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Alexander Kamkin, 12/01/2014 02:27 PM


MMU Description

By Alexander Kamkin and Taya Sergeeva

UNDER CONSTRUCTION

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.

Grammar

startRule 
    : bufferOrAddress*
    ;

bufferOrAddress
    : address
    | buffer
    ;

Address Description

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.

An address space is described using a keyword address. The width and format optional parameters can be specified inside the address space definition.

Grammar

address
    : ''address'' ID ''{''
        (addressParameter '';'')*
      ''}''
    ;

addressParameter
    : width
    | format
    ;

Address Width Parameter

The width parameter specifies the address width. The parameter is optional. The default value is 0.

Grammar

width
    : ''width'' ''='' expr
    ;

Address Format Parameter

The format parameter specifies the address format (a number of named fields). The parameter is optional. By default, the address is unstructured.

Grammar

format
    : ''format'' ''='' ''(''
        field ('','' field)*
      '')''
    ;

field
    : ID '':'' expr (''='' expr)?
    ;

Examples

// The singleton.
address Void {
  width = 0;
}
// An unstructured 64-bit virtual addresses.
address VA {
  width = 64;
}
// A stuctured 40-bit physical addresses.
address PA {
  width = 40;
  format = (tag:24, l1Index:7, dwPosition:2, bytePosition:3);
}

The code above defines three address spaces: (1) a singleton Void; (2) a space VA consisting of 64-bit addresses (virtual addresses) and (3) a space PA consisting of 40-bit addresses (physical addresses), each being divided into for fields: tag (24 bits), l1Index (7 bits), dwPosition (2 bits) and bytePosition (3 bits).

Address Description Grammar

Buffer Description

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.

Let as consider a simple buffer which has only 2 attributes, such as the associativity, associativity, i.e. the set''s size, and the number of sets in the buffer, sets.

buffer TLB 
{ 
  associativity=8;
  sets=64;
} 

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.

Each line of the buffer can be described optionally by tag and data parameters.
For example,

line = (tag:22, data:1024);

describes lines of the cache, each of them containing a 22-bit tag and 1024-bit data.

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,

index(addr:PA) = addr<14..13>;

The cache calculates a 2-bit index. index returns the initial and the final points of the field kept in bytes.

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:

line = (tag:22, data:1024);
match(addr:VA) = line.tag == addr<14..1>;

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.

The strategy which will be used for the lines displacement is specified by policy.

policy = LRU;

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.

There is the example below, describing a real ''lower-level'' cache L1:

buffer L1 
{
    associativity = 4;
    sets = 128;
    line = (tag:30, data:256);
    index(addr:PA) = addr<9..8>;
    match(addr:PA) = line.tag == addr<39..10>;
    policy = lru;
}

Description of each constructor in the buffer example is below:

buffer

  has a name, ''L1'' in our example; it can have names ''L2'' and ''TLB'' also;
  _buffer_ can be described by different parameters, such _associativity_, _sets_, _index_, _match_, _policy_, and so on, which number is infixed;

associativity

  _associativity_ is an associativity of a buffer; it returns the number of lines in a one set;

sets

  _sets_ is the number of sets in a given buffer;

line

  _line_ is an optional description of line''s fields;
  it designates each line of the cache; 
  _line_ includes its own parameters in the braces: _tag_ and _data_, each of them has an appropriate width of the fields kept in bytes;
  in our example _line_ has only two parameters, but in general case it can include more;
  it contains a 30-bit tag and a 256-bit data;

index

   _index_ is the function for index calculation;
   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;
  _index_ depends on an _address_, which is ''physical'' (PA) in our case; the type of an address is set in the braces after _index_; 

match

  _match_ is a predicate checking whether the line and the address match each other or not;
  it returns ''true'' or ''false'' depending on if the data required is in the given line or not; 
  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;
  _match_ description contains the the initial and the final points of the address field in the triangle brackets after _addr_; 
  as _index_ in the round braces _match_ also has the type of the address used; ''PA'' in our case;

policy

  _policy_ is the strategy of data displacement; 
  sets a policy which will be applied to our buffer, ''lru'' (Least Recently Used) in our example; 
  policy also can be ''plru'' (Pseudo LRU) and ''fifo'' (First Input First Out).

Code Structure

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.

The folders ru.ispras.microtesk.translator.mmu.ir.* contain the inner representation of the MMU hierarchy of one buffer.

MMU translator is in the ru.ispras.microtesk.translator.mmu.translator folder.

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.

After grammar files being generated the file ''BufferExample'' can be loaded to the translator.

Updated by Alexander Kamkin almost 10 years ago · 132 revisions