Cache : Direct Mapping ,Assosiate Mapping & Set Assosiate Mapping

Syed Muhammad Ali Raza - Oct 15 '23 - - Dev Community

Introduction:

Effective data management is essential to improve performance in operational systems. Cache, which is used to store frequently accessed data for quick retrieval, plays an important role in improving system responsiveness. The three common types of caches used are direct mapping, associative mapping, and set-associative mapping. In this article, we will explore each method, providing examples and real-life coding scenarios to illustrate their applications.

Direct mapping:

Direct mapping is a mapping technique where each block of main memory is mapped to only one cache. The mapping is determined using a hash function or simple arithmetic. This simplicity makes direct mapping easy to implement, but it can lead to cache misses in locations that block large amounts of memory.

Example:

Consider 8 cache blocks and 32 main memory blocks. Mapping can be done like this:

  • Map cache block 0 to main memory block 0
  • Cache block 1 maps to main memory block 8
  • Map cache block 2 to main memory block 16
def direct_mapping_cache(memory_block, cache_size):
    block your memory % cache_size

# Examples of usage:
cache_size = 8
main_memory block = 16
cache_block = direct_mapping_cache (block_memory_block, size_cache)
print (f "map memory block {main_memory_block} to Block Cache {map {block}");
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Associative mapping:

In Associative Mapping, any main memory block can be mapped to any cache image. Mapping is done using tags associated with each person. This flexibility eliminates the conflict problem, but adds complexity to finding specific blocks in the cache.

Example:

Adopt a character that combines all 4 blocks. The cache can accommodate blocks of main memory:

CacheEntry class:
    def __init__ ( self , label , data ):
        self.tag = tag
        self.data = data

def Associative_mapping_cache(memory_blocking, cache):
    To log in as a guest:
        if enter.tag == memory_block:
            opening

# Examples of usage:
cache_size = 4
cache = [CacheEntry(5, "Data1"), CacheEntry(12, "Data2"), CacheEntry(8, "Data3")]

memory_block_to_find = 12
cache_entry = Associative_mapping_cache ( cache_block_to_find , cache )
print(f "data in cache for memory block {memory_block_to_find}: pain cache_entry.data}");
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Set-Associative Mapping:

Set-associative Mapping combines the direct and associative aspects of mapping. The cache is divided into sets, and each set contains several blocks. Each block in main memory can be mapped to any block in a given set. It strikes a balance between simplicity and flexibility, alleviating some of the problems encountered with direct mapping.

Example:

Consider the 2-way 4-set associative representation:

CacheSet class:
    def __init__ ( self ):
        self.entry = []

def set_associative_mapping_cache(blocking_memori, cachecaches, associative):
    set_index = block_memori%len (cache_sets)
    target_set = cache_sets [set_index]

    To access target_set.entry:
        if enter.tag == memory_block:
            opening

# Examples of usage:
association = 2
cache_sets = [CacheSet() for range(4)]
cache_sets [0]. entry = [CacheEntry(5,"Data1"), CacheEntry(12,"Data2")]

memory_block_to_find = 12
cache_entry = set_associative_mapping_cache (cache_block_to_find, cache_sets, associative)
print(f "data in cache for memory block {memory_block_to_find}: pain cache_entry.data}");
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In this example, a block of memory is mapped to a specific set and then the desired block is searched, providing a compromise between the simplicity of direct set mapping and the flexibility of associative maps.

In conclusion, understanding this type of cache is important to design an efficient memory management system in the operating system. Each mapping method comes with trade-offs, and the choice depends on the specific system requirements. Whether it is the simplicity of direct mapping, the flexibility of associative mapping, or the compactness of associative mapping, these cache patterns play an important role in improving the performance of modern computing systems.

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