
23 // MemoryCache constructor
MemoryCache(Process & process)24 MemoryCache::MemoryCache(Process &process)
25     : m_mutex(), m_L1_cache(), m_L2_cache(), m_invalid_ranges(),
26       m_process(process),
27       m_L2_cache_line_byte_size(process.GetMemoryCacheLineSize()) {}
28 
29 // Destructor
30 MemoryCache::~MemoryCache() = default;
31 
Clear(bool clear_invalid_ranges)32 void MemoryCache::Clear(bool clear_invalid_ranges) {
33   std::lock_guard<std::recursive_mutex> guard(m_mutex);
34   m_L1_cache.clear();
35   m_L2_cache.clear();
36   if (clear_invalid_ranges)
37     m_invalid_ranges.Clear();
38   m_L2_cache_line_byte_size = m_process.GetMemoryCacheLineSize();
39 }
40 
AddL1CacheData(lldb::addr_t addr,const void * src,size_t src_len)41 void MemoryCache::AddL1CacheData(lldb::addr_t addr, const void *src,
42                                  size_t src_len) {
43   AddL1CacheData(
44       addr, DataBufferSP(new DataBufferHeap(DataBufferHeap(src, src_len))));
45 }
46 
AddL1CacheData(lldb::addr_t addr,const DataBufferSP & data_buffer_sp)47 void MemoryCache::AddL1CacheData(lldb::addr_t addr,
48                                  const DataBufferSP &data_buffer_sp) {
49   std::lock_guard<std::recursive_mutex> guard(m_mutex);
50   m_L1_cache[addr] = data_buffer_sp;
51 }
52 
Flush(addr_t addr,size_t size)53 void MemoryCache::Flush(addr_t addr, size_t size) {
54   if (size == 0)
55     return;
56 
57   std::lock_guard<std::recursive_mutex> guard(m_mutex);
58 
59   // Erase any blocks from the L1 cache that intersect with the flush range
60   if (!m_L1_cache.empty()) {
61     AddrRange flush_range(addr, size);
62     BlockMap::iterator pos = m_L1_cache.upper_bound(addr);
63     if (pos != m_L1_cache.begin()) {
64       --pos;
65     }
66     while (pos != m_L1_cache.end()) {
67       AddrRange chunk_range(pos->first, pos->second->GetByteSize());
68       if (!chunk_range.DoesIntersect(flush_range))
69         break;
70       pos = m_L1_cache.erase(pos);
71     }
72   }
73 
74   if (!m_L2_cache.empty()) {
75     const uint32_t cache_line_byte_size = m_L2_cache_line_byte_size;
76     const addr_t end_addr = (addr + size - 1);
77     const addr_t first_cache_line_addr = addr - (addr % cache_line_byte_size);
78     const addr_t last_cache_line_addr =
79         end_addr - (end_addr % cache_line_byte_size);
80     // Watch for overflow where size will cause us to go off the end of the
81     // 64 bit address space
82     uint32_t num_cache_lines;
83     if (last_cache_line_addr >= first_cache_line_addr)
84       num_cache_lines = ((last_cache_line_addr - first_cache_line_addr) /
85                          cache_line_byte_size) +
86                         1;
87     else
88       num_cache_lines =
89           (UINT64_MAX - first_cache_line_addr + 1) / cache_line_byte_size;
90 
91     uint32_t cache_idx = 0;
92     for (addr_t curr_addr = first_cache_line_addr; cache_idx < num_cache_lines;
93          curr_addr += cache_line_byte_size, ++cache_idx) {
94       BlockMap::iterator pos = m_L2_cache.find(curr_addr);
95       if (pos != m_L2_cache.end())
96         m_L2_cache.erase(pos);
97     }
98   }
99 }
100 
AddInvalidRange(lldb::addr_t base_addr,lldb::addr_t byte_size)101 void MemoryCache::AddInvalidRange(lldb::addr_t base_addr,
102                                   lldb::addr_t byte_size) {
103   if (byte_size > 0) {
104     std::lock_guard<std::recursive_mutex> guard(m_mutex);
105     InvalidRanges::Entry range(base_addr, byte_size);
106     m_invalid_ranges.Append(range);
107     m_invalid_ranges.Sort();
108   }
109 }
110 
RemoveInvalidRange(lldb::addr_t base_addr,lldb::addr_t byte_size)111 bool MemoryCache::RemoveInvalidRange(lldb::addr_t base_addr,
112                                      lldb::addr_t byte_size) {
113   if (byte_size > 0) {
114     std::lock_guard<std::recursive_mutex> guard(m_mutex);
115     const uint32_t idx = m_invalid_ranges.FindEntryIndexThatContains(base_addr);
116     if (idx != UINT32_MAX) {
117       const InvalidRanges::Entry *entry = m_invalid_ranges.GetEntryAtIndex(idx);
118       if (entry->GetRangeBase() == base_addr &&
119           entry->GetByteSize() == byte_size)
120         return m_invalid_ranges.RemoveEntryAtIndex(idx);
121     }
122   }
123   return false;
124 }
125 
GetL2CacheLine(lldb::addr_t line_base_addr,Status & error)126 lldb::DataBufferSP MemoryCache::GetL2CacheLine(lldb::addr_t line_base_addr,
127                                                Status &error) {
128   // This function assumes that the address given is aligned correctly.
129   assert((line_base_addr % m_L2_cache_line_byte_size) == 0);
130 
131   std::lock_guard<std::recursive_mutex> guard(m_mutex);
132   auto pos = m_L2_cache.find(line_base_addr);
133   if (pos != m_L2_cache.end())
134     return pos->second;
135 
136   auto data_buffer_heap_sp =
137       std::make_shared<DataBufferHeap>(m_L2_cache_line_byte_size, 0);
138   size_t process_bytes_read = m_process.ReadMemoryFromInferior(
139       line_base_addr, data_buffer_heap_sp->GetBytes(),
140       data_buffer_heap_sp->GetByteSize(), error);
141 
142   // If we failed a read, not much we can do.
143   if (process_bytes_read == 0)
144     return lldb::DataBufferSP();
145 
146   // If we didn't get a complete read, we can still cache what we did get.
147   if (process_bytes_read < m_L2_cache_line_byte_size)
148     data_buffer_heap_sp->SetByteSize(process_bytes_read);
149 
150   m_L2_cache[line_base_addr] = data_buffer_heap_sp;
151   return data_buffer_heap_sp;
152 }
153 
Read(addr_t addr,void * dst,size_t dst_len,Status & error)154 size_t MemoryCache::Read(addr_t addr, void *dst, size_t dst_len,
155                          Status &error) {
156   if (!dst || dst_len == 0)
157     return 0;
158 
159   std::lock_guard<std::recursive_mutex> guard(m_mutex);
160   // FIXME: We should do a more thorough check to make sure that we're not
161   // overlapping with any invalid ranges (e.g. Read 0x100 - 0x200 but there's an
162   // invalid range 0x180 - 0x280). `FindEntryThatContains` has an implementation
163   // that takes a range, but it only checks to see if the argument is contained
164   // by an existing invalid range. It cannot check if the argument contains
165   // invalid ranges and cannot check for overlaps.
166   if (m_invalid_ranges.FindEntryThatContains(addr)) {
167     error.SetErrorStringWithFormat("memory read failed for 0x%" PRIx64, addr);
168     return 0;
169   }
170 
171   // Check the L1 cache for a range that contains the entire memory read.
172   // L1 cache contains chunks of memory that are not required to be the size of
173   // an L2 cache line. We avoid trying to do partial reads from the L1 cache to
174   // simplify the implementation.
175   if (!m_L1_cache.empty()) {
176     AddrRange read_range(addr, dst_len);
177     BlockMap::iterator pos = m_L1_cache.upper_bound(addr);
178     if (pos != m_L1_cache.begin()) {
179       --pos;
180     }
181     AddrRange chunk_range(pos->first, pos->second->GetByteSize());
182     if (chunk_range.Contains(read_range)) {
183       memcpy(dst, pos->second->GetBytes() + (addr - chunk_range.GetRangeBase()),
184              dst_len);
185       return dst_len;
186     }
187   }
188 
189   // If the size of the read is greater than the size of an L2 cache line, we'll
190   // just read from the inferior. If that read is successful, we'll cache what
191   // we read in the L1 cache for future use.
192   if (dst_len > m_L2_cache_line_byte_size) {
193     size_t bytes_read =
194         m_process.ReadMemoryFromInferior(addr, dst, dst_len, error);
195     if (bytes_read > 0)
196       AddL1CacheData(addr, dst, bytes_read);
197     return bytes_read;
198   }
199 
200   // If the size of the read fits inside one L2 cache line, we'll try reading
201   // from the L2 cache. Note that if the range of memory we're reading sits
202   // between two contiguous cache lines, we'll touch two cache lines instead of
203   // just one.
204 
205   // We're going to have all of our loads and reads be cache line aligned.
206   addr_t cache_line_offset = addr % m_L2_cache_line_byte_size;
207   addr_t cache_line_base_addr = addr - cache_line_offset;
208   DataBufferSP first_cache_line = GetL2CacheLine(cache_line_base_addr, error);
209   // If we get nothing, then the read to the inferior likely failed. Nothing to
210   // do here.
211   if (!first_cache_line)
212     return 0;
213 
214   // If the cache line was not filled out completely and the offset is greater
215   // than what we have available, we can't do anything further here.
216   if (cache_line_offset >= first_cache_line->GetByteSize())
217     return 0;
218 
219   uint8_t *dst_buf = (uint8_t *)dst;
220   size_t bytes_left = dst_len;
221   size_t read_size = first_cache_line->GetByteSize() - cache_line_offset;
222   if (read_size > bytes_left)
223     read_size = bytes_left;
224 
225   memcpy(dst_buf + dst_len - bytes_left,
226          first_cache_line->GetBytes() + cache_line_offset, read_size);
227   bytes_left -= read_size;
228 
229   // If the cache line was not filled out completely and we still have data to
230   // read, we can't do anything further.
231   if (first_cache_line->GetByteSize() < m_L2_cache_line_byte_size &&
232       bytes_left > 0)
233     return dst_len - bytes_left;
234 
235   // We'll hit this scenario if our read straddles two cache lines.
236   if (bytes_left > 0) {
237     cache_line_base_addr += m_L2_cache_line_byte_size;
238 
239     // FIXME: Until we are able to more thoroughly check for invalid ranges, we
240     // will have to check the second line to see if it is in an invalid range as
241     // well. See the check near the beginning of the function for more details.
242     if (m_invalid_ranges.FindEntryThatContains(cache_line_base_addr)) {
243       error.SetErrorStringWithFormat("memory read failed for 0x%" PRIx64,
244                                      cache_line_base_addr);
245       return dst_len - bytes_left;
246     }
247 
248     DataBufferSP second_cache_line =
249         GetL2CacheLine(cache_line_base_addr, error);
250     if (!second_cache_line)
251       return dst_len - bytes_left;
252 
253     read_size = bytes_left;
254     if (read_size > second_cache_line->GetByteSize())
255       read_size = second_cache_line->GetByteSize();
256 
257     memcpy(dst_buf + dst_len - bytes_left, second_cache_line->GetBytes(),
258            read_size);
259     bytes_left -= read_size;
260 
261     return dst_len - bytes_left;
262   }
263 
264   return dst_len;
265 }
266 
AllocatedBlock(lldb::addr_t addr,uint32_t byte_size,uint32_t permissions,uint32_t chunk_size)267 AllocatedBlock::AllocatedBlock(lldb::addr_t addr, uint32_t byte_size,
268                                uint32_t permissions, uint32_t chunk_size)
269     : m_range(addr, byte_size), m_permissions(permissions),
270       m_chunk_size(chunk_size)
271 {
272   // The entire address range is free to start with.
273   m_free_blocks.Append(m_range);
274   assert(byte_size > chunk_size);
275 }
276 
277 AllocatedBlock::~AllocatedBlock() = default;
278 
ReserveBlock(uint32_t size)279 lldb::addr_t AllocatedBlock::ReserveBlock(uint32_t size) {
280   // We must return something valid for zero bytes.
281   if (size == 0)
282     size = 1;
283   Log *log = GetLog(LLDBLog::Process);
284 
285   const size_t free_count = m_free_blocks.GetSize();
286   for (size_t i=0; i<free_count; ++i)
287   {
288     auto &free_block = m_free_blocks.GetEntryRef(i);
289     const lldb::addr_t range_size = free_block.GetByteSize();
290     if (range_size >= size)
291     {
292       // We found a free block that is big enough for our data. Figure out how
293       // many chunks we will need and calculate the resulting block size we
294       // will reserve.
295       addr_t addr = free_block.GetRangeBase();
296       size_t num_chunks = CalculateChunksNeededForSize(size);
297       lldb::addr_t block_size = num_chunks * m_chunk_size;
298       lldb::addr_t bytes_left = range_size - block_size;
299       if (bytes_left == 0)
300       {
301         // The newly allocated block will take all of the bytes in this
302         // available block, so we can just add it to the allocated ranges and
303         // remove the range from the free ranges.
304         m_reserved_blocks.Insert(free_block, false);
305         m_free_blocks.RemoveEntryAtIndex(i);
306       }
307       else
308       {
309         // Make the new allocated range and add it to the allocated ranges.
310         Range<lldb::addr_t, uint32_t> reserved_block(free_block);
311         reserved_block.SetByteSize(block_size);
312         // Insert the reserved range and don't combine it with other blocks in
313         // the reserved blocks list.
314         m_reserved_blocks.Insert(reserved_block, false);
315         // Adjust the free range in place since we won't change the sorted
316         // ordering of the m_free_blocks list.
317         free_block.SetRangeBase(reserved_block.GetRangeEnd());
318         free_block.SetByteSize(bytes_left);
319       }
320       LLDB_LOGV(log, "({0}) (size = {1} ({1:x})) => {2:x}", this, size, addr);
321       return addr;
322     }
323   }
324 
325   LLDB_LOGV(log, "({0}) (size = {1} ({1:x})) => {2:x}", this, size,
326             LLDB_INVALID_ADDRESS);
327   return LLDB_INVALID_ADDRESS;
328 }
329 
FreeBlock(addr_t addr)330 bool AllocatedBlock::FreeBlock(addr_t addr) {
331   bool success = false;
332   auto entry_idx = m_reserved_blocks.FindEntryIndexThatContains(addr);
333   if (entry_idx != UINT32_MAX)
334   {
335     m_free_blocks.Insert(m_reserved_blocks.GetEntryRef(entry_idx), true);
336     m_reserved_blocks.RemoveEntryAtIndex(entry_idx);
337     success = true;
338   }
339   Log *log = GetLog(LLDBLog::Process);
340   LLDB_LOGV(log, "({0}) (addr = {1:x}) => {2}", this, addr, success);
341   return success;
342 }
343 
AllocatedMemoryCache(Process & process)344 AllocatedMemoryCache::AllocatedMemoryCache(Process &process)
345     : m_process(process), m_mutex(), m_memory_map() {}
346 
347 AllocatedMemoryCache::~AllocatedMemoryCache() = default;
348 
Clear(bool deallocate_memory)349 void AllocatedMemoryCache::Clear(bool deallocate_memory) {
350   std::lock_guard<std::recursive_mutex> guard(m_mutex);
351   if (m_process.IsAlive() && deallocate_memory) {
352     PermissionsToBlockMap::iterator pos, end = m_memory_map.end();
353     for (pos = m_memory_map.begin(); pos != end; ++pos)
354       m_process.DoDeallocateMemory(pos->second->GetBaseAddress());
355   }
356   m_memory_map.clear();
357 }
358 
359 AllocatedMemoryCache::AllocatedBlockSP
AllocatePage(uint32_t byte_size,uint32_t permissions,uint32_t chunk_size,Status & error)360 AllocatedMemoryCache::AllocatePage(uint32_t byte_size, uint32_t permissions,
361                                    uint32_t chunk_size, Status &error) {
362   AllocatedBlockSP block_sp;
363   const size_t page_size = 4096;
364   const size_t num_pages = (byte_size + page_size - 1) / page_size;
365   const size_t page_byte_size = num_pages * page_size;
366 
367   addr_t addr = m_process.DoAllocateMemory(page_byte_size, permissions, error);
368 
369   Log *log = GetLog(LLDBLog::Process);
370   if (log) {
371     LLDB_LOGF(log,
372               "Process::DoAllocateMemory (byte_size = 0x%8.8" PRIx32
373               ", permissions = %s) => 0x%16.16" PRIx64,
374               (uint32_t)page_byte_size, GetPermissionsAsCString(permissions),
375               (uint64_t)addr);
376   }
377 
378   if (addr != LLDB_INVALID_ADDRESS) {
379     block_sp = std::make_shared<AllocatedBlock>(addr, page_byte_size,
380                                                 permissions, chunk_size);
381     m_memory_map.insert(std::make_pair(permissions, block_sp));
382   }
383   return block_sp;
384 }
385 
AllocateMemory(size_t byte_size,uint32_t permissions,Status & error)386 lldb::addr_t AllocatedMemoryCache::AllocateMemory(size_t byte_size,
387                                                   uint32_t permissions,
388                                                   Status &error) {
389   std::lock_guard<std::recursive_mutex> guard(m_mutex);
390 
391   addr_t addr = LLDB_INVALID_ADDRESS;
392   std::pair<PermissionsToBlockMap::iterator, PermissionsToBlockMap::iterator>
393       range = m_memory_map.equal_range(permissions);
394 
395   for (PermissionsToBlockMap::iterator pos = range.first; pos != range.second;
396        ++pos) {
397     addr = (*pos).second->ReserveBlock(byte_size);
398     if (addr != LLDB_INVALID_ADDRESS)
399       break;
400   }
401 
402   if (addr == LLDB_INVALID_ADDRESS) {
403     AllocatedBlockSP block_sp(AllocatePage(byte_size, permissions, 16, error));
404 
405     if (block_sp)
406       addr = block_sp->ReserveBlock(byte_size);
407   }
408   Log *log = GetLog(LLDBLog::Process);
409   LLDB_LOGF(log,
410             "AllocatedMemoryCache::AllocateMemory (byte_size = 0x%8.8" PRIx32
411             ", permissions = %s) => 0x%16.16" PRIx64,
412             (uint32_t)byte_size, GetPermissionsAsCString(permissions),
413             (uint64_t)addr);
414   return addr;
415 }
416 
DeallocateMemory(lldb::addr_t addr)417 bool AllocatedMemoryCache::DeallocateMemory(lldb::addr_t addr) {
418   std::lock_guard<std::recursive_mutex> guard(m_mutex);
419 
420   PermissionsToBlockMap::iterator pos, end = m_memory_map.end();
421   bool success = false;
422   for (pos = m_memory_map.begin(); pos != end; ++pos) {
423     if (pos->second->Contains(addr)) {
424       success = pos->second->FreeBlock(addr);
425       break;
426     }
427   }
428   Log *log = GetLog(LLDBLog::Process);
429   LLDB_LOGF(log,
430             "AllocatedMemoryCache::DeallocateMemory (addr = 0x%16.16" PRIx64
431             ") => %i",
432             (uint64_t)addr, success);
433   return success;
434 }
435