2019-10-04 14:40:34 -05:00
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// This file describes the second of three pattern matcher setups that
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// forms the `xilinx_dsp` pass described in xilinx_dsp.cc
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// At a high level, it works as follows:
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// (1) Starting from a DSP48E1 cell that (a) doesn't have a CREG already,
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// and (b) uses the 'C' port
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// (2) Match the driver of the 'C' input to a possible $dff cell (CREG)
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// (attached to at most two $mux cells that implement clock-enable or
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// reset functionality, using a subpattern discussed below)
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// Notes:
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2019-10-05 00:24:15 -05:00
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// - Running CREG packing after xilinx_dsp_pack is necessary since there is no
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// guarantee that the cell ordering corresponds to the "expected" case (i.e.
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// the order in which they appear in the source) thus the possiblity existed
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// that a register got packed as a CREG into a downstream DSP that should
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// have otherwise been a PREG of an upstream DSP that had not been visited
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// yet
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2019-10-04 14:40:34 -05:00
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// - The reason this is separated out from the xilinx_dsp.pmg file is
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// for efficiency --- each *.pmg file creates a class of the same basename,
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// which when constructed, creates a custom database tailored to the
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// pattern(s) contained within. Since the pattern in this file must be
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// executed after the pattern contained in xilinx_dsp.pmg, it is necessary
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// to reconstruct this database. Separating the two patterns into
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// independent files causes two smaller, more specific, databases.
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2019-09-23 15:27:10 -05:00
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pattern xilinx_dsp_packC
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udata <std::function<SigSpec(const SigSpec&)>> unextend
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state <SigBit> clock
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state <SigSpec> sigC sigP
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state <bool> ffCcepol ffCrstpol
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state <Cell*> ffC ffCcemux ffCrstmux
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2019-10-05 00:24:15 -05:00
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// Variables used for subpatterns
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2019-09-23 15:27:10 -05:00
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state <SigSpec> argQ argD
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state <bool> ffcepol ffrstpol
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state <int> ffoffset
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udata <SigSpec> dffD dffQ
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udata <SigBit> dffclock
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udata <Cell*> dff dffcemux dffrstmux
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udata <bool> dffcepol dffrstpol
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2019-10-04 14:40:34 -05:00
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// (1) Starting from a DSP48E1 cell that (a) doesn't have a CREG already,
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// and (b) uses the 'C' port
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2019-09-23 15:27:10 -05:00
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match dsp
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select dsp->type.in(\DSP48E1)
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select param(dsp, \CREG, 1).as_int() == 0
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select nusers(port(dsp, \C, SigSpec())) > 1
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endmatch
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2019-10-04 14:43:19 -05:00
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code sigC sigP clock
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2019-09-23 15:27:10 -05:00
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unextend = [](const SigSpec &sig) {
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int i;
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for (i = GetSize(sig)-1; i > 0; i--)
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if (sig[i] != sig[i-1])
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break;
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// Do not remove non-const sign bit
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if (sig[i].wire)
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++i;
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return sig.extract(0, i);
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};
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sigC = unextend(port(dsp, \C, SigSpec()));
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SigSpec P = port(dsp, \P);
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if (param(dsp, \USE_MULT, Const("MULTIPLY")).decode_string() == "MULTIPLY") {
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// Only care about those bits that are used
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int i;
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2019-11-18 01:19:53 -06:00
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for (i = GetSize(P)-1; i >= 0; i--)
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if (nusers(P[i]) > 1)
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2019-09-23 15:27:10 -05:00
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break;
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2019-11-18 01:19:53 -06:00
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i++;
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2019-09-23 15:27:10 -05:00
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log_assert(nusers(P.extract_end(i)) <= 1);
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2019-11-18 01:19:53 -06:00
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sigP = P.extract(0, i);
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2019-09-23 15:27:10 -05:00
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}
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else
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sigP = P;
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2019-10-04 14:43:19 -05:00
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clock = port(dsp, \CLK, SigBit());
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2019-10-04 14:40:34 -05:00
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endcode
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2019-09-23 15:27:10 -05:00
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2019-10-04 14:40:34 -05:00
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// (2) Match the driver of the 'C' input to a possible $dff cell (CREG)
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// (attached to at most two $mux cells that implement clock-enable or
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2019-10-04 15:31:44 -05:00
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// reset functionality, using the in_dffe subpattern)
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2019-10-04 14:40:34 -05:00
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code argQ ffC ffCcemux ffCrstmux ffCcepol ffCrstpol sigC clock
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2019-09-23 15:27:10 -05:00
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argQ = sigC;
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subpattern(in_dffe);
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if (dff) {
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ffC = dff;
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clock = dffclock;
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if (dffrstmux) {
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ffCrstmux = dffrstmux;
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ffCrstpol = dffrstpol;
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}
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if (dffcemux) {
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ffCcemux = dffcemux;
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ffCcepol = dffcepol;
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}
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sigC = dffD;
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}
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endcode
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code
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if (ffC)
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accept;
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endcode
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// #######################
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2019-10-04 15:31:44 -05:00
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// Subpattern for matching against input registers, based on knowledge of the
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2019-10-05 10:57:37 -05:00
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// 'Q' input. Typically, identifying registers with clock-enable and reset
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// capability would be a task would be handled by other Yosys passes such as
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// dff2dffe, but since DSP inference happens much before this, these patterns
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// have to be manually identified.
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2019-10-04 15:31:44 -05:00
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// At a high level:
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// (1) Starting from a $dff cell that (partially or fully) drives the given
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// 'Q' argument
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// (2) Match for a $mux cell implementing synchronous reset semantics ---
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// one that exclusively drives the 'D' input of the $dff, with one of its
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// $mux inputs being fully zero
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// (3) Match for a $mux cell implement clock enable semantics --- one that
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// exclusively drives the 'D' input of the $dff (or the other input of
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// the reset $mux) and where one of this $mux's inputs is connected to
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// the 'Q' output of the $dff
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2019-09-23 15:27:10 -05:00
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subpattern in_dffe
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arg argD argQ clock
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code
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dff = nullptr;
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2019-10-04 15:31:44 -05:00
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for (const auto &c : argQ.chunks()) {
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// Abandon matches when 'Q' is a constant
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2019-09-23 15:27:10 -05:00
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if (!c.wire)
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reject;
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2019-10-04 15:31:44 -05:00
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// Abandon matches when 'Q' has the keep attribute set
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2019-09-23 15:27:10 -05:00
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if (c.wire->get_bool_attribute(\keep))
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reject;
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2019-10-04 15:31:44 -05:00
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// Abandon matches when 'Q' has a non-zero init attribute set
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// (not supported by DSP48E1)
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Const init = c.wire->attributes.at(\init, Const());
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for (auto b : init.extract(c.offset, c.width))
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if (b != State::Sx && b != State::S0)
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reject;
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2019-09-23 15:27:10 -05:00
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}
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endcode
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2019-10-04 15:31:44 -05:00
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// (1) Starting from a $dff cell that (partially or fully) drives the given
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// 'Q' argument
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2019-09-23 15:27:10 -05:00
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match ff
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select ff->type.in($dff)
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// DSP48E1 does not support clock inversion
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select param(ff, \CLK_POLARITY).as_bool()
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slice offset GetSize(port(ff, \D))
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index <SigBit> port(ff, \Q)[offset] === argQ[0]
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// Check that the rest of argQ is present
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filter GetSize(port(ff, \Q)) >= offset + GetSize(argQ)
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filter port(ff, \Q).extract(offset, GetSize(argQ)) == argQ
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2019-10-04 15:31:44 -05:00
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filter clock == SigBit() || port(ff, \CLK) == clock
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2019-09-23 15:27:10 -05:00
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set ffoffset offset
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endmatch
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code argQ argD
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SigSpec Q = port(ff, \Q);
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dff = ff;
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dffclock = port(ff, \CLK);
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dffD = argQ;
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argD = port(ff, \D);
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argQ = Q;
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dffD.replace(argQ, argD);
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// Only search for ffrstmux if dffD only
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// has two (ff, ffrstmux) users
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if (nusers(dffD) > 2)
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argD = SigSpec();
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endcode
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2019-10-04 15:31:44 -05:00
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// (2) Match for a $mux cell implementing synchronous reset semantics ---
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// exclusively drives the 'D' input of the $dff, with one of the $mux
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// inputs being fully zero
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2019-09-23 15:27:10 -05:00
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match ffrstmux
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if !argD.empty()
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select ffrstmux->type.in($mux)
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index <SigSpec> port(ffrstmux, \Y) === argD
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choice <IdString> BA {\B, \A}
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// DSP48E1 only supports reset to zero
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select port(ffrstmux, BA).is_fully_zero()
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define <bool> pol (BA == \B)
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set ffrstpol pol
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semioptional
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endmatch
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code argD
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if (ffrstmux) {
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dffrstmux = ffrstmux;
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dffrstpol = ffrstpol;
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argD = port(ffrstmux, ffrstpol ? \A : \B);
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dffD.replace(port(ffrstmux, \Y), argD);
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// Only search for ffcemux if argQ has at
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// least 3 users (ff, <upstream>, ffrstmux) and
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// dffD only has two (ff, ffrstmux)
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if (!(nusers(argQ) >= 3 && nusers(dffD) == 2))
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argD = SigSpec();
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}
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else
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dffrstmux = nullptr;
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endcode
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2019-10-04 15:31:44 -05:00
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// (3) Match for a $mux cell implement clock enable semantics --- one that
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// exclusively drives the 'D' input of the $dff (or the other input of
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// the reset $mux) and where one of this $mux's inputs is connected to
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// the 'Q' output of the $dff
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2019-09-23 15:27:10 -05:00
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match ffcemux
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if !argD.empty()
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select ffcemux->type.in($mux)
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index <SigSpec> port(ffcemux, \Y) === argD
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choice <IdString> AB {\A, \B}
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index <SigSpec> port(ffcemux, AB) === argQ
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define <bool> pol (AB == \A)
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set ffcepol pol
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semioptional
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endmatch
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code argD
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if (ffcemux) {
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dffcemux = ffcemux;
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dffcepol = ffcepol;
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argD = port(ffcemux, ffcepol ? \B : \A);
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dffD.replace(port(ffcemux, \Y), argD);
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}
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else
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dffcemux = nullptr;
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endcode
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