yosys/passes/pmgen/xilinx_dsp.pmg

427 lines
9.9 KiB
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pattern xilinx_dsp
state <std::function<SigSpec(const SigSpec&)>> unextend
state <SigBit> clock
state <SigSpec> sigA sigffAmuxY sigB sigffBmuxY sigC sigffCmuxY sigD sigffDmuxY sigM sigP
state <IdString> postAddAB postAddMuxAB
state <bool> ffAenpol ffADenpol ffBenpol ffCenpol ffDenpol ffMenpol ffPenpol
state <int> ffPoffset
state <Cell*> ffAD ffADmux ffA ffAmux ffB ffBmux ffC ffCmux ffD ffDmux ffM ffMmux ffP ffPmux
// subpattern
state <SigSpec> argQ argD
state <bool> ffenpol
udata <SigSpec> dffD dffQ
udata <SigBit> dffclock
udata <Cell*> dff dffmux
udata <bool> dffenpol
match dsp
select dsp->type.in(\DSP48E1)
endmatch
code unextend sigA sigB sigC sigD sigM
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 = dsp->connections_.at(\C, SigSpec());
sigD = dsp->connections_.at(\D, SigSpec());
SigSpec P = port(dsp, \P);
if (dsp->parameters.at(\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;
endcode
code argQ ffAD ffADmux ffADenpol sigA clock
if (param(dsp, \ADREG).as_int() == 0) {
argQ = sigA;
subpattern(in_dffe);
if (dff) {
ffAD = dff;
clock = dffclock;
if (dffmux) {
ffADmux = dffmux;
ffADenpol = dffenpol;
}
sigA = dffD;
}
}
endcode
match preAdd
if sigD.empty() || sigD.is_fully_zero()
// Ensure that preAdder not already used
if dsp->parameters.at(\USE_DPORT, Const("FALSE")).decode_string() == "FALSE"
if dsp->connections_.at(\INMODE, Const(0, 5)).is_fully_zero()
select preAdd->type.in($add)
// Output has to be 25 bits or less
select GetSize(port(preAdd, \Y)) <= 25
select nusers(port(preAdd, \Y)) == 2
choice <IdString> AB {\A, \B}
// A port has to be 30 bits or less
select GetSize(port(preAdd, AB)) <= 30
define <IdString> BA (AB == \A ? \B : \A)
// D port has to be 25 bits or less
select GetSize(port(preAdd, BA)) <= 25
index <SigSpec> port(preAdd, \Y) === sigA
optional
endmatch
code sigA sigD
if (preAdd) {
sigA = port(preAdd, \A);
sigD = port(preAdd, \B);
if (GetSize(sigA) < GetSize(sigD))
std::swap(sigA, sigD);
}
endcode
code argQ ffA ffAmux ffAenpol sigA clock ffAD ffADmux ffADenpol
// Only search for ffA if there was a pre-adder
// (otherwise ffA would have been matched as ffAD)
if (preAdd) {
if (param(dsp, \AREG).as_int() == 0) {
argQ = sigA;
subpattern(in_dffe);
if (dff) {
ffA = dff;
clock = dffclock;
if (dffmux) {
ffAmux = dffmux;
ffAenpol = dffenpol;
}
sigA = dffD;
}
}
}
// And if there wasn't a pre-adder,
// move AD register to A
else if (ffAD) {
log_assert(!ffA && !ffAmux);
std::swap(ffA, ffAD);
std::swap(ffAmux, ffADmux);
ffAenpol = ffADenpol;
}
endcode
code argQ ffB ffBmux ffBenpol sigB clock
if (param(dsp, \BREG).as_int() == 0) {
argQ = sigB;
subpattern(in_dffe);
if (dff) {
ffB = dff;
clock = dffclock;
if (dffmux) {
ffBmux = dffmux;
ffBenpol = dffenpol;
}
sigB = dffD;
}
}
endcode
code argQ ffD ffDmux ffDenpol sigD clock
if (param(dsp, \DREG).as_int() == 0) {
argQ = sigD;
subpattern(in_dffe);
if (dff) {
ffD = dff;
clock = dffclock;
if (dffmux) {
ffDmux = dffmux;
ffDenpol = dffenpol;
}
sigD = dffD;
}
}
endcode
code argD ffM ffMmux ffMenpol sigM sigP clock
if (param(dsp, \MREG).as_int() == 0 && nusers(sigM) == 2) {
argD = sigM;
subpattern(out_dffe);
if (dff) {
ffM = dff;
clock = dffclock;
if (dffmux) {
ffMmux = dffmux;
ffMenpol = dffenpol;
}
sigM = dffQ;
}
}
sigP = sigM;
endcode
match postAdd
// Ensure that Z mux is not already used
if port(dsp, \OPMODE).extract(4,3).is_fully_zero()
select postAdd->type.in($add)
select GetSize(port(postAdd, \Y)) <= 48
select nusers(port(postAdd, \Y)) == 2
choice <IdString> AB {\A, \B}
select nusers(port(postAdd, AB)) <= 3
filter ffMmux || nusers(port(postAdd, AB)) == 2
filter !ffMmux || nusers(port(postAdd, AB)) == 3
filter GetSize(unextend(port(postAdd, AB))) <= GetSize(sigP)
filter unextend(port(postAdd, AB)) == sigP.extract(0, GetSize(unextend(port(postAdd, AB))))
filter nusers(sigP.extract_end(GetSize(unextend(port(postAdd, AB))))) <= 1
set postAddAB AB
optional
endmatch
code sigC sigP
if (postAdd) {
sigC = port(postAdd, postAddAB == \A ? \B : \A);
// TODO for DSP48E1, which will have sign extended inputs/outputs
//int natural_mul_width = GetSize(port(dsp, \A)) + GetSize(port(dsp, \B));
//int actual_mul_width = GetSize(sigP);
//int actual_acc_width = GetSize(sigC);
//if ((actual_acc_width > actual_mul_width) && (natural_mul_width > actual_mul_width))
// reject;
//if ((actual_acc_width != actual_mul_width) && (param(dsp, \A_SIGNED).as_bool() != param(postAdd, \A_SIGNED).as_bool()))
// reject;
sigP = port(postAdd, \Y);
}
endcode
code argD ffP ffPmux ffPenpol sigP clock
if (param(dsp, \PREG).as_int() == 0) {
// If ffMmux and no postAdd new-value net must have exactly three users: ffMmux, ffM and ffPmux
if ((ffMmux && !postAdd && nusers(sigP) == 3) ||
// Otherwise new-value net must have exactly two users: dsp and ffPmux
((!ffMmux || postAdd) && nusers(sigP) == 2)) {
argD = sigP;
subpattern(out_dffe);
if (dff) {
ffP = dff;
clock = dffclock;
if (dffmux) {
ffPmux = dffmux;
ffPenpol = dffenpol;
}
sigP = dffQ;
}
}
}
endcode
match postAddMux
if postAdd
if ffP
select postAddMux->type.in($mux)
select nusers(port(postAddMux, \Y)) == 2
choice <IdString> AB {\A, \B}
index <SigSpec> port(postAddMux, AB) === sigP
index <SigSpec> port(postAddMux, \Y) === sigC
set postAddMuxAB AB
optional
endmatch
code sigC
if (postAddMux)
sigC = port(postAddMux, postAddMuxAB == \A ? \B : \A);
endcode
code argQ ffC ffCmux ffCenpol sigC clock
if (param(dsp, \CREG).as_int() == 0) {
argQ = sigC;
subpattern(in_dffe);
if (dff) {
ffC = dff;
clock = dffclock;
if (dffmux) {
ffCmux = dffmux;
ffCenpol = dffenpol;
}
sigC = dffD;
}
}
endcode
code
accept;
endcode
// #######################
subpattern in_dffe
arg argQ clock ffenpol
match ff
select ff->type.in($dff)
// DSP48E1 does not support clock inversion
select param(ff, \CLK_POLARITY).as_bool()
filter GetSize(port(ff, \Q)) >= GetSize(argQ)
slice offset GetSize(port(ff, \Q))
filter offset+GetSize(argQ) <= GetSize(port(ff, \Q))
filter port(ff, \Q).extract(offset, GetSize(argQ)) == argQ
semioptional
endmatch
code argQ
if (ff) {
for (auto b : argQ)
if (b.wire->get_bool_attribute(\keep))
reject;
if (clock != SigBit()) {
if (port(ff, \CLK) != clock)
reject;
}
dffclock = port(ff, \CLK);
dff = ff;
dffD = argQ;
dffD.replace(port(ff, \Q), port(ff, \D));
// Only search for ffmux if ff.Q has at
// least 3 users (ff, dsp, ffmux) and
// its ff.D only has two (ff, ffmux)
if (!(nusers(argQ) >= 3 && nusers(dffD) == 2))
argQ = SigSpec();
}
else {
dff = nullptr;
argQ = SigSpec();
}
endcode
match ffmux
if !argQ.empty()
select ffmux->type.in($mux)
index <SigSpec> port(ffmux, \Y) === port(ff, \D)
filter GetSize(port(ffmux, \Y)) >= GetSize(dffD)
slice offset GetSize(port(ffmux, \Y))
filter offset+GetSize(dffD) <= GetSize(port(ffmux, \Y))
filter port(ffmux, \Y).extract(offset, GetSize(dffD)) == dffD
choice <IdString> AB {\A, \B}
filter offset+GetSize(argQ) <= GetSize(port(ffmux, \Y))
filter port(ffmux, AB).extract(offset, GetSize(argQ)) == argQ
define <bool> pol (AB == \A)
set ffenpol pol
semioptional
endmatch
code
if (ffmux) {
dffmux = ffmux;
dffenpol = ffenpol;
dffD = port(ffmux, dffenpol ? \B : \A);
}
else
dffmux = nullptr;
endcode
// #######################
subpattern out_dffe
arg argD clock ffenpol
arg unextend
match ffmux
select ffmux->type.in($mux)
// ffmux output must have two users: ffmux and ff.D
select nusers(port(ffmux, \Y)) == 2
filter GetSize(port(ffmux, \Y)) >= GetSize(argD)
choice <IdString> BA {\B, \A}
// new-value net must have exactly two users: (upstream) and ffmux
select nusers(port(ffmux, BA)) == 2
slice offset GetSize(port(ffmux, \Y))
filter offset+GetSize(argD) <= GetSize(port(ffmux, \Y))
filter port(ffmux, BA).extract(offset, GetSize(argD)) == argD
define <IdString> AB (BA == \B ? \A : \B)
// keep-last-value net must have at least three users: ffmux, ff, downstream sink(s)
select nusers(port(ffmux, AB)) >= 3
filter GetSize(unextend(port(ffmux, BA))) <= GetSize(argD)
filter unextend(port(ffmux, BA)) == argD.extract(0, GetSize(unextend(port(ffmux, BA))))
// Remaining bits on argD must not have any other users
filter nusers(argD.extract_end(GetSize(unextend(port(ffmux, BA))))) <= 1
define <bool> pol (AB == \A)
set ffenpol pol
semioptional
endmatch
code argD
if (ffmux) {
dffmux = ffmux;
dffenpol = ffenpol;
argD = port(ffmux, \Y);
}
else
dffmux = nullptr;
endcode
match ff_enable
if ffmux
select ff_enable->type.in($dff)
// DSP48E1 does not support clock inversion
select param(ff_enable, \CLK_POLARITY).as_bool()
index <SigSpec> port(ff_enable, \D) === argD
index <SigSpec> port(ff_enable, \Q) === port(ffmux, ffenpol ? \A : \B)
endmatch
match ff
if !ff_enable
select ff->type.in($dff)
// DSP48E1 does not support clock inversion
select param(ff, \CLK_POLARITY).as_bool()
index <SigSpec> port(ff, \D) === argD
semioptional
endmatch
code
if (ff_enable)
dff = ff_enable;
else
dff = ff;
log_dump("ffM", dff, dffmux);
if (dff) {
dffQ = port(dff, \Q);
for (auto b : dffQ)
if (b.wire->get_bool_attribute(\keep))
reject;
if (clock != SigBit()) {
if (port(dff, \CLK) != clock)
reject;
}
dffclock = port(dff, \CLK);
}
// No enable mux possible without flop
else if (ffmux)
reject;
endcode