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Wiki source code of 08 Macro Script

Version 42.1 by Devin Chen on 2023/06/30 17:43
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1 This chapter provides information about scripts in PIStudio.
2
3 = **Script type** =
4
5 Script is applied to realize complex control functions. HMI compile software provide powerful function, simple operation, reliable script system, the features of script are list as follow:
6
7 Similar to BASIC grammatical structure;
8
9 * BASIC work as the first computer language for the general public, it is easy and efficient to use.
10
11 Support all of program logic control structures;
12
13 * Software script supports three logic control structures: order, condition, loops. It could realize complexity procedures.
14
15 Powerful function; Functions of script are divided into two types: system and custom function.
16
17 * System function: the functions that system has been predefined for users.
18 * Custom function: users could define a function and apply to all scripts.
19
20 Support variety of data format;
21
22 * Script supports integer, floating, BCD code, byte, string and etc.
23
24 **Scripts Running Method**
25
26 1. **Background Script:** Run independently during start project, screen updates have no influence and valid of all scripts.
27 1. **Screen Script:** Only run under the designated screen. Screen script start running until screen is closed or switched.
28
29 And both screen and background have four modes for script
30
31 (% class="table-bordered" %)
32 |=**Property**|=**Description**
33 |Initialize|The script would be executed once during loading project.
34 |Close|The script would be run once during closing HMI project.
35 |Timing|The script would run under certain conditions after the HMI is started, until the condition ends.
36 |Bit trigger|Script would be repeat executed when meet the condition of bit trigger.
37
38 == Initialize ==
39
40 Initialize script divided into screen initialize script and background initialize script. Screen initialize script runs once during the initialization of screen; background initialize script runs during the loading of project.
41
42 **Operating procedures**
43
44 Click "Background script" in project manager to enter script editor screen, or click "Screen script" in right click menu of screen to enter script editor screen;
45
46 (% style="text-align:center" %)
47 [[image:9.Scripts_html_96fb2991c0580f0f.gif||class="img-thumbnail"]]
48
49
50 (% style="text-align:center" %)
51 [[image:9.Scripts_html_3cebb8edeabbd760.gif||class="img-thumbnail"]]
52
53 Double click "initialize" to open script edit window, as below shows;
54
55 (% style="text-align:center" %)
56 [[image:9.Scripts_html_8d93c592be893fad.gif||class="img-thumbnail"]]
57
58 Enter scripts in edit window;
59
60 == Close ==
61
62 Close script divided into screen close script and background close script. Screen close script runs once During the destroying of screen because of closing or switching; background close script runs during the closing of project (such as restart HMI, into HMI setup).
63
64 **Operating procedures**
65
66 1. Click "Background script" in project manager to enter script editor screen, or click "Screen script" in right click menu of screen to enter script editor screen;
67 1. Double click "Close" to open script edit window;
68 1. Enter scripts in edit window;
69
70 == Timing ==
71
72 The script would run for a designated time interval.
73
74 **Operating procedures of creating one**
75
76 Click "Background script" in project manager to enter script editor screen, or click "Screen script" in right click menu of screen to enter script editor screen;
77
78 Double click "Timing", it would pop-up below setting window;
79
80 (% style="text-align:center" %)
81 [[image:9.Scripts_html_ca0d08792c31539e.gif||class="img-thumbnail"]]
82
83 (% class="table-bordered" %)
84 |=**Property**|=**Description**
85 |Cycle|Script runs at designated time interval, unit is 10 ms.
86 |Ok|Script created.
87 |Cancel|Cancel the current script setting.
88
89 Enter scripts in edit window;
90
91 **Operating procedures of editing**
92
93 1. Click "Background script" in project manager to enter script editor screen, or click "Screen script" in right click menu of screen to enter script editor screen;
94 1. Select "Timing", and click [[image:9.Scripts_html_d1db672f9b0fe31.gif]] to modify the script execution interval;
95 1. Double click selected "Timing" to open editing window;
96
97 **Operating procedures of deleting**
98
99 Click "Background script" in project manager to enter script editor screen, or click "Screen script" in right click menu of screen to enter script editor screen;
100
101 (% style="text-align:center" %)
102 [[image:9.Scripts_html_f7b5302abd3000e3.gif||class="img-thumbnail"]]
103
104 Select "Timing", and click  [[image:9.Scripts_html_75dc3ed25fdbc359.gif]] to change interval of script, it pops-up above window
105
106 Select "Yes" to execute operation or select "No" to cancel operation;
107
108 (% class="box infomessage" %)
109 (((
110 **✎Note:** The maximum number of timing script for each screen or background is 32.
111 )))
112
113 == Trigger bit ==
114
115 **Introduction**
116
117 Trigger control script is that software will check whether the designated bit meet trigger condition every 20ms. Script execute once condition is met until project closed.
118
119 **Operating procedures of creating one**
120
121 Click "Background script" in project manager to enter script editor screen, or click "Screen script" in right click menu of screen to enter script editor screen;
122
123 Double click "Trigger bit", it pops-up below setting window;
124
125 (% style="text-align:center" %)
126 [[image:9.Scripts_html_5aa68df50f16cfa2.gif||class="img-thumbnail"]]
127
128 * Bit address: It sets trigger address for script;
129 * Condition: detailed information as below shows;
130
131 (% class="table-bordered" %)
132 |=**Condition**|=**Description**
133 |TRUE|Script execute once the bit value is TRUE, detects the bit every per approximately 20 ms;
134 |FALSE|Script execute once the bit value is FALSE, detects the bit every per approximately 20 ms;
135 |Bit changed|Execute once the trigger bit switches state;
136 |Rising|Script execute once the bit value from FALSE to TRUE, detects the bit every per approximately 20 ms;
137 |Falling|Script execute once the bit value from TURE to FALSE, detects the bit every per approximately 20 ms;
138
139 Set trigger bit and condition, click "OK" to open editing window.
140
141 **Operating procedures of editing**
142
143 * Click "Background script" in project manager to enter script editor screen, or click "Screen script" in right click menu of screen to enter script editor screen;
144 * Select "Trigger script", and click [[image:9.Scripts_html_d1db672f9b0fe31.gif]] to change trigger bit and condition;
145 * Double click selected "Trigger script" to open editing window.
146
147 **Operating procedures of deleting**
148
149 * Click "Background script" in project manager to enter script editor screen, or click "Screen script" in right click menu of screen to enter script editor screen;
150 * Select "Trigger script", and click [[image:9.Scripts_html_75dc3ed25fdbc359.gif]] to change interval of script, it pops-up below window
151
152 (% style="text-align:center" %)
153 [[image:9.Scripts_html_f7b5302abd3000e3.gif||class="img-thumbnail"]]
154
155 * Select "Yes" to execute operation or select "No" to cancel operation;
156
157 (% class="box infomessage" %)
158 (((
159 **✎Note:** The maximum number of trigger script for each screen or background is 32.
160 )))
161
162 == Background function ==
163
164 Global function is a collection of codes;it can be called in any script.The method reference system function;
165
166 **Operating procedures**
167
168 Double click "Background function" in project manager;
169
170 (% style="text-align:center" %)
171 [[image:9.Scripts_html_6240f0610ba63eff.gif||class="img-thumbnail"]]
172
173 Set parameters;
174
175 (% style="text-align:center" %)
176 [[image:9.Scripts_html_d196f8a817949f3e.gif||class="img-thumbnail"]]
177
178 (% class="table-bordered" %)
179 |**Property**|**Description**
180 |Function name|Function name could not be the same as existing.
181 |Return type|None, string, integer, float.
182 |Parameter 1|The name of parameter 1.
183
184 **Operating procedures of editing**
185
186 * Click "Background function" in project manager to enter script editor screen;
187 * Select Function name, and click [[image:9.Scripts_html_c653b64bc266a016.gif]] to change parameters;
188 * Double click selected "Trigger script" to open editing window;
189
190 **Operating procedures of deleting**
191
192 * Click "Background function" in project manager to enter script editor screen;
193 * Select Function name, and click  [[image:9.Scripts_html_75dc3ed25fdbc359.gif]] to change interval of script, it pops-up below window
194
195 (% style="text-align:center" %)
196 [[image:9.Scripts_html_f7b5302abd3000e3.gif||class="img-thumbnail"]]
197
198 * Select "Yes" to execute operation or select "No" to cancel operation;
199
200 (% class="box infomessage" %)
201 (((
202 **✎Note:** The maximum parameters for each function are 4, and parameter name can't be unique;
203 )))
204
205 = Script usage =
206
207 Script can make project more convenient and flexible. Script is useful in realizing complex HMI function. If the script is used improperly, it may affect the efficiency of entire project. So pay attention to the follow issues:
208
209 * Do not use too much script loops, if the script loops that execute too many times; it might influence the efficiency of HMI.
210 * In the cycle scripts, avoid using external register, due to the relatively slow serial communication, frequent access to external registers may cause the execution of scripts severely reduced, even influence the screen respond efficiently. There is fine to use internal register.
211 * The maximum script length is 512 rows.
212
213 This section describes how to edit scripts and use some of the accompanying tools and features of the script editor.
214
215 == **Script access to device** ==
216
217 Software script supports an efficiency way to access the device address by using symbol @.
218
219 (% class="table-bordered" %)
220 |=**Writing**|=**Meaning**|=**Examples**
221 |@B_;@b_;|Access designated bit address|(((
222 @B_I0.0:access bit address I0.0
223
224 @b_HDX0.0:access bit address HDX0.0
225 )))
226 |@W_;@w_;|(% rowspan="2" %)(((
227 Access designated word address
228
229 HMI connect more than automatic control devices, "#"stands for choosing number before the symbol,":"stands for accessing the station number before symbol.
230
231 Access the first protocol without "#",access default station number1 without":".
232 )))|(((
233 @W_IW0:access word address IW0
234
235 @b_HDW0:access word address HDW0
236 )))
237 |@B_(the number of protocol connection)#(station number):address|(((
238 @B_2#2:I0.0:access the bit address I0.0, with the connection number 2 and station number 2;
239
240 @B_I0.0:access to bit address I0.0;
241 )))
242
243 The script can access with the device though: write and read.
244
245 **For example**
246
247 {{code language="basic"}}
248 If @B_HDX0.0 = 1 then 'read the value from address HDX0.0.
249
250 @B_HDX0.0 = 0 'write 0 to address HDX0.0
251
252 Else
253
254 @B_HDX0.0 = 1 'write 1 to address HDX0.0
255
256 Endif
257
258 @W_QW0 = @W_QW0 + 1 'read data from address QW0, add 1 to this value then write to address QW0
259 {{/code}}
260
261 == **Grammar checking** ==
262
263 **Operating procedures**
264
265 1. Select [[image:9.Scripts_html_2a530bda982b4281.gif]] from script tool bar;
266 1. System does not prompt grammar error if grammar is correct, or system will list all errors;
267 1. Check error information, and modify errors;
268
269 **Error information**
270
271 ~1. Identifier ~*~** contains invalid characters
272
273 2. Attempt to redeclare sub ~*~**
274
275 3. Attempt to redeclare function ~*~**
276
277 4. Attempt to use reserved word ~*~** as identifier
278
279 5. Attempt to use type ~*~** as identifier
280
281 6. Unexpected ')' while parsing arguments for function ~*~**
282
283 7. Could not parse expression (one of the arguments of function ~*~**)
284
285 8. Could not parse arguments of ~*~**
286
287 9. Too many arguments for function ~*~**
288
289 10. Not enough arguments for function ~*~**
290
291 ~11. '(' expected after sub name ~*~**
292
293 12. Unexpected '(' while parsing arguments for sub ~*~**
294
295 13. Could not parse expression (one of the arguments of sub ~*~**)
296
297 14. Could not parse arguments of ~*~**
298
299 15. Too many arguments for sub/function ~*~**
300
301 16. Not enough arguments for sub/function ~*~**
302
303 17. Could not parse expression
304
305 18. '(' expected after function name ~*~**
306
307 19. Unexpected use of sub ~*~** as a part of expression
308
309 20. Illegal statements preceding subs/functions declaration
310
311 21. Unexpected end of file while looking for 'endsub'
312
313 22. End of line expected after 'else'.
314
315 23. End of line expected after 'endif'.
316
317 24. End of line expected after 'next'.
318
319 25. End of line expected after 'wend'.
320
321 26. 'while', 'until' or end of line expected afte r'do'.
322
323 27. Could not parse expression after 'while'
324
325 28. Could not parse expression after 'until'
326
327 29. 'do' without 'loop'
328
329 30. Sub ~*~** contains invalid character'@'
330
331 31. Sub ~*~** already declared
332
333 32. Function ~*~** already declared
334
335 33. Sub name expected after 'sub'
336
337 34. Function name expected after 'function'
338
339 35. Variable name expected
340
341 36. Argument ~*~** contains invalid character '@'
342
343 37. 'integer', 'floating' or 'string' expected
344
345 38. ''',' or ')' expected
346
347 39. 'endsub' without 'sub'
348
349 40. 'end function' without 'function'
350
351 41. End of line expected after 'beep'
352
353 42. 'dim' unexpected here
354
355 43. Variable name expected after 'dim'
356
357 44. 'as' expected after variable name
358
359 45. 'integer' 'floating' or 'string' expected after 'as'
360
361 46. ',' or end of line expected after type in dim statement
362
363 47. Could not parse expression after 'while'
364
365 48. End of line expected after' while' condition
366
367 49. 'while' without 'wend'
368
369 50. End of line expected after 'wend'
370
371 51. 'wend' without 'while'
372
373 52. Variable name expected after' for'
374
375 53. '=' expected after variable name
376
377 54. Could not parse expression after 'for'
378
379 55. 'to' expected
380
381 56. Could not parse expression after 'to'
382
383 57. Could not parse expression after 'step'
384
385 58. End of line expected
386
387 59. 'for' without 'next'
388
389 60. End of line expected after 'next'
390
391 61. 'Next' without 'for'
392
393 62. Could not parse expression after'if'
394
395 63. 'then' expected
396
397 64. Unexpected end of file while looking for 'endif'
398
399 65. Unexpected end of file while looking for 'else' or 'endif'
400
401 66. 'else' without ‘if'
402
403 67. 'end if' without 'if'
404
405 68. Label name expected after 'goto'
406
407 69. Unexpected end of line while looking for ')' in function call
408
409 70. ',' expected
410
411 71. Missing ')'
412
413 72. Unexpected end of line in expression
414
415 73. Unexpected end of file in expression
416
417 = **Script function list** =
418
419 == Mathematical ==
420
421 (% class="table-bordered" %)
422 |=(% style="width: 181px;" %)**Function**|=(% style="width: 1308px;" %)**Introduction**
423 |[[Abs>>||anchor="HAbs"]]|Get absolute value
424 |[[ACos>>||anchor="HACos"]]|Compute the inverse cosine value
425 |[[Asc>>||anchor="HAsc"]]|Return the first character of the string in ASCII value
426 |[[ASin>>||anchor="HASin"]]|Calculate the arcsine value
427 |[[ATan>>||anchor="HATan"]]|Return an arctangent value,the radian ranges -pi/2 to pi/2
428 |[[ATan2>>||anchor="HATan2"]]|Return the arctangent value
429 |[[Cos>>||anchor="HCos"]]|Return a cosine value of an angle
430 |[[Exp>>||anchor="HExp"]]|
431 |[[Hypot>>||anchor="HHypot"]]|Calculate the value of the hypotenuse of a right triangle
432 |[[Tan>>||anchor="HTan"]]|Implement tan calculation to computing the value
433 |[[Sin>>||anchor="HSin"]]|Implement sin calculation to computing the value
434 |[[Sqr>>||anchor="HSqr"]]|Assign a square root value
435 |[[SignedInt16>>||anchor="HSignedInt16"]]|Assign the value to [val] from address A1 which is signed integer
436 |[[SignedInt32>>||anchor="HSignedInt32"]]|Assign the value to [val] from address A1 which is signed even integer
437
438 == Data migration ==
439
440 (% class="table-bordered" %)
441 |=(% style="width: 178px;" %)**Function**|=(% style="width: 1311px;" %)**Introduction**
442 |[[BMOV>>||anchor="HBMOV"]]|Copy data with a designated length from source address
443 |[[FILL>>||anchor="HFILL"]]|Write the same value to designated address constantly
444 |[[SetKeyMap>>||anchor="HSetKeyMap"]]|The key values of the keyboard are mapped so that multiple keyboard buttons perform the same function
445
446 == Process control ==
447
448 (% class="table-bordered" %)
449 |=(% style="width: 181px;" %)**Function**|=(% style="width: 1308px;" %)**Introduction**
450 |[[Goto>>||anchor="HGoto"]]|Go to the designated row unconditionally in a function body
451 |FOR|Execute a command repeatedly for designated times
452 |[[End>>||anchor="HEnd"]]|End the execution of script
453 |while|If the condition is true, then all the commands before Wend in the statement will be executed and then recheck the condition, if the condition is false, the command after Wend will be executed
454
455 == Data conversion ==
456
457 (% class="table-bordered" %)
458 |=(% style="width: 182px;" %)**Function**|=(% style="width: 1307px;" %)**Introduction**
459 |[[A2H>>||anchor="HA2H"]]|Convert string A1 to hexadecimal number
460 |[[AsFloating>>||anchor="HAsFloating"]]|Convert parameter to a float
461 |[[AsInteger>>||anchor="HAsInteger"]]|Convert parameter to a integer
462 |[[AsString>>||anchor="HAsString"]]|Convert parameter to a string
463 |[[B2W>>||anchor="HB2W"]]|Convert an array
464 |[[BCD>>||anchor="HBCD"]]|Convert binary to BCD, save the result as return value
465 |[[BIN>>||anchor="HBIN"]]|Convert BCDto binary, save the result in return value
466 |[[Chr>>||anchor="HChr"]]|Convert integer parameter into correspond ASCII character,return the character string
467 |[[D2F>>||anchor="HD2F"]]|Convert the 32 bit integer format data to float then output the result
468 |[[D2Float>>||anchor="HD2Float"]]|Convert the designated value to floating then assign to variable
469 |[[D2Int>>||anchor="HD2Int"]]|Output the 32-bit integer in the form of integer
470 |[[DegToRad>>||anchor="HDegToRad"]]|Convert the angle into correspond radian, and display
471 |[[F2D>>||anchor="HF2D"]]|Convert a 32 bit floating to integer format, and then output the result
472 |[[F2S>>||anchor="HF2S"]]|Output a format of floating that in the type of string
473 |[[Float2D>>||anchor="HFloat2D"]]|Copy floating value to the address
474 |[[H2A>>||anchor="HH2A"]]| of ASCII
475 |[[Int2D>>||anchor="HInt2D"]]|Write the 32-bit integer into the specified address
476 |[[Lcase>>||anchor="HLcase"]]|Convert all parameters to lowercase strings
477 |[[MAX>>||anchor="HMAX"]]|Compare the value of A2 and A3, assign the greater number to A1
478 |[[MIN>>||anchor="HMIN"]]|Compare the value of A2 and A3, assign the smaller number to A1
479 |[[RadToDeg>>||anchor="HRadToDeg"]]|Convert radiant value to degree
480 |[[S2F>>||anchor="HS2F"]]|Convert string to floating in the specified format
481 |[[SWAP>>||anchor="HSWAP"]]|Exchange the high and low bytes of the parameter
482 |[[W2B>>||anchor="HW2B"]]|Combine the high byte of the value of two consecutive addresses into a new value
483 |[[W2D>>||anchor="HW2D"]]|Convert the unsigned Word to unsigned Dword and save the result
484 |[[W2F>>||anchor="HW2F"]]|Convert a 16bit integer to a 32bit floating, and then save to the next word address
485 |[[W2S>>||anchor="HW2S"]]|Convert integer word text as S1 format, and then save
486
487 == String processing ==
488
489 (% class="table-bordered" %)
490 |=(% style="width: 180px;" %)**Function**|=(% style="width: 1309px;" %)**Introduction**
491 |[[A2I>>||anchor="HA2I"]]|A string of length is intercepted from A1 and converted to a single/double word integer, and then this integer is assigned to A2
492 |[[InStr>>||anchor="HInStr"]]|Return the position of str1 in str2
493 |[[Left>>||anchor="HLeft"]]|Return a string of the specified length from the left side of parameter
494 |[[Len>>||anchor="HLen"]]|Return the string length
495 |[[LTrim>>||anchor="HLTrim"]]|Remove the left empty part of the string and return
496 |[[Mid>>||anchor="HMid"]]|Returns a string contain a specified characters length from a string
497 |[[Right>>||anchor="HRight"]]|Return a string of the specified length from the right side of parameter
498 |[[RTrim>>||anchor="HRTrim"]]|Clear the empty part on the right side of string [str], then assign the empty part to val
499 |[[Trim>>||anchor="HTrim"]]|Return a value of an address without empty string next to it
500 |[[UCase>>||anchor="HUCase"]]|Capitalize the string data, and then assign the value to val
501
502 == Fixed constant ==
503
504 (% class="table-bordered" %)
505 |=**Function**|=**Introduction**
506 |Pi|pi = 3.14159265358979321
507 |True|TRUE = 1
508 |False|FALSE = 0
509 |Operator|Operator in scripts edit window
510 |Variable|A variable is any factor, trait, or condition that can exist in differing amounts or types
511
512 == Bit control ==
513
514 (% class="table-bordered" %)
515 |=(% style="width: 178px;" %)**Function**|=(% style="width: 1311px;" %)**Introduction**
516 |[[Clrb>>||anchor="HClrb"]]|Set the bit of A1 as FALSE
517 |[[InvB>>||anchor="HInvB"]]|The state of inverse bit
518 |[[SetB>>||anchor="HSetB"]]|Set the bit A1 ON
519
520 == File operation ==
521
522 |=(% style="width: 168px;" %)**Function**|=(% style="width: 1338px;" %)**Introduction**
523 |(% style="width:168px" %)[[HmiRegoperator>>path:#HHmiRegoperator]]|(% style="width:1338px" %)Data of Upload/ Download address
524 |(% style="width:168px" %)[[CopyFile>>path:#HCopyFile]]|(% style="width:1338px" %)Copy the A3 file from the A1 directory to the A2 directory according to the format of A4 and A5
525 |(% style="width:168px" %)[[DbToCSVFile>>path:#HDbToCSVFile]]|(% style="width:1338px" %) file to csv format and export it
526 |(% style="width:168px" %)[[FileCmpDir>>path:#HFileCmpDir]]|(% style="width:1338px" %)The filename input and the filename in the folder whether is duplicate or not
527 |(% style="width:168px" %)[[MyDeleteFile>>path:#HMyDeleteFile]]|(% style="width:1338px" %)Delete the designated file
528 |(% style="width:168px" %)[[WriteWordToFile>>path:#HWriteWordToFile]]|(% style="width:1338px" %)Write data with designated length to designated file
529 |(% style="width:168px" %)[[ReadWordFormFile>>path:#HReadWordFormFile]]|(% style="width:1338px" %)Read data with designated length from designated file
530
531 == Comparison ==
532
533 (% class="table-bordered" %)
534 |=(% colspan="2" style="width: 389.5px;" %)Function|=Introduction
535 |(% rowspan="8" %)IF... THEN GOTO...|(% style="width:148.719px" %)IF=|(% rowspan="18" style="width:691.5px" %)Execute correspond instruction when fulfill condition. Condition will be tested during executing if. it will execute the next instruction block of then, if condition is true. Otherwise, execute the later of else. Complete the two instructions, next execute the later of End if.
536 |(% style="width:148.719px" %)IF<>
537 |(% style="width:148.719px" %)IF>
538 |(% style="width:148.719px" %)IF>=
539 |(% style="width:148.719px" %)IF<
540 |(% style="width:148.719px" %)IF<=
541 |(% style="width:148.719px" %)IF AND=0
542 |(% style="width:148.719px" %)IF AND<>0
543 |(% rowspan="8" style="width:255.281px" %)IF|(% style="width:148.719px" %)IF=
544 |(% style="width:148.719px" %)IF<>
545 |(% style="width:148.719px" %)IF>
546 |(% style="width:148.719px" %)IF>=
547 |(% style="width:148.719px" %)IF<
548 |(% style="width:148.719px" %)IF<=
549 |(% style="width:148.719px" %)IF AND=0
550 |(% style="width:148.719px" %)IF AND<>0
551 |(% colspan="2" style="width:389.5px" %)ELSE
552 |(% colspan="2" style="width:389.5px" %)ENDIF
553
554 == Application type ==
555
556 (% class="table-bordered" %)
557 |=(% style="width: 181px;" %)**Function**|=(% style="width: 1308px;" %)**Introduction**
558 |[[AddrStringCompare>>||anchor="HAddrStringCompare"]]|Compare the designated length of two character strings
559 |[[Beep>>||anchor="HBeep"]]|Enable buzzer
560 |[[IsFloating>>||anchor="HIsFloating"]]|whether a parameter is floating, return TRUE if it is floating, otherwise return FALSE
561 |[[IsInteger>>||anchor="HIsInteger"]]|whether a parameter(A1) is integer, return TRUE if the parameter is integer, otherwise return FALSE
562 |[[Log>>||anchor="HLog"]]|Log function: return the natural logarithm of the value
563 |[[Log10>>||anchor="HLog10"]]|Log function: return the natural logarithm of the value
564 |[[MSeconds>>||anchor="HMSeconds"]]|Display the current microseconds of system
565 |[[NewNoAddr>>||anchor="HNewNoAddr"]]|At the basic of source address A2,offset designated length,obtain a new address A1
566 |[[NewStatAddr>>||anchor="HNewStatAddr"]]|At the basic of source address A2,offset the designated length,to obtain a new station A1.
567 |[[NStringCompare>>||anchor="HNStringCompare"]]|Compare whether the designated length of two strings is the same,return 1 to A1 if yes,otherwise return 0
568 |[[Power>>||anchor="HPower"]]|The value of [expr2] to the power of [expr1] will be assigned to Var
569 |[[RAND>>||anchor="HRAND"]]|Generate a random number
570 |[[ReadAddr>>||anchor="HReadAddr"]]|Assign the value in the specified address to [word]
571 |[[SleepA>>||anchor="HSleepA"]]|Wait time T(ms)
572 |[[WriteAddr>>||anchor="HWriteAddr"]]|Assign the value from A2 to address A1
573
574 == Others ==
575
576 (% class="table-bordered" %)
577 |=(% style="width: 182px;" %)**Function**|=(% style="width: 1307px;" %)**Introduction**
578 |[[DIM...AS...>>||anchor="HDIM...AS..."]]|Declare a variable
579 |do|Condition determent instruction
580 |[[Function>>||anchor="HFunction"]]|Differ from internal function, need to declare the name, parameter, code of the function
581 |[[Sub>>||anchor="HSub"]]|Declare the name, parameters and codes of the Sub (sub function)
582 |[[PrintText>>||anchor="HPrintText"]]|Output the contents to the printer for printing
583 |[[PI_GetTickCount>>||anchor="HPI_GetTickCount"]]|Write the starting time in the set address as a 32-bit integer
584 |[[StAndFtChange>>||anchor="HStAndFtChange"]]|Calculate the number of seconds from January 1, 1970 to the current time
585 |[[GetServerDelayInfo>>||anchor="HGetServerDelayInfo"]]|Convert string to hexadecimal number
586
587 = **Function description** =
588
589 == A2H ==
590
591 **Function**
592
593 Val = A2H(A1)
594
595 **Description**
596
597 Convert string in the specified address to a hexadecimal number;
598
599 **Parameters**
600
601 * **A1:** Source data, only convert the first four digits of string
602 * **Val:** The value is hexadecimal number.
603
604 **Example**
605
606 {{code language="basic"}}
607 @W_HDW20=A2H(@W_HDW10) ' convert the string of HDW10 to hex then save in HDW20.
608 {{/code}}
609
610 **Input:** @W_HDW10=255
611
612 **Result:** @W_HDW20=255
613
614 (% class="box infomessage" %)
615 (((
616 **✎Note:**
617
618 * A1 needs to be address (such as:@W_HDW000002).
619 * Only [0~~1], [a~~f] can be converted, others will be converted to 0
620 )))
621
622 == A2I ==
623
624 **Function**
625
626 A2I (A1, A2, length, S)
627
628 **Description**
629
630 Intercept a string of the specified length from A1,convert it to a single/double word integer and assign this integer to A2.
631
632 **Parameters**
633
634 * **A1:** String to be intercepted
635 * **A2:** The final integer value
636 * **Length:** intercepts the length of the string
637 * **S:** Control single or double words.
638 ** S=0, indicating an integer single word; S=1, indicating an integer double word.
639
640 **Return value:** none
641
642 **Example**
643
644 {{code language="basic"}}
645 A2I("@W_HDW200","@W_HDW100",4,0) 'converts a string into a 16-bit (single word) decimal integer
646
647 A2I("@W_HDW600","@W_HDW500",4,1)' converts a string to a 32-bit (double word) decimal integer
648 {{/code}}
649
650 **Input: **@W_HDW200="12345", **Result:** @W_HDW100=1234
651
652 **Input: **@W_HDW600="12345", **Result:** @W_HDW500=1234
653
654 (% class="box infomessage" %)
655 (((
656 **✎Note:** A1 and A2 need to be address (such as:@W_HDW000002).
657 )))
658
659 == **Abs** ==
660
661 **Function**
662
663 val = Abs(A1)
664
665 **Description**
666
667 The absolute value of A1.
668
669 **Parameters**
670
671 * **A1: **the data of absolute value, need to be variable.
672 * **Val: **it is absolute value that is address or variable.
673
674 **Example**
675
676 {{code language="lua"}}
677 Dim a as integer 'a is defined as integer
678
679 a = SignedInt16("@W_HDW0")'convert the data of @W_HDW0 into signed data.
680
681 @W_HDW1 = Abs(a) 'assign the returned absolute value to @W_HDW1
682 {{/code}}
683
684 **Input: **@W_HDW0=-6
685
686 **Result: **@W_HDW1=6
687
688 (% class="box infomessage" %)
689 (((
690 **✎Note: SignedInt16** function is designed to convert unsigned to signed.
691 )))
692
693 == **ACos** ==
694
695 **Function**
696
697 val = ACos(A1)
698
699 **Description**
700
701 To compute the inverse cosine value of A1.
702
703 **Parameters**
704
705 * **A1: **floating value, can be an address or variable.
706 * **Val: **return value is floating, can be an address or variable.
707
708 **Example**
709
710 {{code language="lua"}}
711 Dim a ,b as floating'define two float variable a,b
712
713 a = 0.5 'assign the designated value to a
714
715 b = ACos(a) 'the inverse cosine value of "a" is a radian which assign to variable b.
716
717 'to add the following sentence if needed to view the return value:
718
719 float2d("@W_HDW200", b)'float b written into HDW200.
720 {{/code}}
721
722 **Result:** @W_HDW200=1.047
723
724 (% class="box infomessage" %)
725 (((
726 **✎Note:** Please call **RadToDeg** function to convert radian into angle.
727 )))
728
729 == **AddrStringCompare** ==
730
731 **Function**
732
733 val = AddrStringCompare(A1, A2, length)
734
735 **Description**
736
737 It is designed to compare the designated length of two character strings. The string value is 1 when the two strings are the same.
738
739 **Parameters**
740
741 * **A1, A2: **character string, need to be an address (such as:"@W_HDW000002")
742 * **Length: **The length of character string.
743 * **Val: **Return value, 0 or 1.
744
745 **Example**
746
747 {{code language="lua"}}
748 if AddrStringCompare("@W_HDW10","@W_HDW0",2)=1 then
749
750 'compare the character string of HDW10 and @W_HDW0 whether value are 1.
751
752 @W_HDW20=1 '@W_HDW20 display 1
753
754 else
755
756 @W_HDW20=0'@W_HDW20 display 0
757
758 Endif
759 {{/code}}
760
761 **Input: **@W_HDW10="1a2 ", @W_HDW0="1a2 ",
762
763 **Result:** @W_HDW20=1
764
765 **Input: **@W_HDW10="ab2 ", @W_HDW0="12a ",
766
767 **Result: **@W_HDW20=0
768
769 == **Asc** ==
770
771 **Function**
772
773 val = Asc(A1)
774
775 **Description**
776
777 Return the first character of the string in ASCII value.
778
779 **Parameters**
780
781 * **A1:**character string, it can be an address (such as: @W_HDW000002)
782 * **val:**return value,ASCII value,it could be an address or variable.
783
784 **Example**
785
786 {{code language="lua"}}
787 @W_HDW10 = Asc("A") 'return the ASCII value of A to HDW10
788
789 @W_HDW11 = Asc("a")'return the ASCII value of a to HDW11
790
791 @W_HDW12 = Asc("Apple") 'return the first character A of string Apple to HDW12
792
793 @W_HDW13 = Asc("123") 'return the first character ASCII value 1 of string 123 to HDW13.
794 {{/code}}
795
796 **Result:**
797
798 * @W_HDW10 = 65
799 * @W_HDW11 = 97
800 * @W_HDW12 = 65
801 * @W_HDW13 = 49
802
803 == **AsFloating** ==
804
805 **Function**
806
807 val = AsFloating(A1)
808
809 **Description**
810
811 Convert parameter A1 to a float.
812
813 **Parameters**
814
815 * A1: integer variable.
816 * **val: **return float value, can be a variable or address.
817
818 **Example**
819
820 {{code language="lua"}}
821 Dim a as integer 'define a integer variable {a}.
822
823 a = @W_HDW10 'assign @W_HDW10 to a
824
825 b = AsFloating(a) 'convert integer a to float then assign to b.
826
827 b = b/1.2 'add as following sentence when need to view the return value:
828
829 Float 2D("@W_HDW11",b) 'float variable b written into HDW11.
830 {{/code}}
831
832 **Input: **@W_HDW10=24,
833
834 **Result: **@W_HDW11=20.00(set two decimals)
835
836 == **ASin** ==
837
838 **Function**
839
840 val = ASin(A1)
841
842 **Description**
843
844 Calculate the arcsine value of A1.
845
846 **Parameters**
847
848 * **A1: **Float can be an address or variable.
849 * **Val: **Return float value, can be an address or variable.
850
851 **Example**
852
853 {{code language="lua"}}
854 Dim a, b as floating'define two float variable a,b
855
856 a = 0.5'assign the designated value to a
857
858 b=ASin(a) 'calculate the arcsine value of a ,assign the radian to b.
859
860 'Add the following command if need to view the return value:
861
862 float2d ("@W_HDW200", b) 'float variable b written into HDW200
863 {{/code}}
864
865 **Result: **@W_HDW200=0.524
866
867 (% class="box infomessage" %)
868 (((
869 **✎Note:** Pleasecall **RadToDeg** function to convert radian into angle.
870 )))
871
872 == **AsInteger** ==
873
874 **Function**
875
876 val = AsInteger(A1)
877
878 **Description**
879
880 Convert parameter A1 to integer value.
881
882 **Parameters**
883
884 * **A1: **floating need to be a variable.
885 * **Val: **the value returned could can be a variable or address.
886
887 **Example**
888
889 {{code language="lua"}}
890 Dim a as floating 'define floating variable a
891
892 a = D2Float("@W_HDW0",a) 'use D2Float function to save the float date of HDW0 in a
893
894 b= AsInteger(a) 'convert the float a into integer, the return value assigned to b
895
896 @W_HDW10=b 'save b to HDW10
897 {{/code}}
898
899 **Input:** @W_HDW0=20.12,
900
901 **Result:** @W_HDW10=20
902
903 == **AsString** ==
904
905 **Function**
906
907 val = AsString(A1)
908
909 **Description**
910
911 Convert parameter A1 to a character string.
912
913 **Parameters**
914
915 * A1: not string parameter, it can be a variable.
916 * Val: return string value, variable or address.
917
918 **Example**
919
920 Script 1:
921
922 {{code}}
923 a=123 'assign a value to a
924
925 b=234 'assign a value to b
926
927 c=AsString(a)+AsString(b) 'convert a and b to string then add up the two strings ,assign the result to c.
928
929 @W_HDW0=c 'assign c to HDW0
930
931 d=a+b 'plus a with b
932
933 @W_HDW100=d 'assign d to (HDW100)
934 {{/code}}
935
936 **Result: **
937
938 * @W_HDW0=123234
939 * @W_HDW100=357
940
941 Script 2:
942
943 {{code language="lua"}}
944 W2S("@W_HDW200","@W_HDW300","02d")
945
946 W2S("@W_HDW210","@W_HDW400","02d")
947
948 W2S("@W_HDW220","@W_HDW500","02d")
949
950 @W_HDW0=AsString(@W_HDW300)+AsString(@W_HDW400)+AsString(@W_HDW500)
951 {{/code}}
952
953 **Input: **@W_HDW200=12,@W_HDW210=34,@W_HDW220=56
954
955 **Result :**@W_HDW300=12,@W_HDW400=34,@W_HDW500=56,@W_HDW0=123456
956
957 (% class="box infomessage" %)
958 (((
959 **✎Note:** Ensure the data always is two words; otherwise occur error. reference the other chapter of W2S function
960 )))
961
962 == **ATan** ==
963
964 **Function**
965
966 var = ATan(A1)
967
968 **Description**
969
970 Return an arctangent value,the radian ranges -pi/2 to pi/2.
971
972 **Parameters**
973
974 * **A1: **Can be float, address or variable.
975 * **Val: **radian of return value.
976
977 **Example**
978
979 {{code language="basic"}}
980 @W_HDW20= Atan(@W_HDW10)'save the arctangent value of (HDW10) to (HDW20)
981 {{/code}}
982
983 **Input: **@W_HDW10=1.000,@W_HDW20=0.785
984
985 (% class="box infomessage" %)
986 (((
987 **✎Note:** Please call RadToDeg function convert radian to angle.
988 )))
989
990 == **ATan2** ==
991
992 **Function**
993
994 val = ATan2(A1,A2)
995
996 **Description**
997
998 Return the arctangent value of A1/A2,radian range
999
1000 **Parameters**
1001
1002 * **A1, A2:** Address or variable.
1003 * **Val: **returned value is a radian, range -pi to pi.
1004 * **Notice: **ATan2 use sign of two parameters to define the quadrant of return value.
1005
1006 **Example**
1007
1008 //{{code language="lua"}}@W_HDW20= ATan2 (@W_HDW10,@W_HDW12)'save the arctangent value of (HDW10/HDW12) to (HDW20).{{/code}}//
1009
1010 **Input:**@W_HDW10=1.0,@W_HDW12=1.0,
1011
1012 **Result: **@W_HDW20=0.785
1013
1014 (% class="box infomessage" %)
1015 (((
1016 **✎Note:** Please call **RadToDeg** function convert radian to angle.
1017 )))
1018
1019 == **B2W** ==
1020
1021 **Function**
1022
1023 B2W(A1, A2, length)
1024
1025 **Description**
1026
1027 Convert an array (begins with A2, unit: byte, to another array (begins with A1, unit: word).
1028
1029 **Parameters**
1030
1031 * **A1: **Saving address after converting
1032 * **A2: **Address of the value be converted 
1033 * **Length:** The length of conversion
1034
1035 **Return value: **None
1036
1037 **Example**
1038
1039 //{{code language="lua"}}B2W(@W_HDW100,@W_HDW10,2) 'convert (@W_HDW10) to the length of 2,save as the result that begins with @W_HDW100.{{/code}}//
1040
1041 **Input: **@W_HDW10=1A2B
1042
1043 **Result: **
1044
1045 * @W_HDW100=2B
1046 * @W_HDW101=1A
1047
1048 (% class="box infomessage" %)
1049 (((
1050 **✎Note:**
1051
1052 * A1 and A2 need to be address(e.g.: @W_HDW000002);
1053 * Length could be address or variable;
1054 * This is a subprogram; it has no returned value.
1055 )))
1056
1057 == **BCD** ==
1058
1059 **Function**
1060
1061 val = BCD(A1)
1062
1063 **Description**
1064
1065 Convert A1(binary) to BCD, save the result as return value.
1066
1067 **Parameters**
1068
1069 * **A1: **The binary be converted; it can be an address or variable.
1070 * **Val: **Return value, BCD code; it can be an address or variable.
1071
1072 **Example**
1073
1074 //{{code language="lua"}}@W_HDW20=BCD(@W_HDW10) 'convert HDW10 (binary) to BCD code, then save in (HDW20){{/code}}//
1075
1076 **Input:** @W_HDW10=11111111(binary)
1077
1078 **Result:** @W_HDW20=255
1079
1080 (% class="box infomessage" %)
1081 (((
1082 **✎Note:** Return value is a word; it hexadecimal corresponds to BCD code.
1083 )))
1084
1085 == **Beep** ==
1086
1087 **Function**
1088
1089 Beep()
1090
1091 **Description**
1092
1093 Enable buzzer
1094
1095 **Parameters**
1096
1097 None
1098
1099 **Example**
1100
1101 {{code language="lua"}}
1102 if @B_HDX100.0=1 then 'beep when the bit switch HDX100.0 set ON
1103
1104 beep()
1105
1106 endif
1107 {{/code}}
1108
1109 **Result: **HMI beep when bit switch HDX100.0 set ON.
1110
1111 == **BIN** ==
1112
1113 **Function**
1114
1115 Val = BIN(A1)
1116
1117 **Description**
1118
1119 Convert A1 (BCD) into binary, save the result in return value.
1120
1121 **Parameters**
1122
1123 * **A1:** The BCD code is converted; it can be address or variable.
1124 * **Val:** Return binary value,it can be address or variable.
1125
1126 **Example**
1127
1128 //{{code language="lua"}}@W_HDW20=BIN(@W_HDW10) 'convert HDW10(BCD) to binary, save the result in (HDW20){{/code}}//
1129
1130 **Input:** @W_HDW10=255
1131
1132 **Result:** @W_HDW20=11111111 (binary)
1133
1134 == **BMOV** ==
1135
1136 **Function**
1137
1138 BMOV(A1, A2,length)
1139
1140 **Description**
1141
1142 Copy data with a designated length from source address A2 to A1.
1143
1144 **Parameter**
1145
1146 * **A1:** saving address;
1147 * **A2:** source address;
1148
1149 **length:** operating length;
1150
1151 **Example**
1152
1153 {{code language="lua"}}
1154 @W_HDW20 = 20 'assign value to HDW20
1155
1156 @W_HDW21 = 21 'assign value to HDW21
1157
1158 @W_HDW22 = 22 'assign value to HDW22
1159
1160 BMOV(@W_HDW10,@W_HDW20,3) 'assign the word address of HDW20, HDW21, HDW22 to HDW10, HDW11, HDW12
1161 {{/code}}
1162
1163 **Result:**
1164
1165 * @W_HDW10 = 20
1166 * @W_HDW11 = 21
1167 * @W_HDW12 = 22
1168
1169 **✎Note:**
1170
1171 * A1 and A2 need to be address
1172 * Length can be an integer variable or an address. When destAddr and srcAddr are PLC (external device) addresses, the length range is 1-2048, and the 2049th address would not be operated when the range is exceeded.
1173 * When destAddr and srcAddr are HMI addresses, the length range is 1-4096, and This function is invalid when out of range.
1174
1175 == **Chr** ==
1176
1177 **Function**
1178
1179 val = Chr(A1, A2, ...)
1180
1181 **Description**
1182
1183 Convert integer parameter into correspond ASCII character, return the character string.
1184
1185 **Parameters**
1186
1187 * **A1, A2....:** converted integer; it can be an address or variable.
1188 * **Val: **returned value, can be an address or variable.
1189
1190 **Example**
1191
1192 {{code language="lua"}}
1193 @W_HDW100=Chr(@W_HDW20, @W_HDW21, @W_HDW22, @W_HDW23, @W_HDW24)
1194
1195 'convert the value of(HDW20, HDW21 ,HDW22, HDW23, HDW24) to ASCII character, assign the value to (HDW100)
1196 {{/code}}
1197
1198 **Input** 72,69,76,76,79 step by step according to HDW20, HDW21, HDW22, HDW23, HDW24,
1199
1200 **Result: **returns HELLO to (@W_HDW100).
1201
1202 == **Clrb** ==
1203
1204 **Function**
1205
1206 ClrB(A1)
1207
1208 **Description**
1209
1210 Set the bit of A1 as FALSE (0).
1211
1212 **Parameters**
1213
1214 **A1:** System address(bit)
1215
1216 **✎Note:** subprogram has no return value.
1217
1218 **Example**
1219
1220 //{{code language="lua"}}ClrB(@B_HDX100.0) 'assign 0 to (@B_HDX100.0){{/code}}//
1221
1222 == **Constant** ==
1223
1224 **Description**
1225
1226 Script supported constant, users can use on script:
1227
1228 pi = 3.14159265358979321
1229
1230 TRUE = 1
1231
1232 FALSE = 0
1233
1234 **Example**
1235
1236 {{code language="lua"}}
1237 Dim a as integer 'define integer a
1238
1239 a = RadToDeg(pi) 'convert radian pi to angle then assign to a,RadToDeg function is used to convert radian to angle.
1240
1241 @W_HDW11 = a 'assign a to (HDW11)
1242 {{/code}}
1243
1244 **Result: **@W_HDW11=180
1245
1246 == **CopyFile** ==
1247
1248 **Function**
1249
1250 A6=CopyFile(A1,A2,A3,A4,A5)
1251
1252 **Description**
1253
1254 Copy the A3 file from the A1 directory to the A2 directory according to the format of A4 and A5, and write returned value status to A6.
1255
1256 **Parameters**
1257
1258 * **A1: **the source path of the file to be copied.
1259 * **A2: **target path.
1260 * **A3:** the name of the file to be copied.
1261 * **A4: **copy type (0: copy file, 1: copy directory).
1262 * **A5: **Whether to overwrite the file with the same name when copying (0: Yes, 1: No).
1263 * **A6: **returned value.
1264 ** 0: copy failed
1265 ** 1: copy succeeded
1266 ** 2: Parameter error
1267 ** 3: U disk does not exist
1268 ** 4: SD card does not exist
1269 ** 5: Path error
1270
1271 **Example**
1272
1273 Copy a single file:
1274
1275 {{code language="lua"}}
1276 @W_HDW100 = " test.csv"
1277
1278 CopyFile("UDisk/Test","Flash/Test","test.csv",0,0) 'Copy the Test.csv file in the UDisk/Test directory to the Flash/Test directory.
1279
1280 Can also be written as CopyFile("UDisk/Test","Flash/Test",@W_HDW100,0,0)
1281
1282 (2) Copy the entire directory file:
1283
1284 CopyFile("UDisk/Test","Flash/Test","",1,0) ' Copy the files in the UDisk/Test
1285
1286 directory to the Flash/Test directory.
1287 {{/code}}
1288
1289 (% class="box infomessage" %)
1290 (((
1291 **✎Note:**
1292
1293 * Both source and destination paths need to begin with UDisk or Flash or SDCard;
1294 * A1 and A2 could be string (requires double quotes) or variable, maximum character length 127 allowed in path;
1295 * A3 could be a string, such as: [FileName] (requires double quotes); or address, such as: @W_HDW100 (no need to add double quotes);
1296 * A4 and A5 could be values, addressesor variable;
1297 * A6 could be address or variable.
1298 )))
1299
1300 == **Cos** ==
1301
1302 **Function**
1303
1304 Val = Cos(A1)
1305
1306 **Description**
1307
1308 Return a cosine value of an angle.
1309
1310 **Parameters**
1311
1312 * **A1: **a float radian of angle, it can be an address or variable.
1313 * **Val: **return float value, it can be an address or variable.
1314
1315 **Example**
1316
1317 {{code language="lua"}}
1318 Dim a, b as floating 'define float a, b
1319
1320 b = pi/3 'convert the value of HDW11 to float and assign to 'b'.
1321
1322 a=Cos(b) 'return the cosine value of'b' and assign the result to 'a'.
1323
1324 'to add the following sentence if need to view the return value:
1325
1326 Float2D("@W_HDW20",a) 'the float value of a written into HDW13.
1327 {{/code}}
1328
1329 **Result: **@W_HDW20=0.5
1330
1331 (% class="box infomessage" %)
1332 (((
1333 **✎Note:** Please call **RadToDeg** function convert radian to angle.
1334 )))
1335
1336 == **D2F** ==
1337
1338 **Function**
1339
1340 D2F (A1, A2) or A1= D2F (A1, A2)
1341
1342 **Description**
1343
1344 Convert the 32-bit integer format data to float then output the result.
1345
1346 **Parameters**
1347
1348 * **A1: **required data, begin with"@";
1349 * **A2: **source data, begin with"@";
1350
1351 **Example**
1352
1353 {{code language="lua"}}
1354 D2F(@W_HDW2,@W_HDW0) 'convert the double word (HDW0) to float, save the result to (HDW2).
1355
1356 @W_HDW2=D2F(@W_HDW2,@W_HDW0) 'convert the double word (HDW0) to float, save the result to (HDW2).
1357 {{/code}}
1358
1359 **Result: **HDW0=100, HDW2=100
1360
1361 == **D2Float** ==
1362
1363 **Function**
1364
1365 F= D2Float("A1",F)
1366
1367 **Description**
1368
1369 Convert the designated value to floating then assign to variable.
1370
1371 **Parameters**
1372
1373 * **A1:** Source data;
1374 * **F:** User-defined floating variable
1375
1376 **Example**
1377
1378 {{code language="lua"}}
1379 dim F as floating 'define F as floating
1380
1381 F=D2Float("@W_HDW10",F) 'assign the value of (HDW10) to F in floating
1382
1383 Float2D("@W_HDW12",F) 'copy the floating value of F to HDW12 register,use to display result.
1384 {{/code}}
1385
1386 **Result: **
1387
1388 * HDW10=200,
1389 * HDW12=200.
1390
1391 (% class="box infomessage" %)
1392 (((
1393 **✎Note:** A1 needs to be address;
1394 )))
1395
1396 == **D2Int** ==
1397
1398 **Function**
1399
1400 A2= D2Float("A1",A2)
1401
1402 **Description**
1403
1404 Output the 32-bit integer in the form of integer.
1405
1406 **Parameters**
1407
1408 * **A1:** Source data can only be the HMI internal or external register starting with "@".
1409 * **A2: **Target data can only use theinteger variable defined by script.
1410
1411 **Example**
1412
1413 {{code language="basic"}}
1414 dim var1 as integer 'define var1 as integer
1415
1416 var1=D2Int("@W_HDW0",var1) 'Read out the 32-bit integer in HDW0 and save the result in var1.
1417
1418 HDW0=9999999
1419 {{/code}}
1420
1421 **Result:** Var1=9999999
1422
1423 == **DataLogToUorSD** ==
1424
1425 **Function**
1426
1427 DataLogToUorSD (A1, A2, A3, A4, A5, A6, A7, A8)
1428
1429 **Description**
1430
1431 Exported Data record (database file) as db or csv format file, and register HSW1853 can change the exported file type.
1432
1433 (HSW1853 = 0: exported as db format, filename format: Start time-end time-group name.db)
1434
1435 (HSW1853 = 1: exported as csv format, filename format: Start time-end time-group name.csv)
1436
1437 **Parameters**
1438
1439 * A1: Data record group name address (string, must be address). For example: " @W_HDW30 "
1440 * A2: Start time address (string, must be address). For example: " @W_HDW40 "
1441 * A3: End time address (string, must be address). For example: " @W_HDW50 "
1442 * A4: db file save location (integer value)
1443 ** = 1: Saved on SD card
1444 ** = 2: Save in USB flash drive
1445 * A5: Return value(string, must be address). For example: " @W_HDW60 ", return result of the script will be written to HDW60; Meaning of value in address:
1446 ** = 1: Script executed successfully
1447 ** = 100: U disk or SD card unplugged
1448 ** = 101: U disk or SD card does not exist
1449 ** = 102: Script executed failed
1450 ** = 201: db export failed
1451 ** = 203: Script is being executed (previous executed script doesn't exit)
1452 * A6: Script running mode (integer value)
1453 ** = 1: Wait for script execution before exit
1454 ** = Others: Exit without waiting for the result of script execution (when the data record volume is large, it takes some time to execute the script, and when wait for the result of script execution, it may affect the execution of other scripts)
1455 * A7: Path name address (string, must be address). For example: " @W_HDW70 ", script will automatically prefix the folder name HMI_, for example: @W_HDW70 = "Log", the db file will be saved under the directory of HMI_Log in U disk or SD.
1456 * A8: Reserved address (string, must be address). For example:" @W_HDW80 ". This address is temporarily useless but needs to be set.
1457
1458 **Example**
1459
1460 {{code language="basic"}}
1461 @W_HDW30 = "Record test" 'Data record group name
1462 @W_HDW40 = 2021
1463 @W_HDW41 = 04
1464 @W_HDW42 = 30
1465 @W_HDW43 = 09
1466 @W_HDW44 = 0
1467 @W_HDW45 = 0
1468 'Start time 2021-04-30 09:00:00
1469 @W_HDW50 = 2021
1470 @W_HDW51 = 04
1471 @W_HDW52 = 30
1472 @W_HDW53 = 20
1473 @W_HDW54 = 0
1474 @W_HDW55 = 0
1475 'End time 2021-04-30 20:00:00
1476 @W_HDW70 = "Log" 'Directory name
1477
1478 DataLogToUorSD ("@ W_HDW30", "@ W_HDW40", "@ W_HDW50", 2, "@ W_HDW60", 1, "@ W_HDW70", "@ W_HDW80")
1479
1480 'Export the data records collected from 2021-04-30 09:00:00 to 2021-04-30 20:00:00 under the group name of the record test to the HMI_Log directory of the U disk with the file name being 20210430090000-20210430200000-record tests. db. (HSW1853 is 0).
1481 {{/code}}
1482
1483 == **DbToCSVFile** ==
1484
1485 **Function**
1486
1487 A8=DbToCSVFile(A1,A2,A3,A4,A5,A6,A7)
1488
1489 **Description**
1490
1491 Convert db (database file) file to csv format and export it.
1492
1493 **Parameters**
1494
1495 * **A1: **db file save path (value is integer);
1496 ** =0: Alarm record file in HMI flash;
1497 ** =1: Alarm record file in UDisk (USB flash disk);
1498 ** =2: Alarm record file in SD card;
1499 ** =3: Data record file in HMI flash;
1500 ** =4: Data record file in UDisk (USB flash disk);
1501 ** =5: Data record file in SD card;
1502 * **A2: **group numer of db file (value is integer);
1503 ** Used during exporting data record file, the group number could be seen in the data record setting interface;
1504 * **A3:** csv file save path (value is integer);
1505 ** =0: Save in UDisk (USB flash disk);
1506 ** =1: Save in SD card;
1507 * **A4: **csv name;
1508 * **A5: **start time of data recordin db file(string), consecutive 6 word addresses (the values in the address are year, month, day, hour, minute, second);
1509 * **A6:** end time of data recordin db file(string), consecutive 6 word addresses (the values in the address are year, month, day, hour, minute, second);
1510 * **A7:** csv encoding format;
1511 ** =0 UTF8 format;
1512 ** =1 GBK format;
1513 * **A8:** returned value;
1514 ** =0: Failed to export;
1515 ** =1: Exported;
1516 ** =2: db file path error;
1517 ** =3: U disk or SD card does not exist;
1518 ** =4: csv name error;
1519 ** =5: db file does not exist;
1520 ** =6: csv file already exists;
1521
1522 **Example**
1523
1524 * @W_HDW100 = 2018
1525 * @W_HDW101 = 12
1526 * @W_HDW102 = 25
1527 * @W_HDW103 = 19
1528 * @W_HDW104 = 10
1529 * @W_HDW105 = 30
1530 * @W_HDW200 = 2018
1531 * @W_HDW201 = 12
1532 * @W_HDW202 = 25
1533 * @W_HDW203 = 20
1534 * @W_HDW204 = 10
1535 * @W_HDW205 = 30
1536
1537 **Export data record file**
1538
1539 {{code language="basic"}}
1540 DbToCsvFile(3,2,0,"123.csv","@W_HDW100","@W_HDW200",0)
1541 'In the HMI flash, the group number is 2, and the data records collected in the time of 2010.12.25 19:10:30-2018.12.25 20:10:30
1542 'are exported to the 123.csv file in the Udisk in UTF8 format.
1543 {{/code}}
1544
1545 **Export alarm record file**
1546
1547 {{code language="basic"}}
1548 DbToCsvFile(0,0,0,"456.csv","@W_HDW100","@W_HDW200",1)
1549 'The alarm records generated in HMI Flash at 2018.12.25 19:10:30-2018.12.25 20:10:30
1550 'are exported to the 456.csv file in the Udisk in GBK format
1551 {{/code}}
1552
1553 (% class="box infomessage" %)
1554 (((
1555 **✎Note:**
1556
1557 * A1 can be an address or a variable or a value, and the path need to start with UDisk or Flash or SDCard;
1558 * A2 can be an address or a variable or a value;
1559 * A3 can be an address or a variable or a value, and the path need to start with UDisk or Flash or SDCard;
1560 * A4 can be an address or variables or string, and the length of the file name (sum of values, English, Chinese) could not exceed 127;
1561 * A5 need to be an address;
1562 * A6 need to be an address;
1563 * A7 can be an address or a variable or a value;
1564 )))
1565
1566 == **DegToRad** ==
1567
1568 **Function**
1569
1570 A2 = DegToRad(A1)
1571
1572 **Description**
1573
1574 Convert the angle into correspond radian, and display.
1575
1576 **Parameters**
1577
1578 * **A1:** inputting angle supports address, other variable or floating.
1579 * **A2: **outputting radian supports address, other variable or floating.
1580
1581 **Example**
1582
1583 Script 1
1584
1585 //{{code language="lua"}}@W_HDW12=DegToRad(@W_HDW10) 'input angle on (HDW10),convert to correspond redian and copy to (HDW12){{/code}}//
1586
1587 **Result: **HDW10=180; HDW12=3.14159
1588
1589 Script 2
1590
1591 {{code language="lua"}}
1592 dim a as floating 'set variable
1593
1594 dim b as floating 'set variable
1595
1596 b=30 'input angle
1597
1598 a=DegToRad(b) 'convert the length of radian and copy to variable {a}
1599
1600 float2d("@W_HDW0", a) 'display the value of floating on(HDW0)
1601 {{/code}}
1602
1603 **Result:** HDW0=0.52360
1604
1605 == **DIM ... AS ...** ==
1606
1607 **Function**
1608
1609 Dim "variable" as "date type"
1610
1611 **Description**
1612
1613 Declare a variable, stable the type of data.
1614
1615 **Parameters**
1616
1617 * **Variable: **begin with letter, other character can be letter, numbers, underscores ('_'), need to begin with '@' if it is address;
1618 * **Data type: **string,floating,integer;
1619
1620 **Example**
1621
1622 {{code language="lua"}}
1623 dim a as integer 'define a as integer
1624
1625 dim @W_HDW0 as floating 'define @W_HDW0 as floating
1626
1627 dim hi as string 'define "hi" as string
1628 {{/code}}
1629
1630 **Result:**
1631
1632 a is integer
1633
1634 @W_HDW0 is floating
1635
1636 hi is string
1637
1638 (% class="box infomessage" %)
1639 (((
1640 **✎Note:** Use the variable of Dim during running, could not change the type, Dim will be missed if the type of variable is no difined. Variable could be declared in once.
1641 )))
1642
1643 == **DO ... LOOP** ==
1644
1645 **Function**
1646
1647 Do [While | Until condition]
1648
1649 [statements]
1650
1651 Loop
1652
1653 or
1654
1655 Do
1656
1657 [statements]
1658
1659 Loop [While | Until condition]
1660
1661 **Description**
1662
1663 Condition determent instruction.
1664
1665 * Do while.loop executes an instruction of block repeatedly when condition is true.
1666 * Do until.loop executes an instruction of block repeatedly until condition is false.
1667
1668 **Parameters**
1669
1670 **Condition: **determine condition; obtain the expression of True or False.
1671
1672 **Statements: **execute one or more instructions repeatedly when condition is True or until condition is True.
1673
1674 If condition is true, all statements are executed until the Wend statement is encountered. Control then returns to the While statement and condition is again checked. If condition is still True, the process is repeated. If it is not true, execution resumes with the statement following the Wend statement.
1675
1676 **Example**
1677
1678 {{code language="lua"}}
1679 dim i as integer 'end DO loop when i=100
1680
1681 do while i<100
1682
1683 i=i+1
1684
1685 @W_HDW0=i
1686
1687 loop
1688 {{/code}}
1689
1690 **Result: **HDW0=100
1691
1692 == **End** ==
1693
1694 **Function**
1695
1696 Terminates the script immediately.
1697
1698 **Description**
1699
1700 End the execution of script.
1701
1702 **Parameters**
1703
1704 **Statement:** Judging condition, use with IF together. end script when meet condition.
1705
1706 **Example**
1707
1708 //{{code language="lua"}}If a = 10 Then End 'end script when a=10.{{/code}}//
1709
1710 **Result:** End the script program.
1711
1712 == **Exp** ==
1713
1714 **Function**
1715
1716 A1=Exp(A2)
1717
1718 **Description**
1719
1720 Returns the power value of e (natural logarithm), save the outputting result to A1, e=2.71828182846.
1721
1722 **Parameters**
1723
1724 * **A1: **the goal date: the power floating value of returning, need to begin with '@'([[(% class="wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink wikiinternallink" %)__e.g.@W_HDW10__>>path:mailto:'@'(e.g.@W_HDW10]](%%));
1725 * **A2: **Source data, natural exponential function, need to be integer or variable. Could not not begin with the address of "@"(e.g.@W_HDW10)
1726
1727 **Example**
1728
1729 {{code language="lua"}}
1730 dim a as integer'define a as integer
1731
1732 a = @W_HDW2 ' assign the value of (HDW2) to variable a
1733
1734 @W_HDW0= Exp(a)'exponential is the value of (HDW2),save result to(HDW0)
1735 {{/code}}
1736
1737 **Result:**
1738
1739 * HDW2=2,
1740 * HDW0=7.38905600
1741
1742 == **F2D** ==
1743
1744 **Function**
1745
1746 F2D (A1, A2)
1747
1748 **Description**
1749
1750 Convert a 32 bit floating to integer format, then output the result.
1751
1752 **Parameters**
1753
1754 * **A1: **Destination, the value can be an address(e.g.@W_HDW12).
1755 * **A2: **source date, it can be an address or other variable.
1756
1757 **Example**
1758
1759 //{{code language="lua"}}F2D(@W_HDW12,@W_HDW10) 'convert the floating of (HDW10) to integer, save in (HDW12).{{/code}}//
1760
1761 **Result:**
1762
1763 * HDW10=200,
1764 * HDW12=200
1765
1766 == **F2S** ==
1767
1768 **Function**
1769
1770 F2S (A1,A2,s1)
1771
1772 **Description**
1773
1774 Output a format of floating that in the type of string.
1775
1776 **Parameters**
1777
1778 * **A1:** Source address, used to store floating, the value is an address(e.g.@W_HDW200);
1779 * **A2:** Destination address, used to store string after converted, value is an address(e.g.@W_HDW100).
1780 * **S1:** the format of displaying goal data. such as the format of 03.03f,f, used for outputting a single-precision in the form of decimal.m.nf:means m column and n decimals when outputting.
1781
1782 **Example**
1783
1784 //{{code language="lua"}}F2S("@W_HDW200", "@W_HDW100", "03.03f") '(HDW200) is floating input,(HDW100) is text output;{{/code}}//
1785
1786 **Result: **
1787
1788 * HDW200=1.22365,
1789 * HDW100=1.224
1790
1791 == **FileCmpDir** ==
1792
1793 **Function**
1794
1795 FileCmpDir(A1, A2, A3, A4, A5, A6, A7, A8, A9)
1796
1797 **Description**
1798
1799 The filename input and the filename in the folder whether is duplicate or not.
1800
1801 **Parameters**
1802
1803 A1: file path (value is integer);
1804
1805 In HMI:
1806
1807 * =0: Recipe folder in HMI flash;
1808 * =1: Custom folder in UDisk (USB flash disk);
1809 * =2: Custom folder in SD card.
1810 * =3: Custom folder in HMI flash;
1811
1812 In simulator:
1813
1814 * = 0: D:/Recipe/
1815 * = 1: C:/WECON/CustomFileDir/
1816 * = 2: C:/WECON/CustomFileDir/
1817 * = 3: C:/WECON/CustomFileDir/
1818
1819 **✎Note:**
1820
1821 A1 can be an address,variable or fixed value.
1822
1823 A2: file name (value is string);
1824
1825 The file name would be compared;
1826
1827 **✎Note: **
1828
1829 A2 can be an address, variable or string. The length of file name cannot exceed 32 characters.
1830
1831 A3: folder name (value is integer);
1832
1833 The folder name would be compared;
1834
1835 **✎Note: **
1836
1837 A3 can be an address, variable or string. The length of file name cannot exceed 32 characters.
1838
1839 A4:file name display address (value is a string);
1840
1841 Display the specified number of file names in the specified folder.
1842
1843 **✎Note:**
1844
1845 A4 Can only use address here. And the length of the file name cannot exceed 32 characters.
1846
1847 A5: Function type (value is an integer)
1848
1849 ~= 0: compare whether the file name in the folder and the file name input are duplicated or not.
1850
1851 ~= 1: return list of file names.
1852
1853 ~= 100: compare file names, without input suffix .csv
1854
1855 **✎Note: **
1856
1857 A5 can be an address, variable or value.
1858
1859 A6: Return value (value is an integer)
1860
1861 ~= 1: Successfully opened the folder.
1862
1863 ~= 2: Failed to open the folder.
1864
1865 ~= 3: The file has duplicate names
1866
1867 **✎Note:**
1868
1869 A6 must be an address.
1870
1871 A7: File number (value is an integer)
1872
1873 Display the number of files in the folder (up to 100)
1874
1875 **✎Note: **
1876
1877 A7 must be an address.
1878
1879 A8: File creation time (value is a string);
1880
1881 Display the time of file creation, time occupies 32 characters
1882
1883 A9: The maximum number of files to read (value is an integer)
1884
1885 Set the maximum number of files to read (up to 100 files)
1886
1887 **✎Note:** A9 can be an address, variable or value.
1888
1889 **Example**
1890
1891 Read the specified number of files in the folder.
1892
1893 (% class="box" %)
1894 (((
1895 FileCmpDir(@W_HDW1254, @W_HDW50, "File", "", 0, "@W_HDW0", "", "", 10)'Determine whether there is a file with the same name as @W_HDW50 in the file directory of HDW1254.@W_HDW0=3 is Yes.@W_HDW0 = 1 is No.@W_HDW0=2 is comparison failed.
1896 )))
1897
1898 Compare filename input and the filename in the folder whether is duplicate or not.
1899
1900 (% class="box" %)
1901 (((
1902 FileCmpDir(@W_HDW1254, "", "File", "@W_HDW200", 1, "@W_HDW0", "@W_HDW300", "@W_HDW400", 10)’The file name under the directory File in the flash is written to the continuous address begin from @W_HDW200, the file creation time is written to the continuous address begin from @W_HDW400, the number of files is written to the address @W_HDW300, the maximum number of files is 10
1903 )))
1904
1905 Compare the csv file name in the folder and the csv file name input whether is duplicated or not.
1906
1907 (% class="box" %)
1908 (((
1909 FileCmpDir(@W_HDW1254, @W_HDW50, "File", "", 100, "@W_HDW0", "", "", 10)' Judge whether there is a file in the directory File in the flash is same with following: @W_HDW50, @W_HDW50.csv, @ W_HDW50.CSV , @W_HDW0=3 is Yes, @W_HDW0 = 1 is No ,@W_HDW0=2 is comparison failed
1910 )))
1911
1912 == **FILL** ==
1913
1914 **Function**
1915
1916 FILL (A1, A2, A3)
1917
1918 **Description**
1919
1920 Write the same value to designated address constantly.
1921
1922 **Parameters**
1923
1924 **A1:** The beginning address, it can be an address (e.g.@ W_ HDW25);
1925
1926 **A2:** Source data, it needs to be written in continuous value, the value can be an address, variable or constant;
1927
1928 **A3:** The number of operation, writing address number, it can be an address, variable or constant;
1929
1930 When the PLC (external device) address is used in this function, the length range is 1-2048, and only the 2048th address can be operated when the range is exceeded.
1931
1932 When the HMI internal address is used in this function, the length range is 1-4096. If the function is out of range, then the function is invalid.
1933
1934 **Example**
1935
1936 //FILL (@W_HDW25, 10, 3) 'At the beginning three address of @W_ HDW25 is 10.//
1937
1938 **Result: **At the beginning three address of @W_ HDW25 is 10, @W_ HDW25=10, @W_ HDW26=10, @W_ HDW27=10.
1939
1940 == **Float2D** ==
1941
1942 **Function**
1943
1944 Float2D (A1,A2);
1945
1946 **Description**
1947
1948 Copy floating value to the address.
1949
1950 **Parameters**
1951
1952 * **A1: **Goal address, the value need to be address (e.g.@W_HDW102);
1953 * **A2:** Source data, it can be floating;
1954
1955 **Example**
1956
1957 {{code language="lua"}}
1958 dim f as floating 'define f as floating
1959
1960 f=1.1 'assign a designated value to f
1961
1962 Float2D ("@W_HDW102",f) 'assign the value f to HDW102
1963 {{/code}}
1964
1965 **Result:** HDW102=1.1
1966
1967 == **For. to. step. next** ==
1968
1969 **Function**
1970
1971 For counter = start to end Step
1972
1973 [Statements]
1974
1975 Next
1976
1977 **Description**
1978
1979 Execute a command repeatedly for designated times.
1980
1981 **Parameters**
1982
1983 * **counter: **Work as a variable for loop counter;
1984 * **start: **The start value of counter, it could be any variable type or expression;
1985 * **end: **The end value of counter, it could be any variable type or expression;
1986 * **step: **Every loop, the changed value of counter is step value, step default if it is not designation. Step default as below:
1987 ** if start>end, step default is 1;
1988 ** if start< end. It could be any variable type or expression;
1989 * **statements: **Between For with Next, execute instruction set of designated times;
1990 ** Set a loop of for...Next in another loop, it can nest call the loop of for...Next. Different from a while, for only search once value from end. Empty for loop will be ignored, and could not delay time.
1991
1992 **Example**
1993
1994 {{code language="lua"}}
1995 'Use HDX2.0 to trigger the loop
1996
1997 for i=100 to 0 step -5 ' set the start is 100,end is 0,subtract 5 every time, execute 20 times totally.
1998
1999 @W_HDW100=@W_HDW100+1 ' execute (HDW100+1) 21 times totally, the final result is 21.
2000
2001 Next
2002
2003 @B_HDX2.0=0
2004 {{/code}}
2005
2006 **Result: **HDW100=21
2007
2008 == **Function** ==
2009
2010 **Function**
2011
2012 * Function name (arglist)
2013 * statements
2014 * name = expression
2015 * statements
2016 * End Function
2017
2018 **Description**
2019
2020 Unlike internal function, it needs to declare the name, parameter, code of the function.
2021
2022 **Parameters**
2023
2024 * **Name: **function name.
2025 * **arglist: **stands for the variable list of parameter, this parameter will be entered during calling function. use comma to separate.
2026 * **statements: **a set of code in running function body.
2027
2028 **Notice: **it could not define a function program at any other program body. Write name first and then follow with parameter list, when calling function. Declare function need to before be calling. in the internal function body, it could be assigned to a function name from returned value at any place. Return value is 0 if not assign function name. Functions can recursive, but it may lead to stack overflow.
2029
2030 **Example**
2031
2032 {{code language="lua"}}
2033 Function sincos (angle as floating)
2034
2035 sincos = sin(angle) + cos(angle)
2036
2037 End Function<
2038
2039 ........
2040
2041 @W_0002 = sincos(pi/2)
2042
2043 ........
2044 {{/code}}
2045
2046 == **GetServerDelayInfo** ==
2047
2048 **Function**
2049
2050 A3=GetSerVerDelayInfo(A1,A2)
2051
2052 **Description**
2053
2054 Convert string A1 to hexadecimal number.
2055
2056 **Parameters**
2057
2058 **A1:** The starting address, save the delay data of each server (10 consecutive addresses, the last 7 addresses are reserved), when the server testing fails, the value in the corresponding address is -1. The unit is ms (signed decimal number).
2059
2060 (% class="table-bordered" %)
2061 |=**Address**|=**Description**
2062 |A1|Delay data of the server configured in [Project Settings]
2063 |A1+1|Delay data of Server 1
2064 |A1+2|Delay data of Server 2
2065
2066 **A2: **Server test result address
2067
2068 (% class="table-bordered" %)
2069 |=(% style="width: 239px;" %)**Address**|=(% style="width: 1250px;" %)**Description**
2070 |(% style="width:239px" %)0 bit|(% style="width:1250px" %)Set ON, Server configured in [Project Settings] fails
2071 |(% style="width:239px" %)1^^st^^bit|(% style="width:1250px" %)Set ON, Server 1 fails
2072 |(% style="width:239px" %)2^^nd^^bit|(% style="width:1250px" %)Set ON, Server 2 fails
2073 |(% style="width:239px" %)3^^rd^^~~ 10^^th^^bits|(% style="width:1250px" %)Reserved
2074 |(% style="width:239px" %)11^^th^^bit|(% style="width:1250px" %)Set ON, network error, network port interface failure
2075
2076 **A3:**Returns the preferred server number or network status (automatically selects the server with the best connection network status).
2077
2078 * =0: Server configured in [Project Settings];
2079 * =1: Server 1;
2080 * =2: Server 2;
2081 * =3~~10: Reserved;
2082 * =100: Try again later (two test intervals need to wait 30 seconds);
2083 * =101: Failed to test Server;
2084
2085 **Example**
2086
2087 //{{code language="lua"}}@W_HDW200 = GetServerDelayInfo("@W_HDW100", "@W_HDW50"){{/code}}//
2088
2089 Result:
2090
2091 * HDW100: Delay data of the server configured in [Project Settings]
2092 * HDW101: Delay data of Server 1
2093 * HDW102: Delay data of Server 2
2094 * HDX50.0=1:Server configured in [Project Settings] fails
2095 * HDX50.1=1: Server 1 fails
2096 * HDX50.2=1:Server 2 fails;
2097 * HDX50.11= 1: network error, network port interface failure;
2098
2099 When the server signal is stable, the optimal server is automatically connected according to the network status @W_HDW200. When the server connection is abnormal, @W_HDW200=101, the server test fails or the test is abnormal.
2100
2101 (% class="box infomessage" %)
2102 (((
2103 **✎Note:** The time interval between executions of this function could not be less than 30 seconds, otherwise an error will occur.
2104 )))
2105
2106 == **Goto** ==
2107
2108 **Function**
2109
2110 Goto label
2111
2112 **Description**
2113
2114 Go to the designated row without any condition in a function body.
2115
2116 **Parameters**
2117
2118 * **Label:** target character, start with letter in row label, end with(:)of any string.row label has no sensitive to the format of letter.
2119
2120 **Example**
2121
2122 //Goto sd 'go to the row which start with "sd";//
2123
2124 **Result:** Go to sd row.
2125
2126 (% class="box infomessage" %)
2127 (((
2128 **✎Note:** Goto only can jump into the internal function that visible row.
2129 )))
2130
2131 == **H2A** ==
2132
2133 **Function**
2134
2135 A1 = H2A (A2)
2136
2137 **Description**
2138
2139 Convert a binary (16-bit) to hexadecimals (4-bit) of ASCII.
2140
2141 **Parameters**
2142
2143 * **A1: **Returned value, string, it could be an address or variable.
2144 * **A2: **Binary is needed to be converted, the value could be a address or variable.
2145
2146 **Example**
2147
2148 //{{code language="lua"}}@W_HDW100= H2A (@W_HDW0) ' convert the binary of (HDW0) to character and save in (HDW100).{{/code}}//
2149
2150 **Result:**
2151
2152 * HDW0=200,
2153 * HDW=100
2154
2155 == **HmiRegoperator** ==
2156
2157 **Function**
2158
2159 HmiRegoperator (A1,A2,A3,A4,A5,A6)
2160
2161 **Description**
2162
2163 Data of Upload/ Download address
2164
2165 **Parameters**
2166
2167 * **A1: **The start address of target
2168 * **A2: **Length, address length, unit: word, range: 1~~1000
2169 * **A3: s**torage
2170 ** A3=0, select USB flash disk as storage, and save files in Root directory;
2171 ** A3=1, select SD card as storage, and save files in Root directory;
2172 * **A4: **File name address, itneed to be address such as"@ W_HDW2"
2173 * **A5**: Upload / download data
2174 ** A5=0, save the data in the specified address as a file and store the file in the root directory;
2175 ** A5=1, Read data from file and it woule be written into specified address;
2176 * **A6:** State display, it needs to be address, such as "@ W_HDW2";
2177 ** A6=1, Normal
2178 ** A6=2, USB flash disk/ SD card does not exist
2179 ** A6=3, File doesn’t exist;
2180 ** A6=4, File name error;
2181 ** A6=5, Check error
2182 ** A6=6, Abnormal communication;
2183 ** A6=7, HUW register is not allowed;
2184 ** A6=8, Address length range error (address length range: 1-1000);
2185
2186 **Example**
2187
2188 Script 1
2189
2190 (% class="box" %)
2191 (((
2192 //HmiRegoperator("@W_HDW0",10,0,"@W_HDW2000",0,"@W_HDW3000")’The data in HDW0-HDW10 is saved as a file, the file name is set by HDW2000 and stored in a USB flash disk.//
2193 )))
2194
2195 Script 2
2196
2197 (% class="box" %)
2198 (((
2199 //HmiRegoperator("@W_HDW0",10,1,"@W_HDW2000",1,"@W_HDW3000")//
2200
2201 //Read the values from files which stored in the SD card (files named by the HDW2000), and write these values to the HDW0-HDW10.//
2202 )))
2203
2204 **✎Note:**
2205
2206 * The length of the file name is less than 32 characters, and the file name consists of numbers and letters (the file name does not meet this standard; WECON does not guarantee the accuracy of the data).
2207 * The interval of download function operation should be 5s or more.
2208 * A1 need to be address such as “@W_HDW2”.
2209 * Please use “Character Input/Display” object for it, and the file name consists of numbers and letters, could not be punctuated characters, maximum character length 32 allowed.
2210
2211 == **Hypot** ==
2212
2213 **Function**
2214
2215 Var = Hypot (expr1, expr2)
2216
2217 **Description**
2218
2219 Calculate the value of the hypotenuse of a right triangle.
2220
2221 **Parameters**
2222
2223 * **expr1, expr2: **Source data, the two sides of right triangle. it need to be address;
2224 * **Var:** Destination data,it need to be address;
2225
2226 **Example**
2227
2228 (% class="box" %)
2229 (((
2230 //@W_HDW200=Hypot (@W_HDW105,@W_HDW108) ' input the value of right-angle side at (HDW105) and (HDW108),and assign the result of the hypotenuse to (HDW200).//
2231 )))
2232
2233 **Result: **
2234
2235 * HDW105=3,
2236 * HDW108=4,
2237 * HDW200=5
2238
2239 (% class="box infomessage" %)
2240 (((
2241 **✎Note:** hypot function could support integer and floating when the format of source data and target data are the same.
2242 )))
2243
2244 == **IF ... THEN ... ELSE ... END IF** ==
2245
2246 **Function**
2247
2248 If condition Then
2249
2250 Statements
2251
2252 [Else
2253
2254 else statements]
2255
2256 End If
2257
2258 **Description**
2259
2260 Conditional judgments instruction. When the [Condition] defined by [IF] is TURN, the operation following [THEN] is performed. When [Condition] is FALSE, the operation after [ELSE] is executed.
2261
2262 **Parameters**
2263
2264 * **condition: **any expression, the value could be true or false.
2265 * **statement: **execute the instruction block when condition is true.
2266 * **else statement: **execute the instruction block when condition is false.
2267
2268 **Example**
2269
2270 {{code language="lua"}}
2271 if @W_HDW105=200 then ' judging condition: whether the value of (HDW105) is 200
2272
2273 @W_HDW108=1 'the value of (HDW108) is 1 if fulfil condition
2274
2275 else
2276
2277 @W_HDW200=1 ' the value of (HDW200) is 1 if not fulfil condition.
2278
2279 Endif
2280 {{/code}}
2281
2282 **Result:**
2283
2284 * HDW105=199;
2285 * HDW108=0;
2286 * HDW200=1
2287
2288 == **InStr** ==
2289
2290 **Function**
2291
2292 var = InStr ("str1", "str2")
2293
2294 **Description**
2295
2296 Returned the position of str1 in str2(start with 0), set -1 if no result.
2297
2298 **Parameters**
2299
2300 * **str1:** source string, it could only be string, not address;
2301 * **str2:** target string, it could only be string, not address;
2302 * **var:** Returned value, the format of data needs to be string;
2303
2304 **Example**
2305
2306 {{code language="lua"}}
2307 dim a as floating
2308
2309 a = InStr ("Hello", "o") ' calculate the position of"o"in"hello".
2310
2311 float2d ("@W_HDW0",a) ' Returned value is 4.(start with 0)
2312 {{/code}}
2313
2314 **Result:** HDW0=4
2315
2316 == **Int2D** ==
2317
2318 **Function**
2319
2320 Int2D("A1",A2)
2321
2322 **Description**
2323
2324 Write the 32-bit integer into the target address
2325
2326 **Parameters**
2327
2328 * **A1: **Source data could only be the HMI internal or external register starting with "@".
2329 * **A2:** Target data could only use the integer variable defined by script.
2330
2331 **Example**
2332
2333 {{code language="lua"}}
2334 dim var1 as integer 'define var1 as integer
2335
2336 Int2D("@W_HDW0", var1)    'Read out the 32-bit integer in var1 and save the result in HDW0 .
2337
2338  var1=9999999,
2339 {{/code}}
2340
2341 **Result:** HDW0=9999999.
2342
2343 == **InvB** ==
2344
2345 **Function**
2346
2347 InvB (A1)
2348
2349 **Description**
2350
2351 The state of inverse bit, it is a sub function, no returned value. Achieve the state of switching address constantly.
2352
2353 **Parameters**
2354
2355 * **A1:** it is an address.
2356
2357 **Example**
2358
2359 //{{code language="lua"}}InvB (@B_HDX0.1) 'switch the state if (HDX0.1).{{/code}}//
2360
2361 **Result: **Switch the state of (HDX0.1) constantly.
2362
2363 == **IsFloating** ==
2364
2365 **Function**
2366
2367 A2=IsFloating (A1)
2368
2369 **Description**
2370
2371 Decide whether a parameter is floating, return true if it is floating, otherwise return FALSE.
2372
2373 **Parameter**
2374
2375 * **A1:** source data, variable;
2376 * **A2:** target data, variable;
2377
2378 **Example**
2379
2380 {{code language="lua"}}
2381 dim a as integer
2382
2383 dim b as floating
2384
2385 b= D2float ("@W_HDW200",b) 'assign the value of (HDW200) to b
2386
2387 a = IsFloating (b) 'judge whether b is floating or not
2388
2389 @W_HDW300=a 'save the result to (HDW300)
2390 {{/code}}
2391
2392 **Result: **HDW300=1
2393
2394 == **IsInteger** ==
2395
2396 **Function**
2397
2398 A2= IsInteger (A1)
2399
2400 **Description**
2401
2402 Determine whether a parameter(A1) is integer, return TRUE if the parameter is integer, otherwise return FALSE.
2403
2404 **Parameter**
2405
2406 * **A1:** Source date, it is variable or number;
2407 * **A2:** Target date, need to be variable, it could not be system address ;
2408
2409 **Example**
2410
2411 {{code language="lua"}}
2412 dim a as integer
2413
2414 a = IsInteger (20) 'determine whether 20 is integer
2415
2416 @W_HDW300=a ' display the result on (HDW300)
2417 {{/code}}
2418
2419 **Result:** HDW300=1
2420
2421 == **IsString** ==
2422
2423 **Function**
2424
2425 val = IsString(expr)
2426
2427 **Description**
2428
2429 Determine whether a parameter is string, return TRUE if it is string, otherwise return FALSE.
2430
2431 **Parameters**
2432
2433 * **Expr:** source string, it could be a variable or string, not address;
2434 * **Val:** target date, the result need to be variable, could not be address;
2435
2436 **Example**
2437
2438 {{code language="lua"}}
2439 dim a as integer 'define variable, display the result;
2440
2441 a= isstring ("hello") 'determine whether"hello"is string;
2442
2443 @W_HDW0=a 'assign the result to (HDW0)
2444 {{/code}}
2445
2446 **Result: **HDW=1
2447
2448 == **Lcase** ==
2449
2450 **Function**
2451
2452 A2 = LCase(A1)
2453
2454 **Description**
2455
2456 Convert all parameters to lowercase strings.
2457
2458 **Parameters**
2459
2460 * **A1: **source string, it could be an address or variable;
2461 * **A2: **outputting string, it could be an address or variable;
2462
2463 **Example**
2464
2465 (% class="box" %)
2466 (((
2467 //@W_HDW33 = LCase (@W_HDW25) 'input source sting on (HDW25), convert it to destination string and display the result on (HDW33);//
2468 )))
2469
2470 **Result:** HDW25=HELLO
2471
2472 HDW33=hello
2473
2474 == **Left** ==
2475
2476 **Function**
2477
2478 Val =Left (String, Length)
2479
2480 **Description**
2481
2482 Return a string of the specified length from the left side of parameter.
2483
2484 **Parameters**
2485
2486 * **String:** source string; it could be an address or string.
2487 * **Length: **return the number of character. It could be an address, integer or variable. Return empty string if length<1. return the whole string if length not less than the character number of string.
2488 * **Val: **destination string, outputting string, it could be an address or variable.
2489
2490 **Example**
2491
2492 (% class="box" %)
2493 (((
2494 //@W_HDW30=Left (@W_HDW36, @W_HDW40) '(HDW36) used to input source string,(HDW30) used to display the string result;//
2495 )))
2496
2497 Result:
2498
2499 * HDW36=hello,
2500 * HDW40=2,
2501 * HDW30=he
2502
2503 == **Len** ==
2504
2505 **Function**
2506
2507 Length=Len(String)
2508
2509 **Description**
2510
2511 Return the string length.
2512
2513 **Parameters**
2514
2515 * **String:** source string, it could be a address or string;
2516 * **Length:** target data, return value, it could be a address, variable, integer or floating;
2517
2518 **Example**
2519
2520 //{{code language="lua"}}@W_HDW30=Len (@W_HDW36) 'count the character number of (HDW36), save the result to (HDW30);{{/code}}//
2521
2522 **Result:**
2523
2524 * HDW36=hello
2525 * HDW30=5
2526
2527 == **Log** ==
2528
2529 **Function**
2530
2531 a= Logn (x)=Log(x)/Log(n)
2532
2533 **Description**
2534
2535 Log function:return the natural logarithm of the value.
2536
2537 **Parameters**
2538
2539 * **a: **source date,it could be a variable, but it could not be address;
2540 * **x, n:** source date, it could be a variable, but it could not be address;
2541
2542 **Example**
2543
2544 {{code language="lua"}}
2545 Dim a as integer 'define a as integer;
2546
2547 Dim b as integer 'define b as integer;
2548
2549 Dim c as integer 'define c as integer;
2550
2551 b=@W_HDW10 'assigns a value to b
2552
2553 c=@W_HDW20 'assigns a value to c
2554
2555 a=Log (b)/Log(c) 'calculate logarithm
2556
2557 @W_HDW0
2558
2559 =a 'assign the result to (HDW0)
2560 {{/code}}
2561
2562 **Result:**
2563
2564 * HDW10=27,
2565 * HDW20=3,
2566 * HDW0=3
2567
2568 == **Log10** ==
2569
2570 **Function**
2571
2572 a=Log10(x)= Log(x) / Log(10)
2573
2574 **Description**
2575
2576 Log function: return the natural logarithm.
2577
2578 **Parameters**
2579
2580 * **A:** target data, result could be variable, could not be address;
2581 * **x:** source data, it could be variable that needs to be the multiples of 10, can’t be address
2582
2583 **Example**
2584
2585 {{code language="lua"}}
2586 dim a as integer 'define a as integer
2587
2588 dim b as integer 'define b as integer
2589
2590 b=@W_HDW10 'assign a value to b
2591
2592 a= Log (b)/Log(10) 'result
2593
2594 @W_HDW0=a 'assign the result to (HDW0)
2595 {{/code}}
2596
2597 **Result: **
2598
2599 * HDW10=100,
2600 * HDW0=2
2601
2602 == **LTrim** ==
2603
2604 **Function**
2605
2606 val=LTrim("string")
2607
2608 **Description**
2609
2610 Remove the left empty part of the string and return.
2611
2612 **Parameters**
2613
2614 * **Val:** Destination string, it could be either a variable or address;
2615 * **string:** Source string, it could be either a variable or address;
2616
2617 **Example**
2618
2619 {{code language="lua"}}
2620 dim a as string
2621
2622 a=Ltrim("hello")
2623
2624 @W_HDW103=a
2625 {{/code}}
2626
2627 **Result:** HDW103=hello
2628
2629 == **MAX** ==
2630
2631 **Function**
2632
2633 A1=MAX(A2,A3)
2634
2635 **Description**
2636
2637 Compare the value of A2 and A3, assign the greater value to A1.
2638
2639 **Parameters**
2640
2641 * **A1:** Return value (used to store the greater value between A2 with A3).
2642 * **A2:** The first comparison value.
2643 * **A3:** The second comparison value.
2644
2645 (% class="box infomessage" %)
2646 (((
2647 **✎Note:** A1,A2,A3 should be only used in unsigned integer or unsigned address.
2648 )))
2649
2650 **Example**
2651
2652 {{code language="lua"}}
2653 DIM A1 as integer
2654
2655 @W_HDW106=10 'assign the value to (@W_HDW106), unsigned decimal word.
2656
2657 @W_HDW107=5 'assign the value to (?@W_HDW107),unsigned decimal word.
2658
2659 A1 = Max(@W_HDW106,@W_HDW107)
2660
2661 @W_HDW105 = A1
2662 {{/code}}
2663
2664 **Result: **@W_HDW105 = 10
2665
2666 == **Mid** ==
2667
2668 **Function**
2669
2670 A1=mid(A2, start, length)
2671
2672 **Description**
2673
2674 Returns a string contain a specified characters length from a string.
2675
2676 **Parameters**
2677
2678 * **A1:** string contains the selected characters, it needs to be a string
2679 * **A2:** string to be selected, it needs to be a variable or address
2680 * **Start:** the start position of string, it needs to be a variable or address, it means that count begin with 0.
2681 * **Length:** the designated length of string, maximum character length 127 allowed
2682
2683 **Example**
2684
2685 {{code language="lua"}}
2686 DIM A1 as string
2687
2688 A1 = Mid("hellokitty",1,2) 'select the string of in "
2689
2690 @W_HDW106=A1
2691 {{/code}}
2692
2693 **Result: **@W_HDW106 'display "el" on text input and output window
2694
2695 == **MIN** ==
2696
2697 **Function**
2698
2699 A1=MIN(A2,A3)
2700
2701 **Description**
2702
2703 Compare the value of A2 and A3, assign the smaller value to A1.
2704
2705 **Parameters**
2706
2707 * **A1: **Return value (used to store the snaker value between A2 with A3).
2708 * **A2: **The first comparison value.
2709 * **A3: **The second comparison value.
2710
2711 **Example**
2712
2713 {{code language="lua"}}
2714 DIM A1 as integer
2715
2716 @W_HDW106=10 'assign the value to (@W_HDW106), unsigned decimal word.
2717
2718 @W_HDW107=5 'assign the value to (@W_HDW107), unsigned decimal word.
2719
2720 A1 = Min(@W_HDW106,@W_HDW107)
2721
2722 @W_HDW105 = A1
2723 {{/code}}
2724
2725 **Result:** @W_HDW105 = 5
2726
2727 **✎Note:** A1, A2,A3 only used in unsigned integer or unsigned address.
2728
2729 == **MSeconds** ==
2730
2731 **Function**
2732
2733 A1=MSeconds( )
2734
2735 **Description**
2736
2737 A1 is used to display the current milliseconds of system.
2738
2739 **Parameters**
2740
2741 * **A1: **used to store the current milliseconds of system.
2742
2743 **Example**
2744
2745 {{code language="lua"}}
2746 DIM A1 as integer
2747
2748 @W_HDW0= 10 'assign a value to (@W_HDW0), unsigned decimal word
2749
2750 A1=MSeconds() 'return the current milliseconds of system to A1
2751
2752 @W_HDW0=A1
2753
2754 @W_HDW1=A1>>16 'display milliseconds on screen, (HDW0) is an 32-bit unsigned decimal integer address
2755 {{/code}}
2756
2757 **Result:** @W_HDW0 will generate the time value of changing milliseconds unit.
2758
2759 (% class="box infomessage" %)
2760 (((
2761 **✎Note:**
2762
2763 * A1 is 32-bit unsigned integer variable or unsigned integer address;
2764 * MSeconds() function rolls back over to zero once the maximum value has been reached (4294967295->0, 1,2,....4294967295->0, 1, 2,....4294967295->0, 1, 2);
2765 )))
2766
2767 == **MyDeleteFile** ==
2768
2769 **Function**
2770
2771 MyDeleteFile (A1,A2,A3,A4,A5)
2772
2773 **Description**
2774
2775 Delete the specified file
2776
2777 **Parameters**
2778
2779 A1: File location (value is an integer);
2780
2781 In HMI:
2782
2783 * =0: Recipe folder in HMI flash;
2784 * =1: Custom folder in UDisk (USB flash disk);
2785 * = 2: Custom folder in SD card.
2786 * =3: Custom folder in HMI flash;
2787
2788 In simulator:
2789
2790 * = 0: D:/Recipe/
2791 * = 1: C:/WECON/CustomFileDir/
2792 * = 2: C:/WECON/CustomFileDir/
2793 * = 3: C:/WECON/CustomFileDir/
2794
2795 **✎Note:**
2796
2797 A1 can be an address, variable or value.
2798
2799 A2: filename (value is string);
2800
2801 Input the name of the file want to delete.
2802
2803 **✎Note: **
2804
2805 A2 can be an address , variable or a character string, and the length of the file name cannot exceed 32 characters.
2806
2807 A3: folder name (value is integer);
2808
2809 Input the folder where the file want to delete.
2810
2811 **✎Note: **
2812
2813 A3 can be an address , variable or a character string, and the length of the folder name cannot exceed 32 characters.
2814
2815 A4: Delete function type (value is integer)
2816
2817 * = 0: Delete the specified file.
2818 * = 1: Delete all files.
2819
2820 **✎Note: **
2821
2822 A4 can be an address , variable or value.
2823
2824 A5: Return value (value is an integer)
2825
2826 * = 0: parameter error
2827 * = 1: Delete successfully
2828 * = 2: Delete failed
2829 * = 3: Failed to open file
2830
2831 **✎Note:** A5 must be an address.
2832
2833 **Example**
2834
2835 (% class="box" %)
2836 (((
2837 MyDeleteFile(@W_HDW1254,@W_HDW4200,@W_HDW4300,@W_HDW1250,"@W_HDW1252")
2838
2839 ‘According to the value of @W_HDW1250, delete the designated file @W_HDW4200 in the folder @W_HDW4300 or delete all files in the folder @W_HDW4300.
2840 )))
2841
2842 == **NewNoAddr** ==
2843
2844 **Function**
2845
2846 A1= NewNoAddr (A2, length)
2847
2848 **Description**
2849
2850 At the basic of source address A2, offset designated length, obtain a new address A1.
2851
2852 **Parameters**
2853
2854 * **A1: **address after offsetting, it must be String type variable.
2855 * **A2:** source address, it must be an address(e.g.:"@W_HDW2")
2856 * **Length: **offset length, it must be a constant or an integer variable.
2857
2858 **Example**
2859
2860 {{code language="lua"}}
2861 DIM A1 as string
2862
2863 A1=NewNoAddr("@W_HDW0",50) '(HDW0) offsets 50 words address (16 bit), and save the result to A1
2864
2865 @W_HDW1=A1 '(HDW50) save in A1
2866 {{/code}}
2867
2868 **Result: **(@W_HDW1) character input/display will show @W_HDW50
2869
2870
2871 **Example**
2872
2873 {{code language="lua"}}
2874 DIM A1 as string
2875
2876 A1=NewNoAddr("@W_HDW0",50) 'HDW0 address is offset by 50 word address and stored in A1, i.e. A1 represents the offset address HDW50
2877
2878 @W_HDW10=ReadAddr(A1) 'Read the value in address A1 (HDW50) and transfer it to HDW10
2879 {{/code}}
2880
2881 **Input: **@W_HDW50= 123
2882
2883 **Result: **@W_HDW10=123
2884
2885 == **NewStatAddr** ==
2886
2887 **Function**
2888
2889 A1= NewStatAddr (A2, length)
2890
2891 **Description**
2892
2893 At the basic of source address A2, offset the designated length, to obtain a new station A1.
2894
2895 **Parameters**
2896
2897 * **A1: **The address after offsetting, it needs to be variable.
2898 * **A2:** Source station address, it needs to be address (e.g.:"@W_1:10").
2899 * **Length: **offset length
2900
2901 **Example**
2902
2903 {{code language="lua"}}
2904 DIM A1 as string
2905
2906 A1=NewStatAddr("@W_1:10",2) 'address 10 of station address 1 that offset 2 station addresses, then save the result to A1
2907
2908 @W_HDW1=A1 'address 3:10 is saved in A1
2909 {{/code}}
2910
2911 **Result: **@W_HDW1 character input/display will show @W_3:10
2912
2913 == **NStringCompare** ==
2914
2915 **Function**
2916
2917 A1= NStringCompare (A2, A3, length)
2918
2919 **Description**
2920
2921 Compare whether the designated length of two strings is the same, return 1 to A1 if yes, otherwise return 0.
2922
2923 **Parameters**
2924
2925 * **A1: **Returned value (compare the designated length of two strings, display 1 when equal, else 0). It could be an address or variable.
2926 * **A2: **the address of string to be compared, it needs to be address.
2927 * **A3: **source string, it needs to be variable or constant string.
2928 * **Length: **string length to be compared
2929
2930 **Example**
2931
2932 {{code language="lua"}}
2933 @W_HDW1= NStringCompare("@W_HDW0","87654",5)
2934
2935 if @W_HDW1=1 then
2936
2937 @B_HDX10.0=1 'result: HDX10.0 set ON 'when the two strings are the same.
2938
2939 endif
2940
2941 if @W_HDW1=0 then
2942
2943 @B_HDX10.0=0 'result:HDX10.0 set OFF 'when not equal.
2944
2945 Endif
2946 {{/code}}
2947
2948 == **Operator** ==
2949
2950 (% class="table-bordered" %)
2951 |=(% scope="row" %)**Operation**|=**Symbol**|=**Example**|=**Return type**
2952 |=Addition|+|A1=A2+A3|Return type depending on the type of variable or address of the addition
2953 |=Subtraction|-|A1=A2-A3|Return type depending on the type of variable or address of the subtraction
2954 |=Multiplication|*|A1=A2*A3|Return type depending on the type of variable or address of the multiplication
2955 |=Division|/|A1=A2/A3|Return type depending on the type of variable or address of the division
2956 |=Remainder|Mod ~(%)|(((
2957 A1=A2 mod A3
2958
2959 A1=A2%A3
2960 )))|Returns the remainder of the division of two numbers. The type of the return value is an integer
2961 |=Logical OR|Or(~|)|(((
2962 A1=A2 or A3
2963
2964 A1=A2|A3
2965 )))|Returns the result of a logical OR. The type of the return value is an integer.
2966 |=Logic AND|And (&)|(((
2967 A1=A2 and A3
2968
2969 A1=A2&A3
2970 )))|Returns the result of a logical AND. The type of the return value is an integer.
2971 |=Logical XOR|Xor (^)|(((
2972 A1=A2 xor A3
2973
2974 A1=A2^A3
2975 )))|Returns the result of a logical XOR. The type of the return value is an integer.
2976 |=Logical reversal|Not (!)|(((
2977 A1=not A1
2978
2979 A1=A2!A3
2980 )))|Returns the result of a logical reversal. The type of the return value is an integer.
2981 |=Left shift|<<|A1=A2<<A3|Shift the value of A2 to the left by A3 digits and return the displacement result. The type of the return value is an integer.
2982 |=Right shift|>>|A1=A2>>A3|Shift the value of A2 to the right by A3 digits and return the displacement result. The type of the return value is an integer.
2983 |=Bit reversal|~~|A1=~~A1|Perform a bit reversal on a value. The type of the return value is an integer.
2984
2985 == **PI_GetTickCount** ==
2986
2987 **Function**
2988
2989 PI_GetTickCount (A1, A2)
2990
2991 **Description**
2992
2993 Writethe startingtime tothe set address asa 32-bit integer.
2994
2995 **Parameters**
2996
2997 * **A1: **Source data could only be the HMI internal or external register starting with "@".
2998 * **A2: **=0: Unit of time for returning 0ms;(the value will become 0 after 49.7 days and so on)
2999 ** =1: Unit of time for returning 10 ms;(the value will become 0 after 497 days and so on)
3000 ** =2: Unit of time for returning 100 ms;(the value will become 0 after 4970 days and so on)
3001 ** =3: Unit of time for returning 1000ms;(the value will become 0 after 49700 days and so on)
3002
3003 (% class="box infomessage" %)
3004 (((
3005 **✎Note: **If user restarts the hmi,all value will be 0.
3006 )))
3007
3008 **Example**
3009
3010 (% class="box" %)
3011 (((
3012 //PI_GetTickCount("@W_HDW100",0)'save the starting time in HDW100 address as a 32-bit integer.//
3013 )))
3014
3015 **Result: **HDW100=123456(different returned data for each moment)
3016
3017 == **Power** ==
3018
3019 **Function**
3020
3021 var = power (expr1, expr2)
3022
3023 **Description**
3024
3025 The value of [expr2] to the power of [expr1] will be assigned to Var.
3026
3027 **Parameters**
3028
3029 * **var:** returned value.
3030 * **expr 1:** base number.
3031 * **expr 2:** power number.
3032
3033 **Example**
3034
3035 {{code language="lua"}}
3036 Dim a as floating
3037
3038 a=power (2, 3) 'the value of 3 to the power of 2 is assigned to a.
3039
3040 Float2D("@W_HDW10",a) 'assign the float value of a to @W_HDW10
3041 {{/code}}
3042
3043 **Result: **@W_HDW10=8
3044
3045 == **PrintText** ==
3046
3047 **Function**
3048
3049 PrintText(A)
3050
3051 **Description**
3052
3053 Print the content of A or locates in A.
3054
3055 **Parameters**
3056
3057 **A:** source data. A could be a variable or a string ( text information),not a register address.
3058
3059 **Example**
3060
3061 A is text information
3062
3063 //PrintText("HMI 8070”)//
3064
3065 **Result: **Printer will print out “HMI 8070”
3066
3067 * A is variable
3068
3069 //Dim a as string//
3070
3071 //a= “HMI 8070”//
3072
3073 //PrintText(a)//
3074
3075 **Result:** Printer will print out “HMI 8070”
3076
3077 **✎Note:**
3078
3079 source data length range:1-128 characters.
3080
3081 == **RadToDeg** ==
3082
3083 **Function**
3084
3085 Var= RadToDeg(expr)
3086
3087 **Description**
3088
3089 Convert radiant value to degree, then assigned to Var.
3090
3091 **Parameters**
3092
3093 * **Var:** return degree value.
3094 * **expr:** input radiant value.
3095
3096 **Example**
3097
3098 {{code language="lua"}}
3099 Dim a as floating
3100
3101 a = RadToDeg(pi)           'assignt the degree value of ? to a.
3102
3103 Float2D("@W_HDW4",a) 'assign the degree value to address "@W_HDW4".
3104 {{/code}}
3105
3106 **Result:** @W_HDW4=180
3107
3108 == **RAND** ==
3109
3110 **Function**
3111
3112 Var = rand(expr1)
3113
3114 **Description**
3115
3116 Generate a random number.
3117
3118 **Parameter**
3119
3120 * **Var:** generated random number.
3121 * **Expr1:** the base number.
3122
3123 **Example**
3124
3125 (% class="box" %)
3126 (((
3127 //@W_HDW0=rand(@W_HDW0) 'Set the value of address@W_HDW0 as the base number to generate random number.//
3128 )))
3129
3130 **Result:** @W_HDW0 random number.
3131
3132 == **ReadAddr** ==
3133
3134 **Function**
3135
3136 Word = ReadAddr(A1)
3137
3138 **Description**
3139
3140 Assigned the red value from A1 to word.
3141
3142 **Parameter**
3143
3144 * **Word: **return value
3145
3146 **Example**
3147
3148 {{code language="lua"}}
3149 Dim word as integer
3150
3151 @W_HDW100=10
3152
3153 word = ReadAddr("@W_HDW100") 'Read the value of address @W_HDW100 and assign to word.
3154
3155 @W_HDW200=word
3156 {{/code}}
3157
3158 **Result:** @W_HDW200=10
3159
3160 == **ReadWordFormFile** ==
3161
3162 **Function**
3163
3164 ReadWordFormFile (A1, A2, A3, A4, A5, A6)
3165
3166 **Description**
3167
3168 Read data of specified length from specified file
3169
3170 **Parameters**
3171
3172 A1: File location (value is an integer);
3173
3174 In HMI:
3175
3176 * =0: Recipe folder in HMI flash;
3177 * =1: Custom folder in UDisk (USB flash disk);
3178 * = 2: Custom folder in SD card.
3179 * =3: Custom folder in HMI flash;
3180
3181 In simulator:
3182
3183 * = 0: D:/Recipe/
3184 * = 1: C:/WECON/CustomFileDir/
3185 * = 2: C:/WECON/CustomFileDir/
3186 * = 3: C:/WECON/CustomFileDir/
3187
3188 **✎Note:** A1 can be an address, variable or value.
3189
3190 A2: File name (value is a string);
3191
3192 Input the file name want to write.
3193
3194 **✎Note: **A2 must be an address, and the length of the file name cannot exceed 32 characters.
3195
3196 A3: Data start address (value is a string);
3197
3198 Input the data want to write
3199
3200 **✎Note: **A3 must be the address.
3201
3202 A4: Data length (value is an integer)
3203
3204 Set the length of the data to be written (unit:word)
3205
3206 **✎Note: **A4 can be an address , variable or value.
3207
3208 A5: Return value (value is an integer)
3209
3210 ~= 1: Successfully read
3211
3212 ~= 2: Failed to open the folder
3213
3214 ~= 3: Read address error
3215
3216 ~= 4: File reading error
3217
3218 **✎Note: **A5 must be an address.
3219
3220 A6: Folder name (value is a string);
3221
3222 Input the folder where to be written the file.
3223
3224 **✎Note:** A6 can be an address or a variable or a character string, and the length of the folder name cannot exceed 32 characters
3225
3226 **Example**
3227
3228 (% class="box" %)
3229 (((
3230 ReadWordFormFile(@W_HDW1254,"@W_HDW4200","@W_HDW2000",@W_HDW4000,"@W_HDW4100", @W_HDW4300)'Write the @W_HDW4000 words in the file @W_HDW4200 in the directory @W_HDW4300 into the address @W_HDW2000 specified location by @W_HDW1254
3231 )))
3232
3233 == **Right** ==
3234
3235 **Function**
3236
3237 val = Right (string, length)
3238
3239 **Description**
3240
3241 Return a string of the specified length from the right side of parameter.
3242
3243 **Parameter**
3244
3245 * **string: **the operated string.
3246 * **length:** the designated number of byte required to return, count from the right side.
3247
3248 **Example**
3249
3250 //@W_HDW103= Right("Hello", 3) 'return "llo"//
3251
3252 **Result: **@W_HDW103="llo"
3253
3254 == **RTrim** ==
3255
3256 **Function**
3257
3258 val = RTrim(str)
3259
3260 **Description**
3261
3262 Clear the empty part on the right side of string [str], then assign the empty part to val
3263
3264 **Parameter**
3265
3266 * **val: **returned value.
3267 * **str:** the string needs to be operated.
3268
3269 **Example**
3270
3271 (% class="box" %)
3272 (((
3273 //@W_HDW0 = RTrim("   -Hell  o-  ") 'retrun"   -Hell  o-"//
3274 )))
3275
3276 **Result:** @W_HDW0display "   -Hell  o-"
3277
3278 == **S2F** ==
3279
3280 **Function**
3281
3282 S2F (A1,A2,s1)
3283
3284 **Description**
3285
3286 S2F is used to translate the string stored in A1 to floating and store the floating number in A2 according to the data format shown in A2.
3287
3288 **Parameters**
3289
3290 * **A1:** initial data address, used to store the string data, it should be the internal address of HMI or external address that started with “@”,like @W_HDW0
3291 * **A2:** destination address, used to store the floating number data. It should be the internal address of HMI or external address that started with “@”,like @W_HDW0
3292 * **S1:** display format of target data, for example m.nf, m means the length of string is m, n means the decimal places, f is the format used to output single precision number. (Since the floating point number is up to 7 digits, the decimal point in the string is also a bit, so it is recommended that the length should not exceed 8 bits)
3293
3294 **Return value:** none
3295
3296 **Example**
3297
3298 (% class="box" %)
3299 (((
3300 The lengTh of string is 8
3301
3302 //@W_HDW0="12345.67"//'Assign the string “12345.67" to HDW1
3303
3304 //S2F("@W_HDW0","@W_HDW100","8.2f") 'read string "12345.67 "from HDW0and convert it into a floating point with 2 decimal places, store in the HDW100//
3305 )))
3306
3307 **Result: **@W_HDW100 address displays “12345.67”.
3308
3309 (% class="box" %)
3310 (((
3311 The length of string is less than 8
3312
3313 //@W_HDW0="1234.5 67"‘assign the string“1234.567”to HDW1//
3314
3315 //S2F("@W_HDW0","@W_HDW100","6.2f") ' read string "1234 .5"from HDW0and convert it into a floating point with 2 decimal places, store in the HDW100 .//
3316 )))
3317
3318 **Result: **the floating value of @W_HDW100 is 1234.50
3319
3320 (% class="box" %)
3321 (((
3322 The length of string is more than 8
3323
3324 //@W_HDW0="12345.6789"’assign the string “12345.6789” to HDW1//
3325
3326 //S2F("@W_HDW0","@W_HDW100","8.2f") ' read string "12345 .67" from HDW0 and convert it into a floating point with 2 decimal places, store in the HDW100 .//
3327 )))
3328
3329 **Result: **the floating value of @W_HDW100 is 12345.67
3330
3331 == **SetB** ==
3332
3333 **Function**
3334
3335 SetB(A1)
3336
3337 **Description**
3338
3339 Set the bit A1 ON.
3340
3341 **Parameters**
3342
3343 * **A1:**Bit address
3344
3345 **Example**
3346
3347 (% class="box" %)
3348 (((
3349 //SetB(@B_HDX100.0) 'Set the address {@B_HDX100.0} ON//
3350 )))
3351
3352 **Result: **@B_HDX100.0=1
3353
3354 == **SetKeyMap** ==
3355
3356 **Function**
3357
3358 SetKeyMap(A1,A2,A3)
3359
3360 **Description**
3361
3362 The key values of the keyboard are mapped so that multiple keyboard buttons perform the same function.
3363
3364 **Parameters**
3365
3366 * **A1:** The starting address of the source key;It needs to be an address format;
3367 * **A2: **The starting address of the mapped value; It needs to be an address format;
3368 * **A3: **Mapping length (continuous length of mapped address); It needs to be a value, the maximum mapping range: 108 key values;
3369
3370 **Example**
3371
3372 (% class="box" %)
3373 (((
3374 //@W_HDW3000 = 3 ' The starting address of the source key//
3375
3376 //@W_HDW3001 = 5//
3377
3378 //@W_HDW3002 = 7//
3379
3380 //@W_HDW3003 = 9//
3381
3382 //@W_HDW3004 = 61//
3383
3384 //@W_HDW4100 = 103 'The starting address of the mapped value//
3385
3386 //@W_HDW4101 = 105//
3387
3388 //@W_HDW4102 = 106//
3389
3390 //@W_HDW4103 = 108//
3391
3392 //@W_HDW4104 = 28//
3393
3394 //SetKeyMap("@W_HDW3000","@W_HDW4100",5) ' Map the values of the HDW4000~~HDW4004 addresses to the HDW3000~~HDW3004 addresses.//
3395 )))
3396
3397 **Result**
3398
3399 Map the value of the HDW4000~~HDW4004 address (mapped to 103 105 106 108 28) to the value of the HDW3000~~HDW3004 address (source key value 3 5 7 9 61)
3400
3401 Button 2 (key value 3) is mapped to the direction key (key value is 103), button 4 (key value 5) is mapped to the left arrow key (key value is 105), and so on. When using the keyboard, the function of input 2 could be performed on both the button 2 and the direction button.
3402
3403 == **SignedInt16** ==
3404
3405 **Function**
3406
3407 val = SignedInt16(A1)
3408
3409 **Description**
3410
3411 Assign the value to {val} from address A1 which is signed integer.
3412
3413 **Parameters**
3414
3415 * **A1: **contain signed integer as "@W_HDW000002"
3416 * **Val: **returned value
3417
3418 **Example**
3419
3420 {{code language="lua"}}
3421 Dim a as integer 'Integer variable a
3422
3423 a = SignedInt16("@W_HDW0") 'read signed integer from HDW0 addresses and assign the value to a
3424
3425 @W_HDW2=a'assign the value a to HDW2
3426 {{/code}}
3427
3428 **Input: **@W_HDW0=-2:
3429
3430 **Result:** @W_HDW2=-2.
3431
3432 == **SignedInt32** ==
3433
3434 **Function**
3435
3436 val = SignedInt32 (A1)
3437
3438 **Description**
3439
3440 Assign the value to {val} from address A1 which is signed even integer.
3441
3442 **Parameters**
3443
3444 * **A1: **the address contains signed even integer
3445 * **Val:** Returned value
3446
3447 **Example**
3448
3449 {{code language="lua"}}
3450 Dim a as integer 'define {a} as a integer
3451
3452 a = SignedInt32("@W_HDW0") 'read signed even integer from HDW0, then assign this value to a.
3453
3454 @W_HDW2=a 'assign the value of a to HDW2
3455
3456 @W_HDW3=a>>16
3457 {{/code}}
3458
3459 **Input: **@W_HDW0=-2
3460
3461 **Result:**
3462
3463 * @W_HDW2=-2
3464 * @W_HDW13=-1
3465
3466 == **Sin** ==
3467
3468 **Function**
3469
3470 val = Sin(A1)
3471
3472 **Description**
3473
3474 Get the sine value of A1, and copy result to val.
3475
3476 **Parameters**
3477
3478 * **A1: **A1 needs to be an angle.
3479 * **Val: **Returned value.
3480
3481 **Example**
3482
3483 {{code language="lua"}}
3484 Dim a as floating 'floating variable a,b
3485
3486 a=sin(pi/6) 'return sinb to a
3487
3488 Float2D("@W_HDW13",a) 'assign the value of the floating variable a to address HDW13.
3489 {{/code}}
3490
3491 **Result:** @W_HDW13=0.5
3492
3493 == **SleepA** ==
3494
3495 **Function**
3496
3497 SleepA(T)
3498
3499 **Description**
3500
3501 Wait time T(ms).
3502
3503 **Parameters**
3504
3505 * **T:** wait time, the unit is [ms]
3506
3507 **Returned value:** none.
3508
3509 **Example**
3510
3511 (% class="box" %)
3512 (((
3513 //SleepA(10) 'wait 10ms//
3514 )))
3515
3516 **Result:** When the script runs to SleepA(10), it means the scripts would go running after waiting 10ms
3517
3518 == **Sqr** ==
3519
3520 **Function**
3521
3522 val = Sqr(A1)
3523
3524 **Description**
3525
3526 Assign a square root value of A1 to val.
3527
3528 **Parameters**
3529
3530 * **A1: **the data need to be operated
3531 * **Val: **Returned value
3532
3533 **Example**
3534
3535 (% class="box" %)
3536 (((
3537 //@W_HDW0 = Sqr(4) 'calculate the square root of HDW0//
3538 )))
3539
3540 **Result:** @W_HDW0=2
3541
3542 == **StAndFtChange** ==
3543
3544 **Function**
3545
3546 StAndFtChange(A1,A2,A3)
3547
3548 **Description**
3549
3550 Calculate the number of seconds from January 1, 1970 to the current time, and also be invertible.
3551
3552 **Parameters**
3553
3554 * **A1: **The start address of curren t time (Enter or output year, month, day, minute, and second); It needs to begin with address"@", and occupies 6 addresses;
3555 * **A2: **The number of seconds; It needs to begin with address “@", data format 32-bit unsigned.
3556 * **A3: **conversion method;
3557 ** A3=0, convert time to seconds;
3558 ** A3=1, convert seconds to time;
3559
3560 **Returned value: **none;
3561
3562 **Example**
3563
3564 Script 1
3565
3566 (% class="box" %)
3567 (((
3568 //StAndFtChange("@W_HDW10","@W_HDW20",0) // //‘use HDW10 as start address, and enter year, month, day, hour, minute, second. The script calculates the number of seconds from January 1, 1970 to the time of the entry, and stores the result in HDW20//
3569 )))
3570
3571 **Input: **HDW10 = 2017,HDW11 = 12, HDW12 = 9 , HDW13 = 15, HDW14 = 15, HDW15 = 0
3572
3573 **Output:** 1512832500
3574
3575 Script 2
3576
3577 (% class="box" %)
3578 (((
3579 //StAndFtChange("@W_HDW30","@W_HDW20",1) ‘read number of seconds from HDW20, and the script calculates the date time, and stores the result start from HDW30//
3580 )))
3581
3582 **Input:** 1512833760
3583
3584 **Output:** HDW30 = 2017, HDW31 = 12, HDW32 = 9, HDW33 = 15, HDW34 = 36, HDW35 = 0
3585
3586 == **Sub** ==
3587
3588 **Function**
3589
3590 Sub name (arglist)
3591
3592 statements
3593
3594 End Sub
3595
3596 **Description**
3597
3598 Declare the name, parameters and codes of the Sub (sub function)
3599
3600 **Parameters**
3601
3602 * **Name: **naming rules refer to variable.
3603 * **Arglist: **variable list.
3604 * **Statements:** the code set of the sub function.
3605
3606 **Example**
3607
3608 {{code language="lua"}}
3609 sub samesub(a,b as integer) ' samesub and integer variable a,b
3610
3611 c=a+b
3612
3613 @W_HDW0=c
3614
3615 endsub
3616
3617 samesub(1,12) 'call function samesub
3618 {{/code}}
3619
3620 **Result:** @W_HDW0=13
3621
3622 == **SWAP** ==
3623
3624 **Function**
3625
3626 SWAP(A1,length)
3627
3628 **Description**
3629
3630 Swap the big-endian with the little-endian from address A1, swap length is adjustable.
3631
3632 **Parameters**
3633
3634 * **A1: **the swapped high endian, need to be an address as HDW_000002.
3635 * **Length: **swap length.
3636
3637 **Returned value:** None.
3638
3639 **Example**
3640
3641 {{code language="lua"}}
3642 @W_HDW103=0x1234 'assign value to HDW103
3643
3644 @W_HDW104=0x2345 'assign value to HDW104
3645
3646 @W_HDW105=0x2565 'assign value to HDW105
3647
3648 @W_HDW106=0x2675 'assign value to HDW106
3649
3650 SWAP(@W_HDW103,4) 'swap the high and low endian for the 4 adjacent addresses start with HDW103.
3651 {{/code}}
3652
3653 **Result:**
3654
3655 * @W_HDW103=0x3412
3656 * @W_HDW104=0x4523
3657 * @W_HDW105=0x6525
3658 * @W_HDW106=0x7526
3659
3660 == **Tan** ==
3661
3662 **Function**
3663
3664 val = Tan(A1)
3665
3666 **Description**
3667
3668 Get the returned tagent value of A1, and then assign to val.
3669
3670 **Parameters**
3671
3672 * **A1: **A1 needs to be an angle.
3673 * **Val: **Returned value.
3674
3675 **Example**
3676
3677 {{code language="lua"}}
3678 Dim a as floating 'define a floating variable a
3679
3680 a=TAN(pi/3) 'calculate the tangent value of pi/3 and assign to a
3681
3682 Float2D("@W_HDW16",a) 'assign the value of a to HDW16
3683 {{/code}}
3684
3685 **Result:** @W_HDW13=1.732
3686
3687 == **Trim** ==
3688
3689 **Function**
3690
3691 val = Trim(A1)
3692
3693 **Description**
3694
3695 Return A string in A1 without empty string next to it.
3696
3697 **Parameters**
3698
3699 * **A1: **The operated string
3700 * **val: **Returned value
3701
3702 **Example**
3703
3704 //{{code language="lua"}}@W_HDW1=Trim(" ab "){{/code}}//
3705
3706 **Result: **@W_HDW1="ab"
3707
3708 == **UCase** ==
3709
3710 **Function**
3711
3712 val = UCase(A1)
3713
3714 **Description**
3715
3716 Capitalize the string data, and then assign the value to val.
3717
3718 **Parameters**
3719
3720 * **A1: **Operated string, address or variable.
3721 * **Val: **Returned value
3722
3723 **Example**
3724
3725 //{{code language="lua"}}@W_HDW1=ucase("abcd") 'Capitalize abcd then assign the value to HDW1{{/code}}//
3726
3727 **Result: **@W_HDW1="ABCD"
3728
3729 == **Variable** ==
3730
3731 **Description**
3732
3733 A variable is any factor, trait, or condition that could exist in differing amounts or types.
3734
3735 **Define variable**
3736
3737 Use Dim to define variable in script. The variable could be string, floating, integer.
3738
3739 **Example:**
3740
3741 {{code language="lua"}}
3742 Dim a as floating ‘define variable {a} as a floating.
3743
3744 Dim b,c,d as integer‘define variable {b,c,d} as integer
3745 {{/code}}
3746
3747 **Naming rules**
3748
3749 The first letter needs to be English letter.
3750
3751 No symbols.
3752
3753 Maximum character length 15 allowed.
3754
3755 == **W2B** ==
3756
3757 **Function**
3758
3759 W2B(A1, A2, A3)
3760
3761 **Description**
3762
3763 Replace the high endian of [A2]+1 with the high endian of A2.
3764
3765 **Parameters**
3766
3767 * **A1:** operated address.
3768 * **A2:** source address.
3769 * **A3: **the conversion length.
3770
3771 **Returned value:** none.
3772
3773 **Example**
3774
3775 {{code language="lua"}}
3776 @W_HDW0 = 4660 'assign 16bit value 1234 to HDW0.
3777
3778 @W_HDW1=0x5678 'assign 16bit value 5678 to HDW1.
3779
3780 @W_HDW2 = 0x2425 'assign 16bit value 2425 to HDW1.
3781
3782 @W_HDW3 = 0x3536 'assign 16bit value 3536 to HDW0.
3783
3784 @W_HDW4 = 0x1415 'assign 16bit value 1415 to HDW0.
3785
3786 W2B(@W_HDW20,@W_HDW0, @W_HDW10)
3787
3788 @W_HDW10=1 ‘save the high endian {34} of HDW0 to HDW20.
3789 {{/code}}
3790
3791 **Result:** @W_HDW20=0x34, @W_HDW21=0, @W_HDW22=0
3792
3793 == **W2D** ==
3794
3795 **Function**
3796
3797 W2D(A1, A2)
3798
3799 **Description**
3800
3801 Convert the unsigned Word to unsigned Dword and save the result in A1.
3802
3803 **Parameters**
3804
3805 * **A1: **operated address .
3806 * **A2:** source address.
3807
3808 Returned value.
3809
3810 **Example**
3811
3812 Unsigned decimal word
3813
3814 (% class="box" %)
3815 (((
3816 //@W_HDW0 = 1234 'assign 1234 to HDW0.//
3817
3818 //W2D(@W_HDW2, @W_HDW0) 'convert unsigned word {1234} from HDW0 to Dword and save in HDW2//
3819 )))
3820
3821 **Result:** @W_HDW0=12345, @W_HDW2=12345, @W_HDW3=0
3822
3823 Signed decimal word
3824
3825 (% class="box" %)
3826 (((
3827 //@W_HDW0 = -12345 'assign value to HDW0: convert {-12344} to unsigned decimal word is {53191}.//
3828
3829 //W2D(@W_HDW2, @W_HDW0) 'save unsigned Dword to HDW0//
3830 )))
3831
3832 **Result: **@W_HDW0=-12345,@W_HDW2=53191,@W_HDW3=0
3833
3834 == **W2F** ==
3835
3836 **Function**
3837
3838 A1 = W2F (A2)
3839
3840 **Description**
3841
3842 Convert a 16bit integer to a 32bit floating, and then save to the next word of A1.
3843
3844 Parameters
3845
3846 * **A1:** operated address.
3847 * **A2:** source address.
3848
3849 **Returned value:** none.
3850
3851 **Example**
3852
3853 A1, A2 are addresses
3854
3855 (% class="box" %)
3856 (((
3857 //@W_HDW0 = 1234 ' assign unsigned word {1234} HDW0 @W_HDW1=W 2F(@W_HDW0) ‘ Convert {1234} to a 32bit floating and then save to HDW1, HDW2.//
3858 )))
3859
3860 **Result: **@W_HDW1=1234'32bit floating
3861
3862 {{code language="lua"}}
3863 A1 is an address,A2 is variable
3864
3865 dim a as integer
3866
3867 a=134 'define a integer 134 to a,
3868
3869 @W_HDW2=W2F (a) 'convert to 32bit floating save to HDW1, HDW2.
3870 {{/code}}
3871
3872 **Result: **@W_HDW1=134' 32bit floating
3873
3874 == **W2S** ==
3875
3876 **Function**
3877
3878 W2S(A1,A2,S1)
3879
3880 **Description**
3881
3882 Convert integer word in address A1 text as S1 format, and then save to A2.
3883
3884 **Parameters**
3885
3886 * **A1:** operated address.
3887 * **A2:** source address.
3888 * **S1:** saving format.
3889 ** d format: Decimal format.d: Real data length.Md: Designated data length. 0md: Designated data length if the length is shorter than m adds 0 at the left.
3890 ** format: Unsigned octal format. Mo and 0mo is also applied.
3891 ** x format: unsigned Hex integer format ?Mx and 0mx is also applied.
3892 ** c format: ASCII format.
3893
3894 **Example**
3895
3896 Decimal format
3897
3898 {{code language="lua"}}
3899 @W_HDW1=1456'assign value {1456} to HDW1.
3900
3901 W2S("@W_HDW1", "@W_HDW10", "6d") ' convert{1456} to decimal text and save to HDW10.
3902 {{/code}}
3903
3904 **Result: **@W_HDW10 shown "1456"
3905
3906 0md
3907
3908 {{code language="lua"}}
3909 @W_HDW1=1456 ' assign value {1456} to HDW1
3910
3911 W2S("@W_HDW1", "@W_HDW10", "06d") ' convert{1456} to integer decimal text and add 2 {0} on the left of the data then save to HDW10.
3912 {{/code}}
3913
3914 **Result:** @W_HDW10 show text "001456"
3915
3916 == **WaitEthernetStart** ==
3917
3918 **Function**
3919
3920 WaitEthernetStart (A1)
3921
3922 **Description**
3923
3924 Waiting for Ethernet to start, it will extend the HMI start up time (only added in PI i series, Ethernet start up is earlier than HMI in other PI series)
3925
3926 **Parameters**
3927
3928 * **A1: **Waiting timeout (1~~20s)
3929 ** If A1=0, the wait timeout is 10s;
3930 ** If A1>20, the wait timeout is 20s;
3931
3932 **Returned value:** None
3933
3934 **Example**
3935
3936 //WaitEthernetStart (15)//
3937
3938 ‘The maximum waiting time is 15 seconds. If Ethernet is not started within 15 seconds, HMI will start the system and no longer wait for ethernet.
3939
3940 == **WHILE ... WEND** ==
3941
3942 **Function**
3943
3944 While condition
3945
3946 [statements]
3947
3948 Wend
3949
3950 **Description**
3951
3952 If the condition is true, then all the commands before Wend in the statement will be executed then recheck the condition, if the condition is false, the command after Wend will be executed.
3953
3954 **Parameters**
3955
3956 * **Condition: **Number or string, the result represents as True or False.
3957
3958 **Returned value:** None.
3959
3960 **Example**
3961
3962 {{code language="lua"}}
3963 while @W_HDW1>50 'the condition is the value of HDW1 bigger than 50.
3964
3965 @W_HDW1=@W_HDW1-1 'when the condition is true, execute subtract 1 from 1HDW.
3966
3967 wend
3968
3969 @W_HDW2=@W_HDW2+1 ' when the condition is false, execute add 1 from 1HDW.
3970 {{/code}}
3971
3972 **Result:** If HDW1=60, after executed; HDW1=50, if the condition is true.
3973
3974 == **WriteAddr** ==
3975
3976 **Function**
3977
3978 WriteAddr(A1,A2)
3979
3980 **Description**
3981
3982 Assign the value from A2 to address A1.
3983
3984 **Parameters**
3985
3986 * **A1:** operated address
3987 * **A2:** source address
3988
3989 **Returned value:** None.
3990
3991 **Example**
3992
3993 {{code language="lua"}}
3994 dim f as integer ' integer f
3995
3996 f=13 ' assign the value 13 to f
3997
3998 WriteAddr("@W_HDW1",f) ' write the value to HDW1.
3999
4000 WriteAddr("@W_HDW10",@W_HDW2) ' write the value from HDW2 to HDW10.
4001 {{/code}}
4002
4003 **Result:**
4004
4005 * HDW1=13
4006 * HDW10= HDW2'IF HDW2=1456,Then HDW10=1456;IF HDW2=-123,Then HDW10=-123
4007
4008 == **WriteWordToFile** ==
4009
4010 **Function**
4011
4012 WriteWordToFile (A1,A2,A3,A4,A5,A6)
4013
4014 **Description**
4015
4016 Write data of designated length to specified file
4017
4018 **Parameters**
4019
4020 A1: File location (value is an integer);
4021
4022 In HMI:
4023
4024 * =0: Recipe folder in HMI flash;
4025 * =1: Custom folder in UDisk (USB flash disk);
4026 * = 2: Custom folder in SD card.
4027 * =3: Custom folder in HMI flash;
4028
4029 In simulator:
4030
4031 * = 0: D:/Recipe/
4032 * = 1: C:/WECON/CustomFileDir/
4033 * = 2: C:/WECON/CustomFileDir/
4034 * = 3: C:/WECON/CustomFileDir/
4035
4036 **✎Note: **A1 can be an address, variable or value.
4037
4038 A2: File name (value is a string);
4039
4040 Input the file name want to write.
4041
4042 **✎Note: **A2 must be an address, and the length of the file name cannot exceed 32 characters.
4043
4044 A3: Data start address (value is a string);
4045
4046 Input the data want to write
4047
4048 **✎Note: **A3 must be the address.
4049
4050 A4: Data length (value is an integer)
4051
4052 Set the length of the data to be written (unit:word)
4053
4054 **✎Note: **A4 can be an address , variable or value.
4055
4056 A5: Return value (value is an integer)
4057
4058 * = 1: Successfully written
4059 * = 2: Failed to open the folder
4060 * = 3: Read address error
4061 * = 4: File writing error
4062 * = 5: The file already exists
4063
4064 **✎Note: **A5 must be an address.
4065
4066 A6: Folder name (value is a string);
4067
4068 Input the folder where to be written the file.
4069
4070 (% class="box infomessage" %)
4071 (((
4072 **✎Note: **A6 can be an address or a variable or a character string, and the length of the folder name cannot exceed 32 characters
4073 )))
4074
4075 **Example**
4076
4077 (% class="box" %)
4078 (((
4079 WriteWordToFile(@W_HDW1254,"@W_HDW4200","@W_HDW1000",@W_HDW4000,"@W_HDW4100", @W_HDW4300)'Write the @W_HDW4000 words in the address @W_HDW1000 to the file @W_HDW4200 in directory @W_HDW4300 specified location by @W_HDW1254
4080 )))