mirror of https://github.com/YosysHQ/yosys.git
133 lines
5.3 KiB
Verilog
133 lines
5.3 KiB
Verilog
// This pass performs an optimisation that decomposes wide arithmetic
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// comparisons into LUT-size chunks (as guided by the `LUT_WIDTH
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// macro) connected to a single lookahead-carry-unit $lcu cell,
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// which is typically mapped to dedicated (and fast) FPGA
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// carry-chains.
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(* techmap_celltype = "$lt $le $gt $ge" *)
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module _80_lcu_cmp_ (A, B, Y);
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parameter A_SIGNED = 0;
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parameter B_SIGNED = 0;
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parameter A_WIDTH = 0;
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parameter B_WIDTH = 0;
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parameter Y_WIDTH = 0;
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(* force_downto *)
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input [A_WIDTH-1:0] A;
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(* force_downto *)
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input [B_WIDTH-1:0] B;
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(* force_downto *)
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output [Y_WIDTH-1:0] Y;
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parameter _TECHMAP_CELLTYPE_ = "";
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generate
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if (_TECHMAP_CELLTYPE_ == "" || `LUT_WIDTH < 2)
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wire _TECHMAP_FAIL_ = 1;
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else if (_TECHMAP_CELLTYPE_ == "$lt") begin
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// Transform $lt into $gt by swapping A and B
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$gt #(.A_SIGNED(B_SIGNED), .B_SIGNED(A_SIGNED), .A_WIDTH(B_WIDTH), .B_WIDTH(A_WIDTH), .Y_WIDTH(Y_WIDTH)) _TECHMAP_REPLACE_ (.A(B), .B(A), .Y(Y));
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end
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else if (_TECHMAP_CELLTYPE_ == "$le") begin
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// Transform $le into $ge by swapping A and B
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$ge #(.A_SIGNED(B_SIGNED), .B_SIGNED(A_SIGNED), .A_WIDTH(B_WIDTH), .B_WIDTH(A_WIDTH), .Y_WIDTH(Y_WIDTH)) _TECHMAP_REPLACE_ (.A(B), .B(A), .Y(Y));
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end
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else begin
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// Perform sign extension on A and B
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localparam WIDTH = A_WIDTH > B_WIDTH ? A_WIDTH : B_WIDTH;
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(* force_downto *)
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wire [WIDTH-1:0] AA = {{(WIDTH-A_WIDTH){A_SIGNED ? A[A_WIDTH-1] : 1'b0}}, A};
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(* force_downto *)
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wire [WIDTH-1:0] BB = {{(WIDTH-B_WIDTH){B_SIGNED ? B[B_WIDTH-1] : 1'b0}}, B};
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// For $ge operation, start with the assumption that A and B are
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// equal (propagating this equality if A and B turn out to be so)
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if (_TECHMAP_CELLTYPE_ == "$ge")
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localparam CI = 1'b1;
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else
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localparam CI = 1'b0;
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$__CMP2LCU #(.AB_WIDTH(WIDTH), .AB_SIGNED(A_SIGNED && B_SIGNED), .LCU_WIDTH(1), .BUDGET(`LUT_WIDTH), .CI(CI))
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_TECHMAP_REPLACE_ (.A(AA), .B(BB), .P(1'b1), .G(1'b0), .Y(Y));
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end
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endgenerate
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endmodule
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module $__CMP2LCU (A, B, P, G, Y);
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parameter AB_WIDTH = 0;
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parameter AB_SIGNED = 0;
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parameter LCU_WIDTH = 1;
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parameter BUDGET = 0;
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parameter CI = 0;
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(* force_downto *)
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input [AB_WIDTH-1:0] A; // A from original $gt/$ge
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(* force_downto *)
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input [AB_WIDTH-1:0] B; // B from original $gt/$ge
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(* force_downto *)
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input [LCU_WIDTH-1:0] P; // P of $lcu
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(* force_downto *)
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input [LCU_WIDTH-1:0] G; // G of $lcu
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output Y;
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parameter [AB_WIDTH-1:0] _TECHMAP_CONSTMSK_A_ = 0;
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parameter [AB_WIDTH-1:0] _TECHMAP_CONSTMSK_B_ = 0;
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parameter [LCU_WIDTH-1:0] _TECHMAP_CONSTMSK_P_ = 0;
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generate
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if (AB_WIDTH == 0) begin
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(* force_downto *)
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wire [LCU_WIDTH-1:0] CO;
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$lcu #(.WIDTH(LCU_WIDTH)) _TECHMAP_REPLACE_ (.P(P), .G(G), .CI(CI), .CO(CO));
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assign Y = CO[LCU_WIDTH-1];
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end
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else begin
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if (_TECHMAP_CONSTMSK_A_[AB_WIDTH-1:0] && _TECHMAP_CONSTMSK_B_[AB_WIDTH-1:0])
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localparam COST = 0;
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else if (_TECHMAP_CONSTMSK_A_[AB_WIDTH-1:0] || _TECHMAP_CONSTMSK_B_[AB_WIDTH-1:0])
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localparam COST = 1;
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else
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localparam COST = 2;
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if (BUDGET < COST)
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$__CMP2LCU #(.AB_WIDTH(AB_WIDTH), .AB_SIGNED(AB_SIGNED), .LCU_WIDTH(LCU_WIDTH+1), .BUDGET(`LUT_WIDTH), .CI(CI))
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_TECHMAP_REPLACE_ (.A(A), .B(B), .P({P, 1'b1}), .G({G, 1'b0}), .Y(Y));
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else begin
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wire PP, GG;
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// Bit-wise equality (xnor) of A and B
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assign PP = A[AB_WIDTH-1] ^~ B[AB_WIDTH-1];
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if (AB_SIGNED)
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assign GG = ~A[AB_WIDTH-1] & B[AB_WIDTH-1];
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else if (_TECHMAP_CONSTMSK_P_[LCU_WIDTH-1]) // First compare for LUT if P (and G) is constant
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assign GG = A[AB_WIDTH-1] & ~B[AB_WIDTH-1];
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else
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// Priority "encoder" that checks A[i] == 1'b1 && B[i] == 1'b0
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// from MSB down, deferring to less significant bits if the
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// MSBs are equal
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assign GG = P[0] & (A[AB_WIDTH-1] & ~B[AB_WIDTH-1]);
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if (LCU_WIDTH == 1) begin
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// Propagate only if all pairs are equal
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// (inconclusive evidence to say A >= B)
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wire P_ = P[0] & PP;
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// Generate if any comparisons call for it
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wire G_ = G[0] | GG;
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end
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else begin
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// Propagate only if all pairs are equal
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// (inconclusive evidence to say A >= B)
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(* force_downto *)
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wire [LCU_WIDTH-1:0] P_ = {P[LCU_WIDTH-1:1], P[0] & PP};
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// Generate if any comparisons call for it
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(* force_downto *)
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wire [LCU_WIDTH-1:0] G_ = {G[LCU_WIDTH-1:1], G[0] | GG};
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end
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if (AB_WIDTH == 1)
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$__CMP2LCU #(.AB_WIDTH(AB_WIDTH-1), .AB_SIGNED(1'b0), .LCU_WIDTH(LCU_WIDTH), .BUDGET(BUDGET-COST), .CI(CI))
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_TECHMAP_REPLACE_ (.A(), .B(), .P(P_), .G(G_), .Y(Y));
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else
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$__CMP2LCU #(.AB_WIDTH(AB_WIDTH-1), .AB_SIGNED(1'b0), .LCU_WIDTH(LCU_WIDTH), .BUDGET(BUDGET-COST), .CI(CI))
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_TECHMAP_REPLACE_ (.A(A[AB_WIDTH-2:0]), .B(B[AB_WIDTH-2:0]), .P(P_), .G(G_), .Y(Y));
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end
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end
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endgenerate
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endmodule
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