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1 93 oharboe
-- ZPU
2
--
3
-- Copyright 2004-2008 oharboe - Øyvind Harboe - oyvind.harboe@zylin.com
4
-- 
5
-- The FreeBSD license
6
-- 
7
-- Redistribution and use in source and binary forms, with or without
8
-- modification, are permitted provided that the following conditions
9
-- are met:
10
-- 
11
-- 1. Redistributions of source code must retain the above copyright
12
--    notice, this list of conditions and the following disclaimer.
13
-- 2. Redistributions in binary form must reproduce the above
14
--    copyright notice, this list of conditions and the following
15
--    disclaimer in the documentation and/or other materials
16
--    provided with the distribution.
17
-- 
18
-- THIS SOFTWARE IS PROVIDED BY THE ZPU PROJECT ``AS IS'' AND ANY
19
-- EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
20
-- THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
21
-- PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
22
-- ZPU PROJECT OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT,
23
-- INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
24
-- (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
25
-- OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
26
-- HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
27
-- STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
28
-- ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF
29
-- ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
30
-- 
31
-- The views and conclusions contained in the software and documentation
32
-- are those of the authors and should not be interpreted as representing
33
-- official policies, either expressed or implied, of the ZPU Project.
34
 
35
library IEEE;
36
use IEEE.STD_LOGIC_1164.ALL;
37
use ieee.numeric_std.all;
38
 
39
library work;
40
use work.zpu_config.all;
41
use work.zpupkg.all;
42
 
43
 
44
entity zpu_core is
45
    Port ( clk : in std_logic;
46
                  -- asynchronous reset signal
47
                          areset : in std_logic;
48
                          -- this particular implementation of the ZPU does not
49
                          -- have a clocked enable signal
50
                          enable : in std_logic;
51
                          in_mem_busy : in std_logic;
52
                          mem_read : in std_logic_vector(wordSize-1 downto 0);
53
                          mem_write : out std_logic_vector(wordSize-1 downto 0);
54
                          out_mem_addr : out std_logic_vector(maxAddrBitIncIO downto 0);
55
                          out_mem_writeEnable : out std_logic;
56
                          out_mem_readEnable : out std_logic;
57
                          -- this implementation of the ZPU *always* reads and writes entire
58
                          -- 32 bit words, so mem_writeMask is tied to (others => '1').
59
                          mem_writeMask: out std_logic_vector(wordBytes-1 downto 0);
60
                          -- Set to one to jump to interrupt vector
61
                          -- The ZPU will communicate with the hardware that caused the
62
                          -- interrupt via memory mapped IO or the interrupt flag can
63
                          -- be cleared automatically
64
                          interrupt : in std_logic;
65
                          -- Signal that the break instruction is executed, normally only used
66
                          -- in simulation to stop simulation
67
                          break : out std_logic);
68
end zpu_core;
69
 
70
architecture behave of zpu_core is
71
 
72
signal          readIO : std_logic;
73
 
74
 
75
 
76
signal memAWriteEnable : std_logic;
77
signal memAAddr : unsigned(maxAddrBit downto minAddrBit);
78
signal memAWrite : unsigned(wordSize-1 downto 0);
79
signal memARead : unsigned(wordSize-1 downto 0);
80
signal memBWriteEnable : std_logic;
81
signal memBAddr : unsigned(maxAddrBit downto minAddrBit);
82
signal memBWrite : unsigned(wordSize-1 downto 0);
83
signal memBRead : unsigned(wordSize-1 downto 0);
84
 
85
 
86
 
87
signal  pc                              : unsigned(maxAddrBit downto 0);
88
signal  sp                              : unsigned(maxAddrBit downto minAddrBit);
89
 
90
-- this signal is set upon executing an IM instruction
91
-- the subsequence IM instruction will then behave differently.
92
-- all other instructions will clear the idim_flag.
93
-- this yields highly compact immediate instructions.
94
signal  idim_flag                       : std_logic;
95
 
96
signal  busy                            : std_logic;
97
 
98
signal  begin_inst                      : std_logic;
99
 
100
 
101
 
102
signal trace_opcode             : std_logic_vector(7 downto 0);
103
signal  trace_pc                                : std_logic_vector(maxAddrBitIncIO downto 0);
104
signal  trace_sp                                : std_logic_vector(maxAddrBitIncIO downto minAddrBit);
105
signal  trace_topOfStack                                : std_logic_vector(wordSize-1 downto 0);
106
signal  trace_topOfStackB                               : std_logic_vector(wordSize-1 downto 0);
107
 
108
-- state machine.
109
type State_Type is
110
(
111
State_Fetch,
112
State_WriteIODone,
113
State_Execute,
114
State_StoreToStack,
115
State_Add,
116
State_Or,
117
State_And,
118
State_Store,
119
State_ReadIO,
120
State_WriteIO,
121
State_Load,
122
State_FetchNext,
123
State_AddSP,
124
State_ReadIODone,
125
State_Decode,
126
State_Resync,
127
State_Interrupt
128
 
129
);
130
 
131
type DecodedOpcodeType is
132
(
133
Decoded_Nop,
134
Decoded_Im,
135
Decoded_ImShift,
136
Decoded_LoadSP,
137
Decoded_StoreSP ,
138
Decoded_AddSP,
139
Decoded_Emulate,
140
Decoded_Break,
141
Decoded_PushSP,
142
Decoded_PopPC,
143
Decoded_Add,
144
Decoded_Or,
145
Decoded_And,
146
Decoded_Load,
147
Decoded_Not,
148
Decoded_Flip,
149
Decoded_Store,
150
Decoded_PopSP,
151
Decoded_Interrupt
152
);
153
 
154
 
155
 
156
signal sampledOpcode : std_logic_vector(OpCode_Size-1 downto 0);
157
signal opcode : std_logic_vector(OpCode_Size-1 downto 0);
158
 
159
signal decodedOpcode : DecodedOpcodeType;
160
signal sampledDecodedOpcode : DecodedOpcodeType;
161
 
162
 
163
signal state : State_Type;
164
 
165
subtype AddrBitBRAM_range is natural range maxAddrBitBRAM downto minAddrBit;
166
signal memAAddr_stdlogic  : std_logic_vector(AddrBitBRAM_range);
167
signal memAWrite_stdlogic : std_logic_vector(memAWrite'range);
168
signal memARead_stdlogic  : std_logic_vector(memARead'range);
169
signal memBAddr_stdlogic  : std_logic_vector(AddrBitBRAM_range);
170
signal memBWrite_stdlogic : std_logic_vector(memBWrite'range);
171
signal memBRead_stdlogic  : std_logic_vector(memBRead'range);
172
 
173
subtype index is integer range 0 to 3;
174
 
175
signal tOpcode_sel : index;
176
 
177
 
178
signal inInterrupt : std_logic;
179
 
180
 
181
 
182
begin
183
 
184
        -- generate a trace file.
185
        -- 
186
        -- This is only used in simulation to see what instructions are
187
        -- executed. 
188
        --
189
        -- a quick & dirty regression test is then to commit trace files
190
        -- to CVS and compare the latest trace file against the last known
191
        -- good trace file
192
        traceFileGenerate:
193
   if Generate_Trace generate
194
        trace_file: trace port map (
195
        clk => clk,
196
        begin_inst => begin_inst,
197
        pc => trace_pc,
198
                opcode => trace_opcode,
199
                sp => trace_sp,
200
                memA => trace_topOfStack,
201
                memB => trace_topOfStackB,
202
                busy => busy,
203
                intsp => (others => 'U')
204
        );
205
        end generate;
206
 
207
 
208
 
209
    -- mem_writeMask is not used in this design, tie it to 1
210
    mem_writeMask <= (others => '1');
211
 
212
 
213
 
214
        memAAddr_stdlogic  <= std_logic_vector(memAAddr(AddrBitBRAM_range));
215
        memAWrite_stdlogic <= std_logic_vector(memAWrite);
216
        memBAddr_stdlogic  <= std_logic_vector(memBAddr(AddrBitBRAM_range));
217
        memBWrite_stdlogic <= std_logic_vector(memBWrite);
218
 
219
 
220
        -- dualport_ram must be defined by the application. 
221
        -- 
222
        -- How this can be implemented is highly dependent on the FPGA
223
        -- and synthesis technology used. 
224
        --
225
        -- sometimes it can be instantiated as in the 
226
        -- zpu/example/helloworld.vhd, using inference,
227
        -- but oftentimes it must be instantiated directly
228
        -- portmapping to part specific FPGA resources
229
        -- 
230
        --
231
        -- DANGER!!!!!! If inference fails, then synthesis will try
232
        -- to implement the memory using basic logic resources. This
233
        -- will almost certainly cause the compiler to get "stuck"
234
        -- since synthesising such a huge number of basic logic resources
235
        -- will take more or less forever.
236
        --
237
        -- So: if your compiler gets "stuck" then inference is not
238
        -- the way to go.
239
        memory: dualport_ram port map (
240
        clk => clk,
241
        memAWriteEnable => memAWriteEnable,
242
        memAAddr => memAAddr_stdlogic,
243
        memAWrite => memAWrite_stdlogic,
244
        memARead => memARead_stdlogic,
245
        memBWriteEnable => memBWriteEnable,
246
        memBAddr => memBAddr_stdlogic,
247
        memBWrite => memBWrite_stdlogic,
248
        memBRead => memBRead_stdlogic
249
        );
250
        memARead <= unsigned(memARead_stdlogic);
251
        memBRead <= unsigned(memBRead_stdlogic);
252
 
253
 
254
 
255
        tOpcode_sel <= to_integer(pc(minAddrBit-1 downto 0));
256
 
257
 
258
 
259
        -- move out calculation of the opcode to a seperate process
260
        -- to make things a bit easier to read
261
        decodeControl:
262
        process(memBRead, pc,tOpcode_sel)
263
                variable tOpcode : std_logic_vector(OpCode_Size-1 downto 0);
264
        begin
265
 
266
        -- simplify opcode selection a bit so it passes more synthesizers
267
        case (tOpcode_sel) is
268
 
269
            when 0 => tOpcode := std_logic_vector(memBRead(31 downto 24));
270
 
271
            when 1 => tOpcode := std_logic_vector(memBRead(23 downto 16));
272
 
273
            when 2 => tOpcode := std_logic_vector(memBRead(15 downto 8));
274
 
275
            when 3 => tOpcode := std_logic_vector(memBRead(7 downto 0));
276
 
277
            when others => tOpcode := std_logic_vector(memBRead(7 downto 0));
278
        end case;
279
 
280
                sampledOpcode <= tOpcode;
281
 
282
                if (tOpcode(7 downto 7)=OpCode_Im) then
283
                        sampledDecodedOpcode<=Decoded_Im;
284
                elsif (tOpcode(7 downto 5)=OpCode_StoreSP) then
285
                        sampledDecodedOpcode<=Decoded_StoreSP;
286
                elsif (tOpcode(7 downto 5)=OpCode_LoadSP) then
287
                        sampledDecodedOpcode<=Decoded_LoadSP;
288
                elsif (tOpcode(7 downto 5)=OpCode_Emulate) then
289
                        sampledDecodedOpcode<=Decoded_Emulate;
290
                elsif (tOpcode(7 downto 4)=OpCode_AddSP) then
291
                        sampledDecodedOpcode<=Decoded_AddSP;
292
                else
293
                        case tOpcode(3 downto 0) is
294
                                when OpCode_Break =>
295
                                        sampledDecodedOpcode<=Decoded_Break;
296
                                when OpCode_PushSP =>
297
                                        sampledDecodedOpcode<=Decoded_PushSP;
298
                                when OpCode_PopPC =>
299
                                        sampledDecodedOpcode<=Decoded_PopPC;
300
                                when OpCode_Add =>
301
                                        sampledDecodedOpcode<=Decoded_Add;
302
                                when OpCode_Or =>
303
                                        sampledDecodedOpcode<=Decoded_Or;
304
                                when OpCode_And =>
305
                                        sampledDecodedOpcode<=Decoded_And;
306
                                when OpCode_Load =>
307
                                        sampledDecodedOpcode<=Decoded_Load;
308
                                when OpCode_Not =>
309
                                        sampledDecodedOpcode<=Decoded_Not;
310
                                when OpCode_Flip =>
311
                                        sampledDecodedOpcode<=Decoded_Flip;
312
                                when OpCode_Store =>
313
                                        sampledDecodedOpcode<=Decoded_Store;
314
                                when OpCode_PopSP =>
315
                                        sampledDecodedOpcode<=Decoded_PopSP;
316
                                when others =>
317
                                        sampledDecodedOpcode<=Decoded_Nop;
318
                        end case;
319
                end if;
320
        end process;
321
 
322
 
323
        opcodeControl:
324
        process(clk, areset)
325
                variable spOffset : unsigned(4 downto 0);
326
        begin
327
                if areset = '1' then
328
                        state <= State_Resync;
329
                        break <= '0';
330
                        sp <= unsigned(spStart(maxAddrBit downto minAddrBit));
331
                        pc <= (others => '0');
332
                        idim_flag <= '0';
333
                        begin_inst <= '0';
334
                        memAAddr <= (others => '0');
335
                        memBAddr <= (others => '0');
336
                        memAWriteEnable <= '0';
337
                        memBWriteEnable <= '0';
338
                        out_mem_writeEnable <= '0';
339
                        out_mem_readEnable <= '0';
340
                        memAWrite <= (others => '0');
341
                        memBWrite <= (others => '0');
342
                        inInterrupt <= '0';
343
                elsif (clk'event and clk = '1') then
344
                        memAWriteEnable <= '0';
345
                        memBWriteEnable <= '0';
346
                        -- This saves ca. 100 LUT's, by explicitly declaring that the
347
            -- memAWrite can be left at whatever value if memAWriteEnable is
348
                        -- not set.
349
                        memAWrite <= (others => DontCareValue);
350
                        memBWrite <= (others => DontCareValue);
351
--                      out_mem_addr <= (others => DontCareValue);
352
--                      mem_write <= (others => DontCareValue);
353
                        spOffset := (others => DontCareValue);
354
                        memAAddr <= (others => DontCareValue);
355
                        memBAddr <= (others => DontCareValue);
356
 
357
                        out_mem_writeEnable <= '0';
358
                        out_mem_readEnable <= '0';
359
                        begin_inst <= '0';
360
                        out_mem_addr <= std_logic_vector(memARead(maxAddrBitIncIO downto 0));
361
                        mem_write <= std_logic_vector(memBRead);
362
 
363
                        decodedOpcode <= sampledDecodedOpcode;
364
                        opcode <= sampledOpcode;
365
                        if interrupt='0' then
366
                                inInterrupt <= '0'; -- no longer in an interrupt
367
                        end if;
368
 
369
                        case state is
370
                                when State_Execute =>
371
                                        state <= State_Fetch;
372
                                        -- at this point:
373
                                        -- memBRead contains opcode word
374
                                        -- memARead contains top of stack
375
                                        pc <= pc + 1;
376
 
377
                                        -- trace
378
                                        begin_inst <= '1';
379
                                        trace_pc <= (others => '0');
380
                                        trace_pc(maxAddrBit downto 0) <= std_logic_vector(pc);
381
                                        trace_opcode <= opcode;
382
                                        trace_sp <= (others => '0');
383
                                        trace_sp(maxAddrBit downto minAddrBit) <= std_logic_vector(sp);
384
                                        trace_topOfStack <= std_logic_vector(memARead);
385
                                        trace_topOfStackB <= std_logic_vector(memBRead);
386
 
387
                                        -- during the next cycle we'll be reading the next opcode       
388
                                        spOffset(4):=not opcode(4);
389
                                        spOffset(3 downto 0) := unsigned(opcode(3 downto 0));
390
 
391
                                        idim_flag <= '0';
392
                                        case decodedOpcode is
393
                                                when Decoded_Interrupt =>
394
                                                        sp <= sp - 1;
395
                                                        memAAddr <= sp - 1;
396
                                                        memAWriteEnable <= '1';
397
                                                        memAWrite <= (others => DontCareValue);
398
                                                        memAWrite(maxAddrBit downto 0) <= pc;
399
                                                        pc <= to_unsigned(32, maxAddrBit+1); -- interrupt address
400
                                                        report "ZPU jumped to interrupt!" severity note;
401
                                                when Decoded_Im =>
402
                                                        idim_flag <= '1';
403
                                                        memAWriteEnable <= '1';
404
                                                        if (idim_flag='0') then
405
                                                                sp <= sp - 1;
406
                                                                memAAddr <= sp-1;
407
                                                                for i in wordSize-1 downto 7 loop
408
                                                                        memAWrite(i) <= opcode(6);
409
                                                                end loop;
410
                                                                memAWrite(6 downto 0) <= unsigned(opcode(6 downto 0));
411
                                                        else
412
                                                                memAAddr <= sp;
413
                                                                memAWrite(wordSize-1 downto 7) <= memARead(wordSize-8 downto 0);
414
                                                                memAWrite(6 downto 0) <= unsigned(opcode(6 downto 0));
415
                                                        end if;
416
                                                when Decoded_StoreSP =>
417
                                                        memBWriteEnable <= '1';
418
                                                        memBAddr <= sp+spOffset;
419
                                                        memBWrite <= memARead;
420
                                                        sp <= sp + 1;
421
                                                        state <= State_Resync;
422
                                                when Decoded_LoadSP =>
423
                                                        sp <= sp - 1;
424
                                                        memAAddr <= sp+spOffset;
425
                                                when Decoded_Emulate =>
426
                                                        sp <= sp - 1;
427
                                                        memAWriteEnable <= '1';
428
                                                        memAAddr <= sp - 1;
429
                                                        memAWrite <= (others => DontCareValue);
430
                                                        memAWrite(maxAddrBit downto 0) <= pc + 1;
431
                                                        -- The emulate address is:
432
                                                        --        98 7654 3210
433
                                                        -- 0000 00aa aaa0 0000
434
                                                        pc <= (others => '0');
435
                                                        pc(9 downto 5) <= unsigned(opcode(4 downto 0));
436
                                                when Decoded_AddSP =>
437
                                                        memAAddr <= sp;
438
                                                        memBAddr <= sp+spOffset;
439
                                                        state <= State_AddSP;
440
                                                when Decoded_Break =>
441
                                                        report "Break instruction encountered" severity failure;
442
                                                        break <= '1';
443
                                                when Decoded_PushSP =>
444
                                                        memAWriteEnable <= '1';
445
                                                        memAAddr <= sp - 1;
446
                                                        sp <= sp - 1;
447
                                                        memAWrite <= (others => DontCareValue);
448
                                                        memAWrite(maxAddrBit downto minAddrBit) <= sp;
449
                                                when Decoded_PopPC =>
450
                                                        pc <= memARead(maxAddrBit downto 0);
451
                                                        sp <= sp + 1;
452
                                                        state <= State_Resync;
453
                                                when Decoded_Add =>
454
                                                        sp <= sp + 1;
455
                                                        state <= State_Add;
456
                                                when Decoded_Or =>
457
                                                        sp <= sp + 1;
458
                                                        state <= State_Or;
459
                                                when Decoded_And =>
460
                                                        sp <= sp + 1;
461
                                                        state <= State_And;
462
                                                when Decoded_Load =>
463
                                                        if (memARead(ioBit)='1') then
464
                                                                out_mem_addr <= std_logic_vector(memARead(maxAddrBitIncIO downto 0));
465
                                                                out_mem_readEnable <= '1';
466
                                                                state <= State_ReadIO;
467
                                                        else
468
                                                                memAAddr <= memARead(maxAddrBit downto minAddrBit);
469
                                                        end if;
470
                                                when Decoded_Not =>
471
                                                        memAAddr <= sp(maxAddrBit downto minAddrBit);
472
                                                        memAWriteEnable <= '1';
473
                                                        memAWrite <= not memARead;
474
                                                when Decoded_Flip =>
475
                                                        memAAddr <= sp(maxAddrBit downto minAddrBit);
476
                                                        memAWriteEnable <= '1';
477
                                                        for i in 0 to wordSize-1 loop
478
                                                                memAWrite(i) <= memARead(wordSize-1-i);
479
                                                        end loop;
480
                                                when Decoded_Store =>
481
                                                        memBAddr <= sp + 1;
482
                                                        sp <= sp + 1;
483
                                                        if (memARead(ioBit)='1') then
484
                                                                state <= State_WriteIO;
485
                                                        else
486
                                                                state <= State_Store;
487
                                                        end if;
488
                                                when Decoded_PopSP =>
489
                                                        sp <= memARead(maxAddrBit downto minAddrBit);
490
                                                        state <= State_Resync;
491
                                                when Decoded_Nop =>
492
                                                        memAAddr <= sp;
493
                                                when others =>
494
                                                        null;
495
                                        end case;
496
                                when State_ReadIO =>
497
                                        if (in_mem_busy = '0') then
498
                                                state <= State_Fetch;
499
                                                memAWriteEnable <= '1';
500
                                                memAWrite <= unsigned(mem_read);
501
                                        end if;
502
                                when State_WriteIO =>
503
                                        sp <= sp + 1;
504
                                        out_mem_writeEnable <= '1';
505
                                        out_mem_addr <= std_logic_vector(memARead(maxAddrBitIncIO downto 0));
506
                                        mem_write <= std_logic_vector(memBRead);
507
                                        state <= State_WriteIODone;
508
                                when State_WriteIODone =>
509
                                        if (in_mem_busy = '0') then
510
                                                state <= State_Resync;
511
                                        end if;
512
                                when State_Fetch =>
513
                                        -- We need to resync. During the *next* cycle
514
                                        -- we'll fetch the opcode @ pc and thus it will
515
                                        -- be available for State_Execute the cycle after
516
                                        -- next
517
                                        memBAddr <= pc(maxAddrBit downto minAddrBit);
518
                                        state <= State_FetchNext;
519
                                when State_FetchNext =>
520
                                        -- at this point memARead contains the value that is either
521
                                        -- from the top of stack or should be copied to the top of the stack
522
                                        memAWriteEnable <= '1';
523
                                        memAWrite <= memARead;
524
                                        memAAddr <= sp;
525
                                        memBAddr <= sp + 1;
526
                                        state <= State_Decode;
527
                                when State_Decode =>
528
                                        if interrupt='1' and inInterrupt='0' and idim_flag='0' then
529
                                                -- We got an interrupt, execute interrupt instead of next instruction
530
                                                inInterrupt <= '1';
531
                                                decodedOpcode <= Decoded_Interrupt;
532
                                        end if;
533
                                        -- during the State_Execute cycle we'll be fetching SP+1
534
                                        memAAddr <= sp;
535
                                        memBAddr <= sp + 1;
536
                                        state <= State_Execute;
537
                                when State_Store =>
538
                                        sp <= sp + 1;
539
                                        memAWriteEnable <= '1';
540
                                        memAAddr <= memARead(maxAddrBit downto minAddrBit);
541
                                        memAWrite <= memBRead;
542
                                        state <= State_Resync;
543
                                when State_AddSP =>
544
                                        state <= State_Add;
545
                                when State_Add =>
546
                                        memAAddr <= sp;
547
                                        memAWriteEnable <= '1';
548
                                        memAWrite <= memARead + memBRead;
549
                                        state <= State_Fetch;
550
                                when State_Or =>
551
                                        memAAddr <= sp;
552
                                        memAWriteEnable <= '1';
553
                                        memAWrite <= memARead or memBRead;
554
                                        state <= State_Fetch;
555
                                when State_Resync =>
556
                                        memAAddr <= sp;
557
                                        state <= State_Fetch;
558
                                when State_And =>
559
                                        memAAddr <= sp;
560
                                        memAWriteEnable <= '1';
561
                                        memAWrite <= memARead and memBRead;
562
                                        state <= State_Fetch;
563
                                when others =>
564
                                        null;
565
                        end case;
566
 
567
                end if;
568
        end process;
569
 
570
 
571
 
572
end behave;

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