def __init__(s, MapperPRTL, src_msgs, sink_msgs, src_delay, sink_delay, dump_vcd=False, test_verilog=False): # Instantiate Models s.src = TestSource(MapperReqMsg(), src_msgs, src_delay) s.mapper = MapperPRTL() s.sink = TestSink(MapperRespMsg(), sink_msgs, sink_delay) # Dump VCD if dump_vcd: s.mapper.vcd_file = dump_vcd # Translation if test_verilog: s.mapper = TranslationTool(s.mapper) # Connect s.connect(s.src.out, s.mapper.req) s.connect(s.mapper.resp, s.sink.in_)
def __init__(s, nbits=8, mbits=1): # Interface s.req = InValRdyBundle(MapperReqMsg()) s.resp = OutValRdyBundle(MapperRespMsg()) # Instantiate datapath and control s.dpath = MapperDpathRTL(nbits, mbits) s.ctrl = MapperCtrlRTL(mbits) # connect input interface to dpath/ctrl s.connect(s.req.msg.data, s.dpath.req_msg_data) s.connect(s.req.msg.type_, s.ctrl.req_msg_type) s.connect(s.req.val, s.ctrl.req_val) s.connect(s.resp.rdy, s.ctrl.resp_rdy) # connect dpath/ctrl to output interface s.connect(s.dpath.resp_msg_data, s.resp.msg.data) s.connect(s.ctrl.resp_msg_type, s.resp.msg.type_) s.connect(s.ctrl.req_rdy, s.req.rdy) s.connect(s.ctrl.resp_val, s.resp.val) # connect dpath/ctrl s.connect(s.ctrl.result_reg_en, s.dpath.result_reg_en) s.connect(s.ctrl.reference_reg_en, s.dpath.reference_reg_en)
def __init__(s): s.req = InValRdyBundle(MapperReqMsg()) s.resp = OutValRdyBundle(MapperRespMsg()) s.dpath = MapperDpath() s.ctrl = MapperCtrl() s.connect(s.req.msg.data, s.dpath.req_msg_data) s.connect(s.req.msg.digit, s.dpath.req_msg_digit) s.connect(s.req.msg.type_, s.dpath.req_msg_type) s.connect(s.req.msg.type_, s.ctrl.req_msg_type) s.connect(s.req.val, s.ctrl.req_val) s.connect(s.req.rdy, s.ctrl.req_rdy) s.connect(s.dpath.resp_msg_data, s.resp.msg.data) s.connect(s.dpath.resp_msg_digit, s.resp.msg.digit) s.connect(s.dpath.resp_msg_type, s.resp.msg.type_) s.connect(s.ctrl.resp_val, s.resp.val) s.connect(s.ctrl.resp_rdy, s.resp.rdy) s.connect_auto(s.dpath, s.ctrl)
def mk_resp_msg(data, type, digit): msg = MapperRespMsg() msg.data = data msg.type_ = type msg.digit = digit return msg
def __init__(s, mapper_num=2, reducer_num=1): # Top Level Interface s.in_ = InValRdyBundle(WordcountReqMsg()) s.out = OutValRdyBundle(WordcountRespMsg()) s.reference = InPort(32) s.base = InPort(32) s.size = InPort(32) # Global Memory Interface s.gmem_req = OutValRdyBundle(MemReqMsg(8, 32, 32)) s.gmem_resp = InValRdyBundle(MemRespMsg(8, 32)) # Local Memory Interface s.lmem_req = OutValRdyBundle(MemReqMsg(8, 32, 32)) s.lmem_resp = InValRdyBundle(MemRespMsg(8, 32)) # Mapper Interface s.map_req = OutValRdyBundle[mapper_num](MapperReqMsg()) s.map_resp = InValRdyBundle[mapper_num](MapperRespMsg()) # Reducer Interface s.red_req = OutValRdyBundle[reducer_num](ReducerReqMsg()) s.red_resp = InValRdyBundle[reducer_num](ReducerRespMsg()) # Task Queue s.task_queue = NormalQueue(2, Bits(32)) # Idle Queue storing mapper ID s.idle_queue = NormalQueue(2, Bits(2)) # States s.STATE_IDLE = 0 # Idle state, scheduler waiting for top level to start s.STATE_SOURCE = 1 # Source state, handling with Test Source, getting base, size, ref info s.STATE_INIT = 2 # Init state, scheduler assigns input info to each Mapper s.STATE_START = 3 # Start state, scheduler starts scheduling s.STATE_END = 4 # End state, shceduler loads all task from global memory and it is done s.state = RegRst(4, reset_value=s.STATE_IDLE) # Counters s.init_count = Wire(2) s.input_count = Wire(32) @s.tick def counter(): if (s.idle_queue.enq.val and s.init): s.init_count.next = s.init_count + 1 if (s.gmem_req.val): s.input_count.next = s.input_count + 1 # Signals s.go = Wire(1) # go signal tells scheduler to start scheduling s.mapper_done = Wire(1) # if one or more mapper is done and send resp s.init = Wire(1) # init signal indicates scheduler at initial state s.end = Wire(1) # end signal indicates all task are loaded s.done = Wire(1) # done signal indicates everything is done s.num_task_queue = Wire(2) s.connect(s.task_queue.num_free_entries, s.num_task_queue) @s.combinational def logic(): s.mapper_done.value = s.map_resp[0].val | s.map_resp[1].val #--------------------------------------------------------------------- # Assign Task to Mapper Combinational Logic #--------------------------------------------------------------------- @s.combinational def mapper(): # initialize mapper req and resp handshake signals for i in xrange(mapper_num): s.map_req[i].val.value = 0 s.task_queue.deq.rdy.value = 0 s.idle_queue.deq.rdy.value = 0 if s.init: s.map_req[s.init_count].msg.data.value = s.reference s.map_req[s.init_count].msg.type_.value = 1 s.map_req[s.init_count].val.value = 1 s.idle_queue.enq.msg.value = s.init_count s.idle_queue.enq.val.value = 1 else: # assign task to mapper if task queue is ready to dequeue # idle queue is ready to dequeue and mapper is ready to take request if (s.task_queue.deq.val and s.idle_queue.deq.val and s.map_req[s.idle_queue.deq.msg].rdy): s.map_req[s.idle_queue.deq. msg].msg.data.value = s.task_queue.deq.msg[0:8] s.map_req[s.idle_queue.deq.msg].msg.type_.value = 0 s.map_req[s.idle_queue.deq.msg].val.value = 1 s.task_queue.deq.rdy.value = 1 s.idle_queue.deq.rdy.value = 1 #--------------------------------------------------------------------- # Send Mapper Resp to Reducer Combinational Logic #--------------------------------------------------------------------- @s.combinational def reducer(): # initialize mapper and reducer handshake signals for i in xrange(mapper_num): s.map_resp[i].rdy.value = 0 for i in xrange(reducer_num): s.red_req[i].val.value = 0 #s.idle_queue.enq.val.value = 0 # get the mapper response, assign the response to reducer if (s.mapper_done): # Check each mapper response, add it to idle queue, send its response # to Reducer, mark its response ready for i in xrange(mapper_num): if (s.map_resp[i].val): if ~s.init: if s.idle_queue.enq.rdy: s.idle_queue.enq.msg.value = i s.idle_queue.enq.val.value = 1 if s.red_req[0].rdy: if s.end and s.num_task_queue == 2: s.red_req[0].msg.data.value = s.map_resp[ i].msg.data s.red_req[0].msg.type_.value = 1 s.red_req[0].val.value = 1 s.done.value = 1 else: s.red_req[0].msg.data.value = s.map_resp[ i].msg.data s.red_req[0].msg.type_.value = 0 s.red_req[0].val.value = 1 s.map_resp[i].rdy.value = 1 break #--------------------------------------------------------------------- # Task State Transition Logic #--------------------------------------------------------------------- @s.combinational def state_transitions(): curr_state = s.state.out next_state = s.state.out if (curr_state == s.STATE_IDLE): if (s.in_.val): next_state = s.STATE_SOURCE if (curr_state == s.STATE_SOURCE): if (s.go): next_state = s.STATE_INIT elif (s.done and s.red_resp[0].val): next_state = s.STATE_IDLE if (curr_state == s.STATE_INIT): if (s.init_count == mapper_num - 1): next_state = s.STATE_START if (curr_state == s.STATE_START): if (s.input_count == s.size - 1): next_state = s.STATE_END if (curr_state == s.STATE_END): if (s.done): next_state = s.STATE_SOURCE s.state.in_.value = next_state #--------------------------------------------------------------------- # Task State Output Logic #--------------------------------------------------------------------- @s.combinational def state_outputs(): current_state = s.state.out s.gmem_req.val.value = 0 s.gmem_resp.rdy.value = 0 s.in_.rdy.value = 0 s.out.val.value = 0 s.task_queue.enq.val.value = 0 # In IDLE state if (current_state == s.STATE_IDLE): s.init_count.value = 0 s.input_count.value = 0 s.end.value = 0 s.go.value = 0 s.init.value = 0 s.done.value = 0 if s.in_.val: if (s.in_.msg.addr == 1): s.base.value = s.in_.msg.data s.in_.rdy.value = 1 s.out.msg.type_.value = WordcountReqMsg.TYPE_WRITE s.out.msg.data.value = 0 s.out.val.value = 1 #In SOURCE state if (current_state == s.STATE_SOURCE): if (s.in_.val and s.out.rdy): if (s.in_.msg.type_ == WordcountReqMsg.TYPE_WRITE): if (s.in_.msg.addr == 0): s.go.value = 1 elif (s.in_.msg.addr == 2): s.size.value = s.in_.msg.data elif (s.in_.msg.addr == 3): s.reference.value = s.in_.msg.data # Send xcel response message s.in_.rdy.value = 1 s.out.msg.type_.value = WordcountReqMsg.TYPE_WRITE s.out.msg.data.value = 0 s.out.val.value = 1 elif (s.in_.msg.type_ == WordcountReqMsg.TYPE_READ): if (s.done and s.red_resp[0].val): s.out.msg.type_.value = WordcountReqMsg.TYPE_READ s.out.msg.data.value = s.red_resp[0].msg.data s.red_resp[0].rdy.value = 1 s.in_.rdy.value = 1 s.out.val.value = 1 # In INIT state if (current_state == s.STATE_INIT): s.init.value = 1 s.go.value = 0 # at the last 2 cycle of init, send read req to global memory if s.init_count == mapper_num - 2: if s.gmem_req.rdy: s.gmem_req.msg.addr.value = s.base + (4 * s.input_count) s.gmem_req.msg.type_.value = TYPE_READ s.gmem_req.val.value = 1 # at the last cycle of init, receive read resp to global memory, put it in task queue # send another read req to global memory if s.init_count == mapper_num - 1: if s.gmem_resp.val and s.gmem_req.rdy: s.task_queue.enq.msg.value = s.gmem_resp.msg s.task_queue.enq.val.value = 1 s.gmem_resp.rdy.value = 1 s.gmem_req.msg.addr.value = s.base + (4 * s.input_count) s.gmem_req.msg.type_.value = TYPE_READ s.gmem_req.val.value = 1 # In START state if (current_state == s.STATE_START): s.init.value = 0 if s.gmem_resp.val and s.gmem_req.rdy: s.task_queue.enq.msg.value = s.gmem_resp.msg s.task_queue.enq.val.value = 1 s.gmem_resp.rdy.value = 1 s.gmem_req.msg.addr.value = s.base + (4 * s.input_count) s.gmem_req.msg.type_.value = TYPE_READ s.gmem_req.val.value = 1 # In END state if (current_state == s.STATE_END): if s.gmem_resp.val: s.task_queue.enq.msg.value = s.gmem_resp.msg s.task_queue.enq.val.value = 1 s.gmem_resp.rdy.value = 1 s.end.value = 1
def mk_resp_msg(data, type): msg = MapperRespMsg() msg.data = data msg.type_ = type return msg
def mk_resp_msg( data, type, digit ): msg = MapperRespMsg() msg.data = data msg.type_ = type msg.digit = digit return msg