// The core logic primitive of the Cyclone V is the Adaptive Logic Module // (ALM). Each ALM is made up of an 8-input, 2-output look-up table, covered // in this file, connected to combinational outputs, a carry chain, and four // D flip-flops (which are covered as MISTRAL_FF in dff_sim.v). // // The ALM is vertically symmetric, so I find it helps to think in terms of // half-ALMs, as that's predominantly the unit that synth_intel_alm uses. // // ALMs are quite flexible, having multiple modes. // // Normal (combinational) mode // --------------------------- // The ALM can implement: // - a single 6-input function (with the other inputs usable for flip-flop access) // - two 5-input functions that share two inputs // - a 5-input and a 4-input function that share one input // - a 5-input and a 3-or-less-input function that share no inputs // - two 4-or-less-input functions that share no inputs // // Normal-mode functions are represented as MISTRAL_ALUTN cells with N inputs. // It would be possible to represent a normal mode function as a single cell - // the vendor cyclone{v,10gx}_lcell_comb cell does exactly that - but I felt // it was more user-friendly to print out the specific function sizes // separately. // // With the exception of MISTRAL_ALUT6, you can think of two normal-mode cells // fitting inside a single ALM. // // Extended (7-input) mode // ----------------------- // The ALM can also fit a 7-input function made of two 5-input functions that // share four inputs, multiplexed by another input. // // Because this can't accept arbitrary 7-input functions, Yosys can't handle // it, so it doesn't have a cell, but I would likely call it MISTRAL_ALUT7(E?) // if it did, and it would take up a full ALM. // // It might be possible to add an extraction pass to examine all ALUT5 cells // that feed into ALUT3 cells to see if they can be combined into an extended // ALM, but I don't think it will be worth it. // // Arithmetic mode // --------------- // In arithmetic mode, each half-ALM uses its carry chain to perform fast addition // of two four-input functions that share three inputs. Oddly, the result of // one of the functions is inverted before being added (you can see this as // the dot on a full-adder input of Figure 1-8 in the Handbook). // // The cell for an arithmetic-mode half-ALM is MISTRAL_ALM_ARITH. One idea // I've had (or rather was suggested by mwk) is that functions that feed into // arithmetic-mode cells could be packed directly into the arithmetic-mode // cell as a function, which reduces the number of ALMs needed. // // Shared arithmetic mode // ---------------------- // Shared arithmetic mode looks a lot like arithmetic mode, but here the // output of every other four-input function goes to the input of the adder // the next bit along. What this means is that adding three bits together can // be done in an ALM, because functions can be used to implement addition that // then feeds into the carry chain. This means that three bits can be added per // ALM, as opposed to two in the arithmetic mode. // // Shared arithmetic mode doesn't currently have a cell, but I intend to add // it as MISTRAL_ALM_SHARED, and have it occupy a full ALM. Because it adds // three bits per cell, it makes addition shorter and use less ALMs, but // I don't know enough to tell whether it's more efficient to use shared // arithmetic mode to shorten the carry chain, or plain arithmetic mode with // the functions packed in. `default_nettype none // Cyclone V LUT output timings (picoseconds): // // CARRY A B C D E F G // COMBOUT - 605 583 510 512 - 97 400 (LUT6) // COMBOUT - 602 583 457 510 302 93 483 (LUT7) // SUMOUT 368 1342 1323 887 927 - 785 - // CARRYOUT 71 1082 1062 866 813 - 1198 - (* abc9_lut=2, lib_whitebox *) module MISTRAL_ALUT6(input A, B, C, D, E, F, output Q); parameter [63:0] LUT = 64'h0000_0000_0000_0000; `ifdef cyclonev specify (A => Q) = 605; (B => Q) = 583; (C => Q) = 510; (D => Q) = 512; (E => Q) = 400; (F => Q) = 97; endspecify `endif assign Q = LUT >> {F, E, D, C, B, A}; endmodule (* abc9_lut=1, lib_whitebox *) module MISTRAL_ALUT5(input A, B, C, D, E, output Q); parameter [31:0] LUT = 32'h0000_0000; `ifdef cyclonev specify (A => Q) = 583; (B => Q) = 510; (C => Q) = 512; (D => Q) = 400; (E => Q) = 97; endspecify `endif assign Q = LUT >> {E, D, C, B, A}; endmodule (* abc9_lut=1, lib_whitebox *) module MISTRAL_ALUT4(input A, B, C, D, output Q); parameter [15:0] LUT = 16'h0000; `ifdef cyclonev specify (A => Q) = 510; (B => Q) = 512; (C => Q) = 400; (D => Q) = 97; endspecify `endif assign Q = LUT >> {D, C, B, A}; endmodule (* abc9_lut=1, lib_whitebox *) module MISTRAL_ALUT3(input A, B, C, output Q); parameter [7:0] LUT = 8'h00; `ifdef cyclonev specify (A => Q) = 510; (B => Q) = 400; (C => Q) = 97; endspecify `endif assign Q = LUT >> {C, B, A}; endmodule (* abc9_lut=1, lib_whitebox *) module MISTRAL_ALUT2(input A, B, output Q); parameter [3:0] LUT = 4'h0; `ifdef cyclonev specify (A => Q) = 400; (B => Q) = 97; endspecify `endif assign Q = LUT >> {B, A}; endmodule (* abc9_lut=1, lib_whitebox *) module MISTRAL_NOT(input A, output Q); `ifdef cyclonev specify (A => Q) = 97; endspecify `endif assign Q = ~A; endmodule (* abc9_box, lib_whitebox *) module MISTRAL_ALUT_ARITH(input A, B, C, D0, D1, (* abc9_carry *) input CI, output SO, (* abc9_carry *) output CO); parameter LUT0 = 16'h0000; parameter LUT1 = 16'h0000; `ifdef cyclonev specify (A => SO) = 1342; (B => SO) = 1323; (C => SO) = 927; (D0 => SO) = 887; (D1 => SO) = 785; (CI => SO) = 368; (A => CO) = 1082; (B => CO) = 1062; (C => CO) = 813; (D0 => CO) = 866; (D1 => CO) = 1198; (CI => CO) = 36; // Divided by 2 to account for there being two ALUT_ARITHs in an ALM) endspecify `endif wire q0, q1; assign q0 = LUT0 >> {D0, C, B, A}; assign q1 = LUT1 >> {D1, C, B, A}; assign {CO, SO} = q0 + !q1 + CI; endmodule