yosys/passes/pmgen/peepopt_shiftmul_left.pmg

pattern shiftmul_left
//
// Optimize mul+shift pairs that result from expressions such as foo[s*W+:W]
//

match shift
	select shift->type.in($shift, $shiftx, $shl)
	select shift->type.in($shl) || param(shift, \B_SIGNED).as_bool()
	filter !port(shift, \B).empty()
endmatch

match neg
	if shift->type.in($shift, $shiftx)
	select neg->type == $neg
	index <SigSpec> port(neg, \Y) === port(shift, \B)
	filter !port(shift, \A).empty()
endmatch

// the left shift amount
state <SigSpec> shift_amount
// log2 scale factor in interpreting of shift_amount
// due to zero padding on the shift cell's B port
state <int> log2scale

code shift_amount log2scale
	if (neg) {
		// case of `$shift`, `$shiftx`
		shift_amount = port(neg, \A);
		if (!param(neg, \A_SIGNED).as_bool())
			shift_amount.append(State::S0);
	} else {
		// case of `$shl`
		shift_amount = port(shift, \B);
		if (!param(shift, \B_SIGNED).as_bool())
			shift_amount.append(State::S0);
	}

	// at this point shift_amount is signed, make
	// sure we can never go negative
	if (shift_amount.bits().back() != State::S0)
		reject;

	while (shift_amount.bits().back() == State::S0) {
		shift_amount.remove(GetSize(shift_amount) - 1);
		if (shift_amount.empty()) reject;
	}

	log2scale = 0;
	while (shift_amount[0] == State::S0) {
		shift_amount.remove(0);
		if (shift_amount.empty()) reject;
		log2scale++;
	}

	if (GetSize(shift_amount) > 20)
		reject;
endcode

state <SigSpec> mul_din
state <Const> mul_const

match mul
	select mul->type.in($mul)
	index <SigSpec> port(mul, \Y) === shift_amount
	filter !param(mul, \A_SIGNED).as_bool()

	choice <IdString> constport {\A, \B}
	filter port(mul, constport).is_fully_const()

	define <IdString> varport (constport == \A ? \B : \A)
	set mul_const SigSpec({port(mul, constport), SigSpec(State::S0, log2scale)}).as_const()
	// get mul_din unmapped (so no `port()` shorthand)
	// because we will be using it to set the \A port
	// on the shift cell, and we want to stay close
	// to the original design
	set mul_din mul->getPort(varport)
endmatch

code
{
	if (mul_const.empty() || GetSize(mul_const) > 20)
		reject;

	// make sure there's no overlap in the signal
	// selections by the shiftmul pattern
	if (GetSize(port(shift, \A)) > mul_const.as_int())
		reject;

	int factor_bits = ceil_log2(mul_const.as_int());
	// make sure the multiplication never wraps around
	if (GetSize(shift_amount) < factor_bits + GetSize(mul_din))
		reject;

	if (neg) {
		// make sure the negation never wraps around
		if (GetSize(port(shift, \B)) < factor_bits + GetSize(mul_din)
										+ log2scale + 1)
			reject;
	}

	did_something = true;
	log("left shiftmul pattern in %s: shift=%s, mul=%s\n", log_id(module), log_id(shift), log_id(mul));

	int const_factor = mul_const.as_int();
	int new_const_factor = 1 << factor_bits;
	SigSpec padding(State::Sm, new_const_factor-const_factor);
	SigSpec old_y = port(shift, \Y), new_y;
	int trunc = 0;

	if (GetSize(old_y) % const_factor != 0) {
		trunc = const_factor - GetSize(old_y) % const_factor;
		old_y.append(SigSpec(State::Sm, trunc));
	}

	for (int i = 0; i*const_factor < GetSize(old_y); i++) {
		SigSpec slice = old_y.extract(i*const_factor, const_factor);
		new_y.append(slice);
		new_y.append(padding);
	}

	if (trunc > 0)
		new_y.remove(GetSize(new_y)-trunc, trunc);

	{
		// Now replace occurences of Sm in new_y with bits
		// of a dummy wire
		int padbits = 0;
		for (auto bit : new_y)
		if (bit == SigBit(State::Sm))
			padbits++;

		SigSpec padwire = module->addWire(NEW_ID, padbits);

		for (int i = new_y.size() - 1; i >= 0; i--)
		if (new_y[i] == SigBit(State::Sm)) {
			new_y[i] = padwire.bits().back();
			padwire.remove(padwire.size() - 1);
		}
	}

	SigSpec new_b = {mul_din, SigSpec(State::S0, factor_bits)};

	shift->setPort(\Y, new_y);
	shift->setParam(\Y_WIDTH, GetSize(new_y));
	if (shift->type == $shl) {
		if (param(shift, \B_SIGNED).as_bool())
			new_b.append(State::S0);
		shift->setPort(\B, new_b);
		shift->setParam(\B_WIDTH, GetSize(new_b));
	} else {
		SigSpec b_neg = module->addWire(NEW_ID, GetSize(new_b) + 1);
		module->addNeg(NEW_ID, new_b, b_neg);
		shift->setPort(\B, b_neg);
		shift->setParam(\B_WIDTH, GetSize(b_neg));
	}

	blacklist(shift);
	accept;
}
endcode
peepopt: Add left-shift 'shiftmul' variant Add a separate shiftmul pattern to match on left shifts which implement demuxing. This mirrors the right shift pattern matcher but is probably best kept separate instead of merging the two into a single matcher. In any case the diff of the two matchers should be easily readable. 2023-08-02 11:04:54 -05:00			`pattern shiftmul_left`
			`//`
			`// Optimize mul+shift pairs that result from expressions such as foo[s*W+:W]`
			`//`

			`match shift`
			`select shift->type.in($shift, $shiftx, $shl)`
			`select shift->type.in($shl) \|\| param(shift, \B_SIGNED).as_bool()`
			`filter !port(shift, \B).empty()`
			`endmatch`

			`match neg`
			`if shift->type.in($shift, $shiftx)`
			`select neg->type == $neg`
			`index <SigSpec> port(neg, \Y) === port(shift, \B)`
			`filter !port(shift, \A).empty()`
			`endmatch`

			`// the left shift amount`
			`state <SigSpec> shift_amount`
			`// log2 scale factor in interpreting of shift_amount`
			`// due to zero padding on the shift cell's B port`
			`state <int> log2scale`

			`code shift_amount log2scale`
			`if (neg) {`
			// case of `$shift`, `$shiftx`
			`shift_amount = port(neg, \A);`
			`if (!param(neg, \A_SIGNED).as_bool())`
			`shift_amount.append(State::S0);`
			`} else {`
			// case of `$shl`
			`shift_amount = port(shift, \B);`
			`if (!param(shift, \B_SIGNED).as_bool())`
			`shift_amount.append(State::S0);`
			`}`

			`// at this point shift_amount is signed, make`
			`// sure we can never go negative`
			`if (shift_amount.bits().back() != State::S0)`
			`reject;`

			`while (shift_amount.bits().back() == State::S0) {`
			`shift_amount.remove(GetSize(shift_amount) - 1);`
			`if (shift_amount.empty()) reject;`
			`}`

			`log2scale = 0;`
			`while (shift_amount[0] == State::S0) {`
			`shift_amount.remove(0);`
			`if (shift_amount.empty()) reject;`
			`log2scale++;`
			`}`

			`if (GetSize(shift_amount) > 20)`
			`reject;`
			`endcode`

			`state <SigSpec> mul_din`
			`state <Const> mul_const`

			`match mul`
			`select mul->type.in($mul)`
			`index <SigSpec> port(mul, \Y) === shift_amount`
			`filter !param(mul, \A_SIGNED).as_bool()`

			`choice <IdString> constport {\A, \B}`
			`filter port(mul, constport).is_fully_const()`

			`define <IdString> varport (constport == \A ? \B : \A)`
			`set mul_const SigSpec({port(mul, constport), SigSpec(State::S0, log2scale)}).as_const()`
			// get mul_din unmapped (so no `port()` shorthand)
			`// because we will be using it to set the \A port`
			`// on the shift cell, and we want to stay close`
			`// to the original design`
			`set mul_din mul->getPort(varport)`
			`endmatch`

			`code`
			`{`
			`if (mul_const.empty() \|\| GetSize(mul_const) > 20)`
			`reject;`

			`// make sure there's no overlap in the signal`
			`// selections by the shiftmul pattern`
			`if (GetSize(port(shift, \A)) > mul_const.as_int())`
			`reject;`

			`int factor_bits = ceil_log2(mul_const.as_int());`
			`// make sure the multiplication never wraps around`
			`if (GetSize(shift_amount) < factor_bits + GetSize(mul_din))`
			`reject;`

			`if (neg) {`
			`// make sure the negation never wraps around`
			`if (GetSize(port(shift, \B)) < factor_bits + GetSize(mul_din)`
			`+ log2scale + 1)`
			`reject;`
			`}`

			`did_something = true;`
			`log("left shiftmul pattern in %s: shift=%s, mul=%s\n", log_id(module), log_id(shift), log_id(mul));`

			`int const_factor = mul_const.as_int();`
			`int new_const_factor = 1 << factor_bits;`
			`SigSpec padding(State::Sm, new_const_factor-const_factor);`
			`SigSpec old_y = port(shift, \Y), new_y;`
			`int trunc = 0;`

			`if (GetSize(old_y) % const_factor != 0) {`
			`trunc = const_factor - GetSize(old_y) % const_factor;`
			`old_y.append(SigSpec(State::Sm, trunc));`
			`}`

			`for (int i = 0; i*const_factor < GetSize(old_y); i++) {`
			`SigSpec slice = old_y.extract(i*const_factor, const_factor);`
			`new_y.append(slice);`
			`new_y.append(padding);`
			`}`

			`if (trunc > 0)`
			`new_y.remove(GetSize(new_y)-trunc, trunc);`

			`{`
			`// Now replace occurences of Sm in new_y with bits`
			`// of a dummy wire`
			`int padbits = 0;`
			`for (auto bit : new_y)`
			`if (bit == SigBit(State::Sm))`
			`padbits++;`

			`SigSpec padwire = module->addWire(NEW_ID, padbits);`

			`for (int i = new_y.size() - 1; i >= 0; i--)`
			`if (new_y[i] == SigBit(State::Sm)) {`
			`new_y[i] = padwire.bits().back();`
			`padwire.remove(padwire.size() - 1);`
			`}`
			`}`

			`SigSpec new_b = {mul_din, SigSpec(State::S0, factor_bits)};`

			`shift->setPort(\Y, new_y);`
			`shift->setParam(\Y_WIDTH, GetSize(new_y));`
			`if (shift->type == $shl) {`
			`if (param(shift, \B_SIGNED).as_bool())`
			`new_b.append(State::S0);`
			`shift->setPort(\B, new_b);`
			`shift->setParam(\B_WIDTH, GetSize(new_b));`
			`} else {`
			`SigSpec b_neg = module->addWire(NEW_ID, GetSize(new_b) + 1);`
			`module->addNeg(NEW_ID, new_b, b_neg);`
			`shift->setPort(\B, b_neg);`
			`shift->setParam(\B_WIDTH, GetSize(b_neg));`
			`}`

			`blacklist(shift);`
			`accept;`
			`}`
			`endcode`