2023-02-20 14:33:30 +01:00
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# "Stack Programming Language" =SPL
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SPL is a simple, concise, concatenative scripting language.
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Example:
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```js
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2023-03-28 02:56:05 +02:00
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func main { mega | with args ;
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2023-02-20 14:33:30 +01:00
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"Running with args: " print
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2023-03-28 02:56:05 +02:00
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args:iter
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2023-02-20 14:33:30 +01:00
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{ str | " " concat } swap:map
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&print swap:foreach
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"" println
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2023-04-08 09:51:40 +02:00
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println <{ "and with that, we're done" }
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2023-02-20 14:34:40 +01:00
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0
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2023-02-20 14:33:30 +01:00
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}
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```
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## "5 minutes" SPL:in
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- `def` introduces a variable.
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```js
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def a
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```
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- Writing a constant pushes it to the stack. This works with strings and numbers.
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```js
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"Hello, World!"
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```
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- Use `=<name>` to assign the topmost value to a variable. In this case, that is
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"Hello, World!"
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```js
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=a
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```
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- This can be written as a single line - line breaks are always optional, and
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equal to a space.
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```js
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def a "Hello, World!" =a
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```
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- Variables consist of two functions: `<name>` and `=<name>`. Use `<name>` to
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obtain the value again.
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```js
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a
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```
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- The `print` function is used to print a value. It takes one value from the stack
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and prints it without a newline. To print with a newline, use `println`. The
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semicolon at the end means 'if this function returns anything, throw it away'.
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This can be used on strings to make them comments, but is not available for
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numeric constants.
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```js
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println;
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```
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```txt
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Hello, World!
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```
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- The `func` keyword introduces a function. The `{ mega |` is the return type
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declaration, which in SPL is done within the block. In this case, our function
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returns one of the `mega` type, which is a 128-bit integer.
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```js
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func main { mega |
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```
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2023-03-28 02:57:26 +02:00
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- The `with` declaration will be explained below. It defines the `args` argument.
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```js
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with args ;
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```
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2023-02-20 14:33:30 +01:00
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- Now, we can write code like before:
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```js
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def list
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```
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- SPL has a varying-length array type, the list. To create any construct (object),
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we use `:new`.
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```js
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List:new =list
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```
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- To add to the end of a list, we `push` to it. All construct methods are
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written with a colon, like before in the `new` example.
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```js
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"Hello," list:push
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```
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Note the lowercase `list`, because we are pushing to the construct in the
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variable.
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- Now, let's also push "World!".
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```js
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"World" list:push
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```
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Beautiful. I'd like to print it now, but how?
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- We can't print a list directly (with what we know so far), but we can iterate
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through it!
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```js
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{ | with item ;
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item print;
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" " print;
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} list:foreach;
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"" println;
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```
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**There is a lot to unpack here!**
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- `{ |` creates a closure with no return type (in C-style languages, that'd be
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a void function).
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- `with item ;` declares arguments. This is optional, and not needed if the
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function does not take arguments. Running `"a" "b" "c"` and calling
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something with a b c ; will leave each letter in the corresponding variable.
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- We already know what print does - it prints the item and a space in this
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case.
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- The semicolons mean we don't care about the result of printing. In this
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case, printing does not return anything, but I added the semicolons just for
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clarity or in case it did.
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- `}` ends the closure, and puts it on the top of our stack.
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- `list:foreach` calls the `foreach` method on our `list`, which is declared
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with callable this ; - that means we need to provide one argument along with
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the implied `this` argument (it can have any name - the interpreter does not
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care about names in any way - `this` is just convention). The `callable`
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here is *not* a type!
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- `foreach` also does not return anything, but I added the semicolon for
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clarity.
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- We then print a newline.
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```txt
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Hello, World!
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```
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- SPL has Ranges, constructed using `<lower> <upper> Range:new`. You can iterate
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over them.
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```js
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0 5 Range:new:iter
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```
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- Now, let's multiply all of these values by 5.
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```js
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{ mega | 5 * } swap:map
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```
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Wait, what?
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Why is there suddenly an inconsistency in method calls, the iterator isn't
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being called, it's something else now!
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It sure does look like it, doesn't it? `swap` swaps the topmost two values on
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the stack. `a b -> b a`. That means we are actually calling to our iterator.
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The closure and the iterator are swapped before the call is made. `swap:map`
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is a more concise way of writing `swap :map`.
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2023-02-20 14:33:30 +01:00
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The map function on the iterator (which is available through `:iter` on most
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collection constructs) is used to apply a function to all items in the
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iterator. The closure here actually takes an argument, but the with
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declaration is omitted. The longer version would be:
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```js
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{ mega | with item ;
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item 5 *
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}
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```
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But this is quite clunky, so when arguments are directly passed on to the next
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function, they are often simply kept on the stack. The `*` is simply a
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function taking two numbers and multilying them. The same goes for `+`, `-`,
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`%`, and `/`. `a b -` is equivalent to `a - b` in other languages. `lt`,
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`gt`, and `eq` are used to compare values.
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Returning is simply done by leaving something on the stack when the function
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exits, and the return declaration *can* technically be left off, but the
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semicolon won't be able to determine the amount of constructs to discard that
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way, so this should never be done unless you're absolutely sure. In this case,
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we are absolutely sure that it will never be called with a
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semicolon, because the mapping iterator has no use for the closure other than
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the returned object (which is the case for most closures in practice.),
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therefore we could even omit the return type declaration and get `{ | 5 *}`.
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Neat!
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- We can use `foreach` on iterators just like arrays. `_str` is used to convert
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a number to a string.
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```js
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{ | _str println } swap:foreach
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```
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```txt
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0
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5
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10
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15
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20
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```
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Ranges are inclusive of the lower bound and exclusive in the upper bound.
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They are often used similarly to the (pseudocode) equivalent in other
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languages:
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```java
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for(int i = 0; i < 5; i++) { println((String) i * 5); }
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```
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2023-04-08 09:51:40 +02:00
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- SPL actually isn't fully concatenative. It supports postfix arguments as well:
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```js
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println <{ "and with that, we're done" }
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```
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This is actually not a special interpreter feature, more so is it a special
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lexer feature. This is 100% equivalent with the non-postfix version, where the
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string is right before the `println`.
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The same can be done for object calls. Let's rewrite the previous code with
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postfix:
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```js
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Range:new <{ 0 5 }
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:iter
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:map <{ { | 5 * } }
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:foreach <{ { | _str println } }
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```
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I lied. This is now no longer 100% equivalent. Let's look at what happens
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under the hood.
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2023-04-08 17:59:04 +02:00
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```js
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call Range
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objpush
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const mega 0
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const mega 5
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objpop
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objcall new
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objcall iter
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objpush
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const func 0
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const mega 5
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call *
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end
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objpop
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objcall map
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objpush
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const func 0
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call _str
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call println
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end
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objpop
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objcall foreach
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```
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You can see there are now `objpush` and `objpop` instructions. This is doing
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the job that `swap` used to do in our previous example. However, swap can only
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swap the topmost values, but postfix arguments allow any amount. That's why
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there is a special instruction just for that. It can also be used through AST
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modifications, but there is no way to get it in normal language use as it can
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cause interpreter panics when they are used wrongly.
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`objpush` and `objpop` operate on a separate stack, called the objcall stack,
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as opposed to the main object stack.
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2023-02-20 14:33:30 +01:00
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More of this tutorial to follow.
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2023-08-04 22:39:05 +02:00
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## Embedding rust into SPL
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Because SPL does not nearly have a complete standard library, embedding rust is required for many tasks.
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This can be done as follows
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```
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> cat rust-test.spl
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func main { |
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1 rusty-test _str println
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0
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}
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func rusty-test @rust !{
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println!("hii");
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let v = #pop:Mega#;
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#push(v + 1)#;
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}
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> spl --build rust-test.spl demo
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---snip---
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> ./spl-demo/target/release/spl-demo rust-test.spl
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hii
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2
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```
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As you can see, it's relatively straight-forward to do; but there are some major limitations right now:
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- It's a new binary, and can't be linked into the currently running program
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- No crates can be added automatically at the moment
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The second one is easy to fix, but I intend to fix the first one first. Sadly, fixing it requires
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compiling the code as a dynamic library and also getting it to work with the program its running in.
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If anyone knows how to do this properly, I'd REALLY appreciate a PR or issue explaining it.
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