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[/] [thor/] [trunk/] [rtl/] [verilog/] [fpUnit/] [fpAddsub.v] - Rev 25
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/* =============================================================== (C) 2006 Robert Finch All rights reserved. rob@birdcomputer.ca fpAddsub.v - floating point adder/subtracter - two cycle latency - can issue every clock cycle - parameterized width - IEEE 754 representation This source code is free for use and modification for non-commercial or evaluation purposes, provided this copyright statement and disclaimer remains present in the file. If you do modify the code, please state the origin and note that you have modified the code. NO WARRANTY. THIS Work, IS PROVIDEDED "AS IS" WITH NO WARRANTIES OF ANY KIND, WHETHER EXPRESS OR IMPLIED. The user must assume the entire risk of using the Work. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE FOR ANY INCIDENTAL, CONSEQUENTIAL, OR PUNITIVE DAMAGES WHATSOEVER RELATING TO THE USE OF THIS WORK, OR YOUR RELATIONSHIP WITH THE AUTHOR. IN ADDITION, IN NO EVENT DOES THE AUTHOR AUTHORIZE YOU TO USE THE WORK IN APPLICATIONS OR SYSTEMS WHERE THE WORK'S FAILURE TO PERFORM CAN REASONABLY BE EXPECTED TO RESULT IN A SIGNIFICANT PHYSICAL INJURY, OR IN LOSS OF LIFE. ANY SUCH USE BY YOU IS ENTIRELY AT YOUR OWN RISK, AND YOU AGREE TO HOLD THE AUTHOR AND CONTRIBUTORS HARMLESS FROM ANY CLAIMS OR LOSSES RELATING TO SUCH UNAUTHORIZED USE. This adder/subtractor handles denormalized numbers. It has a two cycle latency. 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. Ref: Webpack 8.2 Spartan3-4 xc3s1000-4ft256 580 LUTS / 315 slices / 74 MHz =============================================================== */ module fpAddsub(clk, ce, rm, op, a, b, o); 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 FX = (FMSB+2)*2-1; // the MSB of the expanded fraction localparam EX = FX + 1 + EMSB + 1 + 1 - 1; input clk; // system clock input ce; // core clock enable input [1:0] rm; // rounding mode input op; // operation 0 = add, 1 = subtract input [WID-1:0] a; // operand a input [WID-1:0] b; // operand b output [EX:0] o; // output // variables wire so; // sign output wire [EMSB:0] xo; // de normalized exponent output reg [EMSB:0] xo1; // de normalized exponent output wire [FX:0] mo; // mantissa output reg [FX:0] mo1; // mantissa output assign o = {so,xo,mo}; // operands sign,exponent,mantissa wire sa, sb; wire [EMSB:0] xa, xb; wire [FMSB:0] ma, mb; wire [FMSB+1:0] fracta, fractb; wire [FMSB+1:0] fracta1, fractb1; // which has greater magnitude ? Used for sign calc wire xa_gt_xb = xa > xb; wire xa_gt_xb1; wire a_gt_b = xa_gt_xb || (xa==xb && ma > mb); wire a_gt_b1; wire az, bz; // operand a,b is zero wire adn, bdn; // a,b denormalized ? wire xaInf, xbInf; wire aInf, bInf, aInf1, bInf1; wire aNan, bNan, aNan1, bNan1; wire [EMSB:0] xad = xa|adn; // operand a exponent, compensated for denormalized numbers wire [EMSB:0] xbd = xb|bdn; // operand b exponent, compensated for denormalized numbers fpDecomp #(WID) u1a (.i(a), .sgn(sa), .exp(xa), .man(ma), .fract(fracta), .xz(adn), .vz(az), .xinf(xaInf), .inf(aInf), .nan(aNan) ); fpDecomp #(WID) u1b (.i(b), .sgn(sb), .exp(xb), .man(mb), .fract(fractb), .xz(bdn), .vz(bz), .xinf(xbInf), .inf(bInf), .nan(bNan) ); // 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 wire realOp = op ^ sa ^ sb; wire realOp1; wire op1; // Find out if the result will be zero. wire resZero = (realOp && xa==xb && ma==mb) || // subtract, same magnitude (az & bz); // both a,b zero // Compute output exponent // // 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. always @(xaInf,xbInf,resZero,xa,xb,xa_gt_xb) xo1 = (xaInf&xbInf) ? xa : resZero ? 0 : xa_gt_xb ? xa : xb; // Compute output sign reg so1; always @* case ({resZero,sa,op,sb}) // synopsys full_case parallel_case 4'b0000: so1 <= 0; // + + + = + 4'b0001: so1 <= !a_gt_b; // + + - = sign of larger 4'b0010: so1 <= !a_gt_b; // + - + = sign of larger 4'b0011: so1 <= 0; // + - - = + 4'b0100: so1 <= a_gt_b; // - + + = sign of larger 4'b0101: so1 <= 1; // - + - = - 4'b0110: so1 <= 1; // - - + = - 4'b0111: so1 <= a_gt_b; // - - - = sign of larger 4'b1000: so1 <= 0; // A + B, sign = + 4'b1001: so1 <= rm==3; // A + -B, sign = + unless rounding down 4'b1010: so1 <= rm==3; // A - B, sign = + unless rounding down 4'b1011: so1 <= 0; // +A - -B, sign = + 4'b1100: so1 <= rm==3; // -A + B, sign = + unless rounding down 4'b1101: so1 <= 1; // -A + -B, sign = - 4'b1110: so1 <= 1; // -A - +B, sign = - 4'b1111: so1 <= rm==3; // -A - -B, sign = + unless rounding down endcase delay2 #(EMSB+1) d1(.clk(clk), .ce(ce), .i(xo1), .o(xo) ); delay2 #(1) d2(.clk(clk), .ce(ce), .i(so1), .o(so) ); // Compute the difference in exponents, provides shift amount wire [EMSB:0] xdiff = xa_gt_xb ? xad - xbd : xbd - xad; wire [6:0] xdif = xdiff > FMSB+3 ? FMSB+3 : xdiff; wire [6:0] xdif1; // determine which fraction to denormalize wire [FMSB+1:0] mfs = xa_gt_xb ? fractb : fracta; wire [FMSB+1:0] mfs1; // Determine the sticky bit wire sticky, sticky1; redor64 u1 (.a(xdif), .b({mfs,2'b0}), .o(sticky) ); // register inputs to shifter and shift delay1 #(1) d16(.clk(clk), .ce(ce), .i(sticky), .o(sticky1) ); delay1 #(7) d15(.clk(clk), .ce(ce), .i(xdif), .o(xdif1) ); delay1 #(FMSB+2) d14(.clk(clk), .ce(ce), .i(mfs), .o(mfs1) ); wire [FMSB+3:0] md1 = ({mfs1,2'b0} >> xdif1)|sticky1; // sync control signals delay1 #(1) d4 (.clk(clk), .ce(ce), .i(xa_gt_xb), .o(xa_gt_xb1) ); delay1 #(1) d17(.clk(clk), .ce(ce), .i(a_gt_b), .o(a_gt_b1) ); delay1 #(1) d5 (.clk(clk), .ce(ce), .i(realOp), .o(realOp1) ); delay1 #(FMSB+2) d5a(.clk(clk), .ce(ce), .i(fracta), .o(fracta1) ); delay1 #(FMSB+2) d6a(.clk(clk), .ce(ce), .i(fractb), .o(fractb1) ); delay1 #(1) d7 (.clk(clk), .ce(ce), .i(aInf), .o(aInf1) ); delay1 #(1) d8 (.clk(clk), .ce(ce), .i(bInf), .o(bInf1) ); delay1 #(1) d9 (.clk(clk), .ce(ce), .i(aNan), .o(aNan1) ); delay1 #(1) d10(.clk(clk), .ce(ce), .i(bNan), .o(bNan1) ); delay1 #(1) d11(.clk(clk), .ce(ce), .i(op), .o(op1) ); // Sort operands and perform add/subtract // addition can generate an extra bit, subtract can't go negative wire [FMSB+3:0] oa = xa_gt_xb1 ? {fracta1,2'b0} : md1; wire [FMSB+3:0] ob = xa_gt_xb1 ? md1 : {fractb1,2'b0}; wire [FMSB+3:0] oaa = a_gt_b1 ? oa : ob; wire [FMSB+3:0] obb = a_gt_b1 ? ob : oa; wire [FMSB+4:0] mab = realOp1 ? oaa - obb : oaa + obb; always @* casex({aInf1&bInf1,aNan1,bNan1}) 3'b1xx: mo1 = {1'b0,op1,{FMSB-1{1'b0}},op1,{FMSB{1'b0}}}; // inf +/- inf - generate QNaN on subtract, inf on add 3'bx1x: mo1 = {1'b0,fracta1[FMSB+1:0],{FMSB{1'b0}}}; 3'bxx1: mo1 = {1'b0,fractb1[FMSB+1:0],{FMSB{1'b0}}}; default: mo1 = {mab,{FMSB-2{1'b0}}}; // mab has an extra lead bit and two trailing bits endcase delay1 #(FX+1) d3(.clk(clk), .ce(ce), .i(mo1), .o(mo) ); endmodule
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