yosys/passes/pmgen/microchip_dsp_CREG.pmg

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// ISC License
//
// Copyright (C) 2024 Microchip Technology Inc. and its subsidiaries
//
// Permission to use, copy, modify, and/or distribute this software for any
// purpose with or without fee is hereby granted, provided that the above
// copyright notice and this permission notice appear in all copies.
//
// THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
// WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
// MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
// ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
// WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
// ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
// OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
// This file describes the second of three pattern matcher setups that
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// forms the `microchip_dsp` pass described in microchip_dsp.cc
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// At a high level, it works as follows:
// (1) Starting from a DSP cell that (a) doesn't have a CREG already,
// and (b) uses the 'C' port
// (2) Match the driver of the 'C' input to a possible $dff cell (CREG)
// (attached to at most two $mux cells that implement clock-enable or
// reset functionality, using a subpattern discussed below)
// Notes:
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// - Running CREG packing after microchip_dsp_pack is necessary since there is no
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// guarantee that the cell ordering corresponds to the "expected" case (i.e.
// the order in which they appear in the source) thus the possiblity existed
// where a register got packed as a CREG into a downstream DSP, while it should
// have otherwise been a PREG of an upstream DSP that had not been visited.
// yet.
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// - The reason this is separated out from the microchip_dsp.pmg file is
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// for efficiency --- each *.pmg file creates a class of the same basename,
// which when constructed, creates a custom database tailored to the
// pattern(s) contained within. Since the pattern in this file must be
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// executed after the pattern contained in microchip_dsp.pmg, it is necessary
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// to reconstruct this database. Separating the two patterns into
// independent files causes two smaller, more specific, databases.
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pattern microchip_dsp_packC
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udata <std::function<SigSpec(const SigSpec&)>> unextend
state <SigBit> clock
state <SigSpec> sigC sigP
state <Cell*> ffC
// Variables used for subpatterns
state <SigSpec> argQ argD
state <int> ffoffset
udata <SigSpec> dffD dffQ
udata <SigBit> dffclock
udata <Cell*> dff
// (1) Starting from a DSP cell that (a) doesn't have a CREG already,
// and (b) uses the 'C' port
match dsp
select dsp->type.in(\MACC_PA)
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select port(dsp, \C_BYPASS, SigSpec()).is_fully_ones()
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select nusers(port(dsp, \C, SigSpec())) > 1
endmatch
code sigC sigP clock
//helper function to remove unused bits
unextend = [](const SigSpec &sig) {
int i;
for (i = GetSize(sig)-1; i > 0; i--)
if (sig[i] != sig[i-1])
break;
// Do not remove non-const sign bit
if (sig[i].wire)
++i;
return sig.extract(0, i);
};
sigC = unextend(port(dsp, \C, SigSpec()));
SigSpec P = port(dsp, \P);
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// Only care about those bits that are used
int i;
for (i = GetSize(P)-1; i >= 0; i--)
if (nusers(P[i]) > 1)
break;
i++;
log_assert(nusers(P.extract_end(i)) <= 1);
sigP = P.extract(0, i);
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clock = port(dsp, \CLK, SigBit());
endcode
// (2) Match the driver of the 'C' input to a possible $dff cell (CREG)
// (attached to at most two $mux cells that implement clock-enable or
// reset functionality, using the in_dffe subpattern)
code argQ ffC sigC clock
argQ = sigC;
subpattern(in_dffe);
if (dff) {
ffC = dff;
clock = dffclock;
sigC = dffD;
}
endcode
code
if (ffC)
accept;
endcode
// #######################
// Subpattern for matching against input registers, based on knowledge of the
// 'Q' input.
subpattern in_dffe
arg argQ clock
code
dff = nullptr;
if (argQ.empty())
reject;
for (const auto &c : argQ.chunks()) {
// Abandon matches when 'Q' is a constant
if (!c.wire)
reject;
// Abandon matches when 'Q' has the keep attribute set
if (c.wire->get_bool_attribute(\keep))
reject;
// Abandon matches when 'Q' has a non-zero init attribute set
Const init = c.wire->attributes.at(\init, Const());
if (!init.empty())
for (auto b : init.extract(c.offset, c.width))
if (b != State::Sx && b != State::S0)
reject;
}
endcode
match ff
select ff->type.in($dff, $dffe, $sdff, $sdffe, $adff, $adffe)
// does not support clock inversion
select param(ff, \CLK_POLARITY).as_bool()
slice offset GetSize(port(ff, \D))
index <SigBit> port(ff, \Q)[offset] === argQ[0]
// Check that the rest of argQ is present
filter GetSize(port(ff, \Q)) >= offset + GetSize(argQ)
filter port(ff, \Q).extract(offset, GetSize(argQ)) == argQ
filter clock == SigBit() || port(ff, \CLK)[0] == clock
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endmatch
code argQ
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// Check that reset value, if present, is fully 0.
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bool noResetFlop = ff->type.in($dff, $dffe);
bool srstZero = ff->type.in($sdff, $sdffe) && param(ff, \SRST_VALUE).is_fully_zero();
bool arstZero = ff->type.in($adff, $adffe) && param(ff, \ARST_VALUE).is_fully_zero();
bool resetLegal = noResetFlop || srstZero || arstZero;
if (resetLegal)
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{
SigSpec Q = port(ff, \Q);
dff = ff;
dffclock = port(ff, \CLK);
dffD = argQ;
SigSpec D = port(ff, \D);
argQ = Q;
dffD.replace(argQ, D);
}
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endcode