yosys/passes/pmgen/ice40_dsp.pmg

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pattern ice40_dsp
state <SigBit> clock
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state <bool> clock_pol
state <std::set<SigBit>> sigAset sigBset
state <SigSpec> sigA sigB sigCD sigH sigO sigOused
state <Cell*> addAB muxAB
match mul
select mul->type.in($mul, \SB_MAC16)
select GetSize(mul->getPort(\A)) + GetSize(mul->getPort(\B)) > 10
endmatch
code sigAset sigBset
SigSpec A = port(mul, \A);
A.remove_const();
sigAset = A.to_sigbit_set();
SigSpec B = port(mul, \B);
B.remove_const();
sigBset = B.to_sigbit_set();
endcode
code sigH
if (mul->type == $mul)
sigH = mul->getPort(\Y);
else if (mul->type == \SB_MAC16)
sigH = mul->getPort(\O);
else log_abort();
if (GetSize(sigH) <= 10)
reject;
endcode
match ffA
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if mul->type != \SB_MAC16 || !param(mul, \A_REG).as_bool()
if !sigAset.empty()
select ffA->type.in($dff)
filter includes(port(ffA, \Q).to_sigbit_set(), sigAset)
optional
endmatch
code sigA clock clock_pol
sigA = port(mul, \A);
if (ffA) {
for (auto b : port(ffA, \Q))
if (b.wire->get_bool_attribute(\keep))
reject;
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clock = port(ffA, \CLK).as_bit();
clock_pol = param(ffA, \CLK_POLARITY).as_bool();
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sigA.replace(port(ffA, \Q), port(ffA, \D));
}
endcode
match ffB
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if mul->type != \SB_MAC16 || !param(mul, \B_REG).as_bool()
if !sigBset.empty()
select ffB->type.in($dff)
filter includes(port(ffB, \Q).to_sigbit_set(), sigBset)
optional
endmatch
code sigB clock clock_pol
sigB = port(mul, \B);
if (ffB) {
for (auto b : port(ffB, \Q))
if (b.wire->get_bool_attribute(\keep))
reject;
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SigBit c = port(ffB, \CLK).as_bit();
bool cp = param(ffB, \CLK_POLARITY).as_bool();
if (clock != SigBit() && (c != clock || cp != clock_pol))
reject;
clock = c;
clock_pol = cp;
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sigB.replace(port(ffB, \Q), port(ffB, \D));
}
endcode
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match ffFJKG
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if mul->type != \SB_MAC16 || (!param(mul, \TOP_8x8_MULT_REG).as_bool() && !param(mul, \BOT_8x8_MULT_REG).as_bool() && !param(mul, \PIPELINE_16x16_MULT_REG1).as_bool() && !param(mul, \PIPELINE_16x16_MULT_REG2).as_bool())
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select ffFJKG->type.in($dff)
select nusers(port(ffFJKG, \D)) == 2
index <SigSpec> port(ffFJKG, \D) === sigH
// Ensure pipeline register is not already used
optional
endmatch
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code sigH sigO clock clock_pol
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if (ffFJKG) {
sigH = port(ffFJKG, \Q);
for (auto b : sigH)
if (b.wire->get_bool_attribute(\keep))
reject;
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SigBit c = port(ffFJKG, \CLK).as_bit();
bool cp = param(ffFJKG, \CLK_POLARITY).as_bool();
if (clock != SigBit() && (c != clock || cp != clock_pol))
reject;
clock = c;
clock_pol = cp;
}
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sigO = sigH;
endcode
match addA
select addA->type.in($add)
select nusers(port(addA, \A)) == 2
filter param(addA, \A_WIDTH).as_int() <= GetSize(sigH)
//index <SigSpec> port(addA, \A) === sigH.extract(0, param(addA, \A_WIDTH).as_int())
filter port(addA, \A) == sigH.extract(0, param(addA, \A_WIDTH).as_int())
optional
endmatch
match addB
if !addA
select addB->type.in($add, $sub)
select nusers(port(addB, \B)) == 2
filter param(addB, \B_WIDTH).as_int() <= GetSize(sigH)
//index <SigSpec> port(addB, \B) === sigH.extract(0, param(addB, \B_WIDTH).as_int())
filter port(addB, \B) == sigH.extract(0, param(addB, \B_WIDTH).as_int())
optional
endmatch
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code addAB sigCD sigO
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bool CD_SIGNED = false;
if (addA) {
addAB = addA;
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sigCD = port(addAB, \B);
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CD_SIGNED = param(addAB, \B_SIGNED).as_bool();
}
if (addB) {
addAB = addB;
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sigCD = port(addAB, \A);
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CD_SIGNED = param(addAB, \A_SIGNED).as_bool();
}
if (addAB) {
if (mul->type == \SB_MAC16) {
// Ensure that adder is not used
if (param(mul, \TOPOUTPUT_SELECT).as_int() != 3 ||
param(mul, \BOTOUTPUT_SELECT).as_int() != 3)
reject;
}
int natural_mul_width = GetSize(sigA) + GetSize(sigB);
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int actual_mul_width = GetSize(sigH);
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int actual_acc_width = GetSize(sigCD);
if ((actual_acc_width > actual_mul_width) && (natural_mul_width > actual_mul_width))
reject;
// If accumulator, check adder width and signedness
if (sigCD == sigH && (actual_acc_width != actual_mul_width) && (param(mul, \A_SIGNED).as_bool() != param(addAB, \A_SIGNED).as_bool()))
reject;
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sigO = port(addAB, \Y);
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sigCD.extend_u0(32, CD_SIGNED);
}
endcode
match muxA
select muxA->type.in($mux)
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index <int> nusers(port(muxA, \A)) === 2
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index <SigSpec> port(muxA, \A) === sigO
optional
endmatch
match muxB
if !muxA
select muxB->type.in($mux)
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index <int> nusers(port(muxB, \B)) === 2
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index <SigSpec> port(muxB, \B) === sigO
optional
endmatch
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code muxAB
if (muxA)
muxAB = muxA;
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else if (muxB)
muxAB = muxB;
endcode
// Extract the bits of P that actually have a consumer
// (as opposed to being a dummy)
code sigOused
for (int i = 0; i < GetSize(sigO); i++)
if (!sigO[i].wire || nusers(sigO[i]) == 1)
sigOused.append(State::Sx);
else
sigOused.append(sigO[i]);
endcode
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match ffO_lo
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if nusers(sigOused.extract(0,std::min(16,GetSize(sigOused)))) == 2
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select ffO_lo->type.in($dff)
optional
endmatch
code
if (ffO_lo) {
SigSpec O = sigOused.extract(0,std::min(16,param(ffO_lo, \WIDTH).as_int()));
O.remove_const();
if (!includes(port(ffO_lo, \D).to_sigbit_set(), O.to_sigbit_set()))
reject;
}
endcode
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match ffO_hi
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if GetSize(sigOused) > 16
if nusers(sigOused.extract_end(16)) == 2
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select ffO_hi->type.in($dff)
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optional
endmatch
code
if (ffO_hi) {
SigSpec O = sigOused.extract_end(16);
O.remove_const();
if (!includes(port(ffO_hi, \D).to_sigbit_set(), O.to_sigbit_set()))
reject;
}
endcode
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code clock clock_pol sigO sigCD
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if (ffO_lo || ffO_hi) {
if (mul->type == \SB_MAC16) {
// Ensure that register is not already used
if (param(mul, \TOPOUTPUT_SELECT).as_int() == 1 ||
param(mul, \BOTOUTPUT_SELECT).as_int() == 1)
reject;
// Ensure that OLOADTOP/OLOADBOT is unused or zero
if ((mul->hasPort(\OLOADTOP) && !port(mul, \OLOADTOP).is_fully_zero())
|| (mul->hasPort(\OLOADBOT) && !port(mul, \OLOADBOT).is_fully_zero()))
reject;
}
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if (ffO_lo) {
for (auto b : port(ffO_lo, \Q))
if (b.wire->get_bool_attribute(\keep))
reject;
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SigBit c = port(ffO_lo, \CLK).as_bit();
bool cp = param(ffO_lo, \CLK_POLARITY).as_bool();
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if (clock != SigBit() && (c != clock || cp != clock_pol))
reject;
clock = c;
clock_pol = cp;
sigO.replace(port(ffO_lo, \D), port(ffO_lo, \Q));
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}
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if (ffO_hi) {
for (auto b : port(ffO_hi, \Q))
if (b.wire->get_bool_attribute(\keep))
reject;
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SigBit c = port(ffO_hi, \CLK).as_bit();
bool cp = param(ffO_hi, \CLK_POLARITY).as_bool();
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if (clock != SigBit() && (c != clock || cp != clock_pol))
reject;
clock = c;
clock_pol = cp;
sigO.replace(port(ffO_hi, \D), port(ffO_hi, \Q));
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}
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// Loading value into output register is not
// supported unless using accumulator
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if (muxAB) {
if (sigCD != sigO)
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reject;
if (muxA)
sigCD = port(muxAB, \B);
else if (muxB)
sigCD = port(muxAB, \A);
else log_abort();
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sigCD.extend_u0(32, addAB && param(addAB, \A_SIGNED).as_bool() && param(addAB, \B_SIGNED).as_bool());
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}
}
accept;
endcode