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`timescale 1ns / 1ps // ============================================================================ // __ // \\__/ o\ (C) 2019 Robert Finch, Waterloo // \ __ / All rights reserved. // \/_// robfinch<remove>@finitron.ca // || // // fpFMA.v // - floating point fused multiplier + adder // - can issue every clock cycle // - parameterized width // - IEEE 754 representation // // // 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/>. // // Floating Point Multiplier / Divider // // This multiplier/divider handles denormalized numbers. // The output format is of an internal expanded representation // in preparation to be fed into a normalization unit, then // rounding. Basically, it's the same as the regular format // except the mantissa is doubled in size, the leading two // bits of which are assumed to be whole bits. // // // Floating Point Multiplier // // Properties: // +-inf * +-inf = -+inf (this is handled by exOver) // +-inf * 0 = QNaN // // ============================================================================ module fpFMA (clk, ce, op, rm, a, b, c, o, inf); parameter WID = 32; localparam MSB = WID-1; localparam EMSB = WID==128 ? 14 : WID==96 ? 14 : WID==80 ? 14 : WID==64 ? 10 : WID==52 ? 10 : WID==48 ? 11 : WID==44 ? 10 : WID==42 ? 10 : WID==40 ? 9 : WID==32 ? 7 : WID==24 ? 6 : 4; localparam FMSB = WID==128 ? 111 : WID==96 ? 79 : WID==80 ? 63 : WID==64 ? 51 : WID==52 ? 39 : WID==48 ? 34 : WID==44 ? 31 : WID==42 ? 29 : WID==40 ? 28 : WID==32 ? 22 : WID==24 ? 15 : 9; localparam FX = (FMSB+2)*2-1; // the MSB of the expanded fraction localparam EX = FX + 1 + EMSB + 1 + 1 - 1; input clk; input ce; input op; // operation 0 = add, 1 = subtract input [2:0] rm; input [WID:1] a, b, c; output [EX:0] o; output inf; // 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}}}; // ----------------------------------------------------------- // Clock #1 // - decode the input operands // - derive basic information // ----------------------------------------------------------- wire sa1, sb1, sc1; // sign bit wire [EMSB:0] xa1, xb1, xc1; // exponent bits wire [FMSB+1:0] fracta1, fractb1, fractc1; // includes unhidden bit wire a_dn1, b_dn1, c_dn1; // a/b is denormalized wire aNan1, bNan1, cNan1; wire az1, bz1, cz1; wire aInf1, bInf1, cInf1; reg op1; wire xcInf1; fpDecompReg #(WID) u1a (.clk(clk), .ce(ce), .i(a), .sgn(sa1), .exp(xa1), .fract(fracta1), .xz(a_dn1), .vz(az1), .inf(aInf1), .nan(aNan1) ); fpDecompReg #(WID) u1b (.clk(clk), .ce(ce), .i(b), .sgn(sb1), .exp(xb1), .fract(fractb1), .xz(b_dn1), .vz(bz1), .inf(bInf1), .nan(bNan1) ); fpDecompReg #(WID) u1c (.clk(clk), .ce(ce), .i(c), .sgn(sc1), .exp(xc1), .fract(fractc1), .xz(c_dn1), .vz(cz1), .inf(cInf1), .nan(cNan1) ); always @(posedge clk) if (ce) op1 <= op; assign xcInf1 = &xc1; // ----------------------------------------------------------- // Clock #2 // Compute the sum of the exponents. // correct the exponent for denormalized operands // adjust the sum by the exponent offset (subtract 127) // mul: ex1 = xa + xb, result should always be < 1ffh // Form partial products (clocks 2 to 5) // ----------------------------------------------------------- reg abz2; reg [EMSB+2:0] ex2; reg [EMSB:0] xc2; reg realOp2; always @(posedge clk) if (ce) abz2 <= az1|bz1; always @(posedge clk) if (ce) ex2 <= (xa1|a_dn1) + (xb1|b_dn1) - bias; always @(posedge clk) if (ce) xc2 <= (xc1|c_dn1); // Figure out which operation is really needed an add or // subtract ? // If the signs are the same, use the orignal op, // otherwise flip the operation // a + b = add,+ // a + -b = sub, so of larger // -a + b = sub, so of larger // -a + -b = add,- // a - b = sub, so of larger // a - -b = add,+ // -a - b = add,- // -a - -b = sub, so of larger always @(posedge clk) if (ce) realOp2 <= op1 ^ (sa1 ^ sb1) ^ sc1; reg [FX:0] fract5; generate if (WID==80) begin reg [31:0] p00,p01,p02,p03; reg [31:0] p10,p11,p12,p13; reg [31:0] p20,p21,p22,p23; reg [31:0] p30,p31,p32,p33; reg [127:0] fract3a; reg [127:0] fract3b; reg [127:0] fract3c; reg [127:0] fract3d; reg [127:0] fract4a; reg [127:0] fract4b; always @(posedge clk) if (ce) begin p00 <= fracta1[15: 0] * fractb1[15: 0]; p01 <= fracta1[31:16] * fractb1[15: 0]; p02 <= fracta1[47:32] * fractb1[15: 0]; p03 <= fracta1[63:48] * fractb1[15: 0]; p10 <= fracta1[15: 0] * fractb1[31:16]; p11 <= fracta1[31:16] * fractb1[31:16]; p12 <= fracta1[47:32] * fractb1[31:16]; p13 <= fracta1[63:48] * fractb1[31:16]; p20 <= fracta1[15: 0] * fractb1[47:32]; p21 <= fracta1[31:16] * fractb1[47:32]; p22 <= fracta1[47:32] * fractb1[47:32]; p23 <= fracta1[63:48] * fractb1[47:32]; p30 <= fracta1[15: 0] * fractb1[63:48]; p31 <= fracta1[31:16] * fractb1[63:48]; p32 <= fracta1[47:32] * fractb1[63:48]; p33 <= fracta1[63:48] * fractb1[63:48]; end always @(posedge clk) if (ce) begin fract3a <= {p33,p31,p20,p00}; fract3b <= {p32,p12,p10,16'b0} + {p23,p03,p01,16'b0}; fract3c <= {p22,p11,32'b0} + {p13,p02,32'b0}; fract3d <= {p12,48'b0} + {p03,48'b0}; end always @(posedge clk) if (ce) begin fract4a <= fract3a + fract3b; fract4b <= fract3c + fract3d; end always @(posedge clk) if (ce) begin fract5 <= fract4a + fract4b; end end else if (WID==64) begin reg [35:0] p00,p01,p02; reg [35:0] p10,p11,p12; reg [35:0] p20,p21,p22; reg [71:0] fract3a; reg [89:0] fract3b; reg [107:0] fract3c; reg [108:0] fract4a; reg [108:0] fract4b; always @(posedge clk) if (ce) begin p00 <= fracta1[17: 0] * fractb1[17: 0]; p01 <= fracta1[35:18] * fractb1[17: 0]; p02 <= fracta1[52:36] * fractb1[17: 0]; p10 <= fracta1[17: 0] * fractb1[35:18]; p11 <= fracta1[35:18] * fractb1[35:18]; p12 <= fracta1[52:36] * fractb1[35:18]; p20 <= fracta1[17: 0] * fractb1[52:36]; p21 <= fracta1[35:18] * fractb1[52:36]; p22 <= fracta1[52:36] * fractb1[52:36]; end always @(posedge clk) if (ce) begin fract3a <= {p02,p00}; fract3b <= {p21,p10,18'b0} + {p12,p01,18'b0}; fract3c <= {p22,p20,36'b0} + {p11,36'b0}; end always @(posedge clk) if (ce) begin fract4a <= fract3a + fract3b; fract4b <= fract3c; end always @(posedge clk) if (ce) begin fract5 <= fract4a + fract4b; end end else if (WID==40) begin reg [27:0] p00,p01,p02; reg [27:0] p10,p11,p12; reg [27:0] p20,p21,p22; reg [79:0] fract3a; reg [79:0] fract3b; reg [79:0] fract3c; reg [79:0] fract4a; reg [79:0] fract4b; always @(posedge clk) if (ce) begin p00 <= fracta1[13: 0] * fractb1[13: 0]; p01 <= fracta1[27:14] * fractb1[13: 0]; p02 <= fracta1[39:28] * fractb1[13: 0]; p10 <= fracta1[13: 0] * fractb1[27:14]; p11 <= fracta1[27:14] * fractb1[27:14]; p12 <= fracta1[39:28] * fractb1[27:14]; p20 <= fracta1[13: 0] * fractb1[39:28]; p21 <= fracta1[27:14] * fractb1[39:28]; p22 <= fracta1[39:28] * fractb1[39:28]; end always @(posedge clk) if (ce) begin fract3a <= {p02,p00}; fract3b <= {p21,p10,18'b0} + {p12,p01,18'b0}; fract3c <= {p22,p20,36'b0} + {p11,36'b0}; end always @(posedge clk) if (ce) begin fract4a <= fract3a + fract3b; fract4b <= fract3c; end always @(posedge clk) if (ce) begin fract5 <= fract4a + fract4b; end end else if (WID==32) begin reg [23:0] p00,p01,p02; reg [23:0] p10,p11,p12; reg [23:0] p20,p21,p22; reg [63:0] fract3a; reg [63:0] fract3b; reg [63:0] fract4; always @(posedge clk) if (ce) begin p00 <= fracta1[11: 0] * fractb1[11: 0]; p01 <= fracta1[23:12] * fractb1[11: 0]; p10 <= fracta1[11: 0] * fractb1[23:12]; p11 <= fracta1[23:12] * fractb1[23:12]; end always @(posedge clk) if (ce) begin fract3a <= {p11,p00}; fract3b <= {p01,12'b0} + {p10,12'b0}; end always @(posedge clk) if (ce) begin fract4 <= fract3a + fract3b; end always @(posedge clk) if (ce) begin fract5 <= fract4; end end else begin reg [FX:0] p00; reg [FX:0] fract3; reg [FX:0] fract4; always @(posedge clk) if (ce) begin p00 <= fracta1 * fractb1; end always @(posedge clk) if (ce) fract3 <= p00; always @(posedge clk) if (ce) fract4 <= fract3; always @(posedge clk) if (ce) fract5 <= fract4; end endgenerate // ----------------------------------------------------------- // Clock #3 // Select zero exponent // ----------------------------------------------------------- reg [EMSB+2:0] ex3; reg [EMSB:0] xc3; always @(posedge clk) if (ce) ex3 <= abz2 ? 1'd0 : ex2; always @(posedge clk) if (ce) xc3 <= xc2; // ----------------------------------------------------------- // Clock #4 // Generate partial products. // ----------------------------------------------------------- reg [EMSB+2:0] ex4; reg [EMSB:0] xc4; always @(posedge clk) if (ce) ex4 <= ex3; always @(posedge clk) if (ce) xc4 <= xc3; // ----------------------------------------------------------- // Clock #5 // Sum partial products (above) // compute multiplier overflow and underflow // ----------------------------------------------------------- // Status reg under5; reg over5; reg [EMSB:0] ex5; reg [EMSB:0] xc5; wire aInf5, bInf5; wire aNan5, bNan5; wire qNaNOut5; always @(posedge clk) if (ce) under5 <= ex4[EMSB+2]; always @(posedge clk) if (ce) over5 <= (&ex4[EMSB:0] | ex4[EMSB+1]) & !ex4[EMSB+2]; always @(posedge clk) if (ce) ex5 <= ex4[EMSB:0]; always @(posedge clk) if (ce) xc5 <= xc4; delay4 u2a (.clk(clk), .ce(ce), .i(aInf1), .o(aInf5) ); delay4 u2b (.clk(clk), .ce(ce), .i(bInf1), .o(bInf5) ); // determine when a NaN is output wire [WID-1:0] a5,b5; delay4 u5 (.clk(clk), .ce(ce), .i((aInf1&bz1)|(bInf1&az1)), .o(qNaNOut5) ); delay4 u14 (.clk(clk), .ce(ce), .i(aNan1), .o(aNan5) ); delay4 u15 (.clk(clk), .ce(ce), .i(bNan1), .o(bNan5) ); delay5 #(WID) u16 (.clk(clk), .ce(ce), .i(a), .o(a5) ); delay5 #(WID) u17 (.clk(clk), .ce(ce), .i(b), .o(b5) ); // ----------------------------------------------------------- // Clock #6 // - figure multiplier mantissa output // - figure multiplier exponent output // - correct xponent and mantissa for exceptional conditions // ----------------------------------------------------------- reg [FX:0] mo6; reg [EMSB:0] ex6; reg [EMSB:0] xc6; reg exinf6; wire [FMSB+1:0] fractc6; delay5 #(FMSB+2) u61 (.clk(clk), .ce(ce), .i(fractc1), .o(fractc6) ); delay1 u62 (.clk(clk), .ce(ce), .i(under5), .o(under6)); always @(posedge clk) if (ce) xc6 <= xc5; always @(posedge clk) if (ce) casez({aNan5,bNan5,qNaNOut5,aInf5,bInf5,over5}) 6'b1?????: mo6 <= {1'b1,a5[FMSB:0],{FMSB+1{1'b0}}}; 6'b01????: mo6 <= {1'b1,b5[FMSB:0],{FMSB+1{1'b0}}}; 6'b001???: mo6 <= {1'b1,qNaN|3'd4,{FMSB+1{1'b0}}}; // multiply inf * zero 6'b0001??: mo6 <= 0; // mul inf's 6'b00001?: mo6 <= 0; // mul inf's 6'b000001: mo6 <= 0; // mul overflow default: mo6 <= fract5; endcase always @(posedge clk) if (ce) casez({qNaNOut5|aNan5|bNan5,aInf5,bInf5,over5,under5}) 5'b1????: ex6 <= infXp; // qNaN - infinity * zero 5'b01???: ex6 <= infXp; // 'a' infinite 5'b001??: ex6 <= infXp; // 'b' infinite 5'b0001?: ex6 <= infXp; // result overflow 5'b00001: ex6 <= ex5[EMSB:0];//0; // underflow default: ex6 <= ex5[EMSB:0]; // situation normal endcase always @(posedge clk) if (ce) casez({qNaNOut5|aNan5|bNan5,aInf5,bInf5,over5,under5}) 5'b1????: exinf6 <= 1'b1; // qNaN - infinity * zero 5'b01???: exinf6 <= 1'b1; // 'a' infinite 5'b001??: exinf6 <= 1'b1; // 'b' infinite 5'b0001?: exinf6 <= 1'b1; // result overflow 5'b00001: exinf6 <= |ex5[EMSB:0];//0; // underflow default: exinf6 <= |ex5[EMSB:0]; // situation normal endcase // ----------------------------------------------------------- // Clock #7 // - prep for addition, determine greater operand // ----------------------------------------------------------- reg ex_gt_xc7; reg xeq7; reg ma_gt_mc7; reg meq7; reg exinf7; wire az7, bz7, cz7; wire realOp7; always @(posedge clk) if (ce) exinf7 <= exinf6; // which has greater magnitude ? Used for sign calc always @(posedge clk) if (ce) ex_gt_xc7 <= (ex6 > xc6) && !under6; always @(posedge clk) if (ce) xeq7 <= (ex6==xc6) && !under6; always @(posedge clk) if (ce) ma_gt_mc7 <= mo6 > {fractc6,{FMSB+1{1'b0}}}; always @(posedge clk) if (ce) meq7 <= mo6 == {fractc6,{FMSB+1{1'b0}}}; vtdl u71 (.clk(clk), .ce(ce), .a(4'd5), .d(az1), .q(az7)); vtdl u72 (.clk(clk), .ce(ce), .a(4'd5), .d(bz1), .q(bz7)); vtdl u73 (.clk(clk), .ce(ce), .a(4'd5), .d(cz1), .q(cz7)); vtdl u74 (.clk(clk), .ce(ce), .a(4'd4), .d(realOp2), .q(realOp7)); // ----------------------------------------------------------- // Clock #8 // - prep for addition, determine greater operand // - determine if result will be zero // ----------------------------------------------------------- reg a_gt_b8; reg resZero8; reg ex_gt_xc8; wire [EMSB:0] ex8; wire [EMSB:0] xc8; reg exinf8; wire xcInf8; wire [2:0] rm8; wire op8; wire sa8, sb8, sc8; delay2 #(EMSB+1) u81 (.clk(clk), .ce(ce), .i(ex6), .o(ex8)); delay2 #(EMSB+1) u82 (.clk(clk), .ce(ce), .i(xc6), .o(xc8)); vtdl u83 (.clk(clk), .ce(ce), .a(4'd6), .d(xcInf1), .q(xcInf8)); vtdl #(3) u84 (.clk(clk), .ce(ce), .a(4'd7), .d(rm), .q(rm8)); vtdl u85 (.clk(clk), .ce(ce), .a(4'd6), .d(op1), .q(op8)); vtdl u86 (.clk(clk), .ce(ce), .a(4'd7), .d(sa1 ^ sb1), .q(sa8)); vtdl u87 (.clk(clk), .ce(ce), .a(4'd7), .d(sc1), .q(sc8)); always @(posedge clk) if (ce) exinf8 <= exinf7; always @(posedge clk) if (ce) ex_gt_xc8 <= ex_gt_xc7; always @(posedge clk) if (ce) a_gt_b8 <= ex_gt_xc7 || (xeq7 && ma_gt_mc7); // Find out if the result will be zero. always @(posedge clk) if (ce) resZero8 <= (realOp7 & xeq7 & meq7) || // subtract, same magnitude ((az7 | bz7) & cz7); // a or b zero and c zero // ----------------------------------------------------------- // CLock #9 // Compute output exponent and sign // // The output exponent is the larger of the two exponents, // unless a subtract operation is in progress and the two // numbers are equal, in which case the exponent should be // zero. // ----------------------------------------------------------- reg so9; reg [EMSB:0] ex9; reg [EMSB:0] ex9a; reg ex_gt_xc9; reg [EMSB:0] xc9; wire [FX:0] mo9; wire [FMSB+1:0] fractc9; wire under9; always @(posedge clk) if (ce) ex_gt_xc9 <= ex_gt_xc8; always @(posedge clk) if (ce) xc9 <= xc8; always @(posedge clk) if (ce) ex9a <= ex8; delay3 #(FX+1) u93 (.clk(clk), .ce(ce), .i(mo6), .o(mo9)); delay3 #(FMSB+2) u94 (.clk(clk), .ce(ce), .i(fractc6), .o(fractc9)); delay3 u95 (.clk(clk), .ce(ce), .i(under6), .o(under9)); always @(posedge clk) if (ce) ex9 <= (exinf8&xcInf8) ? ex8 : resZero8 ? 0 : ex_gt_xc8 ? ex8 : xc8; // Compute output sign always @* case ({resZero8,sa8,op8,sc8}) // synopsys full_case parallel_case 4'b0000: so9 <= 0; // + + + = + 4'b0001: so9 <= !a_gt_b8; // + + - = sign of larger 4'b0010: so9 <= !a_gt_b8; // + - + = sign of larger 4'b0011: so9 <= 0; // + - - = + 4'b0100: so9 <= a_gt_b8; // - + + = sign of larger 4'b0101: so9 <= 1; // - + - = - 4'b0110: so9 <= 1; // - - + = - 4'b0111: so9 <= a_gt_b8; // - - - = sign of larger 4'b1000: so9 <= 0; // A + B, sign = + 4'b1001: so9 <= rm8==3; // A + -B, sign = + unless rounding down 4'b1010: so9 <= rm8==3; // A - B, sign = + unless rounding down 4'b1011: so9 <= 0; // +A - -B, sign = + 4'b1100: so9 <= rm8==3; // -A + B, sign = + unless rounding down 4'b1101: so9 <= 1; // -A + -B, sign = - 4'b1110: so9 <= 1; // -A - +B, sign = - 4'b1111: so9 <= rm8==3; // -A - -B, sign = + unless rounding down endcase // ----------------------------------------------------------- // Clock #10 // Compute the difference in exponents, provides shift amount // ----------------------------------------------------------- reg [EMSB:0] xdiff10; reg [FX:0] mfs; always @(posedge clk) if (ce) xdiff10 <= ex_gt_xc9 ? ex9a - xc9 : (under9 ? xc9 + ex9a : xc9 - ex9a); // determine which fraction to denormalize always @(posedge clk) if (ce) mfs <= ex_gt_xc9 ? {4'b0,fractc9,{FMSB+1{1'b0}}} : mo9; // ----------------------------------------------------------- // Clock #11 // ----------------------------------------------------------- reg [6:0] xdif11; always @(posedge clk) if (ce) xdif11 <= xdiff10 > FMSB+3 ? FMSB+3 : xdiff10; // ----------------------------------------------------------- // Clock #12 // Determine the sticky bit // ----------------------------------------------------------- wire sticky, sticky12; wire [FX:0] mfs12; wire [6:0] xdif12; generate begin if (WID==128) redor128 u121 (.a(xdif11), .b({mfs,2'b0}), .o(sticky) ); else if (WID==96) redor96 u121 (.a(xdif11), .b({mfs,2'b0}), .o(sticky) ); else if (WID==80) redor80 u121 (.a(xdif11), .b({mfs,2'b0}), .o(sticky) ); else if (WID==64) redor64 u121 (.a(xdif11), .b({mfs,2'b0}), .o(sticky) ); else if (WID==32) redor32 u121 (.a(xdif11), .b({mfs,2'b0}), .o(sticky) ); end endgenerate // register inputs to shifter and shift delay1 #(1) u122(.clk(clk), .ce(ce), .i(sticky), .o(sticky12) ); delay1 #(7) u123(.clk(clk), .ce(ce), .i(xdif11), .o(xdif12) ); delay2 #(FX+1) u124(.clk(clk), .ce(ce), .i(mfs), .o(mfs12) ); // ----------------------------------------------------------- // Clock #13 // - denormalize operand // ----------------------------------------------------------- reg [FX+2:0] mfs13; wire [FX:0] mo13; wire ex_gt_xc13; wire [FMSB+1:0] fractc13; delay4 #(FX+1) u131 (.clk(clk), .ce(ce), .i(mo9), .o(mo13)); delay4 u132 (.clk(clk), .ce(ce), .i(ex_gt_xc9), .o(ex_gt_xc13)); vtdl #(FMSB+2) u133 (.clk(clk), .ce(ce), .a(4'd3), .d(fractc9), .q(fractc13)); always @(posedge clk) if (ce) mfs13 <= ({mfs12,2'b0} >> xdif12)|{sticky12,1'b0}; // ----------------------------------------------------------- // Clock #14 // Sort operands // ----------------------------------------------------------- reg [FX+2:0] oa, ob; wire a_gt_b14; vtdl u141 (.clk(clk), .ce(ce), .a(4'd5), .d(a_gt_b8), .q(a_gt_b14)); always @(posedge clk) if (ce) oa <= ex_gt_xc13 ? {mo13,2'b00} : mfs13; always @(posedge clk) if (ce) ob <= ex_gt_xc13 ? mfs13 : {fractc13,{FMSB+1{1'b0}},2'b00}; // ----------------------------------------------------------- // Clock #15 // - Sort operands // ----------------------------------------------------------- reg [FX+2:0] oaa, obb; wire realOp15; wire [EMSB:0] ex15; vtdl u151 (.clk(clk), .ce(ce), .a(4'd7), .d(realOp7), .q(realOp15)); vtdl #(EMSB+1) u152 (.clk(clk), .ce(ce), .a(4'd5), .d(ex9), .q(ex15)); always @(posedge clk) if (ce) oaa <= a_gt_b14 ? oa : ob; always @(posedge clk) if (ce) obb <= a_gt_b14 ? ob : oa; // ----------------------------------------------------------- // Clock #16 // - perform add/subtract // - addition can generate an extra bit, subtract can't go negative // ----------------------------------------------------------- reg [FX+3:0] mab; wire [FX:0] mo16; wire [FMSB+1:0] fractc16; wire Nan16; wire cNan16; wire aInf16, cInf16; wire op16; wire exinf16; vtdl u161 (.clk(clk), .ce(ce), .a(4'd10), .d(qNaNOut5|aNan5|bNan5), .q(Nan16)); vtdl u162 (.clk(clk), .ce(ce), .a(4'd14), .d(cNan1), .q(cNan16)); vtdl u163 (.clk(clk), .ce(ce), .a(4'd9), .d(exinf6), .q(aInf16)); vtdl u164 (.clk(clk), .ce(ce), .a(4'd14), .d(cInf1), .q(cInf16)); vtdl u165 (.clk(clk), .ce(ce), .a(4'd14), .d(op1), .q(op16)); delay3 #(FX+1) u166 (.clk(clk), .ce(ce), .i(mo13), .o(mo16)); vtdl #(FMSB+2) u167 (.clk(clk), .ce(ce), .a(4'd6), .d(fractc9), .q(fractc16)); delay1 u169 (.clk(clk), .ce(ce), .i(&ex15), .o(exinf16)); always @(posedge clk) if (ce) mab = realOp15 ? oaa - obb : oaa + obb; // ----------------------------------------------------------- // Clock #17 // - adjust for Nans // ----------------------------------------------------------- wire [EMSB:0] ex17; reg [FX:0] mo17; wire so17; vtdl u171 (.clk(clk), .ce(ce), .a(4'd7), .d(so9), .q(so17)); delay2 #(EMSB+1) u172 (.clk(clk), .ce(ce), .i(ex15), .o(ex17)); always @(posedge clk) casez({aInf16&cInf16,Nan16,cNan16,exinf16}) 4'b1???: mo17 <= {1'b0,op16,{FMSB-1{1'b0}},op16,{FMSB{1'b0}}}; // inf +/- inf - generate QNaN on subtract, inf on add 4'b01??: mo17 <= {1'b0,mo16}; 4'b001?: mo17 <= {1'b0,fractc16[FMSB+1:0],{FMSB{1'b0}}}; 4'b0001: mo17 <= 1'd0; default: mo17 <= mab[FX+3:2]; // mab has an extra lead bit and two trailing bits endcase assign o = {so17,ex17,mo17}; vtdl u173 (.clk(clk), .ce(ce), .a(4'd11), .d(over5), .q(overflow) ); vtdl u174 (.clk(clk), .ce(ce), .a(4'd11), .d(over5), .q(inf) ); vtdl u175 (.clk(clk), .ce(ce), .a(4'd11), .d(under5), .q(underflow) ); endmodule // Multiplier with normalization and rounding. module fpFMAnr(clk, ce, op, rm, a, b, c, o, sign_exe, inf, overflow, underflow); parameter WID=32; localparam MSB = WID-1; localparam EMSB = WID==128 ? 14 : WID==96 ? 14 : WID==80 ? 14 : WID==64 ? 10 : WID==52 ? 10 : WID==48 ? 11 : WID==44 ? 10 : WID==42 ? 10 : WID==40 ? 9 : WID==32 ? 7 : WID==24 ? 6 : 4; localparam FMSB = WID==128 ? 111 : WID==96 ? 79 : WID==80 ? 63 : WID==64 ? 51 : WID==52 ? 39 : WID==48 ? 34 : WID==44 ? 31 : WID==42 ? 29 : WID==40 ? 28 : WID==32 ? 22 : WID==24 ? 15 : 9; localparam FX = (FMSB+2)*2-1; // the MSB of the expanded fraction localparam EX = FX + 1 + EMSB + 1 + 1 - 1; input clk; input ce; input op; input [2:0] rm; input [MSB:0] a, b, c; output [MSB:0] o; output sign_exe; output inf; output overflow; output underflow; wire [EX:0] o1; wire sign_exe1, inf1, overflow1, underflow1; wire [MSB+3:0] fpn0; fpFMA #(WID) u1 (clk, ce, op, rm, a, b, c, o1, inf1); fpNormalize #(WID) u2(.clk(clk), .ce(ce), .under(1'b0), .i(o1), .o(fpn0) ); fpRoundReg #(WID) u3(.clk(clk), .ce(ce), .rm(rm), .i(fpn0), .o(o) ); delay2 #(1) u4(.clk(clk), .ce(ce), .i(sign_exe1), .o(sign_exe)); delay2 #(1) u5(.clk(clk), .ce(ce), .i(inf1), .o(inf)); endmodule
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