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//////////////////////////////////////////////////////////////////////
////                                                              ////
////  OR1200 FPU arith                                            ////
////                                                              ////
////  This file is part of the OpenRISC 1200 project              ////
////  http://opencores.org/project,or1k                           ////
////                                                              ////
////  Description                                                 ////
////  Wrapper for floating point arithmetic units.                ////
////                                                              ////
////  To Do:                                                      ////
////   - lf.rem.s and lf.madd.s instruction support               ////
////                                                              ////
////  Author(s):                                                  ////
////      - Original design (FPU100) -                            ////
////        Jidan Al-eryani, jidan@gmx.net                        ////
////      - Conv. to Verilog and inclusion in OR1200 -            ////
////        Julius Baxter, julius@opencores.org                   ////
////                                                              ////
//////////////////////////////////////////////////////////////////////
//
//  Copyright (C) 2006, 2010
//
//      This source file may be used and distributed without        
//      restriction provided that this copyright statement is not   
//      removed from the file and that any derivative work contains 
//      the original copyright notice and the associated disclaimer.
//                                                           
//              THIS SOFTWARE IS PROVIDED ``AS IS'' AND WITHOUT ANY     
//      EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED   
//      TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS   
//      FOR A PARTICULAR PURPOSE. IN NO EVENT SHALL THE AUTHOR      
//      OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,         
//      INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES    
//      (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE   
//      GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR        
//      BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF  
//      LIABILITY, WHETHER IN  CONTRACT, STRICT LIABILITY, OR TORT  
//      (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT  
//      OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE         
//      POSSIBILITY OF SUCH DAMAGE. 
//
 
module or1200_fpu_arith
  (
   clk_i,
   opa_i,
   opb_i,
   fpu_op_i,
   rmode_i,
   output_o,
   start_i,
   ready_o,
   ine_o,
   overflow_o,
   underflow_o,
   div_zero_o,
   inf_o,
   zero_o,
   qnan_o,
   snan_o
   );
 
   parameter FP_WIDTH = 32;
   parameter MUL_SERIAL = 1; // 0 for parallel multiplier, 1 for serial
   parameter MUL_COUNT = 34; //11 for parallel multiplier, 34 for serial
   parameter FRAC_WIDTH = 23;
   parameter EXP_WIDTH = 8;
   parameter ZERO_VECTOR = 31'd0;
   parameter INF = 31'b1111111100000000000000000000000;
   parameter QNAN = 31'b11111111_10000000000000000000000;
   parameter SNAN = 31'b11111111_00000000000000000000001;
 
   // fpu operations (fpu_op_i):
   // ========================
   // 000 = add, 
   // 001 = substract, 
   // 010 = multiply, 
   // 011 = divide,
   // 100 = square root - DISABLED - JPB
   // 101 = unused
   // 110 = unused
   // 111 = unused
 
   // Rounding Mode: 
   // ==============
   // 00 = round to nearest even (default), 
   // 01 = round to zero, 
   // 10 = round up, 
   // 11 = round down
 
   input  clk_i;
   input [FP_WIDTH-1:0] opa_i;
   input [FP_WIDTH-1:0] opb_i;
   input [2:0]           fpu_op_i;
   input [1:0]           rmode_i;
   input                start_i;
   output reg           ready_o;
   output reg [FP_WIDTH-1:0] output_o;
   output reg                ine_o;
   output reg                overflow_o;
   output reg                underflow_o;
   output reg                div_zero_o;
   output reg                inf_o;
   output reg                zero_o;
   output reg                qnan_o;
   output reg                snan_o;
 
   reg [FP_WIDTH-1:0]         s_opa_i;
   reg [FP_WIDTH-1:0]         s_opb_i;
   reg [2:0]                  s_fpu_op_i;
   reg [1:0]                  s_rmode_i;
   reg                       s_start_i;
   reg [5:0]                  s_count; // Max value of 64
 
   reg [FP_WIDTH-1:0]         s_output1;
   reg [FP_WIDTH-1:0]         s_output_o; // Comb
 
   reg                       s_ine_o;
 
   wire                      s_overflow_o,
                             s_underflow_o,
                             s_div_zero_o,
                             s_inf_o, s_zero_o, s_qnan_o, s_snan_o;
 
   wire                      s_infa, s_infb;
 
   parameter t_state_waiting = 0,
               t_state_busy = 1;
 
   reg                       s_state;
 
   //// ***Add/Substract units signals***
   wire [27:0]                prenorm_addsub_fracta_28_o;
   wire [27:0]                prenorm_addsub_fractb_28_o;
 
   wire [7:0]                 prenorm_addsub_exp_o;
 
   wire [27:0]                addsub_fract_o;
   wire                      addsub_sign_o;
 
   wire [31:0]                postnorm_addsub_output_o;
   wire                      postnorm_addsub_ine_o;
 
   //// ***Multiply units signals***
 
   wire [9:0]                 pre_norm_mul_exp_10;
   wire [23:0]                pre_norm_mul_fracta_24 ;
   wire [23:0]                pre_norm_mul_fractb_24 ;
   wire [47:0]                mul_fract_48;
   wire [47:0]                mul_24_fract_48;
   wire                      mul_24_sign;
   wire [47:0]                serial_mul_fract_48;
   wire                      serial_mul_sign;
   wire                      mul_sign;
   wire [31:0]                post_norm_mul_output   ;
   wire                      post_norm_mul_ine;
 
 
   //// ***Division units signals***
 
   wire [49:0]                pre_norm_div_dvdnd;
   wire [26:0]                pre_norm_div_dvsor;
   wire [EXP_WIDTH+1:0]      pre_norm_div_exp;
   wire [26:0]                serial_div_qutnt;
   wire [26:0]                serial_div_rmndr;
   wire                      serial_div_sign;
   wire                      serial_div_div_zero;
   wire [31:0]                post_norm_div_output;
   wire                      post_norm_div_ine;
 
 
   //// ***Square units***
 
   wire [51:0]                pre_norm_sqrt_fracta_o;
   wire [7:0]                 pre_norm_sqrt_exp_o;
   wire [25:0]                sqrt_sqr_o;
   wire                      sqrt_ine_o;
 
   wire [31:0]                post_norm_sqrt_output  ;
   wire                      post_norm_sqrt_ine_o;
 
   //***Add/Substract units***
 
   or1200_fpu_pre_norm_addsub fpu_prenorm_addsub
     (
      .clk_i(clk_i)  ,
      .opa_i(s_opa_i)  ,
      .opb_i(s_opb_i)  ,
      .fracta_28_o(prenorm_addsub_fracta_28_o)  ,
      .fractb_28_o(prenorm_addsub_fractb_28_o)  ,
      .exp_o(prenorm_addsub_exp_o) );
 
   or1200_fpu_addsub fpu_addsub
     (
            .clk_i(clk_i)  ,
            .fpu_op_i(s_fpu_op_i[0]),
            .fracta_i(prenorm_addsub_fracta_28_o)        ,
            .fractb_i(prenorm_addsub_fractb_28_o)        ,
            .signa_i( s_opa_i[31]),
            .signb_i( s_opb_i[31]),
            .fract_o(addsub_fract_o)  ,
            .sign_o(addsub_sign_o)  );
 
   or1200_fpu_post_norm_addsub fpu_postnorm_addsub
     (
      .clk_i(clk_i)  ,
      .opa_i(s_opa_i)  ,
      .opb_i(s_opb_i)  ,
      .fract_28_i(addsub_fract_o)  ,
      .exp_i(prenorm_addsub_exp_o)  ,
      .sign_i(addsub_sign_o)  ,
      .fpu_op_i(s_fpu_op_i[0]),
      .rmode_i(s_rmode_i)  ,
      .output_o(postnorm_addsub_output_o)  ,
      .ine_o(postnorm_addsub_ine_o)
      );
 
   //***Multiply units***
 
   or1200_fpu_pre_norm_mul fpu_pre_norm_mul
     (
      .clk_i(clk_i),
      .opa_i(s_opa_i),
      .opb_i(s_opb_i),
      .exp_10_o(pre_norm_mul_exp_10),
      .fracta_24_o(pre_norm_mul_fracta_24),
      .fractb_24_o(pre_norm_mul_fractb_24));
   /*
    mul_24 i_mul_24
    (
    .clk_i(clk_i)  ,
    .fracta_i(pre_norm_mul_fracta_24)  ,
    .fractb_i(pre_norm_mul_fractb_24)  ,
    .signa_i(s_opa_i[31]),
    .signb_i(s_opb_i[31]),
    .start_i(start_i)  ,
    .fract_o(mul_24_fract_48)  ,
    .sign_o(mul_24_sign)        ,
    .ready_o()  );
    */
   // Serial multiply is default and only one included here
   or1200_fpu_mul fpu_mul
     (
      .clk_i(clk_i)  ,
      .fracta_i(pre_norm_mul_fracta_24)  ,
      .fractb_i(pre_norm_mul_fractb_24)  ,
      .signa_i(s_opa_i[31]),
      .signb_i(s_opb_i[31]),
      .start_i(s_start_i)  ,
      .fract_o(serial_mul_fract_48)  ,
      .sign_o(serial_mul_sign)  ,
      .ready_o()
      );
 
   // Serial or parallel multiplier will be chosen depending on constant 
   // MUL_SERIAL
   assign mul_fract_48 = MUL_SERIAL ? serial_mul_fract_48 : mul_24_fract_48;
   assign mul_sign = MUL_SERIAL ? serial_mul_sign : mul_24_sign;
 
   or1200_fpu_post_norm_mul fpu_post_norm_mul
     (
      .clk_i(clk_i)  ,
      .opa_i(s_opa_i)  ,
      .opb_i(s_opb_i)  ,
      .exp_10_i(pre_norm_mul_exp_10)  ,
      .fract_48_i(mul_fract_48)  , // Parallel multiplier input
      .sign_i(mul_sign)  , // Parallel multiplier input
      .rmode_i(s_rmode_i)  ,
      .output_o(post_norm_mul_output)  ,
      .ine_o(post_norm_mul_ine)
      );
 
   ////***Division units***
 
   or1200_fpu_pre_norm_div fpu_pre_norm_div
     (
      .clk_i(clk_i)  ,
      .opa_i(s_opa_i)  ,
      .opb_i(s_opb_i)  ,
      .exp_10_o(pre_norm_div_exp)  ,
      .dvdnd_50_o(pre_norm_div_dvdnd)    ,
      .dvsor_27_o(pre_norm_div_dvsor)    );
 
   or1200_fpu_div fpu_div
     (
      .clk_i(clk_i) ,
      .dvdnd_i(pre_norm_div_dvdnd)  ,
      .dvsor_i(pre_norm_div_dvsor)  ,
      .sign_dvd_i(s_opa_i[31]),
      .sign_div_i(s_opb_i[31]),
      .start_i(s_start_i)  ,
      .ready_o()  ,
      .qutnt_o(serial_div_qutnt)  ,
      .rmndr_o(serial_div_rmndr)  ,
      .sign_o(serial_div_sign)  ,
      .div_zero_o(serial_div_div_zero)   );
 
   or1200_fpu_post_norm_div fpu_post_norm_div
     (
      .clk_i(clk_i)  ,
      .opa_i(s_opa_i)  ,
      .opb_i(s_opb_i)  ,
      .qutnt_i(serial_div_qutnt)        ,
      .rmndr_i(serial_div_rmndr)  ,
      .exp_10_i(pre_norm_div_exp)  ,
      .sign_i(serial_div_sign)   ,
      .rmode_i(s_rmode_i)       ,
      .output_o(post_norm_div_output)  ,
      .ine_o(post_norm_div_ine)  );
 
   //////////////////////////////////////////////////////////////////-
 
   // Input Registers
   always @(posedge clk_i)
     begin
        s_opa_i <= opa_i;
        s_opb_i <= opb_i;
        s_fpu_op_i <= fpu_op_i;
        s_rmode_i <= rmode_i;
        s_start_i <= start_i;
     end
 
   // Output registers
   always @(posedge clk_i)
     begin
        output_o <= s_output_o;
        ine_o <= s_ine_o;
        overflow_o <= s_overflow_o;
        underflow_o <= s_underflow_o;
        div_zero_o <= s_div_zero_o & !s_infa;
        inf_o <= s_inf_o;
        zero_o <= s_zero_o;
        qnan_o <= s_qnan_o;
        snan_o <= s_snan_o;
     end
 
   always @(posedge clk_i)
     begin
        if (s_start_i)  begin
           s_state <= t_state_busy;
           s_count <= 0;
        end
        else if (s_state == t_state_busy) begin
           // Ready cases
           if (((s_count == 6) & ((fpu_op_i==3'd0) | (fpu_op_i==3'd1))) |
               ((s_count==MUL_COUNT) & (fpu_op_i==3'd2)) |
               ((s_count==33) & (fpu_op_i==3'd3)))
             begin
                s_state <= t_state_waiting;
                ready_o <= 1;
                s_count <= 0;
             end
           else
             s_count <= s_count + 1;
        end // if (s_state == t_state_busy)
        else begin
           s_state <= t_state_waiting;
           ready_o <= 0;
        end // else: !if(s_state == t_state_busy)
     end // else: !if(s_start_i)
 
   //// Output Multiplexer
   always @(posedge clk_i)
     begin
        case(fpu_op_i)
          3'd0,
            3'd1: begin
               s_output1 <= postnorm_addsub_output_o;
               s_ine_o <= postnorm_addsub_ine_o;
            end
          3'd2: begin
             s_output1 <= post_norm_mul_output;
             s_ine_o <= post_norm_mul_ine;
          end
          3'd3: begin
             s_output1 <= post_norm_div_output;
             s_ine_o <= post_norm_div_ine;
          end
          //      3'd4: begin
          //            s_output1       <= post_norm_sqrt_output;
          //            s_ine_o         <= post_norm_sqrt_ine_o;
          //    end
          default: begin
             s_output1 <= 0;
             s_ine_o <= 0;
          end
        endcase // case (fpu_op_i)
     end // always @ (posedge clk_i)
 
   // Infinte exponent
   assign s_infa = &s_opa_i[30:23];
   assign s_infb = &s_opb_i[30:23];
 
   always @*
     begin
        if (s_rmode_i==2'd0 | s_div_zero_o | s_infa | s_infb | s_qnan_o |
            s_qnan_o) // Round to nearest even
          s_output_o = s_output1;
        else if (s_rmode_i==2'd1 & (&s_output1[30:23]))
          // In round-to-zero: the sum of two non-infinity operands is never 
          // infinity,even if an overflow occures
          s_output_o = {s_output1[31], 31'b1111111_01111111_11111111_11111111};
        else if (s_rmode_i==2'd2 & (&s_output1[31:23]))
          // In round-up: the sum of two non-infinity operands is never 
          // negative infinity,even if an overflow occures
          s_output_o = {32'b11111111_01111111_11111111_11111111};
        else if (s_rmode_i==2'd3) begin
           if (((s_fpu_op_i==3'd0) | (s_fpu_op_i==3'd1)) & s_zero_o &
               (s_opa_i[31] | (s_fpu_op_i[0] ^ s_opb_i[31])))
             // In round-down: a-a= -0
             s_output_o = {1'b1,s_output1[30:0]};
           else if (s_output1[31:23]==9'b0_11111111)
             s_output_o = 32'b01111111011111111111111111111111;
           else
             s_output_o = s_output1;
        end
        else
          s_output_o = s_output1;
     end // always @ *
 
   // Exception generation
   assign s_underflow_o = (s_output1[30:23]==8'h00) & s_ine_o;
   assign s_overflow_o = (s_output1[30:23]==8'hff) & s_ine_o;
   assign s_div_zero_o = serial_div_div_zero & fpu_op_i==3'd3;
   assign s_inf_o = s_output1[30:23]==8'hff & !(s_qnan_o | s_snan_o);
   assign s_zero_o = !(|s_output1[30:0]);
   assign s_qnan_o = s_output1[30:0]==QNAN;
   assign s_snan_o = s_output1[30:0]==SNAN;
 
endmodule // or1200_fpu_arith
 
 

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[/] [openrisc/] [trunk/] [orpsocv2/] [rtl/] [verilog/] [or1200/] [or1200_fpu_arith.v] - Blame information for rev 462

Line No.	Rev	Author	Line
1	350	julius	`//////////////////////////////////////////////////////////////////////`
2			`//// ////`
3			`//// OR1200 FPU arith ////`
4			`//// ////`
5			`//// This file is part of the OpenRISC 1200 project ////`
6			`//// http://opencores.org/project,or1k ////`
7			`//// ////`
8			`//// Description ////`
9			`//// Wrapper for floating point arithmetic units. ////`
10			`//// ////`
11			`//// To Do: ////`
12			`//// - lf.rem.s and lf.madd.s instruction support ////`
13			`//// ////`
14			`//// Author(s): ////`
15			`//// - Original design (FPU100) - ////`
16			`//// Jidan Al-eryani, jidan@gmx.net ////`
17			`//// - Conv. to Verilog and inclusion in OR1200 - ////`
18			`//// Julius Baxter, julius@opencores.org ////`
19			`//// ////`
20			`//////////////////////////////////////////////////////////////////////`
21			`//`
22			`// Copyright (C) 2006, 2010`
23			`//`
24			`// This source file may be used and distributed without`
25			`// restriction provided that this copyright statement is not`
26			`// removed from the file and that any derivative work contains`
27			`// the original copyright notice and the associated disclaimer.`
28			`//`
29			// THIS SOFTWARE IS PROVIDED ``AS IS'' AND WITHOUT ANY
30			`// EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED`
31			`// TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS`
32			`// FOR A PARTICULAR PURPOSE. IN NO EVENT SHALL THE AUTHOR`
33			`// OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,`
34			`// INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES`
35			`// (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE`
36			`// GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR`
37			`// BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF`
38			`// LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT`
39			`// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT`
40			`// OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE`
41			`// POSSIBILITY OF SUCH DAMAGE.`
42			`//`
43
44			`module or1200_fpu_arith`
45			`(`
46			`clk_i,`
47			`opa_i,`
48			`opb_i,`
49			`fpu_op_i,`
50			`rmode_i,`
51			`output_o,`
52			`start_i,`
53			`ready_o,`
54			`ine_o,`
55			`overflow_o,`
56			`underflow_o,`
57			`div_zero_o,`
58			`inf_o,`
59			`zero_o,`
60			`qnan_o,`
61			`snan_o`
62			`);`
63
64			`parameter FP_WIDTH = 32;`
65			`parameter MUL_SERIAL = 1; // 0 for parallel multiplier, 1 for serial`
66			`parameter MUL_COUNT = 34; //11 for parallel multiplier, 34 for serial`
67			`parameter FRAC_WIDTH = 23;`
68			`parameter EXP_WIDTH = 8;`
69			`parameter ZERO_VECTOR = 31'd0;`
70			`parameter INF = 31'b1111111100000000000000000000000;`
71			`parameter QNAN = 31'b11111111_10000000000000000000000;`
72			`parameter SNAN = 31'b11111111_00000000000000000000001;`
73
74			`// fpu operations (fpu_op_i):`
75			`// ========================`
76			`// 000 = add,`
77			`// 001 = substract,`
78			`// 010 = multiply,`
79			`// 011 = divide,`
80			`// 100 = square root - DISABLED - JPB`
81			`// 101 = unused`
82			`// 110 = unused`
83			`// 111 = unused`
84
85			`// Rounding Mode:`
86			`// ==============`
87			`// 00 = round to nearest even (default),`
88			`// 01 = round to zero,`
89			`// 10 = round up,`
90			`// 11 = round down`
91
92			`input clk_i;`
93			`input [FP_WIDTH-1:0] opa_i;`
94			`input [FP_WIDTH-1:0] opb_i;`
95			`input [2:0] fpu_op_i;`
96			`input [1:0] rmode_i;`
97			`input start_i;`
98			`output reg ready_o;`
99			`output reg [FP_WIDTH-1:0] output_o;`
100			`output reg ine_o;`
101			`output reg overflow_o;`
102			`output reg underflow_o;`
103			`output reg div_zero_o;`
104			`output reg inf_o;`
105			`output reg zero_o;`
106			`output reg qnan_o;`
107			`output reg snan_o;`
108
109			`reg [FP_WIDTH-1:0] s_opa_i;`
110			`reg [FP_WIDTH-1:0] s_opb_i;`
111			`reg [2:0] s_fpu_op_i;`
112			`reg [1:0] s_rmode_i;`
113			`reg s_start_i;`
114			`reg [5:0] s_count; // Max value of 64`
115
116			`reg [FP_WIDTH-1:0] s_output1;`
117			`reg [FP_WIDTH-1:0] s_output_o; // Comb`
118
119			`reg s_ine_o;`
120
121			`wire s_overflow_o,`
122			`s_underflow_o,`
123			`s_div_zero_o,`
124			`s_inf_o, s_zero_o, s_qnan_o, s_snan_o;`
125
126			`wire s_infa, s_infb;`
127
128			`parameter t_state_waiting = 0,`
129			`t_state_busy = 1;`
130
131			`reg s_state;`
132
133			`//// *Add/Substract units signals*`
134			`wire [27:0] prenorm_addsub_fracta_28_o;`
135			`wire [27:0] prenorm_addsub_fractb_28_o;`
136
137			`wire [7:0] prenorm_addsub_exp_o;`
138
139			`wire [27:0] addsub_fract_o;`
140			`wire addsub_sign_o;`
141
142			`wire [31:0] postnorm_addsub_output_o;`
143			`wire postnorm_addsub_ine_o;`
144
145			`//// *Multiply units signals*`
146
147			`wire [9:0] pre_norm_mul_exp_10;`
148			`wire [23:0] pre_norm_mul_fracta_24 ;`
149			`wire [23:0] pre_norm_mul_fractb_24 ;`
150			`wire [47:0] mul_fract_48;`
151			`wire [47:0] mul_24_fract_48;`
152			`wire mul_24_sign;`
153			`wire [47:0] serial_mul_fract_48;`
154			`wire serial_mul_sign;`
155			`wire mul_sign;`
156			`wire [31:0] post_norm_mul_output ;`
157			`wire post_norm_mul_ine;`
158
159
160			`//// *Division units signals*`
161
162			`wire [49:0] pre_norm_div_dvdnd;`
163			`wire [26:0] pre_norm_div_dvsor;`
164			`wire [EXP_WIDTH+1:0] pre_norm_div_exp;`
165			`wire [26:0] serial_div_qutnt;`
166			`wire [26:0] serial_div_rmndr;`
167			`wire serial_div_sign;`
168			`wire serial_div_div_zero;`
169			`wire [31:0] post_norm_div_output;`
170			`wire post_norm_div_ine;`
171
172
173			`//// *Square units*`
174
175			`wire [51:0] pre_norm_sqrt_fracta_o;`
176			`wire [7:0] pre_norm_sqrt_exp_o;`
177			`wire [25:0] sqrt_sqr_o;`
178			`wire sqrt_ine_o;`
179
180			`wire [31:0] post_norm_sqrt_output ;`
181			`wire post_norm_sqrt_ine_o;`
182
183			`//*Add/Substract units*`
184
185			`or1200_fpu_pre_norm_addsub fpu_prenorm_addsub`
186			`(`
187			`.clk_i(clk_i) ,`
188			`.opa_i(s_opa_i) ,`
189			`.opb_i(s_opb_i) ,`
190			`.fracta_28_o(prenorm_addsub_fracta_28_o) ,`
191			`.fractb_28_o(prenorm_addsub_fractb_28_o) ,`
192			`.exp_o(prenorm_addsub_exp_o) );`
193
194			`or1200_fpu_addsub fpu_addsub`
195			`(`
196			`.clk_i(clk_i) ,`
197			`.fpu_op_i(s_fpu_op_i[0]),`
198			`.fracta_i(prenorm_addsub_fracta_28_o) ,`
199			`.fractb_i(prenorm_addsub_fractb_28_o) ,`
200			`.signa_i( s_opa_i[31]),`
201			`.signb_i( s_opb_i[31]),`
202			`.fract_o(addsub_fract_o) ,`
203			`.sign_o(addsub_sign_o) );`
204
205			`or1200_fpu_post_norm_addsub fpu_postnorm_addsub`
206			`(`
207			`.clk_i(clk_i) ,`
208			`.opa_i(s_opa_i) ,`
209			`.opb_i(s_opb_i) ,`
210			`.fract_28_i(addsub_fract_o) ,`
211			`.exp_i(prenorm_addsub_exp_o) ,`
212			`.sign_i(addsub_sign_o) ,`
213			`.fpu_op_i(s_fpu_op_i[0]),`
214			`.rmode_i(s_rmode_i) ,`
215			`.output_o(postnorm_addsub_output_o) ,`
216			`.ine_o(postnorm_addsub_ine_o)`
217			`);`
218
219			`//*Multiply units*`
220
221			`or1200_fpu_pre_norm_mul fpu_pre_norm_mul`
222			`(`
223			`.clk_i(clk_i),`
224			`.opa_i(s_opa_i),`
225			`.opb_i(s_opb_i),`
226			`.exp_10_o(pre_norm_mul_exp_10),`
227			`.fracta_24_o(pre_norm_mul_fracta_24),`
228			`.fractb_24_o(pre_norm_mul_fractb_24));`
229			`/*`
230			`mul_24 i_mul_24`
231			`(`
232			`.clk_i(clk_i) ,`
233			`.fracta_i(pre_norm_mul_fracta_24) ,`
234			`.fractb_i(pre_norm_mul_fractb_24) ,`
235			`.signa_i(s_opa_i[31]),`
236			`.signb_i(s_opb_i[31]),`
237			`.start_i(start_i) ,`
238			`.fract_o(mul_24_fract_48) ,`
239			`.sign_o(mul_24_sign) ,`
240			`.ready_o() );`
241			`*/`
242			`// Serial multiply is default and only one included here`
243			`or1200_fpu_mul fpu_mul`
244			`(`
245			`.clk_i(clk_i) ,`
246			`.fracta_i(pre_norm_mul_fracta_24) ,`
247			`.fractb_i(pre_norm_mul_fractb_24) ,`
248			`.signa_i(s_opa_i[31]),`
249			`.signb_i(s_opb_i[31]),`
250			`.start_i(s_start_i) ,`
251			`.fract_o(serial_mul_fract_48) ,`
252			`.sign_o(serial_mul_sign) ,`
253			`.ready_o()`
254			`);`
255
256			`// Serial or parallel multiplier will be chosen depending on constant`
257			`// MUL_SERIAL`
258			`assign mul_fract_48 = MUL_SERIAL ? serial_mul_fract_48 : mul_24_fract_48;`
259			`assign mul_sign = MUL_SERIAL ? serial_mul_sign : mul_24_sign;`
260
261			`or1200_fpu_post_norm_mul fpu_post_norm_mul`
262			`(`
263			`.clk_i(clk_i) ,`
264			`.opa_i(s_opa_i) ,`
265			`.opb_i(s_opb_i) ,`
266			`.exp_10_i(pre_norm_mul_exp_10) ,`
267			`.fract_48_i(mul_fract_48) , // Parallel multiplier input`
268			`.sign_i(mul_sign) , // Parallel multiplier input`
269			`.rmode_i(s_rmode_i) ,`
270			`.output_o(post_norm_mul_output) ,`
271			`.ine_o(post_norm_mul_ine)`
272			`);`
273
274			`////*Division units*`
275
276			`or1200_fpu_pre_norm_div fpu_pre_norm_div`
277			`(`
278			`.clk_i(clk_i) ,`
279			`.opa_i(s_opa_i) ,`
280			`.opb_i(s_opb_i) ,`
281			`.exp_10_o(pre_norm_div_exp) ,`
282			`.dvdnd_50_o(pre_norm_div_dvdnd) ,`
283			`.dvsor_27_o(pre_norm_div_dvsor) );`
284
285			`or1200_fpu_div fpu_div`
286			`(`
287			`.clk_i(clk_i) ,`
288			`.dvdnd_i(pre_norm_div_dvdnd) ,`
289			`.dvsor_i(pre_norm_div_dvsor) ,`
290			`.sign_dvd_i(s_opa_i[31]),`
291			`.sign_div_i(s_opb_i[31]),`
292			`.start_i(s_start_i) ,`
293			`.ready_o() ,`
294			`.qutnt_o(serial_div_qutnt) ,`
295			`.rmndr_o(serial_div_rmndr) ,`
296			`.sign_o(serial_div_sign) ,`
297			`.div_zero_o(serial_div_div_zero) );`
298
299			`or1200_fpu_post_norm_div fpu_post_norm_div`
300			`(`
301			`.clk_i(clk_i) ,`
302			`.opa_i(s_opa_i) ,`
303			`.opb_i(s_opb_i) ,`
304			`.qutnt_i(serial_div_qutnt) ,`
305			`.rmndr_i(serial_div_rmndr) ,`
306			`.exp_10_i(pre_norm_div_exp) ,`
307			`.sign_i(serial_div_sign) ,`
308			`.rmode_i(s_rmode_i) ,`
309			`.output_o(post_norm_div_output) ,`
310			`.ine_o(post_norm_div_ine) );`
311
312			`//////////////////////////////////////////////////////////////////-`
313
314			`// Input Registers`
315			`always @(posedge clk_i)`
316			`begin`
317			`s_opa_i <= opa_i;`
318			`s_opb_i <= opb_i;`
319			`s_fpu_op_i <= fpu_op_i;`
320			`s_rmode_i <= rmode_i;`
321			`s_start_i <= start_i;`
322			`end`
323
324			`// Output registers`
325			`always @(posedge clk_i)`
326			`begin`
327			`output_o <= s_output_o;`
328			`ine_o <= s_ine_o;`
329			`overflow_o <= s_overflow_o;`
330			`underflow_o <= s_underflow_o;`
331			`div_zero_o <= s_div_zero_o & !s_infa;`
332			`inf_o <= s_inf_o;`
333			`zero_o <= s_zero_o;`
334			`qnan_o <= s_qnan_o;`
335			`snan_o <= s_snan_o;`
336			`end`
337
338			`always @(posedge clk_i)`
339			`begin`
340			`if (s_start_i) begin`
341			`s_state <= t_state_busy;`
342			`s_count <= 0;`
343			`end`
344			`else if (s_state == t_state_busy) begin`
345			`// Ready cases`
346			`if (((s_count == 6) & ((fpu_op_i==3'd0) \| (fpu_op_i==3'd1))) \|`
347			`((s_count==MUL_COUNT) & (fpu_op_i==3'd2)) \|`
348			`((s_count==33) & (fpu_op_i==3'd3)))`
349			`begin`
350			`s_state <= t_state_waiting;`
351			`ready_o <= 1;`
352			`s_count <= 0;`
353			`end`
354			`else`
355			`s_count <= s_count + 1;`
356			`end // if (s_state == t_state_busy)`
357			`else begin`
358			`s_state <= t_state_waiting;`
359			`ready_o <= 0;`
360			`end // else: !if(s_state == t_state_busy)`
361			`end // else: !if(s_start_i)`
362
363			`//// Output Multiplexer`
364			`always @(posedge clk_i)`
365			`begin`
366			`case(fpu_op_i)`
367			`3'd0,`
368			`3'd1: begin`
369			`s_output1 <= postnorm_addsub_output_o;`
370			`s_ine_o <= postnorm_addsub_ine_o;`
371			`end`
372			`3'd2: begin`
373			`s_output1 <= post_norm_mul_output;`
374			`s_ine_o <= post_norm_mul_ine;`
375			`end`
376			`3'd3: begin`
377			`s_output1 <= post_norm_div_output;`
378			`s_ine_o <= post_norm_div_ine;`
379			`end`
380			`// 3'd4: begin`
381			`// s_output1 <= post_norm_sqrt_output;`
382			`// s_ine_o <= post_norm_sqrt_ine_o;`
383			`// end`
384			`default: begin`
385			`s_output1 <= 0;`
386			`s_ine_o <= 0;`
387			`end`
388			`endcase // case (fpu_op_i)`
389			`end // always @ (posedge clk_i)`
390
391			`// Infinte exponent`
392			`assign s_infa = &s_opa_i[30:23];`
393			`assign s_infb = &s_opb_i[30:23];`
394
395			`always @*`
396			`begin`
397			`if (s_rmode_i==2'd0 \| s_div_zero_o \| s_infa \| s_infb \| s_qnan_o \|`
398			`s_qnan_o) // Round to nearest even`
399	364	julius	`s_output_o = s_output1;`
400	350	julius	`else if (s_rmode_i==2'd1 & (&s_output1[30:23]))`
401			`// In round-to-zero: the sum of two non-infinity operands is never`
402			`// infinity,even if an overflow occures`
403	364	julius	`s_output_o = {s_output1[31], 31'b1111111_01111111_11111111_11111111};`
404	350	julius	`else if (s_rmode_i==2'd2 & (&s_output1[31:23]))`
405			`// In round-up: the sum of two non-infinity operands is never`
406			`// negative infinity,even if an overflow occures`
407	364	julius	`s_output_o = {32'b11111111_01111111_11111111_11111111};`
408	350	julius	`else if (s_rmode_i==2'd3) begin`
409			`if (((s_fpu_op_i==3'd0) \| (s_fpu_op_i==3'd1)) & s_zero_o &`
410			`(s_opa_i[31] \| (s_fpu_op_i[0] ^ s_opb_i[31])))`
411			`// In round-down: a-a= -0`
412	364	julius	`s_output_o = {1'b1,s_output1[30:0]};`
413	350	julius	`else if (s_output1[31:23]==9'b0_11111111)`
414	364	julius	`s_output_o = 32'b01111111011111111111111111111111;`
415	350	julius	`else`
416	364	julius	`s_output_o = s_output1;`
417	350	julius	`end`
418			`else`
419	364	julius	`s_output_o = s_output1;`
420	350	julius	`end // always @ *`
421
422			`// Exception generation`
423			`assign s_underflow_o = (s_output1[30:23]==8'h00) & s_ine_o;`
424			`assign s_overflow_o = (s_output1[30:23]==8'hff) & s_ine_o;`
425			`assign s_div_zero_o = serial_div_div_zero & fpu_op_i==3'd3;`
426	364	julius	`assign s_inf_o = s_output1[30:23]==8'hff & !(s_qnan_o \| s_snan_o);`
427	350	julius	`assign s_zero_o = !(\|s_output1[30:0]);`
428			`assign s_qnan_o = s_output1[30:0]==QNAN;`
429			`assign s_snan_o = s_output1[30:0]==SNAN;`
430
431			`endmodule // or1200_fpu_arith`
432
433