yosys/techlibs/intel_alm/common/quartus_rename.v

`ifdef cyclonev
`define LCELL cyclonev_lcell_comb
`define MAC cyclonev_mac
`define MLAB cyclonev_mlab_cell
`define RAM_BLOCK cyclonev_ram_block
`define IBUF cyclonev_io_ibuf
`define OBUF cyclonev_io_obuf
`define CLKENA cyclonev_clkena
`endif
`ifdef arriav
`define LCELL arriav_lcell_comb
`define MAC arriav_mac
`define MLAB arriav_mlab_cell
`define RAM_BLOCK arriav_ram_block
`define IBUF arriav_io_ibuf
`define OBUF arriav_io_obuf
`define CLKENA arriav_clkena
`endif
`ifdef cyclone10gx
`define LCELL cyclone10gx_lcell_comb
`define MAC cyclone10gx_mac
`define MLAB cyclone10gx_mlab_cell
`define RAM_BLOCK cyclone10gx_ram_block
`define IBUF cyclone10gx_io_ibuf
`define OBUF cyclone10gx_io_obuf
`define CLKENA cyclone10gx_clkena
`endif

module __MISTRAL_VCC(output Q);

MISTRAL_ALUT2 #(.LUT(4'b1111)) _TECHMAP_REPLACE_ (.A(1'b1), .B(1'b1), .Q(Q));

endmodule


module __MISTRAL_GND(output Q);

MISTRAL_ALUT2 #(.LUT(4'b0000)) _TECHMAP_REPLACE_ (.A(1'b1), .B(1'b1), .Q(Q));

endmodule


module MISTRAL_FF(input DATAIN, CLK, ACLR, ENA, SCLR, SLOAD, SDATA, output reg Q);

dffeas #(.power_up("low"), .is_wysiwyg("true")) _TECHMAP_REPLACE_ (.d(DATAIN), .clk(CLK), .clrn(ACLR), .ena(ENA), .sclr(SCLR), .sload(SLOAD), .asdata(SDATA), .q(Q));

endmodule


module MISTRAL_ALUT6(input A, B, C, D, E, F, output Q);
parameter [63:0] LUT = 64'h0000_0000_0000_0000;

`LCELL #(.lut_mask(LUT)) _TECHMAP_REPLACE_ (.dataa(A), .datab(B), .datac(C), .datad(D), .datae(E), .dataf(F), .combout(Q));

endmodule


module MISTRAL_ALUT5(input A, B, C, D, E, output Q);
parameter [31:0] LUT = 32'h0000_0000;

`LCELL #(.lut_mask({2{LUT}})) _TECHMAP_REPLACE_ (.dataa(A), .datab(B), .datac(C), .datad(D), .datae(E), .combout(Q));

endmodule


module MISTRAL_ALUT4(input A, B, C, D, output Q);
parameter [15:0] LUT = 16'h0000;

`LCELL #(.lut_mask({4{LUT}})) _TECHMAP_REPLACE_ (.dataa(A), .datab(B), .datac(C), .datad(D), .combout(Q));

endmodule


module MISTRAL_ALUT3(input A, B, C, output Q);
parameter [7:0] LUT = 8'h00;

`LCELL #(.lut_mask({8{LUT}})) _TECHMAP_REPLACE_ (.dataa(A), .datab(B), .datac(C), .combout(Q));

endmodule


module MISTRAL_ALUT2(input A, B, output Q);
parameter [3:0] LUT = 4'h0;

`LCELL #(.lut_mask({16{LUT}})) _TECHMAP_REPLACE_ (.dataa(A), .datab(B), .combout(Q));

endmodule


module MISTRAL_NOT(input A, output Q);

NOT _TECHMAP_REPLACE_ (.IN(A), .OUT(Q));

endmodule


module MISTRAL_ALUT_ARITH(input A, B, C, D0, D1, CI, output SO, CO);
parameter LUT0 = 16'h0000;
parameter LUT1 = 16'h0000;

`LCELL #(.lut_mask({16'h0, LUT1, 16'h0, LUT0})) _TECHMAP_REPLACE_ (.dataa(A), .datab(B), .datac(C), .datad(D0), .dataf(D1), .cin(CI), .sumout(SO), .cout(CO));

endmodule


module MISTRAL_MLAB(input [4:0] A1ADDR, input A1DATA, A1EN, CLK1, input [4:0] B1ADDR, output B1DATA);

parameter _TECHMAP_CELLNAME_ = "";

// Here we get to an unfortunate situation. The cell has a mem_init0 parameter,
// which takes in a hexadecimal string that could be used to initialise RAM.
// In the vendor simulation models, this appears to work fine, but Quartus,
// either intentionally or not, forgets about this parameter and initialises the
// RAM to zero.
//
// Because of this, RAM initialisation is presently disabled, but the source
// used to generate mem_init0 is kept (commented out) in case this gets fixed
// or an undocumented way to get Quartus to initialise from mem_init0 is found.

`MLAB #(
    .logical_ram_name(_TECHMAP_CELLNAME_),
    .logical_ram_depth(32),
    .logical_ram_width(1),
    .mixed_port_feed_through_mode("Dont Care"),
    .first_bit_number(0),
    .first_address(0),
    .last_address(31),
    .address_width(5),
    .data_width(1),
    .byte_enable_mask_width(1),
    .port_b_data_out_clock("NONE"),
    // .mem_init0($sformatf("%08x", INIT))
) _TECHMAP_REPLACE_ (
    .portaaddr(A1ADDR),
    .portadatain(A1DATA),
    .portbaddr(B1ADDR),
    .portbdataout(B1DATA),
    .ena0(A1EN),
    .clk0(CLK1)
);

endmodule


module MISTRAL_M10K(A1ADDR, A1DATA, A1EN, CLK1, B1ADDR, B1DATA, B1EN);

parameter CFG_ABITS = 10;
parameter CFG_DBITS = 10;

parameter _TECHMAP_CELLNAME_ = "";

input [CFG_ABITS-1:0] A1ADDR, B1ADDR;
input [CFG_DBITS-1:0] A1DATA;
input CLK1, A1EN, B1EN;
output [CFG_DBITS-1:0] B1DATA;

// Much like the MLAB, the M10K has mem_init[01234] parameters which would let
// you initialise the RAM cell via hex literals. If they were implemented.

`RAM_BLOCK #(
    .operation_mode("dual_port"),
    .logical_ram_name(_TECHMAP_CELLNAME_),
    .port_a_address_width(CFG_ABITS),
    .port_a_data_width(CFG_DBITS),
    .port_a_logical_ram_depth(2**CFG_ABITS),
    .port_a_logical_ram_width(CFG_DBITS),
    .port_a_first_address(0),
    .port_a_last_address(2**CFG_ABITS - 1),
    .port_a_first_bit_number(0),
    .port_b_address_width(CFG_ABITS),
    .port_b_data_width(CFG_DBITS),
    .port_b_logical_ram_depth(2**CFG_ABITS),
    .port_b_logical_ram_width(CFG_DBITS),
    .port_b_first_address(0),
    .port_b_last_address(2**CFG_ABITS - 1),
    .port_b_first_bit_number(0),
    .port_b_address_clock("clock0"),
    .port_b_read_enable_clock("clock0")
) _TECHMAP_REPLACE_ (
    .portaaddr(A1ADDR),
    .portadatain(A1DATA),
    .portawe(A1EN),
    .portbaddr(B1ADDR),
    .portbdataout(B1DATA),
    .portbre(B1EN),
    .clk0(CLK1)
);

endmodule


module MISTRAL_MUL27X27(input [26:0] A, B, output [53:0] Y);

parameter A_SIGNED = 1;
parameter B_SIGNED = 1;

`MAC #(
    .ax_width(27),
    .signed_max(A_SIGNED ? "true" : "false"),
    .ay_scan_in_width(27),
    .signed_may(B_SIGNED ? "true" : "false"),
    .result_a_width(54),
    .operation_mode("M27x27")
) _TECHMAP_REPLACE_ (
    .ax(A),
    .ay(B),
    .resulta(Y)
);

endmodule


module MISTRAL_MUL18X18(input [17:0] A, B, output [35:0] Y);

parameter A_SIGNED = 1;
parameter B_SIGNED = 1;

`MAC #(
    .ax_width(18),
    .signed_max(A_SIGNED ? "true" : "false"),
    .ay_scan_in_width(18),
    .signed_may(B_SIGNED ? "true" : "false"),
    .result_a_width(36),
    .operation_mode("M18x18_FULL")
) _TECHMAP_REPLACE_ (
    .ax(A),
    .ay(B),
    .resulta(Y)
);

endmodule


module MISTRAL_MUL9X9(input [8:0] A, B, output [17:0] Y);

parameter A_SIGNED = 1;
parameter B_SIGNED = 1;

`MAC #(
    .ax_width(9),
    .signed_max(A_SIGNED ? "true" : "false"),
    .ay_scan_in_width(9),
    .signed_may(B_SIGNED ? "true" : "false"),
    .result_a_width(18),
    .operation_mode("M9x9")
) _TECHMAP_REPLACE_ (
    .ax(A),
    .ay(B),
    .resulta(Y)
);

endmodule

module MISTRAL_IB(input PAD, output O);
`IBUF #(
    .bus_hold("false"),
    .differential_mode("false")
) _TECHMAP_REPLACE_ (
    .i(PAD),
    .o(O)
);
endmodule

module MISTRAL_OB(output PAD, input I, OE);
`OBUF #(
    .bus_hold("false"),
    .differential_mode("false")
) _TECHMAP_REPLACE_ (
    .i(I),
    .o(PAD),
    .oe(OE)
);
endmodule

module MISTRAL_IO(output PAD, input I, OE, output O);
`IBUF #(
    .bus_hold("false"),
    .differential_mode("false")
) ibuf (
    .i(PAD),
    .o(O)
);

`OBUF #(
    .bus_hold("false"),
    .differential_mode("false")
) obuf (
    .i(I),
    .o(PAD),
    .oe(OE)
);
endmodule

module MISTRAL_CLKBUF (input A, output Q);
`CLKENA #(
    .clock_type("auto"),
    .ena_register_mode("always enabled"),
    .ena_register_power_up("high"),
    .disable_mode("low"),
    .test_syn("high")
) _TECHMAP_REPLACE_ (
    .inclk(A),
    .ena(1'b1),
    .outclk(Q)
);
endmodule
intel_alm: cleanup duplication 2020-04-23 16:44:29 -05:00			`ifdef cyclonev
			`define LCELL cyclonev_lcell_comb
intel_alm: DSP inference 2020-04-25 11:25:59 -05:00			`define MAC cyclonev_mac
intel_alm: direct LUTRAM cell instantiation By instantiating the LUTRAM cell directly, we avoid a trip through altsyncram, which speeds up Quartus synthesis time. This also gives a little more flexibility, as Yosys can build RAMs out of individual 32x1 LUTRAM cells. While working on this, I discovered that the mem_init0 parameter of <family>_mlab_cell gets ignored by Quartus. 2020-04-16 06:24:04 -05:00			`define MLAB cyclonev_mlab_cell
intel_alm: preliminary Arria V support 2021-11-24 15:20:40 -06:00			`define RAM_BLOCK cyclonev_ram_block
intel_alm: Add IO buffer insertion Signed-off-by: gatecat <gatecat@ds0.me> 2021-05-15 08:23:22 -05:00			`define IBUF cyclonev_io_ibuf
			`define OBUF cyclonev_io_obuf
intel_alm: Add global buffer insertion Signed-off-by: gatecat <gatecat@ds0.me> 2021-05-15 08:34:48 -05:00			`define CLKENA cyclonev_clkena
intel_alm: cleanup duplication 2020-04-23 16:44:29 -05:00			`endif
intel_alm: preliminary Arria V support 2021-11-24 15:20:40 -06:00			`ifdef arriav
			`define LCELL arriav_lcell_comb
			`define MAC arriav_mac
			`define MLAB arriav_mlab_cell
			`define RAM_BLOCK arriav_ram_block
			`define IBUF arriav_io_ibuf
			`define OBUF arriav_io_obuf
			`define CLKENA arriav_clkena
			`endif
intel_alm: cleanup duplication 2020-04-23 16:44:29 -05:00			`ifdef cyclone10gx
			`define LCELL cyclone10gx_lcell_comb
intel_alm: DSP inference 2020-04-25 11:25:59 -05:00			`define MAC cyclone10gx_mac
intel_alm: direct LUTRAM cell instantiation By instantiating the LUTRAM cell directly, we avoid a trip through altsyncram, which speeds up Quartus synthesis time. This also gives a little more flexibility, as Yosys can build RAMs out of individual 32x1 LUTRAM cells. While working on this, I discovered that the mem_init0 parameter of <family>_mlab_cell gets ignored by Quartus. 2020-04-16 06:24:04 -05:00			`define MLAB cyclone10gx_mlab_cell
intel_alm: preliminary Arria V support 2021-11-24 15:20:40 -06:00			`define RAM_BLOCK cyclone10gx_ram_block
intel_alm: Add IO buffer insertion Signed-off-by: gatecat <gatecat@ds0.me> 2021-05-15 08:23:22 -05:00			`define IBUF cyclone10gx_io_ibuf
			`define OBUF cyclone10gx_io_obuf
intel_alm: Add global buffer insertion Signed-off-by: gatecat <gatecat@ds0.me> 2021-05-15 08:34:48 -05:00			`define CLKENA cyclone10gx_clkena
intel_alm: cleanup duplication 2020-04-23 16:44:29 -05:00			`endif

synth_intel_alm: alternative synthesis for Intel FPGAs By operating at a layer of abstraction over the rather clumsy Intel primitives, we can avoid special hacks like `dffinit -highlow` in favour of simple techmapping. This also makes the primitives much easier to manipulate, and more descriptive (no more cyclonev_lcell_comb to mean anything from a LUT2 to a LUT6). 2019-11-19 04:19:00 -06:00			`module __MISTRAL_VCC(output Q);`

			`MISTRAL_ALUT2 #(.LUT(4'b1111)) _TECHMAP_REPLACE_ (.A(1'b1), .B(1'b1), .Q(Q));`

			`endmodule`


			`module __MISTRAL_GND(output Q);`

			`MISTRAL_ALUT2 #(.LUT(4'b0000)) _TECHMAP_REPLACE_ (.A(1'b1), .B(1'b1), .Q(Q));`

			`endmodule`


synth_intel_alm: VQM support 2020-04-15 08:28:35 -05:00			`module MISTRAL_FF(input DATAIN, CLK, ACLR, ENA, SCLR, SLOAD, SDATA, output reg Q);`
synth_intel_alm: alternative synthesis for Intel FPGAs By operating at a layer of abstraction over the rather clumsy Intel primitives, we can avoid special hacks like `dffinit -highlow` in favour of simple techmapping. This also makes the primitives much easier to manipulate, and more descriptive (no more cyclonev_lcell_comb to mean anything from a LUT2 to a LUT6). 2019-11-19 04:19:00 -06:00
synth_intel_alm: VQM support 2020-04-15 08:28:35 -05:00			`dffeas #(.power_up("low"), .is_wysiwyg("true")) _TECHMAP_REPLACE_ (.d(DATAIN), .clk(CLK), .clrn(ACLR), .ena(ENA), .sclr(SCLR), .sload(SLOAD), .asdata(SDATA), .q(Q));`
synth_intel_alm: alternative synthesis for Intel FPGAs By operating at a layer of abstraction over the rather clumsy Intel primitives, we can avoid special hacks like `dffinit -highlow` in favour of simple techmapping. This also makes the primitives much easier to manipulate, and more descriptive (no more cyclonev_lcell_comb to mean anything from a LUT2 to a LUT6). 2019-11-19 04:19:00 -06:00
			`endmodule`
intel_alm: cleanup duplication 2020-04-23 16:44:29 -05:00

			`module MISTRAL_ALUT6(input A, B, C, D, E, F, output Q);`
			`parameter [63:0] LUT = 64'h0000_0000_0000_0000;`

			`LCELL #(.lut_mask(LUT)) _TECHMAP_REPLACE_ (.dataa(A), .datab(B), .datac(C), .datad(D), .datae(E), .dataf(F), .combout(Q));

			`endmodule`


			`module MISTRAL_ALUT5(input A, B, C, D, E, output Q);`
			`parameter [31:0] LUT = 32'h0000_0000;`

			`LCELL #(.lut_mask({2{LUT}})) _TECHMAP_REPLACE_ (.dataa(A), .datab(B), .datac(C), .datad(D), .datae(E), .combout(Q));

			`endmodule`


			`module MISTRAL_ALUT4(input A, B, C, D, output Q);`
			`parameter [15:0] LUT = 16'h0000;`

			`LCELL #(.lut_mask({4{LUT}})) _TECHMAP_REPLACE_ (.dataa(A), .datab(B), .datac(C), .datad(D), .combout(Q));

			`endmodule`


			`module MISTRAL_ALUT3(input A, B, C, output Q);`
			`parameter [7:0] LUT = 8'h00;`

			`LCELL #(.lut_mask({8{LUT}})) _TECHMAP_REPLACE_ (.dataa(A), .datab(B), .datac(C), .combout(Q));

			`endmodule`


			`module MISTRAL_ALUT2(input A, B, output Q);`
			`parameter [3:0] LUT = 4'h0;`

			`LCELL #(.lut_mask({16{LUT}})) _TECHMAP_REPLACE_ (.dataa(A), .datab(B), .combout(Q));

			`endmodule`


			`module MISTRAL_NOT(input A, output Q);`

			`NOT _TECHMAP_REPLACE_ (.IN(A), .OUT(Q));`

			`endmodule`


			`module MISTRAL_ALUT_ARITH(input A, B, C, D0, D1, CI, output SO, CO);`
			`parameter LUT0 = 16'h0000;`
			`parameter LUT1 = 16'h0000;`

			`LCELL #(.lut_mask({16'h0, LUT1, 16'h0, LUT0})) _TECHMAP_REPLACE_ (.dataa(A), .datab(B), .datac(C), .datad(D0), .dataf(D1), .cin(CI), .sumout(SO), .cout(CO));

			`endmodule`
intel_alm: direct LUTRAM cell instantiation By instantiating the LUTRAM cell directly, we avoid a trip through altsyncram, which speeds up Quartus synthesis time. This also gives a little more flexibility, as Yosys can build RAMs out of individual 32x1 LUTRAM cells. While working on this, I discovered that the mem_init0 parameter of <family>_mlab_cell gets ignored by Quartus. 2020-04-16 06:24:04 -05:00

			`module MISTRAL_MLAB(input [4:0] A1ADDR, input A1DATA, A1EN, CLK1, input [4:0] B1ADDR, output B1DATA);`

intel_alm: direct M10K instantiation This reverts commit a3a90f6377f251d3b6c5898eb1543f8832493bb8. 2020-07-26 13:28:10 -05:00			`parameter _TECHMAP_CELLNAME_ = "";`

intel_alm: direct LUTRAM cell instantiation By instantiating the LUTRAM cell directly, we avoid a trip through altsyncram, which speeds up Quartus synthesis time. This also gives a little more flexibility, as Yosys can build RAMs out of individual 32x1 LUTRAM cells. While working on this, I discovered that the mem_init0 parameter of <family>_mlab_cell gets ignored by Quartus. 2020-04-16 06:24:04 -05:00			`// Here we get to an unfortunate situation. The cell has a mem_init0 parameter,`
			`// which takes in a hexadecimal string that could be used to initialise RAM.`
			`// In the vendor simulation models, this appears to work fine, but Quartus,`
			`// either intentionally or not, forgets about this parameter and initialises the`
			`// RAM to zero.`
			`//`
			`// Because of this, RAM initialisation is presently disabled, but the source`
			`// used to generate mem_init0 is kept (commented out) in case this gets fixed`
			`// or an undocumented way to get Quartus to initialise from mem_init0 is found.`

			`MLAB #(
intel_alm: direct M10K instantiation This reverts commit a3a90f6377f251d3b6c5898eb1543f8832493bb8. 2020-07-26 13:28:10 -05:00			`.logical_ram_name(_TECHMAP_CELLNAME_),`
intel_alm: direct LUTRAM cell instantiation By instantiating the LUTRAM cell directly, we avoid a trip through altsyncram, which speeds up Quartus synthesis time. This also gives a little more flexibility, as Yosys can build RAMs out of individual 32x1 LUTRAM cells. While working on this, I discovered that the mem_init0 parameter of <family>_mlab_cell gets ignored by Quartus. 2020-04-16 06:24:04 -05:00			`.logical_ram_depth(32),`
			`.logical_ram_width(1),`
			`.mixed_port_feed_through_mode("Dont Care"),`
			`.first_bit_number(0),`
			`.first_address(0),`
			`.last_address(31),`
			`.address_width(5),`
			`.data_width(1),`
			`.byte_enable_mask_width(1),`
			`.port_b_data_out_clock("NONE"),`
			`// .mem_init0($sformatf("%08x", INIT))`
			`) _TECHMAP_REPLACE_ (`
			`.portaaddr(A1ADDR),`
			`.portadatain(A1DATA),`
			`.portbaddr(B1ADDR),`
			`.portbdataout(B1DATA),`
			`.ena0(A1EN),`
			`.clk0(CLK1)`
			`);`

			`endmodule`
intel_alm: DSP inference 2020-04-25 11:25:59 -05:00

intel_alm: direct M10K instantiation This reverts commit a3a90f6377f251d3b6c5898eb1543f8832493bb8. 2020-07-26 13:28:10 -05:00			`module MISTRAL_M10K(A1ADDR, A1DATA, A1EN, CLK1, B1ADDR, B1DATA, B1EN);`

			`parameter CFG_ABITS = 10;`
			`parameter CFG_DBITS = 10;`

			`parameter _TECHMAP_CELLNAME_ = "";`

			`input [CFG_ABITS-1:0] A1ADDR, B1ADDR;`
			`input [CFG_DBITS-1:0] A1DATA;`
			`input CLK1, A1EN, B1EN;`
			`output [CFG_DBITS-1:0] B1DATA;`

			`// Much like the MLAB, the M10K has mem_init[01234] parameters which would let`
			`// you initialise the RAM cell via hex literals. If they were implemented.`

intel_alm: preliminary Arria V support 2021-11-24 15:20:40 -06:00			`RAM_BLOCK #(
intel_alm: direct M10K instantiation This reverts commit a3a90f6377f251d3b6c5898eb1543f8832493bb8. 2020-07-26 13:28:10 -05:00			`.operation_mode("dual_port"),`
			`.logical_ram_name(_TECHMAP_CELLNAME_),`
			`.port_a_address_width(CFG_ABITS),`
			`.port_a_data_width(CFG_DBITS),`
			`.port_a_logical_ram_depth(2**CFG_ABITS),`
			`.port_a_logical_ram_width(CFG_DBITS),`
			`.port_a_first_address(0),`
			`.port_a_last_address(2**CFG_ABITS - 1),`
			`.port_a_first_bit_number(0),`
			`.port_b_address_width(CFG_ABITS),`
			`.port_b_data_width(CFG_DBITS),`
			`.port_b_logical_ram_depth(2**CFG_ABITS),`
			`.port_b_logical_ram_width(CFG_DBITS),`
			`.port_b_first_address(0),`
			`.port_b_last_address(2**CFG_ABITS - 1),`
			`.port_b_first_bit_number(0),`
			`.port_b_address_clock("clock0"),`
			`.port_b_read_enable_clock("clock0")`
			`) _TECHMAP_REPLACE_ (`
			`.portaaddr(A1ADDR),`
			`.portadatain(A1DATA),`
			`.portawe(A1EN),`
			`.portbaddr(B1ADDR),`
			`.portbdataout(B1DATA),`
			`.portbre(B1EN),`
			`.clk0(CLK1)`
			`);`

			`endmodule`


intel_alm: DSP inference 2020-04-25 11:25:59 -05:00			`module MISTRAL_MUL27X27(input [26:0] A, B, output [53:0] Y);`

intel_alm: Add multiply signedness to cells Quartus assumes unsigned multiplication by default, breaking signed multiplies, so add an input signedness parameter to the MISTRAL_MUL* cells to propagate to Quartus' <family>_mac cells. 2020-08-26 12:44:48 -05:00			`parameter A_SIGNED = 1;`
			`parameter B_SIGNED = 1;`

			`MAC #(
			`.ax_width(27),`
			`.signed_max(A_SIGNED ? "true" : "false"),`
			`.ay_scan_in_width(27),`
			`.signed_may(B_SIGNED ? "true" : "false"),`
			`.result_a_width(54),`
			`.operation_mode("M27x27")`
			`) _TECHMAP_REPLACE_ (`
			`.ax(A),`
			`.ay(B),`
			`.resulta(Y)`
			`);`
intel_alm: DSP inference 2020-04-25 11:25:59 -05:00
			`endmodule`


			`module MISTRAL_MUL18X18(input [17:0] A, B, output [35:0] Y);`

intel_alm: Add multiply signedness to cells Quartus assumes unsigned multiplication by default, breaking signed multiplies, so add an input signedness parameter to the MISTRAL_MUL* cells to propagate to Quartus' <family>_mac cells. 2020-08-26 12:44:48 -05:00			`parameter A_SIGNED = 1;`
			`parameter B_SIGNED = 1;`

			`MAC #(
			`.ax_width(18),`
			`.signed_max(A_SIGNED ? "true" : "false"),`
			`.ay_scan_in_width(18),`
			`.signed_may(B_SIGNED ? "true" : "false"),`
			`.result_a_width(36),`
			`.operation_mode("M18x18_FULL")`
			`) _TECHMAP_REPLACE_ (`
			`.ax(A),`
			`.ay(B),`
			`.resulta(Y)`
			`);`
intel_alm: DSP inference 2020-04-25 11:25:59 -05:00
			`endmodule`


			`module MISTRAL_MUL9X9(input [8:0] A, B, output [17:0] Y);`

intel_alm: Add multiply signedness to cells Quartus assumes unsigned multiplication by default, breaking signed multiplies, so add an input signedness parameter to the MISTRAL_MUL* cells to propagate to Quartus' <family>_mac cells. 2020-08-26 12:44:48 -05:00			`parameter A_SIGNED = 1;`
			`parameter B_SIGNED = 1;`

			`MAC #(
			`.ax_width(9),`
			`.signed_max(A_SIGNED ? "true" : "false"),`
			`.ay_scan_in_width(9),`
			`.signed_may(B_SIGNED ? "true" : "false"),`
			`.result_a_width(18),`
			`.operation_mode("M9x9")`
			`) _TECHMAP_REPLACE_ (`
			`.ax(A),`
			`.ay(B),`
			`.resulta(Y)`
			`);`
intel_alm: DSP inference 2020-04-25 11:25:59 -05:00
			`endmodule`
intel_alm: Add IO buffer insertion Signed-off-by: gatecat <gatecat@ds0.me> 2021-05-15 08:23:22 -05:00
			`module MISTRAL_IB(input PAD, output O);`
			`IBUF #(
			`.bus_hold("false"),`
			`.differential_mode("false")`
			`) _TECHMAP_REPLACE_ (`
			`.i(PAD),`
			`.o(O)`
			`);`
			`endmodule`

			`module MISTRAL_OB(output PAD, input I, OE);`
			`OBUF #(
			`.bus_hold("false"),`
			`.differential_mode("false")`
			`) _TECHMAP_REPLACE_ (`
			`.i(I),`
			`.o(PAD),`
			`.oe(OE)`
			`);`
			`endmodule`

			`module MISTRAL_IO(output PAD, input I, OE, output O);`
			`IBUF #(
			`.bus_hold("false"),`
			`.differential_mode("false")`
			`) ibuf (`
			`.i(PAD),`
			`.o(O)`
			`);`

			`OBUF #(
			`.bus_hold("false"),`
			`.differential_mode("false")`
			`) obuf (`
			`.i(I),`
			`.o(PAD),`
			`.oe(OE)`
			`);`
			`endmodule`
intel_alm: Add global buffer insertion Signed-off-by: gatecat <gatecat@ds0.me> 2021-05-15 08:34:48 -05:00
			`module MISTRAL_CLKBUF (input A, output Q);`
			`CLKENA #(
			`.clock_type("auto"),`
			`.ena_register_mode("always enabled"),`
			`.ena_register_power_up("high"),`
			`.disable_mode("low"),`
			`.test_syn("high")`
			`) _TECHMAP_REPLACE_ (`
			`.inclk(A),`
			`.ena(1'b1),`
			`.outclk(Q)`
			`);`
			`endmodule`