Copyright | (C) 2013-2016 University of Twente 2017-2022 Google Inc. 2019 Myrtle Software Ltd 2021-2023 QBayLogic B.V. |
---|---|
License | BSD2 (see the file LICENSE) |
Maintainer | QBayLogic B.V. <devops@qbaylogic.com> |
Safe Haskell | Unsafe |
Language | Haskell2010 |
Extensions |
|
Synopsis
- assert :: (KnownDomain dom, Eq a, ShowX a) => Clock dom -> Reset dom -> String -> Signal dom a -> Signal dom a -> Signal dom b -> Signal dom b
- assertBitVector :: (KnownDomain dom, KnownNat n) => Clock dom -> Reset dom -> String -> Signal dom (BitVector n) -> Signal dom (BitVector n) -> Signal dom b -> Signal dom b
- ignoreFor :: forall dom n a. KnownDomain dom => Clock dom -> Reset dom -> Enable dom -> SNat n -> a -> Signal dom a -> Signal dom a
- stimuliGenerator :: forall l dom a. (KnownNat l, KnownDomain dom) => Clock dom -> Reset dom -> Vec l a -> Signal dom a
- tbClockGen :: KnownDomain testDom => Signal testDom Bool -> Clock testDom
- tbEnableGen :: Enable tag
- tbSystemClockGen :: Signal System Bool -> Clock System
- clockToDiffClock :: KnownDomain dom => Clock dom -> DiffClock dom
- outputVerifier :: forall l a testDom circuitDom. (KnownNat l, KnownDomain testDom, KnownDomain circuitDom, Eq a, ShowX a, 1 <= l) => Clock testDom -> Clock circuitDom -> Reset testDom -> Vec l a -> Signal circuitDom a -> Signal testDom Bool
- outputVerifier' :: forall l a dom. (KnownNat l, KnownDomain dom, Eq a, ShowX a, 1 <= l) => Clock dom -> Reset dom -> Vec l a -> Signal dom a -> Signal dom Bool
- outputVerifierBitVector :: forall l n testDom circuitDom. (KnownNat l, KnownNat n, KnownDomain testDom, KnownDomain circuitDom, 1 <= l) => Clock testDom -> Clock circuitDom -> Reset testDom -> Vec l (BitVector n) -> Signal circuitDom (BitVector n) -> Signal testDom Bool
- outputVerifierBitVector' :: forall l n dom. (KnownNat l, KnownNat n, KnownDomain dom, 1 <= l) => Clock dom -> Reset dom -> Vec l (BitVector n) -> Signal dom (BitVector n) -> Signal dom Bool
- biTbClockGen :: forall testDom circuitDom. (KnownDomain testDom, KnownDomain circuitDom) => Signal testDom Bool -> (Clock testDom, Clock circuitDom)
- unsafeSimSynchronizer :: forall dom1 dom2 a. (KnownDomain dom1, KnownDomain dom2) => Clock dom1 -> Clock dom2 -> Signal dom1 a -> Signal dom2 a
- outputVerifierWith :: forall l a testDom circuitDom. (KnownNat l, KnownDomain testDom, KnownDomain circuitDom, Eq a, ShowX a, 1 <= l) => (Clock testDom -> Reset testDom -> Signal testDom a -> Signal testDom a -> Signal testDom Bool -> Signal testDom Bool) -> Clock testDom -> Clock circuitDom -> Reset testDom -> Vec l a -> Signal circuitDom a -> Signal testDom Bool
Testbench functions for circuits
:: (KnownDomain dom, Eq a, ShowX a) | |
=> Clock dom | |
-> Reset dom | |
-> String | Additional message |
-> Signal dom a | Checked value |
-> Signal dom a | Expected value |
-> Signal dom b | Return value |
-> Signal dom b |
Compares the first two Signal
s for equality and logs a warning when they
are not equal. The second Signal
is considered the expected value. This
function simply returns the third Signal
unaltered as its result. This
function is used by outputVerifier
.
Usage in clashi
NB: When simulating a component that uses assert
in clashi
, usually,
the warnings are only logged the first time the component is simulated.
Issuing :reload
in clashi
will discard the cached result of the
computation, and warnings will once again be emitted.
NB: This function can be used in synthesizable designs.
:: (KnownDomain dom, KnownNat n) | |
=> Clock dom | |
-> Reset dom | |
-> String | Additional message |
-> Signal dom (BitVector n) | Checked value |
-> Signal dom (BitVector n) | Expected value |
-> Signal dom b | Return value |
-> Signal dom b |
The same as assert
, but can handle don't care bits in its expected value.
:: forall dom n a. KnownDomain dom | |
=> Clock dom | |
-> Reset dom | |
-> Enable dom | |
-> SNat n | Number of cycles to ignore incoming signal |
-> a | Value function produces when ignoring signal |
-> Signal dom a | Incoming signal |
-> Signal dom a | Either a passthrough of the incoming signal, or the static value provided as the second argument. |
Ignore signal for a number of cycles, while outputting a static value.
:: forall l dom a. (KnownNat l, KnownDomain dom) | |
=> Clock dom | Clock to which to synchronize the output signal |
-> Reset dom | |
-> Vec l a | Samples to generate |
-> Signal dom a | Signal of given samples |
Example:
testInput :: KnownDomain dom => Clock dom -> Reset dom ->Signal
dom Int testInput clk rst =stimuliGenerator
clk rst $(listToVecTH
[(1::Int),3..21])
>>>
sampleN 14 (testInput systemClockGen resetGen)
[1,1,3,5,7,9,11,13,15,17,19,21,21,21]
tbClockGen :: KnownDomain testDom => Signal testDom Bool -> Clock testDom Source #
Clock generator to be used in the testBench function.
To be used like:
clkSystem en = tbClockGen @System en
Example
module Example where import Clash.Explicit.Prelude import Clash.Explicit.Testbench -- Fast domain: twice as fast as "Slow"createDomain
vSystem
{vName="Fast", vPeriod=10} -- Slow domain: twice as slow as "Fast"createDomain
vSystem
{vName="Slow", vPeriod=20} topEntity ::Clock
"Fast" ->Reset
"Fast" ->Enable
"Fast" ->Clock
"Slow" ->Signal
"Fast" (Unsigned 8) ->Signal
"Slow" (Unsigned 8, Unsigned 8) topEntity clk1 rst1 en1 clk2 i = let h = register clk1 rst1 en1 0 (register clk1 rst1 en1 0 i) l = register clk1 rst1 en1 0 i in unsafeSynchronizer clk1 clk2 (bundle (h, l)) testBench ::Signal
"Slow" Bool testBench = done where testInput =stimuliGenerator
clkA1 rstA1 $(listToVecTH
[1::Unsigned 8,2,3,4,5,6,7,8]) expectedOutput =outputVerifier
clkB2 rstB2 $(listToVecTH
[(0,0) :: (Unsigned 8, Unsigned 8),(1,2),(3,4),(5,6),(7,8)]) done = expectedOutput (topEntity clkA1 rstA1 enableGen clkB2 testInput) notDone = not <$> done clkA1 =tbClockGen
@"Fast" (unsafeSynchronizer clkB2 clkA1 notDone) clkB2 =tbClockGen
@"Slow" notDone rstA1 =resetGen
@"Fast" rstB2 =resetGen
@"Slow"
tbEnableGen :: Enable tag Source #
Enable signal that's always enabled. Because it has a blackbox definition this enable signal is opaque to other blackboxes. It will therefore never be optimized away.
tbSystemClockGen :: Signal System Bool -> Clock System Source #
Clock generator for the System
clock domain.
NB: Can be used in the testBench function
Example
topEntity :: Vec 2 (Vec 3 (Unsigned 8)) -> Vec 6 (Unsigned 8)
topEntity = concat
testBench :: Signal System Bool
testBench = done
where
testInput = pure ((1 :> 2 :> 3 :> Nil) :> (4 :> 5 :> 6 :> Nil) :> Nil)
expectedOutput = outputVerifier' ((1:>2:>3:>4:>5:>6:>Nil):>Nil)
done = exposeClockResetEnable (expectedOutput (topEntity <$> testInput)) clk rst
clk = tbSystemClockGen
(not <$> done)
rst = systemResetGen
:: KnownDomain dom | |
=> Clock dom | Single-ended input |
-> DiffClock dom | Differential output |
Convert a single-ended clock to a differential clock
The tbClockGen
function generates a single-ended clock. This function will
output the two phases of a differential clock corresponding to that
single-ended clock.
This function is only meant to be used in the testBench function, not to create a differential output in hardware.
Example:
clk = clockToDiffClock $ tbClockGen (not <$> done)
:: forall l a testDom circuitDom. (KnownNat l, KnownDomain testDom, KnownDomain circuitDom, Eq a, ShowX a, 1 <= l) | |
=> Clock testDom | Clock to which the test bench is synchronized (but not necessarily the circuit under test) |
-> Clock circuitDom | Clock to which the circuit under test is synchronized |
-> Reset testDom | Reset line of test bench |
-> Vec l a | Samples to compare with |
-> Signal circuitDom a | Signal to verify |
-> Signal testDom Bool | True if all samples are verified |
Compare a signal (coming from a circuit) to a vector of samples. If a
sample from the signal is not equal to the corresponding sample in the
vector, print to stderr and continue testing. This function is
synthesizable in the sense that HDL simulators will run it. If testDom
and
circuitDom
refer to the same domain, it can also be synthesized into
hardware.
NB: This function uses assert
. When simulating this function in
clashi
, read the note.
Example:
expectedOutput :: Clock dom -> Reset dom ->Signal
dom Int ->Signal
dom Bool expectedOutput clk rst =outputVerifier
clk rst $(listToVecTH
([70,99,2,3,4,5,7,8,9,10]::[Int]))
>>>
import qualified Data.List as List
>>>
sampleN 12 (expectedOutput systemClockGen resetGen (fromList (0:[0..10] List.++ [10,10,10])))
cycle(<Clock: System>): 0, outputVerifier expected value: 70, not equal to actual value: 0 [False cycle(<Clock: System>): 1, outputVerifier expected value: 70, not equal to actual value: 0 ,False cycle(<Clock: System>): 2, outputVerifier expected value: 99, not equal to actual value: 1 ,False,False,False,False,False cycle(<Clock: System>): 7, outputVerifier expected value: 7, not equal to actual value: 6 ,False cycle(<Clock: System>): 8, outputVerifier expected value: 8, not equal to actual value: 7 ,False cycle(<Clock: System>): 9, outputVerifier expected value: 9, not equal to actual value: 8 ,False cycle(<Clock: System>): 10, outputVerifier expected value: 10, not equal to actual value: 9 ,False,True]
If you're working with BitVector
s containing don't care bits you should
use outputVerifierBitVector
.
:: forall l a dom. (KnownNat l, KnownDomain dom, Eq a, ShowX a, 1 <= l) | |
=> Clock dom | Clock to which the test bench is synchronized |
-> Reset dom | Reset line of test bench |
-> Vec l a | Samples to compare with |
-> Signal dom a | Signal to verify |
-> Signal dom Bool | Indicator that all samples are verified |
Same as outputVerifier
but used in cases where the test bench domain and
the domain of the circuit under test are the same.
outputVerifierBitVector Source #
:: forall l n testDom circuitDom. (KnownNat l, KnownNat n, KnownDomain testDom, KnownDomain circuitDom, 1 <= l) | |
=> Clock testDom | Clock to which the test bench is synchronized (but not necessarily the circuit under test) |
-> Clock circuitDom | Clock to which the circuit under test is synchronized |
-> Reset testDom | Reset line of test bench |
-> Vec l (BitVector n) | Samples to compare with |
-> Signal circuitDom (BitVector n) | Signal to verify |
-> Signal testDom Bool | Indicator that all samples are verified |
Same as outputVerifier
, but can handle don't care bits in its
expected values.
outputVerifierBitVector' Source #
:: forall l n dom. (KnownNat l, KnownNat n, KnownDomain dom, 1 <= l) | |
=> Clock dom | Clock to which the input signal is synchronized |
-> Reset dom | |
-> Vec l (BitVector n) | Samples to compare with |
-> Signal dom (BitVector n) | Signal to verify |
-> Signal dom Bool | Indicator that all samples are verified |
Same as outputVerifier'
, but can handle don't care bits in its expected
values.
biTbClockGen :: forall testDom circuitDom. (KnownDomain testDom, KnownDomain circuitDom) => Signal testDom Bool -> (Clock testDom, Clock circuitDom) Source #
Same as tbClockGen
, but returns two clocks on potentially different
domains. To be used in situations where the test circuit potentially operates
on a different clock than the device under test.
unsafeSimSynchronizer Source #
:: forall dom1 dom2 a. (KnownDomain dom1, KnownDomain dom2) | |
=> Clock dom1 |
|
-> Clock dom2 |
|
-> Signal dom1 a | |
-> Signal dom2 a |
Cross clock domains in a way that is unsuitable for hardware but good enough for simulation.
It's equal to unsafeSynchronizer
but will warn when used outside of a test
bench. outputVerifier
uses this function when it needs to cross between
clock domains, which will render it unsuitable for synthesis, but good enough
for simulating the generated HDL.
:: forall l a testDom circuitDom. (KnownNat l, KnownDomain testDom, KnownDomain circuitDom, Eq a, ShowX a, 1 <= l) | |
=> (Clock testDom -> Reset testDom -> Signal testDom a -> Signal testDom a -> Signal testDom Bool -> Signal testDom Bool) | The |
-> Clock testDom | Clock to which the test bench is synchronized (but not necessarily the circuit under test) |
-> Clock circuitDom | Clock to which the circuit under test is synchronized |
-> Reset testDom | Reset line of test bench |
-> Vec l a | Samples to compare with |
-> Signal circuitDom a | Signal to verify |
-> Signal testDom Bool | True if all samples are verified |