prog8/docs/source/syntaxreference.rst
2018-10-30 20:29:03 +01:00

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.. _syntaxreference:
================
Syntax Reference
================
Module file
-----------
This is a file with the ``.p8`` suffix, containing *directives* and *code blocks*, described below.
The file is a text file wich can also contain:
Lines, whitespace, indentation
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
Line endings are significant because *only one* declaration, statement or other instruction can occur on every line.
Other whitespace and line indentation is arbitrary and ignored by the compiler.
You can use tabs or spaces as you wish.
Source code comments
^^^^^^^^^^^^^^^^^^^^
Everything after a semicolon ``;`` is a comment and is ignored.
If the whole line is just a comment, it will be copied into the resulting assembly source code.
This makes it easier to understand and relate the generated code. Examples::
A = 42 ; set the initial value to 42
; next is the code that...
.. _directives:
Directives
-----------
.. data:: %output <type>
Level: module.
Global setting, selects program output type. Default is ``prg``.
- type ``raw`` : no header at all, just the raw machine code data
- type ``prg`` : C64 program (with load address header)
.. data:: %launcher <type>
Level: module.
Global setting, selects the program launcher stub to use.
Only relevant when using the ``prg`` output type. Defaults to ``basic``.
- type ``basic`` : add a tiny C64 BASIC program, whith a SYS statement calling into the machine code
- type ``none`` : no launcher logic is added at all
.. data:: %zeropage <style>
Level: module.
Global setting, select ZeroPage handling style. Defaults to ``kernalsafe``.
- style ``kernalsafe`` -- use the part of the ZP that is 'free' or only used by BASIC routines,
and don't change anything else. This allows full use of KERNAL ROM routines (but not BASIC routines),
including default IRQs during normal system operation.
- style ``basicsafe`` -- the most restricted mode; only use the handful 'free' addresses in the ZP, and don't
touch change anything else. This allows full use of BASIC and KERNAL ROM routines including default IRQs
during normal system operation.
- style ``full`` -- claim the whole ZP for variables for the program, overwriting everything,
except the few addresses mentioned above that are used by the system's IRQ routine.
Even though the default IRQ routine is still active, it is impossible to use most BASIC and KERNAL ROM routines.
This includes many floating point operations and several utility routines that do I/O, such as ``print_string``.
It is also not possible to cleanly exit the program, other than resetting the machine.
This option makes programs smaller and faster because many more variables can
be stored in the ZP, which is more efficient.
Also read :ref:`zeropage`.
.. data:: %zpreserved <fromaddress>,<toaddress>
Level: module.
Global setting, can occur multiple times. It allows you to reserve or 'block' a part of the zeropage so
that it will not be used by the compiler.
.. data:: %address <address>
Level: module.
Global setting, set the program's start memory address
- default for ``raw`` output is ``$c000``
- default for ``prg`` output is ``$0801``
- cannot be changed if you select ``prg`` with a ``basic`` launcher;
then it is always ``$081e`` (immediately after the BASIC program), and the BASIC program itself is always at ``$0801``.
This is because the C64 expects BASIC programs to start at this address.
.. data:: %import <name>
Level: module, block.
This reads and compiles the named module source file as part of your current program.
Symbols from the imported module become available in your code,
without a module or filename prefix.
You can import modules one at a time, and importing a module more than once has no effect.
.. data:: %option <option> [, <option> ...]
Level: module.
Sets special compiler options.
For now, only the ``enable_floats`` option is recognised, which will tell the compiler
to deal with floating point numbers (by using various subroutines from the Commodore-64 kernal).
Otherwise, floating point support is not enabled.
.. data:: %asmbinary "<filename>" [, <offset>[, <length>]]
Level: block.
This directive can only be used inside a block.
The assembler will include the file as binary bytes at this point, prog8 will not process this at all.
The optional offset and length can be used to select a particular piece of the file.
.. data:: %asminclude "<filename>", scopelabel
Level: block.
This directive can only be used inside a block.
The assembler will include the file as raw assembly source text at this point,
prog8 will not process this at all, with one exception: the labels.
The scopelabel argument will be used as a prefix to access the labels from the included source code,
otherwise you would risk symbol redefinitions or duplications.
.. data:: %breakpoint
Level: block, subroutine.
Defines a debugging breakpoint at this location. See :ref:`debugging`
.. data:: %asm {{ ... }}
Level: block, subroutine.
Declares that there is *inline assembly code* in the lines enclosed by the curly braces.
This code will be written as-is into the generated output file.
The assembler syntax used should be for the 3rd party cross assembler tool that Prog8 uses.
Note that the start and end markers are both *double curly braces* to minimize the chance
that the inline assembly itself contains either of those. If it does contain a ``}}``,
the parsing of the inline assembler block will end prematurely and cause compilation errors.
Identifiers
-----------
Naming things in Prog8 is done via valid *identifiers*. They start with a letter or underscore,
and after that, a combination of letters, numbers, or underscores. Examples of valid identifiers::
a
A
monkey
COUNTER
Better_Name_2
_something_strange_
Code blocks
-----------
A named block of actual program code. Itefines a *scope* (also known as 'namespace') and
can contain Prog8 *code*, *directives*, *variable declarations* and *subroutines*::
~ <blockname> [<address>] {
<directives>
<variables>
<statements>
<subroutines>
}
The <blockname> must be a valid identifier.
The <address> is optional. If specified it must be a valid memory address such as ``$c000``.
It's used to tell the compiler to put the block at a certain position in memory.
Also read :ref:`blocks`. Here is an example of a code block, to be loaded at ``$c000``::
~ main $c000 {
; this is code inside the block...
}
Labels
------
To label a position in your code where you can jump to from another place, you use a label::
nice_place:
; code ...
It's just an identifier followed by a colon ``:``. It's allowed to put the next statement on
the same line, after the label.
Variables and value literals
----------------------------
The data that the code works on is stored in variables. Variable names have to be valid identifiers.
Values in the source code are written using *value literals*. In the table of the supported
data types below you can see how they should be written.
Variable declarations
^^^^^^^^^^^^^^^^^^^^^
Variables should be declared with their exact type and size so the compiler can allocate storage
for them. You must give them an initial value as well. That value can be a simple literal value,
or an expression. The syntax is::
<datatype> <variable name> [ = <initial value> ]
Various examples::
word thing = 0
byte counter = len([1, 2, 3]) * 20
byte age = 2018 - 1974
float wallet = 55.25
str name = "my name is Irmen"
word address = #counter
byte[5] values = [11, 22, 33, 44, 55]
byte[5] values = 255 ; initialize with five 255 bytes
Data types
^^^^^^^^^^
Prog8 supports the following data types:
=============== ======================= ================= =========================================
type identifier type storage size example var declaration and literal value
=============== ======================= ================= =========================================
``byte`` signed byte 1 byte = 8 bits ``byte myvar = -22``
``ubyte`` unsigned byte 1 byte = 8 bits ``ubyte myvar = $8f``
-- boolean 1 byte = 8 bits ``byte myvar = true`` or ``byte myvar == false``
The true and false are actually just aliases
for the byte values 1 and 0.
``word`` signed word 2 bytes = 16 bits ``word myvar = -12345``
``uword`` unsigned word 2 bytes = 16 bits ``uword myvar = $8fee``
``float`` floating-point 5 bytes = 40 bits ``float myvar = 1.2345``
stored in 5-byte cbm MFLPT format
``byte[x]`` signed byte array x bytes ``byte[4] myvar = [1, 2, 3, 4]``
``ubyte[x]`` unsigned byte array x bytes ``ubyte[4] myvar = [1, 2, 3, 4]``
``word[x]`` signed word array 2*x bytes ``word[4] myvar = [1, 2, 3, 4]``
``uword[x]`` unsigned word array 2*x bytes ``uword[4] myvar = [1, 2, 3, 4]``
``float[x]`` floating-point array 5*x bytes ``float[4] myvar = [1.1, 2.2, 3.3, 4.4]``
``str`` string (petscii) varies ``str myvar = "hello."``
implicitly terminated by a 0-byte
``str_p`` pascal-string (petscii) varies ``str_p myvar = "hello."``
implicit first byte = length, no 0-byte
``str_s`` string (screencodes) varies ``str_s myvar = "hello."``
implicitly terminated by a 0-byte
``str_ps`` pascal-string varies ``str_ps myvar = "hello."``
(screencodes) implicit first byte = length, no 0-byte
=============== ======================= ================= =========================================
**hexadecimal numbers:** you can use a dollar prefix to write hexadecimal numbers: ``$20ac``
**binary numbers:** you can use a percent prefix to write binary numbers: ``%10010011``
**character values:** you can use a single character in quotes like this ``'a'`` for the Petscii byte value of that character.
**``byte`` versus ``word`` values:**
- When an integer value ranges from 0..255 the compiler sees it as a ``ubyte``. For -128..127 it's a ``byte``.
- When an integer value ranges from 256..65535 the compiler sees it as a ``uword``. For -32768..32767 it's a ``word``.
- When a hex number has 3 or 4 digits, for example ``$0004``, it is seen as a ``word`` otherwise as a ``byte``.
- When a binary number has 9 to 16 digits, for example ``%1100110011``, it is seen as a ``word`` otherwise as a ``byte``.
- You can force a byte value into a word value by adding the ``.w`` datatype suffix to the number: ``$2a.w`` is equivalent to ``$002a``.
.. todo::
omit the array size in the var decl if an initialization array is given?
**@todo pointers/addresses? (as opposed to normal WORDs)**
Memory mapped variables
^^^^^^^^^^^^^^^^^^^^^^^
The ``memory`` keyword is used in front of a data type keyword, to say that no storage
should be allocated by the compiler. Instead, the (mandatory) value assigned to the variable
should be the *memory address* where the value is located::
memory byte BORDER = $d020
Constants
^^^^^^^^^
All variables can be assigned new values unless you use the ``const`` keyword.
The initial value will now be evaluated at compile time (it must be a compile time constant expression).
This is only valid for the simple numeric types (byte, word, float)::
const byte max_age = 99
Reserved names
^^^^^^^^^^^^^^
The following names are reserved, they have a special meaning::
A X Y ; 6502 hardware registers
AX AY XY ; 16-bit pseudo register pairs
Range expression
^^^^^^^^^^^^^^^^
A special value is the *range expression* ( ``<startvalue> to <endvalue>`` )
which represents a range of numbers or characters,
from the starting value to (and including) the ending value.
If used in the place of a literal value, it expands into the actual array of values::
byte[100] array = 100 to 199 ; initialize array with [100, 101, ..., 198, 199]
Array indexing
^^^^^^^^^^^^^^
Strings and arrays are a sequence of values. You can access the individual values by indexing.
Syntax is familiar with brackets: ``arrayvar[x]`` ::
array[2] ; the third byte in the array (index is 0-based)
string[4] ; the fifth character (=byte) in the string
Operators
---------
.. todo::
address-of: ``#``
Takes the address of the symbol following it: ``word address = #somevar``
arithmetic: ``+`` ``-`` ``*`` ``/`` ``//`` ``**`` ``%``
``+``, ``-``, ``*``, ``/`` are the familiar arithmetic operations.
``//`` is the floor-divide, the division resulting in a whole number rounded towards minus infinity.
``**`` is the power operator: ``3 ** 5`` is equal to 3*3*3*3*3 and is 243.
``%`` is the remainder operator: ``25 % 7`` is 4.
bitwise arithmetic: ``&`` ``|`` ``^`` ``~``
``&`` is bitwise and, ``|`` is bitwise or, ``^`` is bitwise xor, ``~`` is bitwise invert (this one is an unary operator)
assignment: ``=``
Sets the target on the LHS (left hand side) of the operator to the value of the expression on the RHS (right hand side).
Note that an assignment sometimes is not possible or supported.
augmented assignment: ``+=`` ``-=`` ``*=`` ``/=`` ``**=`` ``&=`` ``|=`` ``^=``
Syntactic sugar; ``A += X`` is equivalent to ``A = A + X``
postfix increment and decrement: ``++`` ``--``
Syntactic sugar; ``A++`` is equivalent to ``A = A + 1``, and ``A--`` is equivalent to ``A = A - 1``.
Because these operations are so common, we have these short forms.
comparison: ``!=`` ``<`` ``>`` ``<=`` ``>=``
Equality, Inequality, Less-than, Greater-than, Less-or-Equal-than, Greater-or-Equal-than comparisons.
The result is a 'boolean' value 'true' or 'false' (which in reality is just a byte value of 1 or 0).
logical: ``not`` ``and`` ``or`` ``xor``
These operators are the usual logical operations that are part of a logical expression to reason
about truths (boolean values). The result of such an expression is a 'boolean' value 'true' or 'false'
(which in reality is just a byte value of 1 or 0).
range creation: ``to``
Creates a range of values from the LHS value to the RHS value, inclusive.
These are mainly used in for loops to set the loop range. Example::
0 to 7 ; range of values 0, 1, 2, 3, 4, 5, 6, 7 (constant)
A = 5
X = 10
A to X ; range of 5, 6, 7, 8, 9, 10
byte[4] array = 10 to 13 ; sets the array to [1, 2, 3, 4]
for i in 0 to 127 {
; i loops 0, 1, 2, ... 127
}
precedence grouping in expressions, or subroutine parameter list: ``(`` *expression* ``)``
Parentheses are used to group parts of an expression to change the order of evaluation.
(the subexpression inside the parentheses will be evaluated first):
``(4 + 8) * 2`` is 24 instead of 20.
Parentheses are also used in a subroutine call, they follow the name of the subroutine and contain
the list of arguments to pass to the subroutine: ``big_function(1, 99)``
Subroutine / function calls
---------------------------
You call a subroutine like this::
[ result = ] subroutinename_or_address ( [argument...] )
; example:
resultvariable = subroutine ( arg1, arg2, arg3 )
Arguments are separated by commas. The argument list can also be empty if the subroutine
takes no parameters.
Subroutine definitions
----------------------
The syntax is::
sub <identifier> ( [parameters] ) [ -> returntype ] {
... statements ...
}
; example:
sub triple_something (amount: word) -> word {
return X * 3
}
The open curly brace must immediately follow the subroutine result specification on the same line,
and can have nothing following it. The close curly brace must be on its own line as well.
The parameters is a (possibly empty) comma separated list of "<parametername>: <datatype>" pairs specifying the input parameters.
The return type has to be specified if the subroutine returns a value.
.. todo::
asmsub with assigning memory address to refer to predefined ROM subroutines
asmsub with a regular body to precisely control what registers are used to call the subroutine
Loops
-----
for loop
^^^^^^^^
The loop variable must be a register or a byte/word variable. It must be defined in the local scope (to reuse
an existing variable), or you can declare it in the for loop directly to make a new one that is only visible
in the body of the for loop.
The expression that you loop over can be anything that supports iteration (such as ranges like ``0 to 100``,
array variables and strings) *except* floating-point arrays (because a floating-point loop variable is not supported).
You can use a single statement, or a statement block like in the example below::
for [byte | word] <loopvar> in <expression> [ step <amount> ] {
; do something...
break ; break out of the loop
continue ; immediately enter next iteration
}
For example, this is a for loop using the existing byte variable ``i`` to loop over a certain range of numbers::
for i in 20 to 155 {
; do something
}
And this is a loop over the values of the array ``fibonacci_numbers`` where the loop variable is declared in the loop itself::
word[20] fibonacci_numbers = [0, 1, 1, 2, 3, 5, 8, 13, 21, 34, 55, 89, 144, 233, 377, 610, 987, 1597, 2584, 4181]
for word fibnr in fibonacci_numbers {
; do something
}
while loop
^^^^^^^^^^
As long as the condition is true (1), repeat the given statement(s).
You can use a single statement, or a statement block like in the example below::
while <condition> {
; do something...
break ; break out of the loop
continue ; immediately enter next iteration
}
repeat--until loop
^^^^^^^^^^^^^^^^^^
Until the given condition is true (1), repeat the given statement(s).
You can use a single statement, or a statement block like in the example below::
repeat {
; do something...
break ; break out of the loop
continue ; immediately enter next iteration
} until <condition>
Conditional Execution and Jumps
-------------------------------
Unconditional jump
^^^^^^^^^^^^^^^^^^
To jump to another part of the program, you use a ``goto`` statement with an addres or the name
of a label or subroutine::
goto $c000 ; address
goto name ; label or subroutine
Notice that this is a valid way to end a subroutine (you can either ``return`` from it, or jump
to another piece of code that eventually returns).
Conditional execution
^^^^^^^^^^^^^^^^^^^^^
With the 'if' / 'else' statement you can execute code depending on the value of a condition::
if <expression> <statements> [else <statements> ]
where <statements> can be just a single statement for instance just a ``goto``, or it can be a block such as this::
if <expression> {
<statements>
} else {
<alternative statements>
}
**Special status register branch form:**
There is a special form of the if-statement that immediately translates into one of the 6502's branching instructions.
It is almost the same as the regular if-statement but it lacks a contional expression part, because the if-statement
itself defines on what status register bit it should branch on::
if_XX <statements> [else <statements> ]
where <statements> can be just a single statement for instance just a ``goto``, or it can be a block such as this::
if_XX {
<statements>
} else {
<alternative statements>
}
The XX corresponds to one of the eigth branching instructions so the possibilities are:
``if_cs``, ``if_cc``, ``if_eq``, ``if_ne``, ``if_pl``, ``if_mi``, ``if_vs`` and ``if_vc``.
It can also be one of the four aliases that are easier to read: ``if_z``, ``if_nz``, ``if_pos`` and ``if_neg``.