Difference between revisions of "L2 and Directory cache controller"

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Il Directory Controller è quel componente che si occupa della gestione della cache L2 (o LLC), in maniera tale da realizzare i meccanismi di coerenza e, sfruttando l'inclusività della L2, è possibile gestire contemporanemante anche la cache della Directory. Infatti se una linea di cache non è presente nella L2 non sarà presente in nessuna delle cache L1 e quindi risulta inutile avere la corrispettiva linea di cache della directory. Pertanto le informazioni della Cache Directory sono associate a quelle della cache L2.
+
The '''Directory controller''' manages the L2 cache and the ownership of memory lines, it is organized in a distributed directory structure.
 +
 
 +
== Introduction ==
 +
This component is composed of three stages, each one with particular tasks. This approach has been taken in order to manage the complexity of the component and to ease testing phase.
 +
 
 +
This component interfaces with the Network Interface in order to send/receive coherence requests.
 +
 
  
Così come si può dedurre dal codice, il Directory Controller può essere suddiviso in tre stage, che vedremo nel dettaglio in seguito.
 
  
 
[[File:L2_cache.jpg|Directory Controller]]
 
[[File:L2_cache.jpg|Directory Controller]]
  
Nel Directory Controller è presente anche un ulteriore componente trasversale, il TSHR, (transaction status handling registers) che si occupa della gestione delle richieste in sospeso.
+
== Stage 1 ==
 +
Stage 1 is responsible for issuing requests to the control logic. All requests are coherence request/response from the network interface.
 +
 
 +
=== TSHR Signals ===
 +
The arbiter checks if a pending request is already issued in the pipeline or ''ongoing'' in the TSHR (see [[L2 and Directory cache controller#TSHR Update Logic | TSHR Update Logic]]). Tags and sets for each type of request are forwarded from TSHR to the arbiter.
 +
TSHR entries are considered valid for that class of request if and only if its hit signal is asserted:
 +
 +
// Signals to TSHR
 +
assign ni_request_address                            = ni_request.memory_address;
 +
assign dc1_tshr_lookup_tag[REQUEST_TSHR_LOOKUP_PORT]  = ni_request_address.tag;
 +
assign dc1_tshr_lookup_set[REQUEST_TSHR_LOOKUP_PORT]  = ni_request_address.index;
 +
 +
// Signals from TSHR
 +
assign request_tshr_hit                              = tshr_lookup_hit[REQUEST_TSHR_LOOKUP_PORT];
 +
assign request_tshr_index                            = tshr_lookup_index[REQUEST_TSHR_LOOKUP_PORT];
 +
assign request_tshr_entry_info                        = tshr_lookup_entry_info[REQUEST_TSHR_LOOKUP_PORT];
  
Un'assunzione fondamentale relativa al Directory Controller è che in ogni momento può essere processata una sola richiesta per volta all'interno della pipe. La filosofia alla base della gestione delle richieste è che se una linea i trova in uno stato stabile, allora è memorizzata in cache, altrimenti nel TSHR.
+
=== Stall Protocol ROM ===
 +
In order to be compliant with the coherence protocol all incoming coherence requests on blocks whose coherence state is non-stable state have to be stalled. This task is performed through a protocol ROM whose output signal will stall the issue of that coherence request when asserted, e.g. when a block is in state S_D and a ''GetS'', ''GetM'' or a ''replacement'' request on the same block are stalled.
 +
In order to assert this signal the protocol ROM receives in input the type of the request, the state and the actual owner of the block:
  
Il Directory Controller si interfaccia con la Network Interface per la ricezione e l'invio di richieste e risposte.
+
assign dpr_state              = tshr_lookup_entry_info[REQUEST_TSHR_LOOKUP_PORT].state;
 +
assign dpr_message_type      = ni_request.packet_type;
 +
assign dpr_from_owner        = ni_request.source == request_tshr_entry_info.owner;
 +
 +
dc_stall_protocol_rom stall_protocol_rom (
 +
.input_state        ( dpr_state        ),
 +
.input_request      ( dpr_message_type ),
 +
.input_is_from_owner ( dpr_from_owner  ),
 +
.dpr_output_stall    ( stall_request    )
 +
);
  
== Stage 1 ==
+
Note that if the request does not come from the current owner it can be issued because it does not change the coherence state for the block (see [[L2 and Directory cache controller#Protocol ROM | Coherence Protocol]]).
Stage 1 is responsible for the issue of requests to controller. A request could be a replacement request from the local core or a coherence request/response from the network interface.
 
  
=== Issue Signals ===
+
=== Issuing a Request ===
In order to issue a request it is required that:
+
In order to issue a request, it is required that:
* TSHR is not full and has not issued the same request;  
+
* TSHR is not full and the address of the request is not already in the TSHR;  
 
* the network interface is available;
 
* the network interface is available;
* the other stages are not busy;
+
* further stages are not busy;
  
This is the case of a replacement request:
+
The following code shows the issuing logic case for a replacement request, other cases are similar:
  
 
  can_issue_replacement_request = !rp_empty &&  
 
  can_issue_replacement_request = !rp_empty &&  
 +
 
     !tshr_full && !replacement_request_tshr_hit &&
 
     !tshr_full && !replacement_request_tshr_hit &&
     ! (( dc2_pending ) ||( dc3_pending )) &&
+
 +
     ! (( dc2_pending ) || ( dc3_pending )) &&
 +
 
     ni_forwarded_request_network_available && ni_response_network_available;
 
     ni_forwarded_request_network_available && ni_response_network_available;
  
Line 30: Line 63:
 
* the network interface provides a valid request;
 
* the network interface provides a valid request;
 
* if the request is already in TSHR it has to be not valid;
 
* if the request is already in TSHR it has to be not valid;
* if the request is already in TSHR and valid it must not have been stalled by Protocol ROM (see [[L2 and Directory cache controller#Stall Signals|Stall Signals]]).
+
* if the request is already in TSHR and valid it must not have been stalled by Protocol ROM (see [[L2 and Directory cache controller#Stall Protocol ROM | Stall Signals]]).
  
 
The latter two are added in order to give priority to pending requests first.
 
The latter two are added in order to give priority to pending requests first.
  
  assign can_issue_request = ni_request_valid && !tshr_full &&  
+
  assign can_issue_request = ni_request_valid &&  
 +
 +
    !tshr_full &&  
 +
 
     ( !request_tshr_hit ||  
 
     ( !request_tshr_hit ||  
 
           ( request_tshr_hit  && !request_tshr_entry_info.valid) ||
 
           ( request_tshr_hit  && !request_tshr_entry_info.valid) ||
 
           ( request_tshr_hit && request_tshr_entry_info.valid  && !stall_request ) ) &&
 
           ( request_tshr_hit && request_tshr_entry_info.valid  && !stall_request ) ) &&
 +
 
     ! (( dc2_pending ) || ( dc3_pending )) &&
 
     ! (( dc2_pending ) || ( dc3_pending )) &&
 +
 
     ni_forwarded_request_network_available && ni_response_network_available;
 
     ni_forwarded_request_network_available && ni_response_network_available;
  
Finally in order to issue a response it is sufficient that the network interface has provided a valid response only:
+
Finally, responses are never stalled, those are elaborated whenever the network interface outputs a response:
  
 
  assign can_issue_response = ni_response_valid;
 
  assign can_issue_response = ni_response_valid;
 
=== TSHR Signals ===
 
In order to find out if a particular request is already issued, tag and sets for each type of request are provided to TSHR.
 
TSHR data respose are considered valid for that class of request if and only if its hit signal is asserted.
 
Here is the code for the class of coherence request signals:
 
 
// Signals to TSHR
 
assign ni_request_address = ni_request.memory_address;
 
assign dc1_tshr_lookup_tag[REQUEST_TSHR_LOOKUP_PORT] = ni_request_address.tag;
 
assign dc1_tshr_lookup_set[REQUEST_TSHR_LOOKUP_PORT] = ni_request_address.index;
 
 
// Signals from TSHR
 
assign request_tshr_hit = tshr_lookup_hit[REQUEST_TSHR_LOOKUP_PORT];
 
assign request_tshr_index = tshr_lookup_index[REQUEST_TSHR_LOOKUP_PORT];
 
assign request_tshr_entry_info = tshr_lookup_entry_info[REQUEST_TSHR_LOOKUP_PORT];
 
 
=== Stall Protocol ROM ===
 
In order to be compliant with the coherence protocol all incoming coherence requests on blocks whose state is in a particular non-stable state have to be stalled. This task is performed through a protocol ROM whose output signal will stall the issue of a coherence request if asserted, that is for example when a block is in state S D and a getS, getM or a replacement request for the same block is received.
 
In order to assert this signal the protocol ROM needs the type of the request, the state and the actual owner of the block:
 
 
assign dpr_state = tshr_lookup_entry_info[REQUEST_TSHR_LOOKUP_PORT].state;
 
assign dpr_message_type = ni_request.packet_type;
 
assign dpr_from_owner = ni_request.source == request_tshr_entry_info.owner;
 
 
dc_stall_protocol_rom stall_protocol_rom (
 
.input_state        ( dpr_state        ),
 
.input_request      ( dpr_message_type ),
 
.input_is_from_owner ( dpr_from_owner  ),
 
.dpr_output_stall    ( stall_request    )
 
);
 
  
 
=== Requests Scheduler ===
 
=== Requests Scheduler ===
Once the conditions for the issue have been verified, two or more requests could be ready at the same time so a scheduler must be used.  
+
Once the issuing conditions have been verified, two or more requests could be ready to be scheduled at the same time so a fixed-priority scheduler is used.  
 
In particular this scheduler uses fixed priorities set as below:
 
In particular this scheduler uses fixed priorities set as below:
  
# Replacement request
+
# replacement request
# Coherence response  
+
# coherence response  
# Coherence request
+
# coherence request
  
This ordering ensures the coherence is maintained ... (NON HO CPT LA FRASE " In particolare, nel caso in cui sia presente almeno una richiesta all'interno della Replacement Queue, essa sarà sempre prelevata ed eseguita con massima priorità al fine di preservare l'ordine di esecuzione delle istruzioni, che equivale a preservare la coerenza.")
+
This ordering ensures coherence is preserved. Once a type of request is scheduled this block drives the output signals for the second stage.
Once a type of request is scheduled this block drives conveniently the output signals for the second stage.
 
  
 
=== L2 Tag & Directory State Cache ===
 
=== L2 Tag & Directory State Cache ===
Finally there is a cache memory to store L2 tags and their directory state (recall that the directory is inclusive). The directory state is updated when the request is processed by stage 3.
+
Finally, a cache memory stores L2 tags and their directory state (recall that the directory is inclusive). The directory state is updated whenever a request is processed by Stage 3 and the protocol modifies it.
  
 
== Stage 2 ==
 
== Stage 2 ==
  
Stage 2 is responsible for managing L2 Data Cache and forwarding signals from Stage 1 to Stage 3. It simply contains the L2 Data Cache and all related logic for managing cache hits and block replacement. The policy used to replace a block is LRU (Least Recently Used).  
+
Stage 2 manages  L2 Data and Info caches, and forwards signals from Stage 1 to Stage 3. It also contains all related logic for managing cache hits and block replacement. The policy used to replace a block is LRU (Least Recently Used).  
  
The L2 Data Cache contains cache data and coherence data, i.e. owner and sharer list (the directory state is included in [[L2 and Directory cache controller#L2 Tag & Directory State Cache| L2 Directory State Cache]]).
+
The L2 cache contains cache data along with coherence information, i.e. the owner and sharers list (the directory state is included in [[L2 and Directory cache controller#L2 Tag & Directory State Cache| L2 Directory State Cache]]).
  
 
Stage 3 updates LRU and cache data once the request is processed.
 
Stage 3 updates LRU and cache data once the request is processed.
 +
 +
=== TSHR ===
 +
''Transaction Status Handling Register'' is used to track ongoing coherence transaction on scheduled memory blocks; whenever a memory line is in the TSHR it is in a non-stable state. <br>
 +
 +
A TSHR entry comprises the following information:
 +
 +
{| class="wikitable"
 +
|-
 +
! Valid
 +
! Address
 +
! State
 +
! Sharers list 
 +
! Owner
 +
|-
 +
|}
 +
 +
* Valid: entry is valid
 +
* Address: entry memory address
 +
* State: actual coherence state
 +
* Sharers list: list of sharers for the block (one-hot codified)
 +
* Owner: block owner
 +
 +
See [[L1_Cache_Controller#Implementation details |MSHR]]  for details about this module implementation.
  
 
== Stage 3 ==
 
== Stage 3 ==
Il compito fondamentale dello Stage 3 è quello di eseguire effettivamente la richiesta in ingresso attraverso i segnali provenienti dalla Protocol ROM. Prima di poter determinare i segnali di controllo in uscita bisogna selezionare opportunamente lo stato in ingresso. Ciò dipende da vari fattori:
+
Stage 3 is responsible for the actual execution of requests based on the protocol ROM. Once a request is processed, this module issues signals to the units in the above stages in order to update information and data in caches properly. Every group of signals to a particular unit is managed by a subsystem, each one represented in the picture below. Each subsystem is simply a combinatorial logic that "converts" signals from protocol ROM in proper commands to the relative unit.
  
* se c'è stato un cache hit, allora lo stato da processare viene prelevato dalla cache;
+
[[File:Stage3.png|800px|DC stage 3]]
* se c'è stato un TSHR hit, allora c'è una richesta pendente e bisogna prelevare lo stato dal TSHR;
 
* se c'è un replacement, allora bisogna prelevare lo stato dal messaggio stesso;
 
* se non si è verificato nessuno dei precedenti casi, allora lo stato è N, non presente in cache.
 
  
La selezione viene realizzata attraverso un scheduler a priorità fissa e l'uscita comprende informazioni relative alla coerenza (stato, sharerer list e owner) con in relativo indirizzo.
+
=== Current State Selector ===
 +
Before a coherence request is processed the correct source for cache block state has to be chosen. These data can be fetched from:
  
Le uscite della Protocol ROM sono molteplici e determinano tutte le principali azioni che svolge lo Stage 3: TSHR update, Cache update, PseudoLRU update e generazione dei messaggi.
+
* cache memory;
 +
* TSHR;
 +
* replacement queue;
  
[[File:Stage3.png|800px|DC stage 3]]
+
The following code shows how the control logic selects the information for the issued request:
 +
 
 +
always_comb begin
 +
if ( dc2_message_tshr_hit ) begin
 +
current_address      = dc2_message_address;
 +
current_state        = dc2_message_tshr_entry_info.state;
 +
current_sharers_list = dc2_message_tshr_entry_info.sharers_list;
 +
current_owner        = dc2_message_tshr_entry_info.owner;
 +
end else if ( dc2_message_cache_hit ) begin
 +
current_address      = dc2_message_address;
 +
current_state        = dc2_message_cache_state;
 +
current_sharers_list = dc2_message_cache_sharers_list;
 +
current_owner        = dc2_message_cache_owner;
 +
end else if (is_replacement) begin
 +
current_address      = dc2_message_address;
 +
current_state        = dc2_replacement_state;
 +
current_sharers_list = dc2_replacement_sharers_list;
 +
current_owner        = dc2_replacement_owner;
 +
end else begin
 +
current_address      = dc2_message_address;
 +
current_state        = {`DIRECTORY_STATE_WIDTH{1'b0}}; // State N
 +
current_sharers_list = {`TILE_COUNT{1'b0}};
 +
current_owner        = tile_address_t'(TILE_MEMORY_ID);
 +
end
 +
end
 +
 
 +
As shown in the above logic, if a TSHR hit occurs then the most updated information for that block are retrieved from the THSR. Otherwise, if a cache hit occurs the information required are fetched from the L2 cache. In case of replacement, those are retrieved from the replacement output signals from the previous stage. If none of the conditions above are met then cache block is considered in state N.
 +
 
 +
=== Protocol ROM ===
 +
This module implements the coherence protocol as represented in the figure below. It takes in input the current state and the request type and decodes the next actions.
 +
 
 +
[[File:MSI_Protocol_dc-rom_new.png|1600px]]
 +
 
 +
The coherence protocol used is MSI plus some changes due to the directory's inclusivity. In particular, a new stable state has been added, ''N'', meaning the block ''is not'' cached in the directory and has to be fetched from the main memory. The N state has been necessary since when a block reaches the stable state ''I'' states that the block ''is'' cached ''only'' by directory controller, and it is not present in any L1 cache, but the directory still has information on the block. While the directory has no information on blocks in state N.
 +
 
 +
Furthermore, new non-stable states have been added:
 +
 
 +
* state '''MN_A''' in which the directory controller is evicting the block which was in state M, and is waiting for an acknowledge message (MC_Ack) from the main memory. This might happens after a replacement request issued for that block. Further requests on the same block are ''stalled'' until data has been received from block owner and sent to the memory. Note that the block is ''invalidated'' so new access to the main memory is necessary;
 +
* state '''SN_A''' in which the directory controller is evicting the block which was in state S, and is waiting for an acknowledge message (MC_Ack) from the main memory. Similar to the '''MN_A''' state;
 +
* state '''NS_D''' in which the directory controller is waiting for data coming from the memory. This might occurs after an Fwd-getS request on a block in state N. Further requests on the same block are stalled until data has been received from the main memory and sent to requestor(s).
 +
 
 +
 
 +
For further details about the memory coherence protocol, please refer to:
 +
* ''[[MSI Protocol]]''
  
 
=== TSHR Update Logic ===
 
=== TSHR Update Logic ===
Line 118: Line 191:
 
* entry update.
 
* entry update.
  
TSHR is used to store cache lines data whose coherence transactions is yet pending. This is the case in which a cache line is in a non-stable state. So an entry allocation is made every time the cache line's state moves towards a non-stable state. In opposite way a deallocation is made when a cache line's state enters a stable state. Finally an update is made when there is something to change regarding the TSHR but cache line's state is yet non-stable.
+
TSHR is used to store cache lines data whose coherence transactions are ''ongoing''. This is the case in which a cache line is in a non-stable state. So an entry allocation is made every time the cache line's state moves towards a non-stable state. In the opposite way, deallocation is performed whenever a cache line's state enters a stable state. Finally, an update is made when there is something to change regarding the TSHR line but the cache line's state is non-stable yet:
  
 +
assign tshr_allocate    =  current_state_is_stable & !next_state_is_stable;
 +
assign tshr_deallocate  = !current_state_is_stable &  next_state_is_stable;
 +
assign tshr_update      = !current_state_is_stable & !next_state_is_stable & coherence_update_info_en;
  
La filosofia alla base della Directory è avere linee di cache valide quando lo stato è stabile, mentre avere la linea di cache allocata nel TSHR quando lo stato è instabile. Per allocare una linea nel TSHR, lo stato corrente deve essere stabile e il successivo no; condizione opposta per la deallocazione di una entry. L'aggiornamento, invece, avviene solo se stato corrente e successivo sono entrambi instabili e bisogna aggiornare una delle informazioni contenute al suo interno.  
+
Note that, if the operation is an entry allocation then the index of the first entry available is passed directly by the TSHR module. Remember that at this point there is surely an empty TSHR line otherwise the request would have not been issued (see [[L2 and Directory cache controller#Issue Signals | Issue Signals]]), since all pending requests are stalled when the TSHR is full.
  
Il segnale che valida un'operazione su TSHR è asserito ogni qual volta viene eseguita una qualsiasi operazione su TSHR.
+
In case of update or deallocation, the index of the entry is forwarded by Stage 1 (through Stage 2):
  
  assign coherence_update_info_en  =
+
  assign dc3_update_tshr_index = tshr_allocate ? tshr_empty_index : dc2_message_tshr_index;
  ( current_state != dpr_output.next_state ) | // cambiamento nello stato
 
  dpr_output.owner_clear | dpr_output.owner_set_requestor | dpr_output.sharers_add_owner | // cambiamento nell'owner
 
  dpr_output.sharers_add_requestor | dpr_output.sharers_clear | dpr_output.sharers_remove_requestor; // cambianento nella sharer list
 
  
assign tshr_allocate = current_state_is_stable && !next_state_is_stable,
+
=== Cache Update Logic ===
  tshr_update  = !current_state_is_stable & !next_state_is_stable & coherence_update_info_en,
+
Cache could be updated in three different ways:
  tshr_deallocate = !current_state_is_stable && next_state_is_stable;
 
  
assign dc3_update_tshr_entry_info.valid =( tshr_allocate | tshr_update ) & ~tshr_deallocate;  
+
* entry allocation;
assign dc3_update_tshr_enable  = dc2_message_valid && ( tshr_allocate || tshr_deallocate || tshr_update ) ;
+
* entry deallocation;
 +
* entry update.
  
=== Cache update ===
+
Unlike TSHR, the cache stores cache lines data whose coherence transactions are ''completed'', and the tracked ache line is considered in a stable state. So an entry allocation is made every time the cache line's state moves towards a stable state from non-stable and it was not already into the cache. In the opposite way, deallocation whenever a cache line's state enters a non-stable state, then it is tracked in the TSHR (see [[L2 and Directory cache controller#TSHR Update Logic | TSHR Update Logic]]). Finally, an update occurs whenever there is something to change regarding the cache line in compliance with the protocol ROM:
Per quanto riguarda la fase di Cache update è necessario definire attentamente quando allocare, deallocare o aggiornare una linea di cache. Ricordando che una linea si trova in cache se lo stato associato è stabile e si trova nel TSHR se lo stato è instabile, l'allocazione di una linea di cache avviene se si passa ad uno stato stabile che non sia N (ovvero la nuova linea di cache non sia invalida), mentre l'update avviene quando una linea era già presente nella cache e bisogna aggiornarne le informazioni (senza però passare ad uno stato instabile).
 
  
Le condizioni per la deallocazione di una linea di cache sono legate anche alla gestione del replacement. Essa avviene quando una linea passa dalla cache al TSHR o eliminata (stato N).
+
assign allocate_cache    = next_state_is_stable & ( coherence_update_info_en | dpr_output.store_data ) & ~(tshr_deallocate & dpr_output.invalidate_cache_way) & ~update_cache;
 +
assign deallocate_cache  = tshr_allocate & dc2_message_cache_hit ;
 +
assign update_cache      = current_state_is_stable & next_state_is_stable & dc2_message_cache_hit & ( coherence_update_info_en | dpr_output.store_data );
  
assign update_cache    = dc2_message_cache_hit & current_state_is_stable & next_state_is_stable & ( coherence_update_info_en | dpr_output.store_data );
+
=== Replacement Logic ===
assign deallocate_cache = ( tshr_allocate & dc2_message_cache_hit) ;
+
Whenever a replacement request occurs the current cache block is invalidated, but the entry is not freed. That is because the same cache line is replaced with a new valid one from a previous coherence request with the same set. The replaced cache block is queued in a replacement queue until Stage 1 issues it (replacement requests have the maximum priority and will be scheduled as soon as they are pending (see [[L2 and Directory cache controller#Requests Scheduler | Requests Scheduler]])).
assign allocate_cache    = next_state_is_stable & ( coherence_update_info_en | dpr_output.store_data ) & ~(tshr_deallocate & dpr_output.invalidate_cache_way);
 
  
assign dc3_update_cache_enable  = dc2_message_valid && !is_replacement && ( allocate_cache || update_cache || deallocate_cache ),
+
This module manages the replacement queue and allows a cache block to be enqueued whenever there is a replacement, this happens whenever the actual coherence request need to store data and info in cache memory, then the current request is not a replacement itself (''!is_replacement'') and a cache miss occurs:
  dc3_update_cache_validity_bit  = ~dpr_output.invalidate_cache_way,
 
  
Ora si consideri questa osservazione: il passaggio allo stato N avviene solo quando è stato eseguito un replacement (tale condizione è generica e non dipendente dal protocollo). Per rendere più efficiente la gestione del replacement, si evita di deallocare la linea di cache ad ogni replacement, sostituendola subito con la nuova entry (quindi già valida) e quella uscente verrà subito inserita nella Replacement Queue. Questa è la parte più delicata dell'aggiornamento della cache, perchè potenzialmente si legge contemporaneamente un dato dalla memoria (che va nella replacement queue), si invia un messaggio sulal rete e si alloca una linea nel TSHR.
+
assign do_replacement  = dc2_message_valid && dc2_message_cache_valid
 
+
        && ((allocate_cache || update_cache) && !deallocate_cache)  
=== Protocol ROM ===
+
        && !is_replacement
This module implements the coherence protocol as represented in figure below:
+
        && !dc2_message_cache_hit;
 
+
[[File:MSI_DC.jpg|1000px|MSI_DC]]
+
assign dc3_replacement_enqueue = dc2_message_valid && do_replacement;
 
 
The coherence protocol used is MSI plus some changes due to the directory's inclusivity. In particular, a new stable state has been added, ''N'', meaning the block ''is not'' cached in directory and has to be taken from off-chip memory. The adding of this state has been necessary because when a block reach the stable state ''I'' it is not updated automatically to off-chip memory until a replacement request for that block has been issued. So the stable state ''I'' means that the block ''is'' cached ''only'' by directory controller and that could have a more recent copy of that block than memory.
 
  
Furthermore other two non-stable states have been added:
+
Signal <code>dc2_message_cache_valid</code> states if the selected way stores a valid lane, if so this line has to be recalled if in state '''M''', and pushed back to the main memory. In case of hit in the case, expression <code>!dc2_message_cache_hit</code>, there is no need of replacement since the control logic is updating an existing line.
  
* state '''MN_A''' in which the directory controller is waiting for data from block owner in order to send it to the off-chip memory after a replacement request issued for that block. Subsequent requests on the same block are ''stalled'' until data has been received from block owner and sent to off-chip memory. Note that the block is ''invalidated'' so a new access to the off-chip memory has to be done;
+
=== Message Generator ===
* state '''NS_D''' in which the directory controller is waiting for data coming from off-chip memory in order to serve coherence request(s) for that block. Subsequent requests on the same block are stalled until data has been received from off-chip memory and sent to requestor(s).
+
This module sends forward or response messages to the network interface whenever is required by the protocol ROM:
  
=== Replacement Logic ===
+
dpr_output.message_response_send,
Così come si può evincere nel codice del protocollo adottato, negli eventi di replacement le linee di cache non vengono invalidate: questo perchè, come detto precedentemente, l'operazione di replacement  sostituisce subito la vecchia linea di cache con la nuova, evitando di passare attraverso la procedura di invalidazione della entry sovrascritta (quindi un'evenutale invalidazione invaliderebbe erroneamente la linea di cache già entrata).
+
        ...
 +
dpr_output.message_forwarded_send,
  
assign do_replacement = dc2_message_valid && update_cache && !dc2_message_cache_hit && dc2_message_cache_valid;
+
The above snippet shows the output of the protocol ROM related to the output message to generate. When <code>message_response_send</code> is asserted the directory sends a response over the network, dually, when <code>message_forwarded_send</code> is high, a forwarded is generated.
assign dc3_replacement_enqueue  = dc2_message_valid && do_replacement;
 
  
=== Generazione dei messaggi di uscita ===
+
Note that this block manages instruction cache misses as well. In such a case, requests are forwarded directly to memory bypassing the coherence logic.
I messaggi che possono essere generati possono essere di forward request o di response: quando e come generare tali messaggi è definito dal protocollo di coerenza.
 
  
 
== See Also ==
 
== See Also ==
[[L1_Cache_Controller#MSHR |TSHR]]
+
[[Coherence]]

Latest revision as of 10:12, 12 July 2019

The Directory controller manages the L2 cache and the ownership of memory lines, it is organized in a distributed directory structure.

Introduction

This component is composed of three stages, each one with particular tasks. This approach has been taken in order to manage the complexity of the component and to ease testing phase.

This component interfaces with the Network Interface in order to send/receive coherence requests.


Directory Controller

Stage 1

Stage 1 is responsible for issuing requests to the control logic. All requests are coherence request/response from the network interface.

TSHR Signals

The arbiter checks if a pending request is already issued in the pipeline or ongoing in the TSHR (see TSHR Update Logic). Tags and sets for each type of request are forwarded from TSHR to the arbiter. TSHR entries are considered valid for that class of request if and only if its hit signal is asserted:

// Signals to TSHR
assign ni_request_address                             = ni_request.memory_address;
assign dc1_tshr_lookup_tag[REQUEST_TSHR_LOOKUP_PORT]  = ni_request_address.tag;
assign dc1_tshr_lookup_set[REQUEST_TSHR_LOOKUP_PORT]  = ni_request_address.index;

// Signals from TSHR
assign request_tshr_hit                               = tshr_lookup_hit[REQUEST_TSHR_LOOKUP_PORT];
assign request_tshr_index                             = tshr_lookup_index[REQUEST_TSHR_LOOKUP_PORT];
assign request_tshr_entry_info                        = tshr_lookup_entry_info[REQUEST_TSHR_LOOKUP_PORT];

Stall Protocol ROM

In order to be compliant with the coherence protocol all incoming coherence requests on blocks whose coherence state is non-stable state have to be stalled. This task is performed through a protocol ROM whose output signal will stall the issue of that coherence request when asserted, e.g. when a block is in state S_D and a GetS, GetM or a replacement request on the same block are stalled. In order to assert this signal the protocol ROM receives in input the type of the request, the state and the actual owner of the block:

assign dpr_state              = tshr_lookup_entry_info[REQUEST_TSHR_LOOKUP_PORT].state;
assign dpr_message_type       = ni_request.packet_type;
assign dpr_from_owner         = ni_request.source == request_tshr_entry_info.owner;

dc_stall_protocol_rom stall_protocol_rom (
.input_state         ( dpr_state        ),
.input_request       ( dpr_message_type ),
.input_is_from_owner ( dpr_from_owner   ),
.dpr_output_stall    ( stall_request    )
);

Note that if the request does not come from the current owner it can be issued because it does not change the coherence state for the block (see Coherence Protocol).

Issuing a Request

In order to issue a request, it is required that:

  • TSHR is not full and the address of the request is not already in the TSHR;
  • the network interface is available;
  • further stages are not busy;

The following code shows the issuing logic case for a replacement request, other cases are similar:

can_issue_replacement_request = !rp_empty && 

   !tshr_full && !replacement_request_tshr_hit &&

   ! (( dc2_pending ) || ( dc3_pending )) &&

   ni_forwarded_request_network_available && ni_response_network_available;

A cache coherence request adds more constraints other than those above, that is:

  • the network interface provides a valid request;
  • if the request is already in TSHR it has to be not valid;
  • if the request is already in TSHR and valid it must not have been stalled by Protocol ROM (see Stall Signals).

The latter two are added in order to give priority to pending requests first.

assign can_issue_request = ni_request_valid && 

    !tshr_full && 

   ( !request_tshr_hit || 
          ( request_tshr_hit  && !request_tshr_entry_info.valid) ||
          ( request_tshr_hit && request_tshr_entry_info.valid  && !stall_request ) ) &&

   ! (( dc2_pending ) || ( dc3_pending )) &&

   ni_forwarded_request_network_available && ni_response_network_available;

Finally, responses are never stalled, those are elaborated whenever the network interface outputs a response:

assign can_issue_response = ni_response_valid;

Requests Scheduler

Once the issuing conditions have been verified, two or more requests could be ready to be scheduled at the same time so a fixed-priority scheduler is used. In particular this scheduler uses fixed priorities set as below:

  1. replacement request
  2. coherence response
  3. coherence request

This ordering ensures coherence is preserved. Once a type of request is scheduled this block drives the output signals for the second stage.

L2 Tag & Directory State Cache

Finally, a cache memory stores L2 tags and their directory state (recall that the directory is inclusive). The directory state is updated whenever a request is processed by Stage 3 and the protocol modifies it.

Stage 2

Stage 2 manages L2 Data and Info caches, and forwards signals from Stage 1 to Stage 3. It also contains all related logic for managing cache hits and block replacement. The policy used to replace a block is LRU (Least Recently Used).

The L2 cache contains cache data along with coherence information, i.e. the owner and sharers list (the directory state is included in L2 Directory State Cache).

Stage 3 updates LRU and cache data once the request is processed.

TSHR

Transaction Status Handling Register is used to track ongoing coherence transaction on scheduled memory blocks; whenever a memory line is in the TSHR it is in a non-stable state.

A TSHR entry comprises the following information:

Valid Address State Sharers list Owner
  • Valid: entry is valid
  • Address: entry memory address
  • State: actual coherence state
  • Sharers list: list of sharers for the block (one-hot codified)
  • Owner: block owner

See MSHR for details about this module implementation.

Stage 3

Stage 3 is responsible for the actual execution of requests based on the protocol ROM. Once a request is processed, this module issues signals to the units in the above stages in order to update information and data in caches properly. Every group of signals to a particular unit is managed by a subsystem, each one represented in the picture below. Each subsystem is simply a combinatorial logic that "converts" signals from protocol ROM in proper commands to the relative unit.

DC stage 3

Current State Selector

Before a coherence request is processed the correct source for cache block state has to be chosen. These data can be fetched from:

  • cache memory;
  • TSHR;
  • replacement queue;

The following code shows how the control logic selects the information for the issued request:

always_comb begin
	if ( dc2_message_tshr_hit ) begin
		current_address      = dc2_message_address;
		current_state        = dc2_message_tshr_entry_info.state;
		current_sharers_list = dc2_message_tshr_entry_info.sharers_list;
		current_owner        = dc2_message_tshr_entry_info.owner;
	end else if ( dc2_message_cache_hit ) begin
		current_address      = dc2_message_address;
		current_state        = dc2_message_cache_state;
		current_sharers_list = dc2_message_cache_sharers_list;
		current_owner        = dc2_message_cache_owner;
	end else if (is_replacement) begin
		current_address      = dc2_message_address;
		current_state        = dc2_replacement_state;
		current_sharers_list = dc2_replacement_sharers_list;
		current_owner        = dc2_replacement_owner;
	end else begin
		current_address      = dc2_message_address;
		current_state        = {`DIRECTORY_STATE_WIDTH{1'b0}}; // State N
		current_sharers_list = {`TILE_COUNT{1'b0}};
		current_owner        = tile_address_t'(TILE_MEMORY_ID);
	end
end

As shown in the above logic, if a TSHR hit occurs then the most updated information for that block are retrieved from the THSR. Otherwise, if a cache hit occurs the information required are fetched from the L2 cache. In case of replacement, those are retrieved from the replacement output signals from the previous stage. If none of the conditions above are met then cache block is considered in state N.

Protocol ROM

This module implements the coherence protocol as represented in the figure below. It takes in input the current state and the request type and decodes the next actions.

MSI Protocol dc-rom new.png

The coherence protocol used is MSI plus some changes due to the directory's inclusivity. In particular, a new stable state has been added, N, meaning the block is not cached in the directory and has to be fetched from the main memory. The N state has been necessary since when a block reaches the stable state I states that the block is cached only by directory controller, and it is not present in any L1 cache, but the directory still has information on the block. While the directory has no information on blocks in state N.

Furthermore, new non-stable states have been added:

  • state MN_A in which the directory controller is evicting the block which was in state M, and is waiting for an acknowledge message (MC_Ack) from the main memory. This might happens after a replacement request issued for that block. Further requests on the same block are stalled until data has been received from block owner and sent to the memory. Note that the block is invalidated so new access to the main memory is necessary;
  • state SN_A in which the directory controller is evicting the block which was in state S, and is waiting for an acknowledge message (MC_Ack) from the main memory. Similar to the MN_A state;
  • state NS_D in which the directory controller is waiting for data coming from the memory. This might occurs after an Fwd-getS request on a block in state N. Further requests on the same block are stalled until data has been received from the main memory and sent to requestor(s).


For further details about the memory coherence protocol, please refer to:

TSHR Update Logic

TSHR could be updated in three different ways:

  • entry allocation;
  • entry deallocation;
  • entry update.

TSHR is used to store cache lines data whose coherence transactions are ongoing. This is the case in which a cache line is in a non-stable state. So an entry allocation is made every time the cache line's state moves towards a non-stable state. In the opposite way, deallocation is performed whenever a cache line's state enters a stable state. Finally, an update is made when there is something to change regarding the TSHR line but the cache line's state is non-stable yet:

assign tshr_allocate     =  current_state_is_stable & !next_state_is_stable;
assign tshr_deallocate   = !current_state_is_stable &  next_state_is_stable; 
assign tshr_update       = !current_state_is_stable & !next_state_is_stable & coherence_update_info_en;

Note that, if the operation is an entry allocation then the index of the first entry available is passed directly by the TSHR module. Remember that at this point there is surely an empty TSHR line otherwise the request would have not been issued (see Issue Signals), since all pending requests are stalled when the TSHR is full.

In case of update or deallocation, the index of the entry is forwarded by Stage 1 (through Stage 2):

assign dc3_update_tshr_index = tshr_allocate ? tshr_empty_index : dc2_message_tshr_index;

Cache Update Logic

Cache could be updated in three different ways:

  • entry allocation;
  • entry deallocation;
  • entry update.

Unlike TSHR, the cache stores cache lines data whose coherence transactions are completed, and the tracked ache line is considered in a stable state. So an entry allocation is made every time the cache line's state moves towards a stable state from non-stable and it was not already into the cache. In the opposite way, deallocation whenever a cache line's state enters a non-stable state, then it is tracked in the TSHR (see TSHR Update Logic). Finally, an update occurs whenever there is something to change regarding the cache line in compliance with the protocol ROM:

assign allocate_cache    = next_state_is_stable & ( coherence_update_info_en | dpr_output.store_data ) & ~(tshr_deallocate & dpr_output.invalidate_cache_way) & ~update_cache; 
assign deallocate_cache  = tshr_allocate & dc2_message_cache_hit ;
assign update_cache      = current_state_is_stable & next_state_is_stable & dc2_message_cache_hit & ( coherence_update_info_en | dpr_output.store_data );

Replacement Logic

Whenever a replacement request occurs the current cache block is invalidated, but the entry is not freed. That is because the same cache line is replaced with a new valid one from a previous coherence request with the same set. The replaced cache block is queued in a replacement queue until Stage 1 issues it (replacement requests have the maximum priority and will be scheduled as soon as they are pending (see Requests Scheduler)).

This module manages the replacement queue and allows a cache block to be enqueued whenever there is a replacement, this happens whenever the actual coherence request need to store data and info in cache memory, then the current request is not a replacement itself (!is_replacement) and a cache miss occurs:

assign do_replacement  = dc2_message_valid && dc2_message_cache_valid
       && ((allocate_cache || update_cache) && !deallocate_cache) 
       && !is_replacement 
       && !dc2_message_cache_hit;

assign dc3_replacement_enqueue = dc2_message_valid && do_replacement;

Signal dc2_message_cache_valid states if the selected way stores a valid lane, if so this line has to be recalled if in state M, and pushed back to the main memory. In case of hit in the case, expression !dc2_message_cache_hit, there is no need of replacement since the control logic is updating an existing line.

Message Generator

This module sends forward or response messages to the network interface whenever is required by the protocol ROM:

	dpr_output.message_response_send,
       ...
	dpr_output.message_forwarded_send,

The above snippet shows the output of the protocol ROM related to the output message to generate. When message_response_send is asserted the directory sends a response over the network, dually, when message_forwarded_send is high, a forwarded is generated.

Note that this block manages instruction cache misses as well. In such a case, requests are forwarded directly to memory bypassing the coherence logic.

See Also

Coherence