package Bus(mkBus, Bus(..)) where import Types import BusTypes import Client import TagEngine import Vector import Util import Arbiter import FIFO import FIFOF import SpecialFIFOs import Printf busRequestToAddr :: BusRequest -> Addr busRequestToAddr req = case req of BusReadRequest (ReadRequest addr _) -> addr BusWriteRequest (WriteRequest addr _) -> addr -- Create a Bus Module that supports multiple clients and servers -- submitting requests and simultaneously returning responses. -- Responses can be consumed by clients out of order as all client -- submitted requests are tagged - and servers keep that tag -- when responding. mkBus :: (Add n (TLog numServers) (TLog (TAdd numServers 1))) => (Addr -> Maybe (MkServerIdx numServers)) -> Module (Bus inFlightTransactions numClients numServers) mkBus serverMap = do -- Tag engines for each client to manage transaction tags tagEngineByClientVec :: Vector numClients (TagEngine inFlightTransactions) tagEngineByClientVec <- replicateM mkTagEngine -- There are `numClients` clients, each of which needs its own arbiter as -- there are up to `numServer` servers that may wish to submit a response -- to a given client. Furthermore the rule that routes client requests to -- servers makes for another potential requestor as it may determine that -- a request is unmappable and instead opt to form and submit a -- `BusError UnMapped` response directly to a client response arbiter. Thus -- we must arbit between a total of `numServers + 1` requestors. responseArbiterByClient :: Vector numClients (Arbiter.Arbiter_IFC (TAdd numServers 1)) responseArbiterByClient <- replicateM (mkArbiter False) -- There are `numServer` servers, each of which needs its own arbiter as -- there are up to `numClient` clients that may wish to submit a response -- to a given server. requestArbiterByServer :: Vector numServers (Arbiter.Arbiter_IFC numClients) requestArbiterByServer <- replicateM (mkArbiter False) dummyVar :: Reg(Bool) dummyVar <- mkReg False -- Queues to hold requests from clients clientRequestQueues :: Vector numClients (FIFOF (TaggedBusRequest inFlightTransactions)) clientRequestQueues <- replicateM (mkSizedBypassFIFOF (valueOf inFlightTransactions)) -- Queues to hold responses to clients clientResponseQueues :: Vector numClients (FIFOF (TaggedBusResponse inFlightTransactions)) clientResponseQueues <- replicateM (mkSizedBypassFIFOF (valueOf inFlightTransactions)) -- The following two vectors of FIFOs make it easier to push/pull data to/from internal -- server methods: consumeRequestQueues :: Vector numServers ( FIFOF ( MkClientTagType numClients, TaggedBusRequest inFlightTransactions ) ) consumeRequestQueues <- replicateM mkBypassFIFOF submitResponseQueues :: Vector numServers ( FIFOF ( MkClientTagType numClients, TaggedBusResponse inFlightTransactions ) ) submitResponseQueues <- replicateM mkBypassFIFOF let clientRules :: Vector numClients (Rules) clientRules = genWith $ \clientIdx -> let selectedClientReqQueue :: FIFOF (TaggedBusRequest inFlightTransactions) selectedClientReqQueue = select clientRequestQueues clientIdx selectedClientRespQueue :: FIFOF (TaggedBusResponse inFlightTransactions) selectedClientRespQueue = select clientResponseQueues clientIdx selectedClientRespArbiter :: Arbiter.Arbiter_IFC (TAdd numServers 1) selectedClientRespArbiter = select responseArbiterByClient clientIdx clientRouterRule :: Rules clientRouterRule = clientRouteRequest clientIdx selectedClientReqQueue requestArbiterByServer responseArbiterByClient serverMap clientArbiterRule :: Rules clientArbiterRule = clientArbitSubmission clientIdx selectedClientReqQueue selectedClientRespQueue selectedClientRespArbiter submitResponseQueues in clientRouterRule <+> clientArbiterRule let serverRules :: Vector numServers (Rules) serverRules = genWith $ \serverIdx -> let selectedServerArbiter :: Arbiter.Arbiter_IFC numClients selectedServerArbiter = (select requestArbiterByServer serverIdx) selectedConsumeRequestQueue :: FIFOF ( MkClientTagType numClients, TaggedBusRequest inFlightTransactions ) selectedConsumeRequestQueue = (select consumeRequestQueues serverIdx) in rules (sprintf "server[%d] arbit requests" serverIdx): when True ==> do let grantedClientIdx :: MkClientTagType numClients grantedClientIdx = unpack selectedServerArbiter.grant_id selectedClientRequestQueue :: FIFOF (TaggedBusRequest inFlightTransactions) selectedClientRequestQueue = (select clientRequestQueues grantedClientIdx) clientRequest :: TaggedBusRequest inFlightTransactions clientRequest = selectedClientRequestQueue.first selectedConsumeRequestQueue.enq (grantedClientIdx, clientRequest) selectedClientRequestQueue.deq (sprintf "server[%d] route response" serverIdx): when True ==> do let selectedSubmitResponseQueue :: FIFOF ( MkClientTagType numClients, TaggedBusResponse inFlightTransactions ) selectedSubmitResponseQueue = (select submitResponseQueues serverIdx) response :: (MkClientTagType numClients, TaggedBusResponse inFlightTransactions) response = selectedSubmitResponseQueue.first clientTag :: MkClientTagType numClients clientTag = response.fst targetClientResponseArbiter :: Arbiter.Arbiter_IFC (TAdd numServers 1) targetClientResponseArbiter = (select responseArbiterByClient clientTag) arbiterClientSlot :: Arbiter.ArbiterClient_IFC arbiterClientSlot = (select targetClientResponseArbiter.clients serverIdx) arbiterClientSlot.request addRules |> foldr (<+>) (rules {}) clientRules addRules |> foldr (<+>) (rules {}) serverRules -- Client interface vector let clients :: Vector numClients (BusClient inFlightTransactions) clients = genWith $ \clientIdx -> let selectedClientRequestQueue :: FIFOF (TaggedBusRequest inFlightTransactions) selectedClientRequestQueue = (select clientRequestQueues clientIdx) selectedClientResponseQueue :: FIFOF (TaggedBusResponse inFlightTransactions) selectedClientResponseQueue = (select clientResponseQueues clientIdx) selectedTagEngine :: TagEngine inFlightTransactions selectedTagEngine = (select tagEngineByClientVec clientIdx) in interface BusClient submitRequest :: BusRequest -> ActionValue (MkTagType inFlightTransactions) submitRequest busRequest = do tag <- selectedTagEngine.requestTag let taggedReuqest = TaggedBusRequest {tag = tag; busRequest = busRequest} selectedClientRequestQueue.enq taggedReuqest return tag consumeResponse :: ActionValue (TaggedBusResponse inFlightTransactions) consumeResponse = do let busResponse :: (TaggedBusResponse inFlightTransactions) busResponse = selectedClientResponseQueue.first selectedTagEngine.retireTag busResponse.tag selectedClientResponseQueue.deq return busResponse -- Server interface vector let servers :: Vector numServers (BusServer inFlightTransactions numClients) servers = genWith $ \serverIdx -> let selectedConsumeRequestQueue :: FIFOF ( MkClientTagType numClients, TaggedBusRequest inFlightTransactions ) selectedConsumeRequestQueue = (select consumeRequestQueues serverIdx) in interface BusServer consumeRequest :: ActionValue ( MkClientTagType numClients, TaggedBusRequest inFlightTransactions ) consumeRequest = do selectedConsumeRequestQueue.deq return selectedConsumeRequestQueue.first submitResponse :: ( MkClientTagType numClients, TaggedBusResponse inFlightTransactions ) -> Action submitResponse (clientTag, taggedBusResponse) = do let selectedSubmitResponseQueue :: FIFOF ( MkClientTagType numClients, TaggedBusResponse inFlightTransactions ) selectedSubmitResponseQueue = (select submitResponseQueues serverIdx) selectedSubmitResponseQueue.enq (clientTag, taggedBusResponse) return $ interface Bus clients = clients servers = servers