pattern xilinx_dsp_pack state clock state sigA sigB sigC sigD sigM sigP state postAddAB postAddMuxAB state ffA1cepol ffA2cepol ffADcepol ffB1cepol ffB2cepol ffDcepol ffMcepol ffPcepol state ffArstpol ffADrstpol ffBrstpol ffDrstpol ffMrstpol ffPrstpol state ffAD ffADcemux ffADrstmux ffA1 ffA1cemux ffA1rstmux ffA2 ffA2cemux ffA2rstmux state ffB1 ffB1cemux ffB1rstmux ffB2 ffB2cemux ffB2rstmux state ffD ffDcemux ffDrstmux ffM ffMcemux ffMrstmux ffP ffPcemux ffPrstmux // subpattern state argQ argD state ffcepol ffrstpol state ffoffset udata dffD dffQ udata dffclock udata dff dffcemux dffrstmux udata dffcepol dffrstpol match dsp select dsp->type.in(\DSP48E1) endmatch code sigA sigB sigC sigD sigM clock auto 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); }; sigA = unextend(port(dsp, \A)); sigB = unextend(port(dsp, \B)); sigC = port(dsp, \C, SigSpec()); sigD = port(dsp, \D, SigSpec()); SigSpec P = port(dsp, \P); if (param(dsp, \USE_MULT, Const("MULTIPLY")).decode_string() == "MULTIPLY") { // Only care about those bits that are used int i; for (i = 0; i < GetSize(P); i++) { if (nusers(P[i]) <= 1) break; sigM.append(P[i]); } log_assert(nusers(P.extract_end(i)) <= 1); } else sigM = P; // This sigM could have no users if downstream $add // is narrower than $mul result, for example if (sigM.empty()) reject; clock = port(dsp, \CLK, SigBit()); endcode code argQ ffAD ffADcemux ffADrstmux ffADcepol ffADrstpol sigA clock if (param(dsp, \ADREG).as_int() == 0) { argQ = sigA; subpattern(in_dffe); if (dff) { ffAD = dff; clock = dffclock; if (dffrstmux) { ffADrstmux = dffrstmux; ffADrstpol = dffrstpol; } if (dffcemux) { ffADcemux = dffcemux; ffADcepol = dffcepol; } sigA = dffD; } } endcode match preAdd if sigD.empty() || sigD.is_fully_zero() // Ensure that preAdder not already used if param(dsp, \USE_DPORT, Const("FALSE")).decode_string() == "FALSE" if port(dsp, \INMODE, Const(0, 5)).is_fully_zero() select preAdd->type.in($add) // Output has to be 25 bits or less select GetSize(port(preAdd, \Y)) <= 25 select nusers(port(preAdd, \Y)) == 2 choice AB {\A, \B} // A port has to be 30 bits or less select GetSize(port(preAdd, AB)) <= 30 define BA (AB == \A ? \B : \A) // D port has to be 25 bits or less select GetSize(port(preAdd, BA)) <= 25 index port(preAdd, \Y) === sigA optional endmatch code sigA sigD if (preAdd) { sigA = port(preAdd, \A); sigD = port(preAdd, \B); if (GetSize(sigA) < GetSize(sigD)) std::swap(sigA, sigD); } endcode code argQ ffAD ffADcemux ffADrstmux ffADcepol ffADrstpol sigA clock ffA2 ffA2cemux ffA2rstmux ffA2cepol ffArstpol ffA1 ffA1cemux ffA1rstmux ffA1cepol // Only search for ffA2 if there was a pre-adder // (otherwise ffA2 would have been matched as ffAD) if (preAdd) { if (param(dsp, \AREG).as_int() == 0) { argQ = sigA; subpattern(in_dffe); if (dff) { ffA2 = dff; clock = dffclock; if (dffrstmux) { ffA2rstmux = dffrstmux; ffArstpol = dffrstpol; } if (dffcemux) { ffA2cepol = dffcepol; ffA2cemux = dffcemux; } sigA = dffD; } } } // And if there wasn't a pre-adder, // move AD register to A else if (ffAD) { log_assert(!ffA2 && !ffA2cemux && !ffA2rstmux); std::swap(ffA2, ffAD); std::swap(ffA2cemux, ffADcemux); std::swap(ffA2rstmux, ffADrstmux); ffA2cepol = ffADcepol; ffArstpol = ffADrstpol; } // Now attempt to match A1 if (ffA2) { argQ = sigA; subpattern(in_dffe); if (dff) { if ((ffA2rstmux != nullptr) ^ (dffrstmux != nullptr)) goto ffA1_end; if (dffrstmux) { if (ffArstpol != dffrstpol) goto ffA1_end; if (port(ffA2rstmux, \S) != port(dffrstmux, \S)) goto ffA1_end; ffA1rstmux = dffrstmux; } ffA1 = dff; clock = dffclock; if (dffcemux) { ffA1cemux = dffcemux; ffA1cepol = dffcepol; } sigA = dffD; ffA1_end: ; } } endcode code argQ ffB2 ffB2cemux ffB2rstmux ffB2cepol ffBrstpol sigB clock ffB1 ffB1cemux ffB1rstmux ffB1cepol if (param(dsp, \BREG).as_int() == 0) { argQ = sigB; subpattern(in_dffe); if (dff) { ffB2 = dff; clock = dffclock; if (dffrstmux) { ffB2rstmux = dffrstmux; ffBrstpol = dffrstpol; } if (dffcemux) { ffB2cemux = dffcemux; ffB2cepol = dffcepol; } sigB = dffD; // Now attempt to match B1 if (ffB2) { argQ = sigB; subpattern(in_dffe); if (dff) { if ((ffB2rstmux != nullptr) ^ (dffrstmux != nullptr)) goto ffB1_end; if (dffrstmux) { if (ffBrstpol != dffrstpol) goto ffB1_end; if (port(ffB2rstmux, \S) != port(dffrstmux, \S)) goto ffB1_end; ffB1rstmux = dffrstmux; } ffB1 = dff; clock = dffclock; if (dffcemux) { ffB1cemux = dffcemux; ffB1cepol = dffcepol; } sigB = dffD; ffB1_end: ; } } } } endcode code argQ ffD ffDcemux ffDrstmux ffDcepol ffDrstpol sigD clock if (param(dsp, \DREG).as_int() == 0) { argQ = sigD; subpattern(in_dffe); if (dff) { ffD = dff; clock = dffclock; if (dffrstmux) { ffDrstmux = dffrstmux; ffDrstpol = dffrstpol; } if (dffcemux) { ffDcemux = dffcemux; ffDcepol = dffcepol; } sigD = dffD; } } endcode code argD ffM ffMcemux ffMrstmux ffMcepol ffMrstpol sigM sigP clock if (param(dsp, \MREG).as_int() == 0 && nusers(sigM) == 2) { argD = sigM; subpattern(out_dffe); if (dff) { ffM = dff; clock = dffclock; if (dffrstmux) { ffMrstmux = dffrstmux; ffMrstpol = dffrstpol; } if (dffcemux) { ffMcemux = dffcemux; ffMcepol = dffcepol; } sigM = dffQ; } } sigP = sigM; endcode match postAdd // Ensure that Z mux is not already used if port(dsp, \OPMODE, SigSpec()).extract(4,3).is_fully_zero() select postAdd->type.in($add) select GetSize(port(postAdd, \Y)) <= 48 choice AB {\A, \B} select nusers(port(postAdd, AB)) <= 3 filter ffMcemux || nusers(port(postAdd, AB)) == 2 filter !ffMcemux || nusers(port(postAdd, AB)) == 3 index port(postAdd, AB)[0] === sigP[0] filter GetSize(port(postAdd, AB)) >= GetSize(sigP) filter port(postAdd, AB).extract(0, GetSize(sigP)) == sigP filter port(postAdd, AB).extract_end(GetSize(sigP)) == SigSpec(sigP[GetSize(sigP)-1], GetSize(port(postAdd, AB))-GetSize(sigP)) set postAddAB AB optional endmatch code sigC sigP if (postAdd) { sigC = port(postAdd, postAddAB == \A ? \B : \A); sigP = port(postAdd, \Y); } endcode code argD ffP ffPcemux ffPrstmux ffPcepol ffPrstpol sigP clock if (param(dsp, \PREG).as_int() == 0) { int users = 2; // If ffMcemux and no postAdd new-value net must have three users: ffMcemux, ffM and ffPcemux if (ffMcemux && !postAdd) users++; if (nusers(sigP) == users) { argD = sigP; subpattern(out_dffe); if (dff) { ffP = dff; clock = dffclock; if (dffrstmux) { ffPrstmux = dffrstmux; ffPrstpol = dffrstpol; } if (dffcemux) { ffPcemux = dffcemux; ffPcepol = dffcepol; } sigP = dffQ; } } } endcode match postAddMux if postAdd if ffP select postAddMux->type.in($mux) select nusers(port(postAddMux, \Y)) == 2 choice AB {\A, \B} index port(postAddMux, AB) === sigP index port(postAddMux, \Y) === sigC set postAddMuxAB AB optional endmatch code sigC if (postAddMux) sigC = port(postAddMux, postAddMuxAB == \A ? \B : \A); endcode match overflow if ffP if param(dsp, \USE_PATTERN_DETECT, Const("NO_PATDET")).decode_string() == "NO_PATDET" select overflow->type.in($ge) select GetSize(port(overflow, \Y)) <= 48 select port(overflow, \B).is_fully_const() define B port(overflow, \B).as_const() select std::count(B.bits.begin(), B.bits.end(), State::S1) == 1 index port(overflow, \A) === sigP optional endmatch code accept; endcode // ####################### subpattern in_dffe arg argD argQ clock code dff = nullptr; for (auto c : argQ.chunks()) { if (!c.wire) reject; if (c.wire->get_bool_attribute(\keep)) reject; Const init = c.wire->attributes.at(\init, State::Sx); if (!init.is_fully_undef() && !init.is_fully_zero()) reject; } endcode match ff select ff->type.in($dff) // DSP48E1 does not support clock inversion select param(ff, \CLK_POLARITY).as_bool() slice offset GetSize(port(ff, \D)) index 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 set ffoffset offset endmatch code argQ argD { if (clock != SigBit() && port(ff, \CLK) != clock) reject; SigSpec Q = port(ff, \Q); dff = ff; dffclock = port(ff, \CLK); dffD = argQ; argD = port(ff, \D); argQ = Q; dffD.replace(argQ, argD); // Only search for ffrstmux if dffD only // has two (ff, ffrstmux) users if (nusers(dffD) > 2) argD = SigSpec(); } endcode match ffrstmux if !argD.empty() select ffrstmux->type.in($mux) index port(ffrstmux, \Y) === argD choice BA {\B, \A} // DSP48E1 only supports reset to zero select port(ffrstmux, BA).is_fully_zero() define pol (BA == \B) set ffrstpol pol semioptional endmatch code argD if (ffrstmux) { dffrstmux = ffrstmux; dffrstpol = ffrstpol; argD = port(ffrstmux, ffrstpol ? \A : \B); dffD.replace(port(ffrstmux, \Y), argD); // Only search for ffcemux if argQ has at // least 3 users (ff, , ffrstmux) and // dffD only has two (ff, ffrstmux) if (!(nusers(argQ) >= 3 && nusers(dffD) == 2)) argD = SigSpec(); } else dffrstmux = nullptr; endcode match ffcemux if !argD.empty() select ffcemux->type.in($mux) index port(ffcemux, \Y) === argD choice AB {\A, \B} index port(ffcemux, AB) === argQ define pol (AB == \A) set ffcepol pol semioptional endmatch code argD if (ffcemux) { dffcemux = ffcemux; dffcepol = ffcepol; argD = port(ffcemux, ffcepol ? \B : \A); dffD.replace(port(ffcemux, \Y), argD); } else dffcemux = nullptr; endcode // ####################### subpattern out_dffe arg argD argQ clock code dff = nullptr; for (auto c : argD.chunks()) if (c.wire->get_bool_attribute(\keep)) reject; endcode match ffcemux select ffcemux->type.in($mux) // ffcemux output must have two users: ffcemux and ff.D select nusers(port(ffcemux, \Y)) == 2 choice AB {\A, \B} // keep-last-value net must have at least three users: ffcemux, ff, downstream sink(s) select nusers(port(ffcemux, AB)) >= 3 slice offset GetSize(port(ffcemux, \Y)) define BA (AB == \A ? \B : \A) index port(ffcemux, BA)[offset] === argD[0] // Check that the rest of argD is present filter GetSize(port(ffcemux, BA)) >= offset + GetSize(argD) filter port(ffcemux, BA).extract(offset, GetSize(argD)) == argD set ffoffset offset define pol (AB == \A) set ffcepol pol semioptional endmatch code argD argQ dffcemux = ffcemux; if (ffcemux) { SigSpec BA = port(ffcemux, ffcepol ? \B : \A); SigSpec Y = port(ffcemux, \Y); argQ = argD; argD.replace(BA, Y); argQ.replace(BA, port(ffcemux, ffcepol ? \A : \B)); dffcemux = ffcemux; dffcepol = ffcepol; } endcode match ffrstmux select ffrstmux->type.in($mux) // ffrstmux output must have two users: ffrstmux and ff.D select nusers(port(ffrstmux, \Y)) == 2 choice BA {\B, \A} // DSP48E1 only supports reset to zero select port(ffrstmux, BA).is_fully_zero() slice offset GetSize(port(ffrstmux, \Y)) define AB (BA == \B ? \A : \B) index port(ffrstmux, AB)[offset] === argD[0] // Check that offset is consistent filter !ffcemux || ffoffset == offset // Check that the rest of argD is present filter GetSize(port(ffrstmux, AB)) >= offset + GetSize(argD) filter port(ffrstmux, AB).extract(offset, GetSize(argD)) == argD set ffoffset offset define pol (AB == \A) set ffrstpol pol semioptional endmatch code argD argQ dffrstmux = ffrstmux; if (ffrstmux) { SigSpec AB = port(ffrstmux, ffrstpol ? \A : \B); SigSpec Y = port(ffrstmux, \Y); argD.replace(AB, Y); dffrstmux = ffrstmux; dffrstpol = ffrstpol; } endcode match ff select ff->type.in($dff) // DSP48E1 does not support clock inversion select param(ff, \CLK_POLARITY).as_bool() slice offset GetSize(port(ff, \D)) index port(ff, \D)[offset] === argD[0] // Check that offset is consistent filter (!ffcemux && !ffrstmux) || ffoffset == offset // Check that the rest of argD is present filter GetSize(port(ff, \D)) >= offset + GetSize(argD) filter port(ff, \D).extract(offset, GetSize(argD)) == argD // Check that FF.Q is connected to CE-mux filter !ffcemux || port(ff, \Q).extract(offset, GetSize(argQ)) == argQ set ffoffset offset endmatch code argQ if (ff) { if (clock != SigBit() && port(ff, \CLK) != clock) reject; SigSpec D = port(ff, \D); SigSpec Q = port(ff, \Q); if (!ffcemux) { argQ = argD; argQ.replace(D, Q); } for (auto c : argQ.chunks()) { Const init = c.wire->attributes.at(\init, State::Sx); if (!init.is_fully_undef() && !init.is_fully_zero()) reject; } dff = ff; dffQ = argQ; dffclock = port(ff, \CLK); } // No enable/reset mux possible without flop else if (dffcemux || dffrstmux) reject; endcode