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1 22 jguarin200
--! @file raytrac.vhd
2 67 jguarin200
--! @brief Descripción del sistema aritmetico usado por raytrac.
3 52 jguarin200
--! @author Juli´n Andrés Guarín Reyes.
4 8 jguarin200
-- RAYTRAC
5
-- Author Julian Andres Guarin
6
-- uf.vhd
7
-- This file is part of raytrac.
8
-- 
9
--     raytrac is free software: you can redistribute it and/or modify
10
--     it under the terms of the GNU General Public License as published by
11
--     the Free Software Foundation, either version 3 of the License, or
12
--     (at your option) any later version.
13
-- 
14
--     raytrac is distributed in the hope that it will be useful,
15
--     but WITHOUT ANY WARRANTY; without even the implied warranty of
16
--     MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
17
--     GNU General Public License for more details.
18
-- 
19
--     You should have received a copy of the GNU General Public License
20
--     along with raytrac.  If not, see <http://www.gnu.org/licenses/>.
21
 
22 52 jguarin200
--! Libreria de definicion de senales y tipos estandares, comportamiento de operadores aritmeticos y logicos.
23 2 jguarin200
library ieee;
24 52 jguarin200
--! Paquete de definicion estandard de logica. 
25 2 jguarin200
use ieee.std_logic_1164.all;
26 27 jguarin200
 
27
--! Paquete para el manejo de aritmŽtica con signo sobre el tipo std_logic_vector 
28
use ieee.std_logic_signed.all;
29
 
30 78 jguarin200
--! Paquete para calculo de funciones reales.
31
use ieee.math_real.all;
32
 
33 50 jguarin200
--! Paquete estandar de texto
34
use std.textio.all;
35
 
36 52 jguarin200
--! Se usaran en esta descripcion los componentes del package arithpack.vhd. 
37 2 jguarin200
use work.arithpack.all;
38
 
39 22 jguarin200
 
40 67 jguarin200
--! uf es la descripci&oacute;on del circuito que realiza la aritm&eacute;tica del Rt Engine.
41 22 jguarin200
 
42 67 jguarin200
--! La entrada opcode indica la operaci&oacute;n que se est&aacute; realizando, en los sumadores, es la misma se&ntilde;al que se encuentra en la entidad opcoder, que selecciona si se est&aacute; realizando un producto punto o un producto cruz. Dentro de la arquitectura de uf, la se&ntilde;al opcode selecciona en la primera etapa de sumadores, si la operaci&oacute;n a realizar ser&aacute; una resta o una suma. 
43
--! Los resultados estar&acute;n en distintas salidas dependiendo de la operaci&oacute;n, lo cual es apenas natural: El producto cruz tiene por resultado un vector, mientras que el producto punto tiene por resultado un escalar. 
44
--! Esta entidad utiliza las se&ntilde;ales de control clk y rst.
45 22 jguarin200
--! \n\n
46 67 jguarin200
--! La caracter&iacute;stica fundamental de uf, es que puede realizar 2 operaciones de producto punto al mimso tiempo &oacute; una operaci&oacute;n de producto cruz. La otra caracter&iacute;stica importante es que el pipe de producto punto es mas largo que el pipe de producto cruz: el producto punto tomar&acute; 3 clocks para realizarse, mientras que el procto punto tomara 4 clocks para realizarse.    
47 78 jguarin200
--! Es importante entender que las resultados de las operaciones, correspondientes a las salidas de esta entidad no est'an conectadas directamente a la salida del circuito combinatorio que ejecuta sus repectivas operaciones: en vez de ello, los resutados est'an conectados a la salida de un registro. 
48
--! Este circuito es una ALU
49 27 jguarin200
entity uf is
50
        generic (
51 78 jguarin200
                square_root_width : integer := 16;
52
                use_std_logic_signed : string := "NO";
53
                testbench_generation : string := "NO";
54
                carry_logic : string := "CLA"
55 27 jguarin200
        );
56 2 jguarin200
        port (
57 67 jguarin200
                opcode          : in std_logic; --! Entrada que dentro de la arquitectura funciona como selector de la operaci&oacute;n que se lleva a cabo en la primera etapa de sumadores/restadores. 
58 78 jguarin200
                exp0,exp1       : in std_logic_vector(integer(ceil(log(real(square_root_width),2.0)))-1 downto 0); --! Junto con la mantissa este es el exponente del valor flotante, mejora muchisimo la precisi'on. 
59 67 jguarin200
                m0f0,m0f1,m1f0,m1f1,m2f0,m2f1,m3f0,m3f1,m4f0,m4f1,m5f0,m5f1 : in std_logic_vector(17 downto 0); --! Entradas que van conectadas a los multiplicadores en la primera etapa de la descripci&oacute;n.  
60 77 jguarin200
                cpx,cpy,cpz,dp0,dp1,kvx0,kvy0,kvz0,kvx1,kvy1,kvz1 : out std_logic_vector(31 downto 0); --! Salidas donde se registran los resultados de las operaciones aritm&eacute;ticas: cpx,cpy,cpz ser&acute;n los componentes del vector que da por resultado el producto cruz entre los vectores AxB &oacute; CxD. kvx0, kvy0, kvz0, kvx1, kvy1, kvz1 es el resultado de los multiplicadores   
61 22 jguarin200
                clk,rst         : in std_logic --! Las entradas de control usuales.  
62 2 jguarin200
        );
63
end uf;
64
 
65
architecture uf_arch of uf is
66
 
67 8 jguarin200
        -- Stage 0 signals
68 2 jguarin200
 
69 22 jguarin200
        signal stage0mf00,stage0mf01,stage0mf10,stage0mf11,stage0mf20,stage0mf21,stage0mf30,stage0mf31,stage0mf40,stage0mf41,stage0mf50,stage0mf51 : std_logic_vector(17 downto 0); --! Señales que conectan los operandos seleccionados en opcode a las entradas de los multiplicadores.
70 78 jguarin200
        signal stage0p0,stage0p1, stage0p2, stage0p3, stage0p4, stage0p5 : std_logic_vector(31 downto 0); --! Se&ntilde;ales / buses, con los productos de los multiplicadores. 
71 28 jguarin200
        signal stageMopcode : std_logic; --! Señal de atraso del opcode. Revisar el diagrama de bloques para mayor claridad.
72 78 jguarin200
        signal stage0exp0       : std_logic_vector(integer(ceil(log(real(square_root_width),2.0)))-1 downto 0);
73
        signal stage0exp1       : std_logic_vector(integer(ceil(log(real(square_root_width),2.0)))-1 downto 0);
74 2 jguarin200
 
75 8 jguarin200
        --Stage 1 signals 
76 2 jguarin200
 
77 22 jguarin200
        signal stage1p0, stage1p1, stage1p2, stage1p3, stage1p4, stage1p5 : std_logic_vector (31 downto 0); --! Señales provenientes de los productos de la etapa previa de multiplicadores.
78
        signal stage1a0, stage1a1, stage1a2 : std_logic_vector (31 downto 0); --! Señales / buses, con los resultados de los sumadores. 
79 67 jguarin200
        signal stageSRopcode : std_logic; --! Señal proveniente del opcode que selecciona si los sumadores deben ejecutar una resta o una suma dependiendo de la operaci&oacute;n que se ejecute en ese momento del pipe.  
80 78 jguarin200
        signal stage1exp0       : std_logic_vector(integer(ceil(log(real(square_root_width),2.0)))-1 downto 0);
81
        signal stage1exp1       : std_logic_vector(integer(ceil(log(real(square_root_width),2.0)))-1 downto 0);
82 2 jguarin200
 
83 8 jguarin200
        -- Some support signals
84 52 jguarin200
        signal stage1_internalCarry     : std_logic_vector(2 downto 0); --! Cada uno de los 3 sumadores de la etapa de sumadores est&acute; compuesto de una cascada de 2 sumadores Carry Look Ahead: aXhigh y aXlow. El carry out del componente low y el carry in del componente high, se conectar&acute; a trav&eacute;s de las señales internal carry.   
85
        signal stage2_internalCarry : std_logic_vector(1 downto 0); --! Cada uno de los 2 sumadores de la última etapa de sumadores est&acute; compuesto de una cascada de 2 sumadores Carry Look AheadÑ: aXhigh y aXlow. El carry out del componente low y el carry in del componente high, se conectar&acute; a trav&eacute;s de las señales internal carry.  
86 2 jguarin200
 
87 22 jguarin200
        --Stage 2 signals       
88
        signal stage2a0, stage2a2, stage2a3, stage2a4, stage2p2, stage2p3 : std_logic_vector (31 downto 0); --! Estas señales corresponden a los sumandos derivados de la primera etapa de multiplicadores (stage2p2, stage2p3) y a los sumandos derivados del resultado de las sumas en la primera etapa de sumadores. 
89 8 jguarin200
 
90
 
91
 
92 2 jguarin200
begin
93
 
94 8 jguarin200
        -- Multiplicator Instantiation (StAgE 0)
95 22 jguarin200
        --! Multiplicador 0 
96 50 jguarin200
        m0 : lpm_mult
97
        generic map (
98
                lpm_hint =>  "DEDICATED_MULTIPLIER_CIRCUITRY=YES,MAXIMIZE_SPEED=9",
99
                lpm_pipeline =>  2,
100
                lpm_representation => "SIGNED",
101
                lpm_type => "LPM_MULT",
102
                lpm_widtha => 18,
103
                lpm_widthb => 18,
104
                lpm_widthp => 32
105
        )
106 8 jguarin200
        port map (
107
                aclr    => rst,
108
                clock   => clk,
109 15 jguarin200
                dataa   => stage0mf00,
110
                datab   => stage0mf01,
111
                result  => stage0p0
112 8 jguarin200
        );
113 77 jguarin200
        kvx0 <= stage0p0;
114 22 jguarin200
        --! Multiplicador 1
115 50 jguarin200
        m1 : lpm_mult
116
        generic map (
117
                lpm_hint =>  "DEDICATED_MULTIPLIER_CIRCUITRY=YES,MAXIMIZE_SPEED=9",
118
                lpm_pipeline =>  2,
119
                lpm_representation => "SIGNED",
120
                lpm_type => "LPM_MULT",
121
                lpm_widtha => 18,
122
                lpm_widthb => 18,
123
                lpm_widthp => 32
124
        )
125 8 jguarin200
        port map (
126
                aclr    => rst,
127
                clock   => clk,
128 15 jguarin200
                dataa   => stage0mf10,
129
                datab   => stage0mf11,
130
                result  => stage0p1
131 8 jguarin200
        );
132 77 jguarin200
        kvy0 <= stage0p1;
133 22 jguarin200
 
134
        --! Multiplicador 2
135 50 jguarin200
        m2 : lpm_mult
136
        generic map (
137
                lpm_hint =>  "DEDICATED_MULTIPLIER_CIRCUITRY=YES,MAXIMIZE_SPEED=9",
138
                lpm_pipeline =>  2,
139
                lpm_representation => "SIGNED",
140
                lpm_type => "LPM_MULT",
141
                lpm_widtha => 18,
142
                lpm_widthb => 18,
143
                lpm_widthp => 32
144
        )
145 8 jguarin200
        port map (
146
                aclr    => rst,
147
                clock   => clk,
148 15 jguarin200
                dataa   => stage0mf20,
149
                datab   => stage0mf21,
150
                result  => stage0p2
151 8 jguarin200
        );
152 77 jguarin200
        kvz0 <= stage0p2;
153 22 jguarin200
 
154
        --! Multiplicador 3
155 50 jguarin200
        m3 : lpm_mult
156
        generic map (
157
                lpm_hint =>  "DEDICATED_MULTIPLIER_CIRCUITRY=YES,MAXIMIZE_SPEED=9",
158
                lpm_pipeline =>  2,
159
                lpm_representation => "SIGNED",
160
                lpm_type => "LPM_MULT",
161
                lpm_widtha => 18,
162
                lpm_widthb => 18,
163
                lpm_widthp => 32
164
        )
165 8 jguarin200
        port map (
166
                aclr    => rst,
167
                clock   => clk,
168 15 jguarin200
                dataa   => stage0mf30,
169
                datab   => stage0mf31,
170
                result  => stage0p3
171 8 jguarin200
        );
172 77 jguarin200
        kvx1 <= stage0p3;
173 22 jguarin200
        --! Multiplicador 4
174 50 jguarin200
        m4 : lpm_mult
175
        generic map (
176
                lpm_hint =>  "DEDICATED_MULTIPLIER_CIRCUITRY=YES,MAXIMIZE_SPEED=9",
177
                lpm_pipeline =>  2,
178
                lpm_representation => "SIGNED",
179
                lpm_type => "LPM_MULT",
180
                lpm_widtha => 18,
181
                lpm_widthb => 18,
182
                lpm_widthp => 32
183
        )
184 8 jguarin200
        port map (
185
                aclr    => rst,
186
                clock   => clk,
187 15 jguarin200
                dataa   => stage0mf40,
188
                datab   => stage0mf41,
189
                result  => stage0p4
190 8 jguarin200
        );
191 77 jguarin200
        kvy1 <= stage0p4;
192 22 jguarin200
 
193
        --! Multiplicador 5
194 50 jguarin200
        m5 : lpm_mult
195
        generic map (
196
                lpm_hint =>  "DEDICATED_MULTIPLIER_CIRCUITRY=YES,MAXIMIZE_SPEED=9",
197
                lpm_pipeline =>  2,
198
                lpm_representation => "SIGNED",
199
                lpm_type => "LPM_MULT",
200
                lpm_widtha => 18,
201
                lpm_widthb => 18,
202
                lpm_widthp => 32
203
        )
204 8 jguarin200
        port map (
205
                aclr    => rst,
206
                clock   => clk,
207 15 jguarin200
                dataa   => stage0mf50,
208
                datab   => stage0mf51,
209
                result  => stage0p5
210 8 jguarin200
        );
211 77 jguarin200
        kvz1 <= stage0p5;
212 8 jguarin200
 
213
 
214 27 jguarin200
        useIeee:
215
        if use_std_logic_signed="YES" generate
216
                -- Adder Instantiation (sTaGe 1)
217
                stage1adderProc:
218 28 jguarin200
                process (stage1p0,stage1p1,stage1p2,stage1p3,stage1p4,stage1p5,stageSRopcode)
219 27 jguarin200
                begin
220 28 jguarin200
                        case (stageSRopcode) is
221 27 jguarin200
                                when '1' =>             -- Cross Product
222
                                        stage1a0 <= stage1p0-stage1p1;
223
                                        stage1a2 <= stage1p4-stage1p5;
224
                                when others =>  -- Dot Product
225
                                        stage1a0 <= stage1p0+stage1p1;
226
                                        stage1a2 <= stage1p4+stage1p5;
227
                        end case;
228
                end process stage1adderProc;
229
                stage1a1 <= stage1p2-stage1p3;  -- This is always going to be a substraction
230
 
231
                -- Adder Instantiation (Stage 2)
232
                stage2a3 <= stage2a0+stage2p2;
233
                stage2a4 <= stage2p3+stage2a2;
234 77 jguarin200
 
235 27 jguarin200
        end generate useIeee;
236 78 jguarin200
 
237 8 jguarin200
        -- Incoming from opcoder.vhd signals into pipeline's stage 0.
238 15 jguarin200
        stage0mf00 <= m0f0;
239
        stage0mf01 <= m0f1;
240
        stage0mf10 <= m1f0;
241
        stage0mf11 <= m1f1;
242
        stage0mf20 <= m2f0;
243
        stage0mf21 <= m2f1;
244
        stage0mf30 <= m3f0;
245
        stage0mf31 <= m3f1;
246
        stage0mf40 <= m4f0;
247
        stage0mf41 <= m4f1;
248
        stage0mf50 <= m5f0;
249
        stage0mf51 <= m5f1;
250 8 jguarin200
 
251
        -- Signal sequencing: as the multipliers use registered output and registered input is not necessary to write the sequence of stage 0 signals to stage 1 signals.
252
        -- so the simplistic path is taken: simply connect stage 0 to stage 1 lines. However this would not apply for the opcode signal
253 15 jguarin200
        stage1p0 <= stage0p0;
254
        stage1p1 <= stage0p1;
255
        stage1p2 <= stage0p2;
256
        stage1p3 <= stage0p3;
257
        stage1p4 <= stage0p4;
258
        stage1p5 <= stage0p5;
259 8 jguarin200
 
260
 
261
        --Outcoming to the rest of the system (by the time i wrote this i dont know where this leads to... jeje)
262 78 jguarin200
        --May 31 23:31:56 Guess What!, now I know!!!
263
 
264 15 jguarin200
        cpx <= stage1a0;
265
        cpy <= stage1a1;
266
        cpz <= stage1a2;
267 78 jguarin200
 
268
 
269 15 jguarin200
        dp0 <= stage2a3;
270
        dp1 <= stage2a4;
271 8 jguarin200
 
272
        -- Looking into the design the stage 1 to stage 2 are the sequences pipe stages that must be controlled in this particular HDL.
273 22 jguarin200
        --! Este proceso describe la manera en que se organizan las etapas de pipe.
274 67 jguarin200
        --! Todas las señales internas en las etapas de pipe, en el momento en que la entrada rst alcanza el nivel rstMasterValue, se colocan en '0'. N&oacute;tese que, salvo stageMopcode<=stageSRopcode, las señales que vienen desde la entrada hacia los multiplicadores en la etapa 0 y desde la salida de los multiplicadores desde la etapa0 hacia la etapa 1, no est&acute;n siendo descritas en este proceso, la explicaci&oacute;n de es simple: Los multiplicadores que se est&acute;n instanciado tienen registros a la entrada y la salida, permitiendo as&iacute;, registrar las entradas y registrar los productos o salidas de los  multiplicadores, hacia la etapa 1 o etapa de sumadores/restadores. 
275 22 jguarin200
 
276
        uf_seq: process (clk,rst)
277 8 jguarin200
        begin
278
 
279
                if rst=rstMasterValue then
280 28 jguarin200
                        stageMopcode    <= '0';
281
                        stageSRopcode   <= '0';
282 3 jguarin200
 
283 15 jguarin200
                        stage2a2 <= (others => '0');
284
                        stage2p3 <= (others => '0');
285
                        stage2p2 <= (others => '0');
286
                        stage2a0 <= (others => '0');
287 8 jguarin200
 
288
                elsif clk'event and clk = '1' then
289
 
290 15 jguarin200
                        stage2a2 <= stage1a2;
291
                        stage2p3 <= stage1p3;
292
                        stage2p2 <= stage1p2;
293
                        stage2a0 <= stage1a0;
294 3 jguarin200
 
295 8 jguarin200
                        -- Opcode control sequence
296 28 jguarin200
                        stageMopcode <= opcode;
297
                        stageSRopcode <= stageMopcode;
298 8 jguarin200
 
299
                end if;
300
        end process uf_seq;
301 15 jguarin200
 
302 50 jguarin200
        --! Codigo generado para realizar test bench
303
        tbgen:
304
        if testbench_generation="YES" generate
305
                tbproc0:
306
                process
307
                        variable buff : line;
308 55 jguarin200
                        variable theend : time :=30835 ns;
309 52 jguarin200
                        file mbuff : text open write_mode is "TRACE_multiplier_content.csv";
310 50 jguarin200
                begin
311 54 jguarin200
                write(buff,string'("#UF multipliers test benching"));
312 50 jguarin200
                writeline(mbuff, buff);
313 54 jguarin200
                write(buff,string'("#{Time} {m0result} {m1result} {m2result} {m3result} {m4result} {m5result}"));
314
                writeline(mbuff, buff);
315 50 jguarin200
                wait for 5 ns;
316
                wait until rst=not(rstMasterValue);
317
                wait until clk='1';
318
                wait for tclk2+tclk4; --! Garantizar la estabilidad de los datos que se van a observar en la salida.
319
                displayRom:
320
                loop
321 54 jguarin200
                        write (buff,string'("{"));
322 55 jguarin200
                        write (buff,now,unit =>ns);
323 54 jguarin200
                        write (buff,string'("}{"));
324 50 jguarin200
                        hexwrite_0 (buff,stage1p0(31 downto 0));
325 54 jguarin200
                        write (buff,string'("}{"));
326 50 jguarin200
                        hexwrite_0 (buff,stage1p1(31 downto 0));
327 54 jguarin200
                        write (buff,string'("}{"));
328 50 jguarin200
                        hexwrite_0 (buff,stage1p2(31 downto 0));
329 54 jguarin200
                        write (buff,string'("}{"));
330 58 jguarin200
                        hexwrite_0 (buff,stage1p3(31 downto 0));
331 54 jguarin200
                        write (buff,string'("}{"));
332 50 jguarin200
                        hexwrite_0 (buff,stage1p4(31 downto 0));
333 54 jguarin200
                        write (buff,string'("}{"));
334 50 jguarin200
                        hexwrite_0 (buff,stage1p5(31 downto 0));
335 54 jguarin200
                        write (buff,string'("}"));
336 50 jguarin200
                        writeline(mbuff,buff);
337
                        wait for tclk;
338 56 jguarin200
                        if now>theend then
339 54 jguarin200
                                wait;
340
                        end if;
341 50 jguarin200
                end loop displayRom;
342
                end process tbproc0;
343
                tbproc1:
344
                process
345
                        variable buff : line;
346 55 jguarin200
                        variable theend : time :=30795 ns;
347 52 jguarin200
                        file fbuff : text open write_mode is "TRACE_decoded_factors_content.csv";
348 50 jguarin200
                begin
349
 
350 54 jguarin200
                        write(buff,string'("#UF factors decoded test benching"));
351 50 jguarin200
                        writeline(fbuff, buff);
352 54 jguarin200
                        write(buff,string'("#{Time} {m0f0,m0f1}{m1f0,m1f1}{m2f0,m2f1}{m3f0,m3f1}{m4f0,m4f1}{m5f0,m5f1}"));
353
                        writeline(fbuff, buff);
354 50 jguarin200
                        wait for 5 ns;
355
                        wait until rst=not(rstMasterValue);
356
                        wait until clk='1';
357
                        wait for tclk2+tclk4; --! Garantizar la estabilidad de los datos que se van a observar en la salida.
358
                        displayRom:
359
                        loop
360 52 jguarin200
                                write (buff,string'(" { "));
361 54 jguarin200
                                write (buff,now,unit =>ns);
362
                                write (buff,string'(" } "));
363
                                write (buff,string'(" { "));
364 50 jguarin200
                                hexwrite_0 (buff,m0f0(17 downto 0));
365 52 jguarin200
                                write (buff,string'(","));
366 50 jguarin200
                                hexwrite_0 (buff,m0f1(17 downto 0));
367 52 jguarin200
                                write (buff,string'(" } { "));
368 50 jguarin200
                                hexwrite_0 (buff,m1f0(17 downto 0));
369 52 jguarin200
                                write (buff,string'(","));
370 50 jguarin200
                                hexwrite_0 (buff,m1f1(17 downto 0));
371 52 jguarin200
                                write (buff,string'(" } { "));
372 50 jguarin200
                                hexwrite_0 (buff,m2f0(17 downto 0));
373 52 jguarin200
                                write (buff,string'(","));
374 50 jguarin200
                                hexwrite_0 (buff,m2f1(17 downto 0));
375 52 jguarin200
                                write (buff,string'(" } { "));
376 50 jguarin200
                                hexwrite_0 (buff,m3f0(17 downto 0));
377 52 jguarin200
                                write (buff,string'(","));
378 50 jguarin200
                                hexwrite_0 (buff,m3f1(17 downto 0));
379 52 jguarin200
                                write (buff,string'(" } { "));
380 50 jguarin200
                                hexwrite_0 (buff,m4f0(17 downto 0));
381 52 jguarin200
                                write (buff,string'(","));
382
                                hexwrite_0 (buff,m4f1(17 downto 0));
383
                                write (buff,string'(" } { "));
384 50 jguarin200
                                hexwrite_0 (buff,m5f0(17 downto 0));
385 52 jguarin200
                                write (buff,string'(","));
386 50 jguarin200
                                hexwrite_0 (buff,m5f1(17 downto 0));
387 52 jguarin200
                                write (buff,string'(" }"));
388 50 jguarin200
                                writeline(fbuff,buff);
389
                                wait for tclk;
390 56 jguarin200
                                if now>theend then
391 55 jguarin200
                                        wait;
392
                                end if;
393 50 jguarin200
                        end loop displayRom;
394
                end process tbproc1;
395
 
396 77 jguarin200
                tbproc2:
397 50 jguarin200
                process
398
                        variable buff : line;
399 55 jguarin200
                        variable theend : time :=30855 ns;
400 52 jguarin200
                        file rbuff : text open write_mode is "TRACE_results_content.csv";
401 50 jguarin200
                begin
402
 
403 54 jguarin200
                        write(buff,string'("#UF results test benching"));
404 50 jguarin200
                        writeline(rbuff, buff);
405 54 jguarin200
                        write(buff,string'("#{Time} {CPX,CPY,CPZ}{DP0,DP1}"));
406
                        writeline(rbuff, buff);
407
 
408 50 jguarin200
                        wait for 5 ns;
409
                        wait until rst=not(rstMasterValue);
410
                        wait until clk='1';
411
                        wait for tclk2+tclk4; --! Garantizar la estabilidad de los datos que se van a observar en la salida.
412
                        displayRom:
413
                        loop
414 54 jguarin200
                                write (buff,string'(" { "));
415 50 jguarin200
                                write (buff,now,unit =>ns);
416 54 jguarin200
                                write (buff,string'(" }{ "));
417 50 jguarin200
                                hexwrite_0 (buff,stage1a0(31 downto 0));
418 52 jguarin200
                                write (buff,string'(","));
419 50 jguarin200
                                hexwrite_0 (buff,stage1a1(31 downto 0));
420 52 jguarin200
                                write (buff,string'(","));
421 50 jguarin200
                                hexwrite_0 (buff,stage1a2(31 downto 0));
422 54 jguarin200
                                write (buff,string'(" }{ "));
423 50 jguarin200
                                hexwrite_0 (buff,stage2a3(31 downto 0));
424 54 jguarin200
                                write (buff,string'("}{"));
425 50 jguarin200
                                hexwrite_0 (buff,stage2a4(31 downto 0));
426 52 jguarin200
                                write (buff,string'(" }"));
427 50 jguarin200
                                writeline(rbuff,buff);
428
                                wait for tclk;
429 56 jguarin200
                                if now>theend then
430 55 jguarin200
                                        wait;
431 77 jguarin200
                                end if;
432 50 jguarin200
                        end loop displayRom;
433
                end process tbproc2;
434
 
435
        end generate tbgen;
436 78 jguarin200
        dontUseIeee:
437
        if use_std_logic_signed="NO" generate
438
                --! Adder 0, 16 bit carry lookahead low adder.
439
                a0low : adder
440
                generic map (16,carry_logic,"YES")      -- Carry Look Ahead Logic (More Gates Used, But Less Time)
441
                                                                                -- Yes instantiate Xor gates stage in the adder so we can substract on the opcode signal command.
442
                port map        (stage1p0(15 downto 0),stage1p1(15 downto 0),stageSRopcode,'0',stage1a0(15 downto 0),stage1_internalCarry(0));
443
                --Adder 0, 16 bit carry lookahead high adder.
444
                a0high : adder
445
                generic map (16,carry_logic,"YES")      -- Carry Look Ahead Logic (More Gates Used, But Less Time)
446
                                                                                -- Yes instantiate Xor gates stage in the adder so we can substract on the opcode signal command.
447
                port map        (stage1p0(31 downto 16),stage1p1(31 downto 16),stageSRopcode,stage1_internalCarry(0),stage1a0(31 downto 16),open);
448
                --! Adder 1, 16 bit carry lookahead low adder. 
449
                a1low : adder
450
                generic map (16,carry_logic,"YES")      -- Carry Look Ahead Logic (More Gates Used, But Less Time)
451
                                                                                -- Yes instantiate Xor gates stage in the adder so we can substract on the opcode signal command.
452
                port map        (stage1p2(15 downto 0),stage1p3(15 downto 0),'1','0',stage1a1(15 downto 0),stage1_internalCarry(1));
453
                --! Adder 1, 16 bit carry lookahead high adder.
454
                a1high : adder
455
                generic map (16,carry_logic,"YES")      -- Carry Look Ahead Logic (More Gates Used, But Less Time)
456
                                                                                -- Yes instantiate Xor gates stage in the adder so we can substract on the opcode signal command.
457
                port map        (stage1p2(31 downto 16),stage1p3(31 downto 16),'1',stage1_internalCarry(1),stage1a1(31 downto 16),open);
458
                --! Adder 2, 16 bit carry lookahead low adder. 
459
                a2low : adder
460
                generic map (16,carry_logic,"YES")      -- Carry Look Ahead Logic (More Gates Used, But Less Time)
461
                                                                                -- Yes instantiate Xor gates stage in the adder so we can substract on the opcode signal command.
462
                port map        (stage1p4(15 downto 0),stage1p5(15 downto 0),stageSRopcode,'0',stage1a2(15 downto 0),stage1_internalCarry(2));
463
                --! Adder 2, 16 bit carry lookahead high adder.
464
                a2high : adder
465
                generic map (16,carry_logic,"YES")      -- Carry Look Ahead Logic (More Gates Used, But Less Time)
466
                                                                                -- Yes instantiate Xor gates stage in the adder so we can substract on the opcode signal command.
467
                port map        (stage1p4(31 downto 16),stage1p5(31 downto 16),stageSRopcode,stage1_internalCarry(2),stage1a2(31 downto 16),open);
468
                -- Adder Instantiation (Stage 2)
469
                --! Adder 3, 16 bit carry lookahead low adder. 
470
                a3low : adder
471
                generic map (16,carry_logic,"NO")               -- Carry Look Ahead Logic (More Gates Used, But Less Time)
472
                                                                                -- Dont instantiate Xor gates stage in the adder.
473
                port map        (stage2a0(15 downto 0),stage2p2(15 downto 0),'0','0',stage2a3(15 downto 0),stage2_internalCarry(0));
474
                --Adder 3, 16 bit carry lookahead high adder.
475
                a3high : adder
476
                generic map (16,carry_logic,"NO")               -- Carry Look Ahead Logic (More Gates Used, But Less Time)
477
                                                                                -- Dont instantiate Xor gates stage in the adder.
478
                port map        (stage2a0(31 downto 16),stage2p2(31 downto 16),'0',stage2_internalCarry(0),stage2a3(31 downto 16),open);
479
                --! Adder 4, 16 bit carry lookahead low adder. 
480
                a4low : adder
481
                generic map (16,carry_logic,"NO")               -- Carry Look Ahead Logic (More Gates Used, But Less Time)
482
                                                                                -- Dont instantiate Xor gates stage in the adder.
483
                port map        (stage2p3(15 downto 0),stage2a2(15 downto 0),'0','0',stage2a4(15 downto 0),stage2_internalCarry(1));
484
                --! Adder 4, 16 bit carry lookahead high adder.
485
                a4high : adder
486
                generic map (16,carry_logic,"NO")               -- Carry Look Ahead Logic (More Gates Used, But Less Time)
487
                                                                                -- Dont instantiate Xor gates stage in the adder.
488
                port map        (stage2p3(31 downto 16),stage2a2(31 downto 16),'0',stage2_internalCarry(1),stage2a4(31 downto 16),open);
489
 
490
        end generate dontUseIeee;
491 15 jguarin200
 
492
 
493 50 jguarin200
 
494 2 jguarin200
end uf_arch;

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