Project

General

Profile

MMU description » History » Version 62

Alexander Kamkin, 03/07/2013 08:12 AM

1 24 Alexander Kamkin
h1. MMU Description
2 1 Taya Sergeeva
3 62 Alexander Kamkin
_~By Taya Sergeeva~_
4
5 35 Alexander Kamkin
A _memory management unit_ (_MMU_) is known to be one of the most complex and error-prone components of a modern microprocessor. MicroTESK has a special subsystem, called _MMU subsystem_, intended for (1) specifying memory devices and (2) deriving testing knowledge from such specifications. The subsystem provides unified facilities for describing memory buffers (like _L1_ and _L2 caches_, _translation look-aside buffers_ (_TLBs_), etc.) as well as a means for connecting several buffers into a memory hierarchy.
6 34 Alexander Kamkin
7 38 Alexander Kamkin
h2. Address Description
8
9 40 Alexander Kamkin
A buffer is accessed by an _address_, which is typically a _bit vector_ of a fixed length (width). Different buffers are allowed to have a common address space (e.g., L1 and L2 are usually both addressed by physical addresses). However, in general case, each buffer has its own domain.
10
11 60 Alexander Kamkin
An address space is described using a construct *address*. A few examples are given below.
12 38 Alexander Kamkin
13 1 Taya Sergeeva
<pre>
14 61 Alexander Kamkin
// The singleton.
15 56 Taya Sergeeva
address Void { width = 0;  }
16 45 Alexander Kamkin
</pre>
17 46 Alexander Kamkin
18 1 Taya Sergeeva
<pre>
19 61 Alexander Kamkin
// 40-bit physical addresses.
20
address PA { width = 40; }
21 38 Alexander Kamkin
</pre>
22 1 Taya Sergeeva
23
<pre>
24 61 Alexander Kamkin
// 64-bit virtual addresses.
25
address VA { width = 64; }
26 58 Alexander Kamkin
</pre>
27
28 59 Alexander Kamkin
The code above defines three address spaces: (1) a singleton @Void@; (2) a space @PA@ consisting of 40-bit addresses (_physical addresses_) and (3) a space @VA@ consisting of 64-bit addresses (_virtual addresses_).
29 10 Alexander Kamkin
30 2 Taya Sergeeva
h2. Buffer Description
31 1 Taya Sergeeva
32 57 Taya Sergeeva
Buffer is described by the construct *buffer*. Buffer can have different parameters, such as an associativity, a number of lines, the tag computing function, the index computing function, and the structure of data unit displacement, the controlling bits, the strategies of data changing when ''miss'' occurs, and so on. 
33 1 Taya Sergeeva
34 57 Taya Sergeeva
Let as consider a simple buffer which has only 2 attributes, such as the associativity, *sets*, i.e. the set''s size, and the number of sets in the buffer, *lines*. 
35
36 56 Taya Sergeeva
<pre>
37
buffer TLB 
38
{ 
39
  sets=8;
40
  lines=64;
41
} 
42 1 Taya Sergeeva
</pre>
43
44 57 Taya Sergeeva
The example above describes translation lookaside buffer (_TLB_), which has an associativity being equal to 8, (i.e. the number of lines in one set in this TLB buffer is equal to 8), and has the number of lines being equal to 64.   
45 56 Taya Sergeeva
46 57 Taya Sergeeva
Each *line* of the buffer can be described optionally by _tag_ and _data_ parameters. 
47 56 Taya Sergeeva
For example, 
48
49 1 Taya Sergeeva
<pre>
50 56 Taya Sergeeva
line = (tag:22, data:1024);
51 1 Taya Sergeeva
</pre>
52 56 Taya Sergeeva
53 1 Taya Sergeeva
describes lines of the cache, each of them containing a 22-bit tag and 1024-bit data.
54 56 Taya Sergeeva
55 57 Taya Sergeeva
In a MMU buffer also can have the *index* computing function. When accessing data, the cache determines a set by calculating a x-bit index. For example,
56 56 Taya Sergeeva
57 1 Taya Sergeeva
<pre>
58 57 Taya Sergeeva
index(addr:PA) = addr<14..13>;
59 1 Taya Sergeeva
</pre>
60
61 57 Taya Sergeeva
The cache calculates a 2-bit index. _index_ returns the initial and the final points of the field kept in bytes.
62 1 Taya Sergeeva
63 57 Taya Sergeeva
Each device stores some data which can be accessed (read from or written into) by their address. If a device contains a line with a given address, this situation is called a ''hit''; the opposite situation referes to as a ''miss''. If a ''miss'' occurs, the device usually displaces one of the set''s line with the line associated with the address given. The predicate which determines if there is a ''miss'' or ''hit'' situation is called *match*. There is the example below:
64
65 56 Taya Sergeeva
<pre>
66 57 Taya Sergeeva
line = (tag:22, data:1024);
67
match(addr:VA) = line.tag == addr<14..1>;
68 56 Taya Sergeeva
</pre>
69
70 57 Taya Sergeeva
If the set contains a line with the tag equal to the 22 upper bits of the physical address, this is a ''hit''. _match_ returns ''true'' if there is a ''hit'' in the line, and returns ''false'' otherwise.
71 56 Taya Sergeeva
72 57 Taya Sergeeva
The strategy which will be used for the lines displacement is specified by *policy*. 
73 56 Taya Sergeeva
74 57 Taya Sergeeva
<pre>
75
policy = LRU;
76
</pre>
77 56 Taya Sergeeva
78 57 Taya Sergeeva
Example above sets the strategy of data replacement to be _Last_ _Recently_ _Used_ policy, i.e. if the ''miss'' occured, the cache displaces the least-recently-used line of the set.
79 56 Taya Sergeeva
80 57 Taya Sergeeva
There is the example below, describing a real ''lower-level'' cache L1: 
81 2 Taya Sergeeva
82 53 Taya Sergeeva
<pre>
83
buffer L1 
84
{
85
	sets = 4;
86
	lines = 128;
87
	line = (tag:30, data:256);
88 10 Alexander Kamkin
	index(addr:PA) = addr<9..8>;
89 1 Taya Sergeeva
	match(addr:PA) = line.tag == addr<39..10>;
90
	policy = lru;
91
}
92
</pre>
93 19 Taya Sergeeva
94
_Description of each constructor_ in the buffer example is below:
95 49 Taya Sergeeva
96 21 Taya Sergeeva
h3. buffer
97 55 Taya Sergeeva
98 21 Taya Sergeeva
<pre>
99 1 Taya Sergeeva
  has a name, ''L1'' in our example; it can have names ''L2'' and ''TLB'' also;
100 51 Taya Sergeeva
  _buffer_ can be described by different parameters, such _sets_, _lines_, _index_, _match_, _policy_, and so on, which number is infixed;
101 16 Taya Sergeeva
</pre>
102 15 Taya Sergeeva
103 54 Taya Sergeeva
h3.  sets 
104 15 Taya Sergeeva
105 1 Taya Sergeeva
<pre>
106 49 Taya Sergeeva
  _sets_ is an associativity of a buffer; it returns the number of lines in a one set;
107 17 Taya Sergeeva
</pre>
108 15 Taya Sergeeva
109 54 Taya Sergeeva
h3.  lines
110 15 Taya Sergeeva
111 13 Taya Sergeeva
<pre>
112 49 Taya Sergeeva
  _lines_ is the number of sets in a given buffer;
113 1 Taya Sergeeva
</pre>
114 17 Taya Sergeeva
115 54 Taya Sergeeva
h3.  line
116
117 1 Taya Sergeeva
<pre>
118 52 Taya Sergeeva
  _line_ is an optional description of line''s fields;
119 54 Taya Sergeeva
  it designates each line of the cache; 
120 14 Taya Sergeeva
  _line_ includes its own parameters in the braces: _tag_ and _data_, each of them has an appropriate width of the fields kept in bytes;
121 1 Taya Sergeeva
  in our example _line_ has only two parameters, but in general case it can include more;
122
  it contains a 30-bit tag and a 256-bit data;
123 49 Taya Sergeeva
</pre>
124 17 Taya Sergeeva
125 54 Taya Sergeeva
h3.  index
126
127 1 Taya Sergeeva
<pre>
128
   _index_ is the function for index calculation;
129
   returns the initial and the final points of the field kept in bytes; they are marked in a three-cornered brackets, after _addr_; in our case index has 2 bits;
130
  _index_ depends on an _address_, which is ''physical'' (PA) in our case; the type of an address is set in the braces after _index_; 
131 49 Taya Sergeeva
</pre>
132 17 Taya Sergeeva
133 54 Taya Sergeeva
h3.  match 
134
135
<pre>
136 1 Taya Sergeeva
  _match_ is a predicate checking whether the line and the address match each other or not;
137
  it returns ''true'' or ''false'' depending on if the data required is in the given line or not; 
138 52 Taya Sergeeva
  it returns ''true'' if there is a ''hit'' in the line, and returns ''false'' otherwise; if the set contains a line with the tag equal to the 30 upper bits of the physical address, this is a ''hit''; if the set does not contain the line, this is a ''miss'' situation;
139 1 Taya Sergeeva
  _match_ description contains the the initial and the final points of the address field in the triangle brackets after _addr_; 
140
  as _index_ in the round braces _match_ also has the type of the address used; ''PA'' in our case;
141
</pre>
142 49 Taya Sergeeva
143 1 Taya Sergeeva
h3.  policy
144 54 Taya Sergeeva
145 56 Taya Sergeeva
<pre>
146 52 Taya Sergeeva
  _policy_ is the strategy of data displacement; 
147 1 Taya Sergeeva
  sets a policy which will be applied to our buffer, ''lru'' (Least Recently Used) in our example; 
148 25 Alexander Kamkin
  policy also can be ''plru'' (Pseudo LRU) and ''fifo'' (First Input First Out).
149
</pre>
150
151
h2. Code Structure
152
153
The MMU grammar is in ru.ispras.microtesk.translator.mmu.grammar folder. It contains Lexer, Parser and TreeWalker files. These files can be compiled by build.xml file (microtesk++/build.xml). The files generated (MMULexer.java, MMUParser.java, MMUTreeWalker.java) are in microtesk++.gen.ru.ispras.microtesk.translator.mmu.grammar folder. 
154
155
The folders ru.ispras.microtesk.translator.mmu.ir.* contain the inner representation of the MMU hierarchy of one buffer.  
156 1 Taya Sergeeva
157
MMU translator is in the ru.ispras.microtesk.translator.mmu.translator folder. 
158 26 Alexander Kamkin
159
Files in ru.ispras.microtesk.model.api.mmu folder contain different policies of cache. Folder ru.ispras.microtesk.model.api.mmu.buffer contains the model of MMU - the files which describe Buffer, Set, Line, Address expressions.  
160 1 Taya Sergeeva
161
After grammar files being generated the file ''BufferExample'' can be loaded to the translator.