X-Git-Url: https://git.libre-soc.org/?a=blobdiff_plain;f=src%2Fadd%2Fexample_buf_pipe.py;h=8b9c74f78f8abc4ef1be278e374eb6e024cfa55f;hb=25357c032b55274ce620a331ecc1dc0874f5fdac;hp=8f3742259518750dd93f005276ac4bd1f19e672b;hpb=b90c533476affe63a34292bfe54dde62a105bed8;p=ieee754fpu.git

diff --git a/src/add/example_buf_pipe.py b/src/add/example_buf_pipe.py
index 8f374225..8b9c74f7 100644
--- a/src/add/example_buf_pipe.py
+++ b/src/add/example_buf_pipe.py
@@ -12,12 +12,12 @@
     where data will flow on *every* clock when the conditions are right.
 
     input acceptance conditions are when:
-        * incoming previous-stage strobe (i.p_valid) is HIGH
-        * outgoing previous-stage ready   (o.p_ready) is LOW
+        * incoming previous-stage strobe (p.i_valid) is HIGH
+        * outgoing previous-stage ready   (p.o_ready) is LOW
 
     output transmission conditions are when:
-        * outgoing next-stage strobe (o.n_valid) is HIGH
-        * outgoing next-stage ready   (i.n_ready) is LOW
+        * outgoing next-stage strobe (n.o_valid) is HIGH
+        * outgoing next-stage ready   (n.i_ready) is LOW
 
     the tricky bit is when the input has valid data and the output is not
     ready to accept it.  if it wasn't for the clock synchronisation, it
@@ -45,14 +45,82 @@
 
 from nmigen import Signal, Cat, Const, Mux, Module
 from nmigen.cli import verilog, rtlil
+from collections.abc import Sequence
 
 
-class ExampleStage:
-    """ an example of how to use the buffered pipeline.  actual names of
-        variables (i_data, r_data, o_data, result) below do not matter:
-        the functions however do.
+class PrevControl:
+    """ contains signals that come *from* the previous stage (both in and out)
+        * i_valid: input from previous stage indicating incoming data is valid
+        * o_ready: output to next stage indicating readiness to accept data
+        * i_data : an input - added by the user of this class
+    """
+
+    def __init__(self):
+        self.i_valid = Signal(name="p_i_valid") # >>in
+        self.o_ready = Signal(name="p_o_ready") # <<out
+
+    def connect_in(self, prev):
+        """ helper function to connect stage to an input source.  do not
+            use to connect stage-to-stage!
+        """
+        return [self.i_valid.eq(prev.i_valid),
+                prev.o_ready.eq(self.o_ready),
+                eq(self.i_data, prev.i_data),
+               ]
+
+
+class NextControl:
+    """ contains the signals that go *to* the next stage (both in and out)
+        * o_valid: output indicating to next stage that data is valid
+        * i_ready: input from next stage indicating that it can accept data
+        * o_data : an output - added by the user of this class
+    """
+    def __init__(self):
+        self.o_valid = Signal(name="n_o_valid") # out>>
+        self.i_ready = Signal(name="n_i_ready") # <<in
 
-        input data i_data is read (only), is processed and goes into an
+    def connect_to_next(self, nxt):
+        """ helper function to connect to the next stage data/valid/ready.
+            data/valid is passed *TO* nxt, and ready comes *IN* from nxt.
+        """
+        return [nxt.i_valid.eq(self.o_valid),
+                self.i_ready.eq(nxt.o_ready),
+                eq(nxt.i_data, self.o_data),
+               ]
+
+    def connect_out(self, nxt):
+        """ helper function to connect stage to an output source.  do not
+            use to connect stage-to-stage!
+        """
+        return [nxt.o_valid.eq(self.o_valid),
+                self.i_ready.eq(nxt.i_ready),
+                eq(nxt.o_data, self.o_data),
+               ]
+
+
+def eq(o, i):
+    if not isinstance(o, Sequence):
+        o, i = [o], [i]
+    res = []
+    for (ao, ai) in zip(o, i):
+        res.append(ao.eq(ai))
+    return res
+
+
+class BufferedPipeline:
+    """ buffered pipeline stage.  data and strobe signals travel in sync.
+        if ever the input is ready and the output is not, processed data
+        is stored in a temporary register.
+
+        stage-1   p.i_valid >>in   stage   n.o_valid out>>   stage+1
+        stage-1   p.o_ready <<out  stage   n.i_ready <<in    stage+1
+        stage-1   p.i_data  >>in   stage   n.o_data  out>>   stage+1
+                              |             |
+                            process --->----^
+                              |             |
+                              +-- r_data ->-+
+
+        input data p.i_data is read (only), is processed and goes into an
         intermediate result store [process()].  this is updated combinatorially.
 
         in a non-stall condition, the intermediate result will go into the
@@ -66,157 +134,261 @@ class ExampleStage:
         on the next cycle (as long as stall is not raised again) the
         input may begin to be processed and transferred directly to output.
     """
+    def __init__(self, stage):
+        """ pass in a "stage" which may be either a static class or a class
+            instance, which has three functions:
+            * ispec: returns input signals according to the input specification
+            * ispec: returns output signals to the output specification
+            * process: takes an input instance and returns processed data
+
+            p.i_data -> process() -> result --> n.o_data
+                                       |           ^
+                                       |           |
+                                       +-> r_data -+
+        """
+        self.stage = stage
 
-    def __init__(self):
-        """ i_data can be a DIFFERENT type from everything else
-            o_data, r_data and result are best of the same type.
-            however this is not strictly the case.  an intermediate
-            transformation process could hypothetically be applied, however
-            it is result and r_data that definitively need to be of the same
-            (intermediary) type, as it is both result and r_data that
-            are transferred into o_data:
-
-            i_data -> process() -> result --> o_data
-                                     |           ^
-                                     |           |
-                                     +-> r_data -+
-        """
-        self.i_data = Signal(16)
-        self.r_data = Signal(16)
-        self.o_data = Signal(16)
-        self.result = Signal(16)
-
-    def process(self):
-        """ process the input data and store it in result.
-            (not needed to be known: result is combinatorial)
-        """
-        return self.result.eq(self.i_data + 1)
+        # set up input and output IO ACK (prev/next ready/valid)
+        self.p = PrevControl()
+        self.n = NextControl()
+
+        # set up the input and output data
+        self.p.i_data = stage.ispec() # input type
+        self.r_data   = stage.ospec() # all these are output type
+        self.result   = stage.ospec()
+        self.n.o_data = stage.ospec()
+
+    def connect_to_next(self, nxt):
+        """ helper function to connect to the next stage data/valid/ready.
+        """
+        return self.n.connect_to_next(nxt.p)
+
+    def connect_in(self, prev):
+        """ helper function to connect stage to an input source.  do not
+            use to connect stage-to-stage!
+        """
+        return self.p.connect_in(prev.p)
+
+    def connect_out(self, nxt):
+        """ helper function to connect stage to an output source.  do not
+            use to connect stage-to-stage!
+        """
+        return self.n.connect_out(nxt.n)
+
+    def set_input(self, i):
+        """ helper function to set the input data
+        """
+        return eq(self.p.i_data, i)
 
     def update_buffer(self):
-        """ copies the result into the intermediate register r_data
+        """ copies the result into the intermediate register r_data,
+            which will need to be outputted on a subsequent cycle
+            prior to allowing "normal" operation.
         """
-        return self.r_data.eq(self.result)
+        return eq(self.r_data, self.result)
 
     def update_output(self):
         """ copies the (combinatorial) result into the output
         """
-        return self.o_data.eq(self.result)
+        return eq(self.n.o_data, self.result)
 
     def flush_buffer(self):
         """ copies the *intermediate* register r_data into the output
         """
-        return self.o_data.eq(self.r_data)
+        return eq(self.n.o_data, self.r_data)
 
     def ports(self):
-        return [self.i_data, self.o_data]
-
-class IOAckIn:
-
-    def __init__(self):
-        self.p_valid = Signal()  # >>in - comes in from PREVIOUS stage
-        self.n_ready = Signal() # in<< - comes in from the NEXT stage
-
-
-class IOAckOut:
-
-    def __init__(self):
-        self.n_valid = Signal()  # out>> - goes out to the NEXT stage
-        self.p_ready = Signal() # <<out - goes out to the PREVIOUS stage
-
-
-class BufferedPipeline:
-    """ buffered pipeline stage
-
-        stage-1   i.p_valid  >>in   stage   o.n_valid  out>>   stage+1
-        stage-1   o.p_ready <<out  stage   i.n_ready <<in    stage+1
-        stage-1   i_data   >>in   stage   o_data   out>>   stage+1
-                              |             |
-                              +------->  process
-                              |             |
-                              +-- r_data ---+
-    """
-    def __init__(self):
-        # input: strobe comes in from previous stage, ready comes in from next
-        self.i = IOAckIn()
-        #self.i.p_valid = Signal()    # >>in - comes in from PREVIOUS stage
-        #self.i.n_ready = Signal()   # in<< - comes in from the NEXT stage
-
-        # output: strobe goes out to next stage, ready comes in from previous
-        self.o = IOAckOut()
-        #self.o.n_valid = Signal()    # out>> - goes out to the NEXT stage
-        #self.o.p_ready = Signal()   # <<out - goes out to the PREVIOUS stage
+        return [self.p.i_data, self.n.o_data]
 
     def elaborate(self, platform):
         m = Module()
+        if hasattr(self.stage, "setup"):
+            self.stage.setup(m, self.p.i_data)
 
         # establish some combinatorial temporaries
-        o_p_readyn = Signal(reset_less=True)
         o_n_validn = Signal(reset_less=True)
-        i_n_readyn = Signal(reset_less=True)
         i_p_valid_o_p_ready = Signal(reset_less=True)
-        m.d.comb += [i_n_readyn.eq(~self.i.n_ready),
-                     o_n_validn.eq(~self.o.n_valid),
-                     o_p_readyn.eq(~self.o.p_ready),
-                     i_p_valid_o_p_ready.eq(self.i.p_valid & self.o.p_ready),
+        m.d.comb += [o_n_validn.eq(~self.n.o_valid),
+                     i_p_valid_o_p_ready.eq(self.p.i_valid & self.p.o_ready),
         ]
 
         # store result of processing in combinatorial temporary
-        with m.If(self.i.p_valid): # input is valid: process it
-            m.d.comb += self.stage.process()
+        with m.If(self.p.i_valid): # input is valid: process it
+            m.d.comb += eq(self.result, self.stage.process(self.p.i_data))
         # if not in stall condition, update the temporary register
-        with m.If(self.o.p_ready): # not stalled
-            m.d.sync += self.stage.update_buffer()
-
-        #with m.If(self.i.p_rst): # reset
-        #    m.d.sync += self.o.n_valid.eq(0)
-        #    m.d.sync += self.o.p_ready.eq(0)
-        with m.If(self.i.n_ready): # next stage is ready
-            with m.If(self.o.p_ready): # not stalled
+        with m.If(self.p.o_ready): # not stalled
+            m.d.sync += self.update_buffer()
+
+        #with m.If(self.p.i_rst): # reset
+        #    m.d.sync += self.n.o_valid.eq(0)
+        #    m.d.sync += self.p.o_ready.eq(0)
+        with m.If(self.n.i_ready): # next stage is ready
+            with m.If(self.p.o_ready): # not stalled
                 # nothing in buffer: send (processed) input direct to output
-                m.d.sync += [self.o.n_valid.eq(self.i.p_valid),
-                             self.stage.update_output(),
+                m.d.sync += [self.n.o_valid.eq(self.p.i_valid),
+                             self.update_output(),
                             ]
-            with m.Else(): # o.p_ready is false, and something is in buffer.
+            with m.Else(): # p.o_ready is false, and something is in buffer.
                 # Flush the [already processed] buffer to the output port.
-                m.d.sync += [self.o.n_valid.eq(1),
-                             self.stage.flush_buffer(),
+                m.d.sync += [self.n.o_valid.eq(1),
+                             self.flush_buffer(),
                              # clear stall condition, declare register empty.
-                             self.o.p_ready.eq(1),
+                             self.p.o_ready.eq(1),
                             ]
-                # ignore input, since o.p_ready is also false.
+                # ignore input, since p.o_ready is also false.
 
-        # (i.n_ready) is false here: next stage is ready
+        # (n.i_ready) is false here: next stage is ready
         with m.Elif(o_n_validn): # next stage being told "ready"
-            m.d.sync += [self.o.n_valid.eq(self.i.p_valid),
-                         self.o.p_ready.eq(1), # Keep the buffer empty
+            m.d.sync += [self.n.o_valid.eq(self.p.i_valid),
+                         self.p.o_ready.eq(1), # Keep the buffer empty
                          # set the output data (from comb result)
-                         self.stage.update_output(),
+                         self.update_output(),
                         ]
-        # (i.n_ready) false and (o.n_valid) true:
+        # (n.i_ready) false and (n.o_valid) true:
         with m.Elif(i_p_valid_o_p_ready):
             # If next stage *is* ready, and not stalled yet, accept input
-            m.d.sync += self.o.p_ready.eq(~(self.i.p_valid & self.o.n_valid))
+            m.d.sync += self.p.o_ready.eq(~(self.p.i_valid & self.n.o_valid))
 
         return m
 
     def ports(self):
-        return [self.i.p_valid, self.i.n_ready,
-                self.o.n_valid, self.o.p_ready,
+        return [self.p.i_valid, self.n.i_ready,
+                self.n.o_valid, self.p.o_ready,
                ]
 
 
-class BufPipe(BufferedPipeline):
+class ExampleAddStage:
+    """ an example of how to use the buffered pipeline, as a class instance
+    """
+
+    def ispec(self):
+        """ returns a tuple of input signals which will be the incoming data
+        """
+        return (Signal(16), Signal(16))
+
+    def ospec(self):
+        """ returns an output signal which will happen to contain the sum
+            of the two inputs
+        """
+        return Signal(16)
+
+    def process(self, i):
+        """ process the input data (sums the values in the tuple) and returns it
+        """
+        return i[0] + i[1]
+
+
+class ExampleBufPipeAdd(BufferedPipeline):
+    """ an example of how to use the buffered pipeline, using a class instance
+    """
 
     def __init__(self):
-        BufferedPipeline.__init__(self)
-        self.stage = ExampleStage()
+        addstage = ExampleAddStage()
+        BufferedPipeline.__init__(self, addstage)
+
+
+class ExampleStage:
+    """ an example of how to use the buffered pipeline, in a static class
+        fashion
+    """
+
+    def ispec():
+        return Signal(16)
+
+    def ospec():
+        return Signal(16)
+
+    def process(i):
+        """ process the input data and returns it (adds 1)
+        """
+        return i + 1
+
+
+class ExampleBufPipe(BufferedPipeline):
+    """ an example of how to use the buffered pipeline.
+    """
+
+    def __init__(self):
+        BufferedPipeline.__init__(self, ExampleStage)
+
+
+class CombPipe:
+    """A simple pipeline stage containing combinational logic that can execute
+    completely in one clock cycle.
+
+    Parameters:
+    -----------
+    input_shape : int or tuple or None
+        the shape of ``input.data`` and ``comb_input``
+    output_shape : int or tuple or None
+        the shape of ``output.data`` and ``comb_output``
+    name : str
+        the name
+
+    Attributes:
+    -----------
+    input : StageInput
+        The pipeline input
+    output : StageOutput
+        The pipeline output
+    comb_input : Signal, input_shape
+        The input to the combinatorial logic
+    comb_output: Signal, output_shape
+        The output of the combinatorial logic
+    """
+
+    def __init__(self, stage):
+        self.stage = stage
+        self._data_valid = Signal()
+        # set up input and output IO ACK (prev/next ready/valid)
+        self.p = PrevControl()
+        self.n = NextControl()
+
+        # set up the input and output data
+        self.p.i_data = stage.ispec() # input type
+        self.r_data = stage.ispec() # input type
+        self.result = stage.ospec() # output data
+        self.n.o_data = stage.ospec() # output type
+        self.n.o_data.name = "outdata"
+
+    def set_input(self, i):
+        """ helper function to set the input data
+        """
+        return eq(self.p.i_data, i)
+
+    def elaborate(self, platform):
+        m = Module()
+        if hasattr(self.stage, "setup"):
+            self.stage.setup(m, self.r_data)
+        m.d.comb += eq(self.result, self.stage.process(self.r_data))
+        m.d.comb += self.n.o_valid.eq(self._data_valid)
+        m.d.comb += self.p.o_ready.eq(~self._data_valid | self.n.i_ready)
+        m.d.sync += self._data_valid.eq(self.p.i_valid | \
+                                        (~self.n.i_ready & self._data_valid))
+        with m.If(self.p.i_valid & self.p.o_ready):
+            m.d.sync += eq(self.r_data, self.p.i_data)
+        m.d.comb += eq(self.n.o_data, self.result)
+        return m
 
     def ports(self):
-        return self.stage.ports() + BufferedPipeline.ports(self)
+        return [self.p.i_data, self.n.o_data]
+
+
+class ExampleCombPipe(CombPipe):
+    """ an example of how to use the combinatorial pipeline.
+    """
+
+    def __init__(self):
+        CombPipe.__init__(self, ExampleStage)
 
 
 if __name__ == '__main__':
-    dut = BufPipe()
+    dut = ExampleBufPipe()
     vl = rtlil.convert(dut, ports=dut.ports())
     with open("test_bufpipe.il", "w") as f:
         f.write(vl)
+
+    dut = ExampleCombPipe()
+    vl = rtlil.convert(dut, ports=dut.ports())
+    with open("test_combpipe.il", "w") as f:
+        f.write(vl)