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[/] [ft816float/] [trunk/] [rtl/] [verilog/] [fpDiv.v] - Rev 6
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// ============================================================================ // __ // \\__/ o\ (C) 2006-2016 Robert Finch, Stratford // \ __ / All rights reserved. // \/_// robfinch<remove>@finitron.ca // || // // This source file is free software: you can redistribute it and/or modify // it under the terms of the GNU Lesser General Public License as published // by the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // This source file is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program. If not, see <http://www.gnu.org/licenses/>. // // fpDiv.v // - floating point divider // - parameterized width // - IEEE 754 representation // // Floating Point Divider // // Properties: // +-0 / +-0 = QNaN // // ============================================================================ // module fpDiv(clk, ce, ld, a, b, o, done, sign_exe, overflow, underflow); parameter WID = 32; localparam MSB = WID-1; localparam EMSB = WID==80 ? 14 : WID==64 ? 10 : WID==52 ? 10 : WID==48 ? 10 : WID==44 ? 10 : WID==42 ? 10 : WID==40 ? 9 : WID==32 ? 7 : WID==24 ? 6 : 4; localparam FMSB = WID==80 ? 63 : WID==64 ? 51 : WID==52 ? 39 : WID==48 ? 35 : WID==44 ? 31 : WID==42 ? 29 : WID==40 ? 28 : WID==32 ? 22 : WID==24 ? 15 : 9; localparam WX = 3; localparam FX = (FMSB+1)*2-1; // the MSB of the expanded fraction localparam EX = FX + WX + EMSB + 1; input clk; input ce; input ld; input [MSB:0] a, b; output [EX+1:0] o; output done; output sign_exe; output overflow; output underflow; // registered outputs reg sign_exe; reg inf; reg overflow; reg underflow; reg so; reg [EMSB:0] xo; reg [FX+WX:0] mo; assign o = {so,xo,mo}; // constants wire [EMSB:0] infXp = {EMSB+1{1'b1}}; // infinite / NaN - all ones // The following is the value for an exponent of zero, with the offset // eg. 8'h7f for eight bit exponent, 11'h7ff for eleven bit exponent, etc. wire [EMSB:0] bias = {1'b0,{EMSB{1'b1}}}; //2^0 exponent // The following is a template for a quiet nan. (MSB=1) wire [FMSB:0] qNaN = {1'b1,{FMSB{1'b0}}}; // variables wire [EMSB+2:0] ex1; // sum of exponents wire [FX+WX:0] divo; // Operands wire sa, sb; // sign bit wire [EMSB:0] xa, xb; // exponent bits wire [FMSB+1:0] fracta, fractb; wire a_dn, b_dn; // a/b is denormalized wire az, bz; wire aInf, bInf; // ----------------------------------------------------------- // - decode the input operands // - derive basic information // - calculate exponent // - calculate fraction // ----------------------------------------------------------- fpDecompose #(WID) u1a (.i(a), .sgn(sa), .exp(xa), .fract(fracta), .xz(a_dn), .vz(az), .inf(aInf) ); fpDecompose #(WID) u1b (.i(b), .sgn(sb), .exp(xb), .fract(fractb), .xz(b_dn), .vz(bz), .inf(bInf) ); // Compute the exponent. // - correct the exponent for denormalized operands // - adjust the difference by the bias (add 127) // - also factor in the different decimal position for division assign ex1 = (xa|a_dn) - (xb|b_dn) + bias + FMSB + 1; // check for exponent underflow/overflow wire under = ex1[EMSB+2]; // MSB set = negative exponent wire over = (&ex1[EMSB:0] | ex1[EMSB+1]) & !ex1[EMSB+2]; // Perform divide // could take either 1 or 16 clock cycles fpdivr2 #(FMSB+2) u2 (.clk(clk), .ld(ld), .a(fracta), .b(fractb), .q(divo[(FMSB+1)*2-1:0]), .r(), .done(done)); assign divo[FX+WX:(FMSB+1)*2] = 0; // determine when a NaN is output wire qNaNOut = (az&bz)|(aInf&bInf); always @(posedge clk) if (ce) begin if (done) begin casex({qNaNOut,bInf,bz}) 3'b1xx: xo = infXp; // NaN exponent value 3'bx1x: xo = 0; // divide by inf 3'bxx1: xo = infXp; // divide by zero default: xo = ex1; // normal or underflow: passthru neg. exp. for normalization endcase casex({qNaNOut,bInf,bz}) 3'b1xx: mo = {1'b0,qNaN[FMSB:0]|{aInf,1'b0}|{az,bz},{FMSB+1{1'b0}}}; 3'bx1x: mo = 0; // div by inf 3'bxx1: mo = 0; // div by zero default: mo = divo; // plain div endcase so = sa ^ sb; sign_exe = sa & sb; overflow = over; underflow = under; end end endmodule module fpDiv_tb(); reg clk; reg ld; wire ce = 1'b1; wire sgnx1,sgnx2,sgnx3,sgnx4,sgnx5,sgnx6; wire inf1,inf2,inf3,inf4,inf5,inf6; wire of1,of2,of3,of4,of5,of6; wire uf1,uf2,uf3,uf4,uf5,uf6; wire [57:0] o1,o2,o3,o4,o5,o6; wire [35:0] o11,o12,o13; wire [31:0] o21,o22,o23; wire done0,done1,done2,done3,done4,done5,done6; initial begin clk = 0; ld = 0; #20 ld = 1; #40 ld = 0; end always #10 clk <= ~clk; fpDiv u1 (.clk(clk), .ce(1'b1), .ld(ld), .a(0), .b(0), .o(o1), .done(done1), .sign_exe(sgnx1), .overflow(of1), .underflow(uf1)); fpDiv u2 (.clk(clk), .ce(1'b1), .ld(ld), .a(0), .b(0), .o(o2), .done(done2), .sign_exe(sgnx2), .overflow(of2), .underflow(uf2)); // 10/10 fpDiv u3 (.clk(clk), .ce(1'b1), .ld(ld), .a(32'h41200000), .b(32'h41200000), .done(done3), .o(o3), .sign_exe(sgnx2), .overflow(of2), .underflow(uf2)); // 21/-17 fpDiv u4 (.clk(clk), .ce(1'b1), .ld(ld), .a(32'h41a80000), .b(32'hc1880000), .done(done4), .o(o4), .sign_exe(sgnx2), .overflow(of2), .underflow(uf2)); // -17/-15 fpDiv u5 (.clk(clk), .ce(1'b1), .ld(ld), .a(32'hc1880000), .b(32'hc1700000), .done(done5), .o(o5), .sign_exe(sgnx2), .overflow(of2), .underflow(uf2)); fpNormalize u11 (clk, ce, 1'b0, o3, o11); fpNormalize u12 (clk, ce, 1'b0, o4, o12); fpNormalize u13 (clk, ce, 1'b0, o5, o13); fpRound u21 (3'd1, o11, o21); // zero for zero fpRound u22 (3'd1, o12, o22); // fpRound u23 (3'd1, o13, o23); // endmodule
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