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millfork/docs/lang/literals.md
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Literals and initializers

Numeric literals

Decimal: 1, 10

Binary: %0101, 0b101001

Quaternary: 0q2131

Octal: 0o172

Hexadecimal: $D323, 0x2a2

When using Intel syntax for inline assembly, another hexadecimal syntax is available: 0D323H, 2a2h. It is not allowed in any other places.

String literals

String literals can be used as either array initializers or expressions of type pointer.

String literals are equivalent to constant arrays. Writing to them via their pointer is undefined behaviour.

If a string literal is used as an expression, then the text data will be located in the default code segment, regardless of which code segment the current function is located it. This may be subject to change in future releases.

String literals are surrounded with double quotes and optionally followed by the name of the encoding:

"this is a string" ascii
"this is also a string"

If there is no encoding name specified, then the default encoding is used. Two encoding names are special and refer to platform-specific encodings: default and scr.

You can also append z to the name of the encoding to make the string zero-terminated. This means that the string will have one extra byte appended, equal to nullchar. The exact value of nullchar is encoding-dependent:

  • in the vectrex encoding it's 128,

  • in the zx80 encoding it's 1,

  • in the zx81 encoding it's 11,

  • in the utf16be and utf16le encodings it's exceptionally two bytes: 0, 0

  • in other encodings it's 0 (this might be a subject to change in future versions).

    "this is a zero-terminated string" asciiz "this is also a zero-terminated string"z

Most characters between the quotes are interpreted literally. To allow characters that cannot be inserted normally, each encoding may define escape sequences. Every encoding is guaranteed to support at least {q} for double quote and {apos} for single quote/apostrophe.

The number of bytes used to represent given characters may differ from the number of the characters. For example, the petjp, msx_jp and jis encodings represent ポ as two separate characters, and therefore two bytes.

For the list of all text encodings and escape sequences, see this page.

In some encodings, multiple characters are mapped to the same byte value, for compatibility with multiple variants.

If the characters in the literal cannot be encoded in particular encoding, an error is raised. However, if the command-line option -flenient-encoding is used, then literals using default and scr encodings replace unsupported characters with supported ones, skip unsupported escape sequences, and a warning is issued. For example, if -flenient-encoding is enabled, then a literal "£¥↑ž©ß" is equivalent to:

  • "£Y↑z(C)ss" if the default encoding is pet

  • "£Y↑z©ss" if the default encoding is bbc

  • "?Y^z(C)ss" if the default encoding is ascii

  • "?Y^ž(C)ss" if the default encoding is iso_yu

  • "?Y^z(C)ß" if the default encoding is iso_de

  • "?¥^z(C)ss" if the default encoding is jisx

  • "£¥^z(C)β" if the default encoding is msx_intl

Note that the final length of the string may vary.

Character literals

Character literals are surrounded by single quotes and optionally followed by the name of the encoding:

'x' ascii
'W'

Character literals have to be separated from preceding operators with whitespace:

a='a'    // wrong 
a = 'a'  // ok 

From the type system point of view, they are constants of type byte.

If the character cannot be represented as one byte, an error is raised.

For the list of all text encodings and escape sequences, see this page.

If the characters in the literal cannot be encoded in particular encoding, an error is raised. However, if the command-line option -flenient-encoding is used, then literals using default and scr encodings replace unsupported characters with supported ones. If the replacement is one character long, only a warning is issued, otherwise an error is raised.

Struct constructors

You can create a constant of a given struct type by listing constant values of fields as arguments:

struct point { word x, word y }
point(5,6)

Array initializers

An array is initialized with either:

  • (only byte arrays) a string literal

  • (only byte arrays) a file expression

  • a for-style expression

  • (only byte arrays) a format, followed by an array initializer:

    • @word_le: for every term of the array initializer, emit two bytes, first being the low byte of the value, second being the high byte:
      @word_le [$1122] is equivalent to [$22, $11]

    • @word_be like the above, but opposite:
      @word_be [$1122] is equivalent to [$11, $22]

    • @word: equivalent to @word_le on little-endian architectures and @word_be on big-endian architectures

    • @long, @long_le, @long_be: similar, but with four bytes
      @long_le [$11223344] is equivalent to [$44, $33, $22, $11]
      @long_be [$11223344] is equivalent to [$11, $22, $33, $44]

    • @struct: every term of the initializer is interpreted as a struct constructor (see below) and treated as a list of bytes with no padding
      @struct [s(1, 2)] is equivalent to [1, 2] when struct s {byte x, byte y} is defined
      @struct [s(1, 2), s(3, 4)] is equivalent to [1, 0, 2, 0, 3, 0, 4, 0] on little-endian machines when struct s {word x, word y} is defined

  • a list of literals and/or other array initializers, surrounded by brackets:

      array a = [1, 2]
      array b = "----" scr
      array c = ["hello world!" ascii, 13]
      array d = file("d.bin")
      array e = file("d.bin", 128, 256)
      array f = for x,0,until,8 [x * 3 + 5]  // equivalent to [5, 8, 11, 14, 17, 20, 23, 26]
      array(point) g = [point(2,3), point(5,6)]
      array(point) i = for x,0,until,100 [point(x, x+1)]
    

Trailing commas ([1, 2,]) are not allowed.

The parameters for file are: file path, optional start offset, optional length (start offset and length have to be either both present or both absent).

The for-style expression has a variable, a starting index, a direction, a final index, and a parameterizable array initializer. The initializer is repeated for every value of the variable in the given range.

Struct constructors look like a function call, where the callee name is the name of the struct type and the parameters are the values of fields in the order of declaration.
Fields of arithmetic, pointer and enum types are declared using normal expressions.
Fields of struct types are declared using struct constructors. Fields of union types cannot be declared.

What might be useful is the fact that the compiler allows for built-in trigonometric functions in constant expressions only:

  • sin(x, n) returns n·sin(xπ/128)

  • cos(x, n) returns n·cos(xπ/128)

  • tan(x, n) returns n·tan(xπ/128)