System Function DR: Difference between revisions
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{{BoxLine|<apll>L</apll> is an integer scalar or one-element vector datatype (see the table above), or a special value (see below).}} | {{BoxLine|<apll>L</apll> is an integer scalar or one-element vector datatype (see the table above), or a special value (see below).}} | ||
{{BoxEnd|<apll>Z</apll> is <apll>R</apll> where each of the values are converted to the datatype indicated by <apll>L</apll>.}} | {{BoxEnd|<apll>Z</apll> is <apll>R</apll> where each of the values are converted to the datatype indicated by <apll>L</apll>.}} | ||
Returned value '''Z''' may alternatively be: numeric scalar, vector of numbers, or a character string - depending on what the value of | Returned value <big>'''Z'''</big> may alternatively be: numeric scalar, vector of numbers, or a character string - depending on what the value of left argument <big>'''L'''</big> was.<br /><br> | ||
<p>If the conversion is from a narrower datatype to a wider datatype, there must be exactly enough columns in the right argument to match a multiple of the size of the wider datatype. For example, when converting from character (16-bit) to integer (64-bit), the last column of the right argument must be a multiple of 4 (= 64/16); otherwise, a <apll>LENGTH ERROR</apll> is signalled.</p> | <p>If the conversion is from a narrower datatype to a wider datatype, there must be exactly enough columns in the right argument to match a multiple of the size of the wider datatype. For example, when converting from character (16-bit) to integer (64-bit), the last column of the right argument must be a multiple of 4 (= 64/16); otherwise, a <apll>LENGTH ERROR</apll> is signalled.</p> | ||
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</apll> | </apll> | ||
<p>Keep in mind how [[APA|Arithmetic Progression Arrays]] are created and represented | <p>Keep in mind '''<u>how</u> [[APA|Arithmetic Progression Arrays]]''' are <u>created and represented</u>; they can fool both the casual programmer as well as an experienced coder. For example, one might try the following to convert from Boolean to integer:</p> | ||
<apll> | <apll> | ||
6412 ⎕DR 2 64⍴1<br /> | 6412 ⎕DR 2 64⍴1 ⍝ APA created<br /> | ||
1 0 2 64<br /> | 1 0 2 64<br /> | ||
</apll> | </apll> | ||
<p>However, this doesn't produce the expected result because this particular right argument is an APA, not a Boolean vector. That is, under certain circumstances, the reshape primitive creates an APA. In this case, the APA is an array with an offset of <apll>1</apll>, a multiplier of <apll>0</apll> and a shape of <apll>2 64</apll>.</p> | <p>However, this doesn't produce the expected result because this particular right argument is an <big>APA</big>, and <u>not</u> a simple Boolean vector of 1's. That is, under certain circumstances, the reshape primitive creates an APA. In this case, the APA is an array with an offset of <apll>1</apll>, a multiplier of <apll>0</apll> and a shape of <apll>2</apll> rows and <apll>64</apll> cols. The usefulness of APS's in reducing data storage and processing times outweighs their sometimes added code complexity or additional insight, which may be required.</p> | ||
<p>On the other hand, this expression</p> | <p>On the other hand, this expression:</p> | ||
<apll> | <apll> | ||
6412 ⎕DR 2 64⍴1 1<br /> | 6412 ⎕DR 2 64⍴1 1 ⍝ contrast to prior example - Boolean vec created here, NOT an APA<br /> | ||
¯1<br /> | ¯1<br /> | ||
¯1<br /> | ¯1<br /> | ||
</apll> | </apll> | ||
<p>produces the expected result because the right argument is | <p>produces the expected result because the right argument is "right upon moment of vector '''1 1''' creation" - Boolean.</p> | ||
===Special Values=== | ===Special Values=== |
Revision as of 12:16, 21 August 2015
This function is available in both monadic and dyadic forms.
Monadic Function
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R is an arbitrary array. | ||||
Z is a numeric scalar which represents the datatype of R. |
The datatypes are encoded with a unique index in the low-order two digits, and (where appropriate) the bits per element in the higher-order digits:
- 110: Boolean, one bit per element
- 1611: Character, 16 bits per element
- 6412: Integer, 64 bits per element
- 6413: Floating Point, 64 bits per element (double precision)
- 14: Rational, 16 bytes plus two 4- or 8-byte pointers plus size of limbs per element
- 15: Variable-precision Floating Point, 12 bytes plus one 4- or 8-byte pointer plus size of limbs per element
- 19: Arithmetic Progression Array, 64 bits each for the offset and multiplier
- 20: Heterogeneous, one 4- or 8-byte pointer per element
- 21: Nested, one 4- or 8-byte pointer per element
For example,
⎕DR 1 0 1
110
⎕DR ⌈/⍬
6413
⎕DR 2 64⍴1 — Note this is really an APA, not Boolean
19
⎕DR 2 64⍴1 1 — This one is Boolean because Reshape produces APAs for integer singleton right arguments only
110
Dyadic Function
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R is an arbitrary array. | ||||
L is an integer scalar or one-element vector datatype (see the table above), or a special value (see below). | ||||
Z is R where each of the values are converted to the datatype indicated by L. |
Returned value Z may alternatively be: numeric scalar, vector of numbers, or a character string - depending on what the value of left argument L was.
If the conversion is from a narrower datatype to a wider datatype, there must be exactly enough columns in the right argument to match a multiple of the size of the wider datatype. For example, when converting from character (16-bit) to integer (64-bit), the last column of the right argument must be a multiple of 4 (= 64/16); otherwise, a LENGTH ERROR is signalled.
6412 ⎕DR 'NARS2000' — Eight 16-bit characters (=128 bits) converts to two 64-bit integers:
23362775258562638 13511005043687474
If the conversion is from a wider datatype to a narrower datatype, the number of values in the result is a multiple of the ratio of the wider datatype to the narrower datatype. For example, when converting from integer (64-bit) to character (16-bit), the last column in the result is the product of last column of the right argument and 4 (= 64/16).
For example(inverse of the example just above),
⍴⎕←1611 ⎕DR 23362775258562638 13511005043687474
NARS2000
8
Keep in mind how Arithmetic Progression Arrays are created and represented; they can fool both the casual programmer as well as an experienced coder. For example, one might try the following to convert from Boolean to integer:
6412 ⎕DR 2 64⍴1 ⍝ APA created
1 0 2 64
However, this doesn't produce the expected result because this particular right argument is an APA, and not a simple Boolean vector of 1's. That is, under certain circumstances, the reshape primitive creates an APA. In this case, the APA is an array with an offset of 1, a multiplier of 0 and a shape of 2 rows and 64 cols. The usefulness of APS's in reducing data storage and processing times outweighs their sometimes added code complexity or additional insight, which may be required.
On the other hand, this expression:
6412 ⎕DR 2 64⍴1 1 ⍝ contrast to prior example - Boolean vec created here, NOT an APA
¯1
¯1
produces the expected result because the right argument is "right upon moment of vector 1 1 creation" - Boolean.
Special Values
There are several special values you may use as a left argument to ⎕DR:
The value 0 displays the datatype of the right argument as a text string so you don't need to remember the datatype numbers.
For example,
⎕DR 'a' 1611 ⍴⎕DR 'a' ⍝ the shape of a scalar is null ⍴⍴⎕DR 'a' 0 ⍝ the shape of the shape of a scalar is always zero; monadic ⎕DR 'a' results in scalar number Z=1611 0 ⎕DR 'a' Character (1611): 16 bits per element ⍝ string result returned where left arg of ⎕DR was zero ⍴0 ⎕DR 'a' 38 ⍝ the shape of the data returned is 38; dyadic 0 ⎕DR 'a' results in a character array, a string of length 38 0 ⎕DR ⍳12 Arithmetic Progression Array (19): 64 bit offset + 64 bit multiplier -- PV1 ⍝ 64-bit signatures re integer numeric progression ⍴0 ⎕DR ⍳12 76 ⍝ again dyadic ⎕DR results in a string, this time of length 76
Note in the above that iota-12 in System Function call 0 ⎕DR ⍳12 - was run using the 64-bit NARS version, hence the 64-bit offset and 64-bit multiplier. Had it been run in 32-bit NARS, it would have returned 32-bit signatures.
Many times in programming for debugging, data scrutiny or other purposes: It is very important to know exactly how the data is represented by the program. ⎕DR or Data Representation is a feature designed to allow close scrutiny of how data is stored in memory and operated on in NARS.
Some arrays have properties that may be displayed by this function:
PV0 This array is a Permutation Vector, origin-0 PV1 This array is a Permutation Vector, origin-1 All2s This array consists of all 2s FPCnnn This array is a VFP and all entries are represented in Precision nnn FPC-Mixed This array is a VFP whose entries are represented in two or more different precisions The value 1 converts between hex-character and floating point computer formats. This argument makes it very useful to view representations of floating point numbers - in order to better understand numeric precisions, program storage formats, debug multi-precision floating-point math routines(by NARS developers) or examine perceived floating point issues.
For example,
⎕PP←99
1 ⎕DR 1.1
3FF199999999999A ⍝ note the hexadecimal char representation of 1.1 is shown at left
⍴1 ⎕DR 1.1
16 ⍝ length of floating pt num 1.1 hex repr = 16 hex-chars = 64-bit-NARS
1 ⎕DR '3fd',13⍴'5'
0.3333333333333333
1 ⎕DR ¯∞ ∞
FFF0000000000000
7FF0000000000000
1 ⎕DR '7fe',13⍴'f' — The largest positive number
1.7976931348623157E308
1 ⎕DR '001',13⍴'0' — The smallest positive number
2.2250738585072014E¯308
1 ⎕DR '801',13⍴'0' — The largest negative number
¯2.2250738585072014E¯308
1 ⎕DR 'ffe',13⍴'f' — The smallest negative number
¯1.7976931348623157E308
The value 2 converts between character and 64-bit integer. This argument makes it easy to see the representation of integers.
For example,
2 ⎕DR ¯1
FFFFFFFFFFFFFFFF
2 ⎕DR '7',15⍴'f' — The largest positive integer
9223372036854775807
2 ⎕DR '8',15⍴'0' — The smallest negative integer
¯9223372036854775808
2 ⎕DR 9223372036854775807 ¯9223372036854775808
7FFFFFFFFFFFFFFF
8000000000000000
A Word of Caution
This system function allows you to create special numbers we don't support in that no other primitive generates these numbers and the behavior of all other primitives on these numbers is undefined. Examples of such special numbers include Quiet NaNs, Signaling NaNs, Negative Zero, and Denormals. If the system doesn't behave as you expect when using these special numbers, don't be surprised.
For example,
⎕CT←0 ⋄ ⎕PP←99
6413 ⎕DR ¯64↑1
¯0
QNaN←6413 ⎕DR ¯64↑13⍴1 — A Quiet NaN (Not a Number)
1 ⎕DR QNaN
FFF8000000000000
QNaN=QNaN
0
1 ⎕DR '000fffffffffffff' — The largest positive denormal
2.225073858507201E¯308
1 ⎕DR '0000000000000001' — The smallest positive denormal
5E¯324
Note: ⎕DR is available as both a monadic and dyadic form system function, you cannot assign a value to it.
System Variables (A value may be assigned to these except for ⎕DM) | |||||||||
---|---|---|---|---|---|---|---|---|---|
⎕ALX | ⎕CT | ⎕DM | ⎕DT | ⎕ELX | ⎕FC | ⎕FEATURE | ⎕FPC | ⎕IC | ⎕IO |
⎕LR | ⎕LX | ⎕PP | ⎕PR | ⎕PW | ⎕RL | ⎕SA | ⎕WSID | ||
Niladic System Functions (a value cannot be assigned to these) | |||||||||
⎕A | ⎕AV | ⎕EM | ⎕ET | ⎕LC | ⎕NNAMES | ⎕NNUMS | ⎕SI | ⎕SYSID | ⎕SYSVER |
⎕T | ⎕TC | ⎕TCBEL | ⎕TCBS | ⎕TCESC | ⎕TCFF | ⎕TCHT | ⎕TCLF | ⎕TCNL | ⎕TCNUL |
⎕TS | ⎕WA | ||||||||
Monadic or dyadic system functions (a value cannot be assigned to these) | |||||||||
⎕AT | ⎕CR | ⎕DC | ⎕DFT | ⎕DL | ⎕DR | ⎕EA | ⎕EC | ⎕ERROR | ⎕ES |
⎕EX | ⎕FMT | ⎕FX | ⎕MF | ⎕NAPPEND | ⎕NC | ⎕NCREATE | ⎕NERASE | ⎕NINFO | ⎕NL |
⎕NLOCK | ⎕NREAD | ⎕NRENAME | ⎕NREPLACE | ⎕NRESIZE | ⎕NSIZE | ⎕NTIE | ⎕NUNTIE | ⎕STOP | ⎕TF |
⎕TRACE | ⎕UCS | ⎕VR | |||||||
Note that quad functions and variables (except for the ⎕A family of functions) are case insensitive |
See Also | ||
System Commands | System Variables and Functions | Operators |
Keyboard | ||||||||||||||
Alt+Shift | ⍪ | ≡ | ≢ | ⍒ | ⍋ | ⌽ | ⍉ | ⊖ | ⍟ | ⍱ | ⍲ | ⍠ | ⌹ | |
Alt | ⋄ | ¨ | ¯ | < | ≤ | ∅ | ≥ | > | ≠ | ∨ | ∧ | × | ÷ | |
Shift | ~ | ! | @ | # | $ | % | ^ | & | * | ( | ) | _ | + | |
Key | ` | 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 0 | - | = | |
Alt+Shift | ⍷ | √ | ⍨ | ⍸ | ⍥ | ⍣ | ⍞ | ⍬ | ⊣ | |||||
Alt | ? | ⍵ | ∊ | ⍴ | § | ↑ | ↓ | ⍳ | ○ | π | ← | → | ⊢ | |
Shift | Q | W | E | R | T | Y | U | I | O | P | { | } | | | |
Key | q | w | e | r | t | y | u | i | o | p | [ | ] | \ | |
Alt+Shift | ∫ | ∂ | ⌻ | ⍢ | ⍙ | ⍤ | ⍫ | ⌷ | ||||||
Alt | ⍺ | ⌈ | ⌊ | ∞ | ∇ | ∆ | ∘ | ‼ | ⎕ | ⍎ | ⍕ | |||
Shift | A | S | D | F | G | H | J | K | L | : | " | |||
Key | a | s | d | f | g | h | j | k | l | ; | ' | |||
Alt+Shift | ⊆ | ⊇ | χ | ⍡ | ⍭ | ⊙ | ||||||||
Alt | ⊂ | ⊃ | ∩ | ∪ | ⊥ | ⊤ | ⍦ | ⍝ | ⍀ | ⌿ | ||||
Shift | Z | X | C | V | B | N | M | < | > | ? | ||||
Key | z | x | c | v | b | n | m | , | . | / |
NARS 2000 Lang Tool Bar |
← | → | + | - | × | ÷ | * | ⍟ | ⌹ | ○ | ! | ? | √ | | | ⌈ | ⌊ | ⊥ | ⊤ | ⊣ | ⊢ | |||
≡ | ≢ | < | ≤ | = | ≥ | > | ≠ | ∨ | ∧ | ⍱ | ⍲ | ↑ | ↓ | ⊂ | ⊃ | ⌷ | ⍋ | ⍒ | |||||
⍳ | ∊ | ⍸ | ⍷ | ∪ | ∩ | ⊆ | ⊇ | ~ | § | π | .. | , | ⍪ | ⍴ | ⌽ | ⊖ | ⍉ | ||||||
/ | \ | ⌿ | ⍀ | ⊙ | ¨ | ⍨ | ⍤ | ⍣ | ⍡ | ⍥ | ⍦ | . | ∘ | ⍠ | ‼ | ⌻ | ∂ | ∫ | ⍞ | ⎕ | ⍎ | ⍕ | |
⋄ | ⍝ | ∇ | ∆ | ⍙ | _ | ⍺ | ⍵ | ¯ | ⍬ | ∞ | ∅ | ||||||||||||
Second Row | i j k | i j k l | g | p | r | v | x |