memory_system.doxygen revision 9264:1607119c36bb
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36# Author: Djordje Kovacevic
37
38/*! \page gem5MemorySystem Memory System in gem5
39
40  \tableofcontents
41
42  The document describes memory subsystem in gem5 with focus on program flow
43  during CPU’s simple memory transactions (read or write).
44
45
46  \section gem5_MS_MH MODEL HIERARCHY
47
48  Model that is used in this document consists of two out-of-order (O3)
49  ARM v7 CPUs with corresponding L1 data caches and Simple Memory. It is
50  created by running gem5 with the following parameters:
51
52  configs/example/fs.py --caches --cpu-type=arm_detailed --num-cpus=2
53
54  Gem5 uses Memory Objects (MemObject) derived objects as basic blocks for
55  building memory system. They are connected via ports with established
56  master/slave hierarchy. Data flow is initiated on master port while the
57  response messages and snoop queries appear on the slave port. The following
58  figure shows the hierarchy of Memory Objects used in this document:
59
60  \image html "gem5_MS_Fig1.PNG" "Memory Object hierarchy of the model" width=3cm
61
62  \section gem5_CPU CPU
63
64  It is not in the scope of this document to describe O3 CPU model in details, so
65  here are only a few relevant notes about the model:
66
67  <b>Read access </b>is initiated by sending message to the port towards DCache
68  object. If DCache rejects the message (for being blocked or busy) CPU will
69  flush the pipeline and the access will be re-attempted later on. The access
70  is completed upon receiving reply message (ReadRep) from DCache.
71
72  <b>Write access</b> is initiated by storing the request into store buffer whose
73  context is emptied and sent to DCache on every tick. DCache may also reject
74  the request. Write access is completed when write reply (WriteRep) message is
75  received from DCache.
76
77  Load & store buffers  (for read and write access) don’t impose any
78  restriction on the number of active memory accesses. Therefore, the maximum
79  number of outstanding CPU’s memory access requests is not limited by CPU
80  Memory Object but by underlying memory system model.
81
82  <b>Split memory access</b> is implemented.
83
84  The message that is sent by CPU contains memory type (Normal, Device, Strongly
85  Ordered and cachebility) of the accessed region. However, this is not being used
86  by the rest of the model that takes more simplified approach towards memory types.
87
88  \section gem5_DCache DATA CACHE OBJECT
89
90  Data Cache object implements a standard cache structure:
91
92  \image html "gem5_MS_Fig2.PNG" "DCache Memory Object" width=3cm
93
94  <b>Cached memory reads</b> that match particular cache tag (with Valid & Read
95  flags) will be completed (by sending ReadResp to CPU) after a configurable time.
96  Otherwise, the request is forwarded to Miss Status and Handling Register
97  (MSHR) block.
98
99  <b>Cached memory writes</b> that match particular cache tag (with Valid, Read
100  & Write flags) will be completed (by sending WriteResp CPU) after the same
101  configurable time. Otherwise, the request is forwarded to Miss Status and
102  Handling Register(MSHR) block.
103
104  <b>Uncached memory reads</b> are forwarded to MSHR block.
105
106  <b>Uncached memory writes</b> are forwarded to WriteBuffer block.
107
108  <b>Evicted (& dirty) cache lines</b> are forwarded to WriteBuffer block.
109
110  CPU’s access to Data Cache is blocked if any of the following is true:
111
112    - MSHR block is full. (The size of MSHR’s buffer is configurable.)
113
114    - Writeback block is full. (The size of the block’s buffer is
115    configurable.)
116
117    - The number of outstanding memory accesses against the same memory cache line
118    has reached configurable threshold value – see MSHR and Write Buffer for details.
119
120  Data Cache in block state will reject any request from slave port (from CPU)
121  regardless of whether it would result in cache hit or miss. Note that
122  incoming messages on master port (response messages and snoop requests)
123  are never rejected.
124
125  Cache hit on uncachable memory region (unpredicted behaviour according to
126  ARM ARM) will invalidate cache line and fetch data from memory.
127
128  \subsection gem5_MS_TAndDBlock Tags & Data Block
129
130  Cache lines (referred as blocks in source code) are organised into sets with
131  configurable associativity and size. They have the following status flags:
132    - <b>Valid.</b> It holds data. Address tag is valid
133    - <b>Read.</b> No read request will be accepted without this flag being set.
134      For example, cache line is valid and unreadable when it waits for write flag
135      to complete write access.
136    - <b>Write.</b> It may accept writes. Cache line with Write flags
137      identifies Unique state – no other cache memory holds the copy.
138    - <b>Dirty.</b> It needs Writeback when evicted.
139
140  Read access will hit cache line if address tags match and Valid and Read
141  flags are set. Write access will hit cache line if address tags match and
142  Valid, Read and Write flags are set.
143
144  \subsection gem5_MS_Queues MSHR and Write Buffer Queues
145
146  Miss Status and Handling Register (MSHR) queue holds the list of CPU’s
147  outstanding memory requests that require read access to lower memory
148  level. They are:
149    - Cached Read misses.
150    - Cached Write misses.
151    - Uncached reads.
152
153  WriteBuffer queue holds the following memory requests:
154    - Uncached writes.
155    - Writeback from evicted (& dirty) cache lines.
156
157  \image html "gem5_MS_Fig3.PNG" "MSHR and Write Buffer Blocks" width=6cm
158
159  Each memory request is assigned to corresponding MSHR object (READ or WRITE
160  on diagram above) that represents particular block (cache line) of memory
161  that has to be read or written in order to complete the command(s). As shown
162  on gigure above, cached read/writes against the same cache line have a common
163  MSHR object and will be completed with a single memory access.
164
165  The size of the block (and therefore the size of read/write access to lower
166  memory) is:
167    - The size of cache line for cached access & writeback;
168    - As specified in CPU instruction for uncached access.
169
170  In general, Data Cache model distinguishes between just two memory types:
171    - Normal Cached memory. It is always treated as write back, read and write
172      allocate.
173    - Normal uncached, Device and Strongly Ordered types are treated equally
174      (as uncached memory)
175
176  \subsection gem5_MS_Ordering Memory Access Ordering
177
178  An unique order number is assigned to each CPU read/write request(as they appear on
179  slave port). Order numbers of MSHR objects are copied from the first
180  assigned read/write.
181
182  Memory read/writes from each of these two queues are executed in order (according
183  to the assigned order number). When both queues are not empty the model will
184  execute memory read from MSHR block unless WriteBuffer is full. It will,
185  however, always preserve the order of read/writes on the same
186  (or overlapping) memory cache line (block).
187
188  In summary:
189    - Order of accesses to cached memory is not preserved unless they target
190      the same cache line. For example, the accesses #1, #5 & #10 will
191      complete simultaneously in the same tick (still in order). The access
192      #5 will complete before #3.
193    - Order of all uncached memory writes is preserved. Write#6 always
194      completes before Write#13.
195    - Order to all uncached memory reads is preserved. Read#2 always completes
196      before Read#8.
197    - The order of a read and a write uncached access is not necessarily
198      preserved  - unless their access regions overlap. Therefore, Write#6
199      always completes before Read#8 (they target the same memory block).
200      However, Write#13 may complete before Read#8.
201
202
203  \section gem5_MS_Bus COHERENT BUS OBJECT
204
205  \image html "gem5_MS_Fig4.PNG" "Coherent Bus Object" width=3cm
206
207  Coherent Bus object provides basic support for snoop protocol:
208
209  <b>All requests on the slave port</b> are forwarded to the appropriate master port. Requests
210  for cached memory regions are also forwarded to other slave ports (as snoop
211  requests).
212
213  <b>Master port replies</b> are forwarded to the appropriate slave port.
214
215  <b>Master port snoop requests</b> are forwarded to all slave ports.
216
217  <b>Slave port snoop replies</b> are forwarded to the port that was the source of the
218  request. (Note that the source of snoop request can be either slave or
219  master port.)
220
221  The bus declares itself blocked for a configurable period of time after
222  any of the following events:
223    - A packet is sent (or failed to be sent) to a slave port.
224    - A reply message is sent to a master port.
225    - Snoop response from one slave port is sent to another slave port.
226
227  The bus in blocked state rejects the following incoming messages:
228    - Slave port requests.
229    - Master port replies.
230    - Master port snoop requests.
231
232  \section gem5_MS_SimpleMemory SIMPLE MEMORY OBJECT
233
234  It never blocks the access on slave port.
235
236  Memory read/write takes immediate effect. (Read or write is performed when
237  the request is received).
238
239  Reply message is sent after a configurable period of time .
240
241  \section gem5_MS_MessageFlow MESSAGE FLOW
242
243  \subsection gem5_MS_Ordering Read Access
244
245  The following diagram shows read access that hits Data Cache line with Valid
246  and Read flags:
247
248  \image html "gem5_MS_Fig5.PNG" "Read Hit (Read flag must be set in cache line)" width=3cm
249
250  Cache miss read access will generate the following sequence of messages:
251
252  \image html "gem5_MS_Fig6.PNG" "Read Miss with snoop reply" width=3cm
253
254  Note that bus object never gets response from both DCache2 and Memory object.
255  It sends the very same ReadReq package (message) object to memory and data
256  cache. When Data Cache wants to reply on snoop request it marks the message
257  with MEM_INHIBIT flag that tells Memory object not to process the message.
258
259  \subsection gem5_MS_Ordering Write Access
260
261  The following diagram shows write access that hits DCache1 cache line with
262  Valid & Write flags:
263
264  \image html "gem5_MS_Fig7.PNG" "Write Hit (with Write flag set in cache line)" width=3cm
265
266  Next figure shows write access that hits DCache1 cache line with Valid but no
267  Write flags – which qualifies as write miss. DCache1 issues UpgradeReq to
268  obtain write permission. DCache2::snoopTiming will invalidate cache line that
269  has been hit. Note that UpgradeResp message doesn’t carry data.
270
271  \image html "gem5_MS_Fig8.PNG" "Write Miss – matching tag with no Write flag" width=3cm
272
273  The next diagram shows write miss in DCache. ReadExReq invalidates cache line
274  in DCache2. ReadExResp carries the content of memory cache line.
275
276  \image html "gem5_MS_Fig9.PNG" "Miss - no matching tag" width=3cm
277
278*/
279