This can cause confusion:
* If the erroneous object is None, it is printed as 'None', which
appears as a string (and could be the result of converting None
to a string.)
* If the erroneous object is a string, it is printed as ''<val>'',
which is a rather strange combination of quotes.
The write port priority in Yosys is derived directly from the order
in which the ports are declared in the Verilog frontend. It is being
removed for several reasons:
1. It is not clear if it works correctly for all cases (FFRAM,
LUTRAM, BRAM).
2. Although it is roundtripped via Verilog with correct simulation
semantics, the resulting code has a high chance of being
interpreted incorrectly by Xilinx tools.
3. It cannot be roundtripped via FIRRTL, which is an alternative
backend that is an interesting future option. (FIRRTL leaves
write collision completely undefined.)
3. It is a niche feature that, if it is needed, can be completely
replaced using an explicit comparator, priority encoder, and
write enable gating circuit. (This is what Xilinx recommends
for handling this case.)
In the future we should extend nMigen's formal verification to assert
that a write collision does not happen.
Almost no code would specify Signal(_, name) as a positional argument
on purpose, but forgetting parens and accidentally placing signedness
into the name position is so common that we had a test for it.
Unless exact_depth=True is specified.
The logic introduced in this commit is idempotent: that is, if one
uses the depth of one AsyncFIFOBuffered in the constructor of another
AsyncFIFOBuffered, they will end up with the same depth. More naive
logic would result in an unbounded, quadratic growth with each such
step.
Fixes#219.
These functions were originally changed in 3ed51938, in an attempt
to make them take one cycle instead of two. However, this does not
actually work because of drawbacks of the simulator interface.
Avoid committing to any specific implementation for now, and instead
make them compat-only extensions.
Before this commit, it was possible to set and get clock constraints
placed on Pin objects. This was not a very good implementation, since
it relied on matching the identity of the provided Pin object to
a previously requested one. The only reason it worked like that is
deficiencies in nextpnr.
Since then, nextpnr has been fixed to allow setting constraints on
arbitrary nets. Correspondingly, backends that are using Synplify
were changed to use [get_nets] instead of [get_ports] in SDC files.
However, in some situations, Synplify does not allow specifying
ports in [get_nets]. (In fact, nextpnr had a similar problem, but
it has also been fixed.)
The simplest way to address this is to refer to the interior net
(after the input buffer), which always works. The only downside
of this is that requesting a clock as a raw pin using
platform.request("clk", dir="-")
and directly applying a constraint to it could fail in some cases.
This is not a significant issue.
This is necessary for consistency, since for transparent read ports,
we currently do not support .en at all (it is fixed at 1) due to
YosysHQ/yosys#760. Before this commit, changing port transparency
would require adding or removing an assignment to .en, which is
confusing and error-prone.
Also, most read ports are always enabled, so this behavior is also
convenient.
Also, replace `bits, sign = x.shape()` with more idiomatic
`width, signed = x.shape()`.
This unifies all properties corresponding to `len(x)` to `x.width`.
(Not all values have a `width` property.)
Fixes#210.
This obscure functionality was likely only ever used in old MiSoC
code, and doesn't justify the added complexity. It was also not
provided (and could not be reasonably provided) in SyncFIFOBuffered,
which made its utility extremely marginal.
Platform.prepare() was completely broken after addition of local
clock domains, and only really worked before by a series of
accidents because there was a circular dependency between creation
of missing domains, fragment preparation, and insertion of pin
subfragments.
This commit untangles the dependency by adding a separate public
method Fragment.create_missing_domains(), used in build.plat.
It also makes DomainCollector consider both used and defined domains,
such that it will work on fragments before domain propagation, since
create_missing_domains() can be called by user code before prepare().
The fragment driving missing clock domain is not flattened anymore,
because flattening does not work well combined with local domains.
