URL https://opencores.org/ocsvn/xilinx_virtex_fp_library/xilinx_virtex_fp_library/trunk

Subversion Repositories xilinx_virtex_fp_library

[/] [xilinx_virtex_fp_library/] [trunk/] [GeneralPrecMAF/] [Multiply_Accumulate.v] - Blame information for rev 19

Details | Compare with Previous | View Log


`timescale 1ns / 1ps
//////////////////////////////////////////////////////////////////////////////////
// Company: 
// Engineer: 
// 
// Create Date:    17:53:05 10/15/2013 
// Design Name: 
// Module Name:    Multiply_Accumulate 
// Project Name: 
// Target Devices: 
// Tool versions: 
// Description: C � A*B
//
// Dependencies: 
//
// Revision: 
// Revision 0.01 - File Created
// Additional Comments: 
//
//////////////////////////////////////////////////////////////////////////////////
module Multiply_Accumulate #(   parameter size_mantissa = 24,                   //mantissa bits(1.M)
                                                                                parameter size_exponent = 8,    //exponent bits
                                                                                parameter size_counter  = 5,    //log2(size_mantissa) + 1 = 5
                                                                                parameter size_exception_field  = 2,    // zero/normal numbers/infinity/NaN
                                                                                parameter zero                                  = 00,   //00
                                                                                parameter normal_number                 = 01,   //01
                                                                                parameter infinity                              = 10,   //10
                                                                                parameter NaN                                   = 11,   //11
                                                                                parameter pipeline              = 0,
                                                                                parameter pipeline_pos  = 0,  //8 bits
 
                                                                                parameter size = size_exponent + size_mantissa + size_exception_field,
                                                                                parameter size_mul_mantissa = size_mantissa + size_mantissa,
                                                                                parameter size_mul_counter = size_counter + 1)
                                                                        (       input [size - 1:0] a_number_i,
                                                                                input [size - 1:0] b_number_i,
                                                                                input [size - 1:0] c_number_i,
                                                                                input sub,
                                                                                output[size - 1:0] resulting_number_o);
 
        parameter bias_0_bits = size_exponent - 1;
        parameter shift_mantissa_0_bits = size_mantissa-1'b1;
 
        wire [size_exception_field - 1 : 0] sp_case_a_number, sp_case_b_number, sp_case_c_number;
        wire [size_mantissa - 1 : 0] m_a_number, m_b_number, m_c_number;
        wire [size_exponent - 1 : 0] e_a_number, e_b_number, e_c_number;
        wire s_a_number, s_b_number, s_c_number;
 
        wire [size_exponent     : 0] ab_greater_exponent, c_greater_exponent;
 
        wire [size_exponent - 1 : 0] exp_difference;
        wire [size_exponent - 1 : 0] unadjusted_exponent;
        wire [size_exponent     : 0] exp_inter;
 
        wire [size_mantissa - 2 : 0] mul_mantissa;
 
        wire [size_mul_mantissa - 1     : 0] m_ab_mantissa, c_mantissa;
        wire [size_exponent                     : 0] e_ab_number_inter, e_ab_number;
        wire [size_mul_counter - 1      : 0] lz_mul;
 
        wire zero_flag;
        wire sign_res;
        wire eff_op;
 
        wire [size_mantissa - 1         : 0] initial_rounding_bits, inter_rounding_bits, final_rounding_bits;
        wire [size_mul_mantissa + 1 : 0] normalized_mantissa, adder_mantissa;
        wire [size_mul_mantissa         : 0] unnormalized_mantissa;
        wire [size_mul_mantissa - 1 : 0] shifted_m_ab;
        wire [size_mul_mantissa - 1 : 0] m_c, m_ab;
 
        wire [size_exception_field - 1 : 0] sp_case_mul_result_o;
 
        wire [size_exception_field - 1 : 0] sp_case_result_o;
        wire [size_mantissa - 2 : 0] final_mantissa;
        wire [size_exponent - 1 : 0] final_exponent;
        wire [size_mantissa : 0] rounded_mantissa;
 
 
        assign m_a_number                       = {1'b1, a_number_i[size_mantissa - 2 :0]};
        assign m_b_number                       = {1'b1, b_number_i[size_mantissa - 2 :0]};
        assign m_c_number                       = {1'b1, c_number_i[size_mantissa - 2 :0]};
        assign e_a_number                       = a_number_i[size_mantissa + size_exponent - 1 : size_mantissa - 1];
        assign e_b_number                       = b_number_i[size_mantissa + size_exponent - 1 : size_mantissa - 1];
        assign e_c_number                       = c_number_i[size_mantissa + size_exponent - 1 : size_mantissa - 1];
        assign s_a_number                       = a_number_i[size - size_exception_field - 1];
        assign s_b_number                       = b_number_i[size - size_exception_field - 1];
        assign s_c_number                       = c_number_i[size - size_exception_field - 1];
        assign sp_case_a_number = a_number_i[size - 1 : size - size_exception_field];
        assign sp_case_b_number = b_number_i[size - 1 : size - size_exception_field];
        assign sp_case_c_number = c_number_i[size - 1 : size - size_exception_field];
 
 
        //instantiate multiply component
        multiply #(     .size_mantissa(size_mantissa),
                                        .size_counter(size_counter),
                                        .size_mul_mantissa(size_mul_mantissa))
                multiply_instance (     .a_mantissa_i(m_a_number),
                                                                        .b_mantissa_i(m_b_number),
                                                                        .mul_mantissa(m_ab_mantissa));
 
        assign mul_mantissa = m_ab_mantissa[size_mul_mantissa-1]?       m_ab_mantissa[size_mul_mantissa-2 : size_mul_mantissa - size_mantissa] :
                                                                                                                                m_ab_mantissa[size_mul_mantissa-3 : size_mul_mantissa - size_mantissa - 1];
 
        assign c_mantissa       = {1'b0,m_c_number, {(shift_mantissa_0_bits){1'b0}}};
        assign e_ab_number_inter = e_a_number + e_b_number;
        assign e_ab_number = e_ab_number_inter  - {(bias_0_bits){1'b1}};
 
        //find the greater exponent
        assign ab_greater_exponent = e_ab_number - e_c_number;
        assign c_greater_exponent = e_c_number - e_ab_number;
 
        //find the difference between exponents
        assign exp_difference   = (ab_greater_exponent[size_exponent])? c_greater_exponent[size_exponent - 1 : 0] : ab_greater_exponent[size_exponent - 1 : 0];
        assign exp_inter                = (c_greater_exponent[size_exponent])? {1'b0, e_ab_number} : {1'b0, e_c_number};
 
        //set shifter always on m_ab_number
        assign {m_c, m_ab} = (ab_greater_exponent[size_exponent])? {c_mantissa, m_ab_mantissa} :
                                                        {m_ab_mantissa, c_mantissa};
 
        //shift m_ab_number                             
        shifter #(      .INPUT_SIZE(size_mul_mantissa),
                                .SHIFT_SIZE(size_exponent),
                                .OUTPUT_SIZE(size_mul_mantissa + size_mantissa),
                                .DIRECTION(1'b0), //0=right, 1=left
                                .PIPELINE(pipeline),
                                .POSITION(pipeline_pos))
                m_b_shifter_instance(   .a(m_ab),//mantissa
                                                                .arith(1'b0),//logical shift
                                                                .shft(exp_difference),
                                                                .shifted_a({shifted_m_ab, initial_rounding_bits}));
 
 
        //instantiate effective_op component
        effective_op effective_op_instance(     .sign_a(s_a_number),
                                                                                                        .sign_b(s_b_number),
                                                                                                        .sign_c(s_c_number),
                                                                                                        .sub(sub),
                                                                                                        .eff_sub(eff_op));
 
        //instantiate accumulate component
        accumulate #(.size_mul_mantissa(size_mul_mantissa))
                accumulate_instance (   .m_a(m_c),
                                                                .m_b(shifted_m_ab),
                                                                .eff_op(eff_op),
                                                                .adder_mantissa(adder_mantissa));
 
        //compute unnormalized_mantissa
        assign {unnormalized_mantissa, inter_rounding_bits} =
                                (adder_mantissa[size_mul_mantissa + 1])?        ({~adder_mantissa[size_mul_mantissa : 0], ~initial_rounding_bits}) :
                                                                                                                        ({adder_mantissa[size_mul_mantissa      : 0], initial_rounding_bits});
 
        //instantiate leading_zeros component
        leading_zeros #(        .SIZE_INT(size_mul_mantissa + 1'b1),
                                                        .SIZE_COUNTER(size_mul_counter),
                                                        .PIPELINE(pipeline))
                leading_zeros_instance( .a(unnormalized_mantissa[size_mul_mantissa : 0]),
                                                                                .ovf(unnormalized_mantissa[size_mul_mantissa]),
                                                                                .lz(lz_mul));
 
        //instantiate shifter component
        shifter #(      .INPUT_SIZE(size_mul_mantissa + size_mantissa + 1),
                                        .SHIFT_SIZE(size_mul_counter),
                                        .OUTPUT_SIZE(size_mul_mantissa + size_mantissa + 2),
                                        .DIRECTION(1'b1),
                                        .PIPELINE(pipeline),
                                        .POSITION(pipeline_pos))
                shifter_instance(       .a({unnormalized_mantissa, inter_rounding_bits}),
                                                                .arith(1'b0),
                                                                .shft(lz_mul),
                                                                .shifted_a({normalized_mantissa, final_rounding_bits}));
 
        //instantiate rounding_component
        rounding #(     .SIZE_MOST_S_MANTISSA(size_mantissa+1),
                                .SIZE_LEAST_S_MANTISSA(size_mul_mantissa+2))
                rounding_instance(      .unrounded_mantissa({1'b0, normalized_mantissa[size_mul_mantissa+1 : size_mantissa + 2]}),
                                    .dummy_bits({normalized_mantissa[size_mantissa + 1 : 0],final_rounding_bits}),
                                    .rounded_mantissa(rounded_mantissa));
 
        //instantiate special_cases_mul and special_cases_mul_acc components
        special_cases_mul_acc   #(      .size_exception_field(size_exception_field),
                                                                .zero(zero),
                                                                .normal_number(normal_number),
                                                                .infinity(infinity),
                                                                .NaN(NaN))
                special_cases_mul_acc_instance  (       .sp_case_a_number(sp_case_a_number),
                                                                                        .sp_case_b_number(sp_case_b_number),
                                                                                        .sp_case_c_number(sp_case_c_number),
                                                                                        .sp_case_result_o(sp_case_result_o));
 
        special_cases_mul       #(      .size_exception_field(size_exception_field),
                                                        .zero(zero),
                                                        .normal_number(normal_number),
                                                        .infinity(infinity),
                                                        .NaN(NaN))
                special_cases_mul_instance(     .sp_case_a_number(sp_case_a_number),
                                                                        .sp_case_b_number(sp_case_b_number),
                                                                        .sp_case_result_o(sp_case_mul_result_o));
 
        //set zero_flag in case of equal numbers
        assign zero_flag = ~(|(rounded_mantissa));
 
        //compute resulted_sign
        assign sign_res =       (eff_op)?       (!c_greater_exponent[size_exponent]?
                                                                                (!ab_greater_exponent[size_exponent]? ~adder_mantissa[size_mul_mantissa+1] : s_c_number) : ~(s_b_number^s_a_number)) : s_c_number;
 
        assign final_mantissa = (rounded_mantissa[size_mantissa])?
                                                                        (rounded_mantissa[size_mantissa : 1]) :
                                                                        (rounded_mantissa[size_mantissa-1: 0]);
 
        assign unadjusted_exponent = exp_inter - lz_mul;
        assign final_exponent = unadjusted_exponent + 2'd2;
        assign resulting_number_o = (zero_flag)? {size{1'b0}} :
                                                                (!sp_case_a_number || !sp_case_b_number)? {c_number_i[size-1 : size-size_exception_field], s_c_number, c_number_i[size-1-size_exception_field-1 : 0]} :
                                                                (!sp_case_c_number)?
                                                                        (eff_op?
                                                                                {sp_case_mul_result_o, ~(s_a_number^s_b_number), e_ab_number[size_exponent-1 : 0], mul_mantissa} :
                                                                                {sp_case_mul_result_o, s_a_number^s_b_number, e_ab_number[size_exponent-1 : 0], mul_mantissa}) :
                                                                                        {sp_case_result_o, sign_res, final_exponent, final_mantissa};
endmodule

Line No.	Rev	Author	Line
1	5	constantin	`timescale 1ns / 1ps
2			`//////////////////////////////////////////////////////////////////////////////////`
3			`// Company:`
4			`// Engineer:`
5			`//`
6			`// Create Date: 17:53:05 10/15/2013`
7			`// Design Name:`
8			`// Module Name: Multiply_Accumulate`
9			`// Project Name:`
10			`// Target Devices:`
11			`// Tool versions:`
12			`// Description: C � A*B`
13			`//`
14			`// Dependencies:`
15			`//`
16			`// Revision:`
17			`// Revision 0.01 - File Created`
18			`// Additional Comments:`
19			`//`
20			`//////////////////////////////////////////////////////////////////////////////////`
21	19	constantin	`module Multiply_Accumulate #( parameter size_mantissa = 24, //mantissa bits(1.M)`
22	9	constantin	`parameter size_exponent = 8, //exponent bits`
23	3	constantin	`parameter size_counter = 5, //log2(size_mantissa) + 1 = 5`
24	19	constantin	`parameter size_exception_field = 2, // zero/normal numbers/infinity/NaN`
25			`parameter zero = 00, //00`
26			`parameter normal_number = 01, //01`
27			`parameter infinity = 10, //10`
28			`parameter NaN = 11, //11`
29	5	constantin	`parameter pipeline = 0,`
30			`parameter pipeline_pos = 0, //8 bits`
31	3	constantin
32	5	constantin	`parameter size = size_exponent + size_mantissa + size_exception_field,`
33			`parameter size_mul_mantissa = size_mantissa + size_mantissa,`
34			`parameter size_mul_counter = size_counter + 1)`
35	19	constantin	`( input [size - 1:0] a_number_i,`
36	5	constantin	`input [size - 1:0] b_number_i,`
37			`input [size - 1:0] c_number_i,`
38			`input sub,`
39			`output[size - 1:0] resulting_number_o);`
40
41	9	constantin	`parameter bias_0_bits = size_exponent - 1;`
42			`parameter shift_mantissa_0_bits = size_mantissa-1'b1;`
43	5	constantin
44	9	constantin	`wire [size_exception_field - 1 : 0] sp_case_a_number, sp_case_b_number, sp_case_c_number;`
45	5	constantin	`wire [size_mantissa - 1 : 0] m_a_number, m_b_number, m_c_number;`
46			`wire [size_exponent - 1 : 0] e_a_number, e_b_number, e_c_number;`
47			`wire s_a_number, s_b_number, s_c_number;`
48
49	9	constantin	`wire [size_exponent : 0] ab_greater_exponent, c_greater_exponent;`
50	5	constantin
51	9	constantin	`wire [size_exponent - 1 : 0] exp_difference;`
52			`wire [size_exponent - 1 : 0] unadjusted_exponent;`
53			`wire [size_exponent : 0] exp_inter;`
54
55	19	constantin	`wire [size_mantissa - 2 : 0] mul_mantissa;`
56
57	9	constantin	`wire [size_mul_mantissa - 1 : 0] m_ab_mantissa, c_mantissa;`
58			`wire [size_exponent : 0] e_ab_number_inter, e_ab_number;`
59			`wire [size_mul_counter - 1 : 0] lz_mul;`
60
61			`wire zero_flag;`
62	5	constantin	`wire sign_res;`
63	9	constantin	`wire eff_op;`
64
65			`wire [size_mantissa - 1 : 0] initial_rounding_bits, inter_rounding_bits, final_rounding_bits;`
66			`wire [size_mul_mantissa + 1 : 0] normalized_mantissa, adder_mantissa;`
67			`wire [size_mul_mantissa : 0] unnormalized_mantissa;`
68			`wire [size_mul_mantissa - 1 : 0] shifted_m_ab;`
69			`wire [size_mul_mantissa - 1 : 0] m_c, m_ab;`
70
71	19	constantin	`wire [size_exception_field - 1 : 0] sp_case_mul_result_o;`
72
73			`wire [size_exception_field - 1 : 0] sp_case_result_o;`
74	9	constantin	`wire [size_mantissa - 2 : 0] final_mantissa;`
75			`wire [size_exponent - 1 : 0] final_exponent;`
76			`wire [size_mantissa : 0] rounded_mantissa;`
77
78	3	constantin
79	9	constantin	`assign m_a_number = {1'b1, a_number_i[size_mantissa - 2 :0]};`
80	5	constantin	`assign m_b_number = {1'b1, b_number_i[size_mantissa - 2 :0]};`
81			`assign m_c_number = {1'b1, c_number_i[size_mantissa - 2 :0]};`
82			`assign e_a_number = a_number_i[size_mantissa + size_exponent - 1 : size_mantissa - 1];`
83			`assign e_b_number = b_number_i[size_mantissa + size_exponent - 1 : size_mantissa - 1];`
84			`assign e_c_number = c_number_i[size_mantissa + size_exponent - 1 : size_mantissa - 1];`
85			`assign s_a_number = a_number_i[size - size_exception_field - 1];`
86			`assign s_b_number = b_number_i[size - size_exception_field - 1];`
87			`assign s_c_number = c_number_i[size - size_exception_field - 1];`
88			`assign sp_case_a_number = a_number_i[size - 1 : size - size_exception_field];`
89			`assign sp_case_b_number = b_number_i[size - 1 : size - size_exception_field];`
90			`assign sp_case_c_number = c_number_i[size - 1 : size - size_exception_field];`
91	3	constantin
92	5	constantin
93			`//instantiate multiply component`
94			`multiply #( .size_mantissa(size_mantissa),`
95			`.size_counter(size_counter),`
96			`.size_mul_mantissa(size_mul_mantissa))`
97			`multiply_instance ( .a_mantissa_i(m_a_number),`
98			`.b_mantissa_i(m_b_number),`
99	9	constantin	`.mul_mantissa(m_ab_mantissa));`
100	19	constantin
101			`assign mul_mantissa = m_ab_mantissa[size_mul_mantissa-1]? m_ab_mantissa[size_mul_mantissa-2 : size_mul_mantissa - size_mantissa] :`
102			`m_ab_mantissa[size_mul_mantissa-3 : size_mul_mantissa - size_mantissa - 1];`
103	5	constantin
104	9	constantin	`assign c_mantissa = {1'b0,m_c_number, {(shift_mantissa_0_bits){1'b0}}};`
105			`assign e_ab_number_inter = e_a_number + e_b_number;`
106	12	constantin	`assign e_ab_number = e_ab_number_inter - {(bias_0_bits){1'b1}};`
107	5	constantin
108	9	constantin	`//find the greater exponent`
109			`assign ab_greater_exponent = e_ab_number - e_c_number;`
110			`assign c_greater_exponent = e_c_number - e_ab_number;`
111	5	constantin
112	9	constantin	`//find the difference between exponents`
113			`assign exp_difference = (ab_greater_exponent[size_exponent])? c_greater_exponent[size_exponent - 1 : 0] : ab_greater_exponent[size_exponent - 1 : 0];`
114			`assign exp_inter = (c_greater_exponent[size_exponent])? {1'b0, e_ab_number} : {1'b0, e_c_number};`
115	5	constantin
116	9	constantin	`//set shifter always on m_ab_number`
117			`assign {m_c, m_ab} = (ab_greater_exponent[size_exponent])? {c_mantissa, m_ab_mantissa} :`
118			`{m_ab_mantissa, c_mantissa};`
119	5	constantin
120	9	constantin	`//shift m_ab_number`
121	5	constantin	`shifter #( .INPUT_SIZE(size_mul_mantissa),`
122	9	constantin	`.SHIFT_SIZE(size_exponent),`
123			`.OUTPUT_SIZE(size_mul_mantissa + size_mantissa),`
124			`.DIRECTION(1'b0), //0=right, 1=left`
125			`.PIPELINE(pipeline),`
126			`.POSITION(pipeline_pos))`
127			`m_b_shifter_instance( .a(m_ab),//mantissa`
128			`.arith(1'b0),//logical shift`
129			`.shft(exp_difference),`
130			`.shifted_a({shifted_m_ab, initial_rounding_bits}));`
131	5	constantin
132
133			`//instantiate effective_op component`
134			`effective_op effective_op_instance( .sign_a(s_a_number),`
135			`.sign_b(s_b_number),`
136			`.sign_c(s_c_number),`
137			`.sub(sub),`
138	9	constantin	`.eff_sub(eff_op));`
139
140	5	constantin	`//instantiate accumulate component`
141	9	constantin	`accumulate #(.size_mul_mantissa(size_mul_mantissa))`
142			`accumulate_instance ( .m_a(m_c),`
143			`.m_b(shifted_m_ab),`
144			`.eff_op(eff_op),`
145			`.adder_mantissa(adder_mantissa));`
146
147			`//compute unnormalized_mantissa`
148			`assign {unnormalized_mantissa, inter_rounding_bits} =`
149			`(adder_mantissa[size_mul_mantissa + 1])? ({~adder_mantissa[size_mul_mantissa : 0], ~initial_rounding_bits}) :`
150			`({adder_mantissa[size_mul_mantissa : 0], initial_rounding_bits});`
151
152	5	constantin	`//instantiate leading_zeros component`
153			`leading_zeros #( .SIZE_INT(size_mul_mantissa + 1'b1),`
154			`.SIZE_COUNTER(size_mul_counter),`
155			`.PIPELINE(pipeline))`
156	9	constantin	`leading_zeros_instance( .a(unnormalized_mantissa[size_mul_mantissa : 0]),`
157			`.ovf(unnormalized_mantissa[size_mul_mantissa]),`
158	5	constantin	`.lz(lz_mul));`
159
160			`//instantiate shifter component`
161	9	constantin	`shifter #( .INPUT_SIZE(size_mul_mantissa + size_mantissa + 1),`
162	5	constantin	`.SHIFT_SIZE(size_mul_counter),`
163	9	constantin	`.OUTPUT_SIZE(size_mul_mantissa + size_mantissa + 2),`
164	5	constantin	`.DIRECTION(1'b1),`
165			`.PIPELINE(pipeline),`
166			`.POSITION(pipeline_pos))`
167	9	constantin	`shifter_instance( .a({unnormalized_mantissa, inter_rounding_bits}),`
168	5	constantin	`.arith(1'b0),`
169			`.shft(lz_mul),`
170	9	constantin	`.shifted_a({normalized_mantissa, final_rounding_bits}));`
171
172			`//instantiate rounding_component`
173			`rounding #( .SIZE_MOST_S_MANTISSA(size_mantissa+1),`
174			`.SIZE_LEAST_S_MANTISSA(size_mul_mantissa+2))`
175			`rounding_instance( .unrounded_mantissa({1'b0, normalized_mantissa[size_mul_mantissa+1 : size_mantissa + 2]}),`
176			`.dummy_bits({normalized_mantissa[size_mantissa + 1 : 0],final_rounding_bits}),`
177			`.rounded_mantissa(rounded_mantissa));`
178
179	19	constantin	`//instantiate special_cases_mul and special_cases_mul_acc components`
180	5	constantin	`special_cases_mul_acc #( .size_exception_field(size_exception_field),`
181	19	constantin	`.zero(zero),`
182			`.normal_number(normal_number),`
183			`.infinity(infinity),`
184			`.NaN(NaN))`
185	5	constantin	`special_cases_mul_acc_instance ( .sp_case_a_number(sp_case_a_number),`
186	19	constantin	`.sp_case_b_number(sp_case_b_number),`
187			`.sp_case_c_number(sp_case_c_number),`
188			`.sp_case_result_o(sp_case_result_o));`
189
190			`special_cases_mul #( .size_exception_field(size_exception_field),`
191			`.zero(zero),`
192			`.normal_number(normal_number),`
193			`.infinity(infinity),`
194			`.NaN(NaN))`
195			`special_cases_mul_instance( .sp_case_a_number(sp_case_a_number),`
196			`.sp_case_b_number(sp_case_b_number),`
197			`.sp_case_result_o(sp_case_mul_result_o));`
198	9	constantin
199			`//set zero_flag in case of equal numbers`
200	19	constantin	`assign zero_flag = ~(\|(rounded_mantissa));`
201	5	constantin
202			`//compute resulted_sign`
203	9	constantin	`assign sign_res = (eff_op)? (!c_greater_exponent[size_exponent]?`
204			`(!ab_greater_exponent[size_exponent]? ~adder_mantissa[size_mul_mantissa+1] : s_c_number) : ~(s_b_number^s_a_number)) : s_c_number;`
205	5	constantin
206	9	constantin	`assign final_mantissa = (rounded_mantissa[size_mantissa])?`
207			`(rounded_mantissa[size_mantissa : 1]) :`
208			`(rounded_mantissa[size_mantissa-1: 0]);`
209
210			`assign unadjusted_exponent = exp_inter - lz_mul;`
211			`assign final_exponent = unadjusted_exponent + 2'd2;`
212	19	constantin	`assign resulting_number_o = (zero_flag)? {size{1'b0}} :`
213			`(!sp_case_a_number \|\| !sp_case_b_number)? {c_number_i[size-1 : size-size_exception_field], s_c_number, c_number_i[size-1-size_exception_field-1 : 0]} :`
214			`(!sp_case_c_number)?`
215			`(eff_op?`
216			`{sp_case_mul_result_o, ~(s_a_number^s_b_number), e_ab_number[size_exponent-1 : 0], mul_mantissa} :`
217			`{sp_case_mul_result_o, s_a_number^s_b_number, e_ab_number[size_exponent-1 : 0], mul_mantissa}) :`
218			`{sp_case_result_o, sign_res, final_exponent, final_mantissa};`
219	5	constantin	`endmodule`

Browse

Tools

Subversion Repositories xilinx_virtex_fp_library

[/] [xilinx_virtex_fp_library/] [trunk/] [GeneralPrecMAF/] [Multiply_Accumulate.v] - Blame information for rev 19