rust_multistackvm

Crates.iorust_multistackvm
lib.rsrust_multistackvm
version0.17.0
sourcesrc
created_at2024-09-15 19:58:09.878375
updated_at2024-10-29 21:04:51.658991
descriptionStack-based virtual machine on top of rust_multistack crate
homepage
repositoryhttps://github.com/vulogov/rust_multistackvm
max_upload_size
id1375734
size2,558,424
Vladimir Uogov (vulogov)

documentation

README

What's on your stack ?

rust_multistackvm is a Rust crate that implements a Virtual Machine operating on top of a two-dimensional stack rather than a single stack and registers. This two-dimensional stack structure, defined in the rust_multistack crate, offers functionality for the Rust programming language. It can contain dynamically typed values provided by the rust_dynamic crate, organized in a stack of stacks structure. This approach assists in achieving data isolation and control. At its core is a circular ring buffer of references on the stacks. The actual data stacks could be anonymous or named. Users can define and manipulate stacks and perform data manipulation through callbacks.

Show me the code!

let mut vm = VM::new();
vm.apply(Value::from(42.0).unwrap()).unwrap();
let val = vm.stack.pull().expect("No pull() happens");
assert_eq!(val.cast_float().unwrap(), 42.0 as f64);

After creating a Virtual Machine, we assigned it a number. The MultistackVM's default behavior is to push data to the current stack. If the passed value is a type of CALL, it executes the requested function. It's as simple as that. We retrieve data from the current stack upon evaluating the number, confirming its value as 42.0.

let mut vm = VM::new();
vm.apply(Value::call("list".to_string(), Vec::new())).unwrap();
vm.apply(Value::call(":".to_string(), Vec::new())).unwrap();
vm.apply(Value::from(42.0).unwrap()).unwrap();
vm.apply(Value::call(";".to_string(), Vec::new())).unwrap();
let val = vm.stack.pull().expect("No pull() happens");
let list_val = val.cast_list().unwrap();
assert_eq!(list_val[0].cast_float().unwrap(), 42.0 as f64);

This snippet demonstrated two important concepts:

  • Execution of the VM functions;
  • Autoadd feature.

When we pass Value::call("list".to_string(), Vec::new()) to VM::apply(), the default behavior is to execute the VM function or command or lambda. Function list is defined as a VM inline function, and this function puts an empty Value::list to the current stack.

What is auto-add?

When working with a VM, you may need to create a list or define a lambda and store some content. By default, the VM stores values on the stack or executes commands. The VM command : changes this behavior, bringing the VM into automated mode. In this mode, when the VM evaluates the data, instead of pushing the value to the stack, it pushes the data to the LIST or LAMBDA value on top of the current stack. For example, the Value::from(42.0) doesn't go to the stack but to the LIST stored earlier. The VM command ; resets the VM behavior to the default. When casting LIST to Vector and checking an element in the list, we can verify that the autoadd feature is working.

How to control VM

All virtual machine (VM) controls are accessed through methods implemented within the VM struct. Data processing is carried out using inline functions defined for either the VM or stack TS structures. The TS inline functions primarily handle stack management, while the VM inline functions are dedicated to overall logic and data processing. A VM inline function is a self-contained function that takes a reference to the VM as a parameter and returns a Result<> containing a reference to the same VM or an Error. Here is an example of VM inline function implementation.

pub fn stdlib_print_inline(vm: &mut VM) -> Result<&mut VM, Error> {
    if vm.stack.current_stack_len() < 1 {
        bail!("Stack is too shallow for inline clear_in()");
    }
    match vm.stack.pull() {
        Some(value) => {
            print!("{}", &value);
        }
        None => {
            bail!("PRINT returns: NO DATA");
        }
    }
    Ok(vm)
}

In this straightforward example, each inline function clearly defines how it consumes data from the stack and outlines the expected behavior of that data. And here is an example of how you register new inline function.

let _ = vm.register_inline("print".to_string(), stdlib_print_inline);

Methods of VM struct

Function name Description
VM::new() Creates a new instance of the VM. Adds one named stack "main" to serve as initial default stack. Imports all internal TS and VM standard libraries
VM::register_alias() Creates alias for existing lambda or inline functions
VM::is_alias() Check if alias exists
VM::unregister_alias() Removes existing alias
VM::get_alias() Return alias or raise an Error
VM::register_inline() Register new inline functions
VM::is_inline() Check if inline function exists
VM::unregister_inline() Removes existing inline function
VM::get_inline() Return inline function or raise an Error
VM::register_lambda() Register new lambda functions
VM::is_lambda() Check if lambda function exists
VM::unregister_lambda() Removes existing lambda function
VM::get_lambda() Return lambda function or raise an Error
VM::lambda_eval() Evaluate lambda passed as parameter
VM::lambda_eval_in() Evaluate lambda passed as parameter in the context of named stack
VM::apply() Evaluate single Value in VM
VM::apply_in() Evaluate single Value in VM in the context of named stack

Inline functions of Multistack VM

These inline functions are defined for the VM, with additional inline functions specifically defined for the stack. All of these are documented in the rust_multistack crate.

Function name Description
print Takes a single value from stack and prints it
println Takes a single value from stack and prints it with newline
print. Takes a single value from workbench and prints it
println. Takes a single value from workbench and prints it with newline
space prints a single space
nl Prints a new line
format Taking a format string from the stack and then for all key sequentially start to get values from stack. Names are not important, but they will be resolved as they are allocated in the stack
format. Taking a format string from the workbench and then for all key sequentially start to get values from stack. Names are not important, but they will be resolved as they are allocated in the stack
alias Takes two string values from stack and create alias for a function or lambda
unalias Takes a single string from stack and remove alias referred by this name
list Places an empty list to stack
dict Place empty dictionary to the stack
nodata Place NODATA element to the stack
lambda Places an empty lambda to stack
ptr Places an PTR reference to function to stack
true Places an TRUE boolean value to to stack
false Places an FALSE boolean value to to stack
execute Takes executable context information from the stack and execute inline or lambda referred by this information
execute. Takes executable context information from workbench and execute inline or lambda referred by this information
resolve Resolving lambda or inline function to PTR if function exists, raise an Error otherwise
len Peeking for the value on the stack and pushing it's length
attribute Assign attribute to the value on top of the stack
tag Tag value on top of the stack
clear_stacks Clear stack of stacks
drop_stacks Drop top name of stack from stack of stacks
+ Mathematical add of two values on the stack. If the Value is of type LIST, appending or merging of lists will be executed.
- Mathematical sub of two values on the stack
* Mathematical mul of two values on the stack
/ Mathematical div of two values on the stack
+. Mathematical add of value on workbench with value on the stack. Result is pushed to workbench
-. Mathematical sub of value on workbench with value on the stack. Result is pushed to workbench
*. Mathematical mul of value on workbench with value on the stack. Result is pushed to workbench
/. Mathematical div of value on workbench with value on the stack. Result is pushed to workbench

Example of the format function

41 42     // For format variables a
          // and b, a = 42, b = 41 since they are
          // resolved as allocated
"Answer is {a}, but not {b}. It is really {a}!" format

This snippet will leave foollowing string on the stack:

"Answer is 42, but not 41. It is really 42!"

Group of functions for boolean logic operations

Function name Description
not Perform boolean NOT operation
and Perform boolean AND operation
or Perform boolean OR operation

Group of function for comparing values on the stack. Returns a boolean value

Function name Description
== EQ compare operation
!= NE compare operation
> GT compare operation
< LT compare operation
>= GT or EQ compare operation
<= LT or EQ compare operation
1 0 <     // Will return TRUE on stack

Here is group of functions that is doing a conditional move of data in stack and workbench

Function name Description
?. Take lambda function from stack and execute it. If then top of the stack have a boolean TRUE, take the next value and move it to workbench
?move Take lambda function from stack and execute it. If then top of the stack have a boolean TRUE, take the name of the stack and value from the stack and move the value to named stack

Here is some example

42.0              // Put some value to the stack
{ dup > 0 } ?.    // Check if value is more than 0
                  // Since logical operator consumes 
                  // value from stack, we duplicate it inside lambda
                  // If test return TRUE, word "?." will move next value
                  // To workbench

The outcome of this snippet is value 42.0 stored in workbench if only this value is greater than 0

Here is the group of functions to work with application-defined anonymous and named functions

Function name Description
register Register lambda function as named function
unregister Remove named function
execute Execute lambda function
// First, let's define function and register it with name "FortyTwo"
:FortyTwo {
  42
} register
// And then let's execute it
FortyTwo

Here is the group of functions covering the application logic

Function name Description
if This function will (or will not) execute lambda function stored in stack if stack having a boolean value TRUE
if. This function will (or will not) execute lambda function stored in stack if workbench having a boolean value TRUE
if.stack This function will (or will not) execute lambda function stored in stack if current stack matches the name
?true This is an alias for if function. Condition is taken from stack
?true. This is an alias for if function. Condition is taken from workbench
?false This function will (or will not) execute lambda function stored in stack if stack having a boolean value FALSE
?false. This function will (or will not) execute lambda function stored in stack if workbench having a boolean value FALSE
loop This function will loop over all elements of the list that is obtained from stack, push the value to the stack and evaluate lambda for each pushed value
loop. This function will loop over all elements of the list that is obtained from workbench, push the value to the stack and evaluate lambda for each pushed value
while This function will execute lambda function until detect FALSE value on the stack
while. This function will execute lambda function until detect FALSE value on the workbench
for This function will execute lambda function in the loop until it returns FALSE to stack
for. This function will execute lambda function in the loop until it returns FALSE to workbench
do This function will execute lambda function util current stack is empty
do. This function will execute lambda function taken from workbench util current stack is empty
times This function will execute lambda function number of times as specified by the value pushed from the stack
times. This function will execute lambda function number of times as specified by the value pushed from the workbench
map This function will execute lambda function over list of values obtained from stack and will return the list of values for which this function is applied to the stack. Note, function must leave value on stack
map. This function will execute lambda function over list of values obtained from workbench and will return the list of values for which this function is applied to workbech. Note, function must leave value on stack

Examples of use IF conditional functions

true
{
  // This code will be executed
}
if
true
{
  // This code will not be executed
}
?false
:main
{
  // This code will be executed only if name of the current stack is "main"
}
if.stack

Example of use LOOP function

[ 42 ] { . } loop

Example of WHILE function

true
{
  42.0 . false
}
while

After single loop over lambda, condition is met and number 42.0 is in workbench

Example of FOR function

{
  "This lambda function will be executed at least once " println
  false
} for

After single loop over lambda, condition is met.

Example of TIMES. function

0       // Send an initial value
3 .     // Send a counter to workbench
{
  +     // Perform math operation in lambda
} times.

Example of MAP function

[ "Hello World!"]   // First, let's define data
{ :string.upper } map

This snipper will return following value on the list [ "HELLO WORLD!"]

This snippet will execute lambda function three times and leave number 3 on top of the stack.

In this example, we are pushing content of the list to stack and evaluate lambda after each push. This code will push integer 42 to workbench.

And here is functions that is working with dictionaries

Function name Description
dict Create an empry dictionary and store it on stack
set Set the value in dictionary
get Get value from dictionary
// We create an empty dictionary
dict
  // Then provide a key-value
  :ANSWER
  42.0
  // And set the value. Dictionary is on top of stack
  set
  // Set the key and get the Value
  :ANSWER
  get
// This snippet shall render 42.0 on top of the stack

There are number of internal libraries for multistackvm

Math library

Function name Description
float.NaN Return float point NaN to stack
float.+Inf Return float point +Inf to stack
float.-Inf Return float point -Inf to stack
float.Pi Return float point Pi to stack
float.E Return float point E to stack
math.floor Return floor() computed for float point to stack
math.abs Return abs() computed for float point to stack
math.signum Return signum() computed for float point to stack
math.cbrt Return cbrt() - cubic root computed for float point to stack
math.ceil Return ceil() computed for float point to stack
math.round Return round() computed for float point to stack
math.fract Return fract() computed for float point to stack
math.sqrt Return sqrt() computed for float point to stack
math.sin Return sin() computed for float point to stack
math.cos Return cos() computed for float point to stack
math.tan Return tan() computed for float point to stack
math.asin Return asin() computed for float point to stack
math.acos Return acos() computed for float point to stack
math.atan Return atan() computed for float point to stack
math.sinh Return sinh() computed for float point to stack
math.cosh Return cosh() computed for float point to stack
math.tanh Return tanh() computed for float point to stack

String library

Function name Description
string.upper Return value stored in stack in UPPERCASE
string.lower Return value stored in stack in LOWERCASE
string.title Return value stored in stack in TITLE
string.camel Return value stored in stack in CAMELCASE
string.snake Return value stored in stack in SNAKECASE

Conversion library

Conversion library support both stack and workbench operations. For the word operating with workbench add "." to name. For example, the word convert.to_int. will perform conversion in workbench.

Function name Description
convert.to_string Convert value from supported value types to STRING
convert.to_int Convert value from supported value types to INT
convert.to_float Convert value from supported value types to FLOAT
convert.to_bool Convert value from supported value types to BOOL
convert.to_list Convert value from supported value types to LIST

Time library

Function name Description
time.now Return current timestamp to stack
time.timestamp Create timestamp from INT that taken from stack

VM control functions

Function name Description
: Turn on auto-add feature
; Turn off auto-add feature

Default aliases

Alias is basically another name for the function or lambda. Here is an example, where I am calling function "." that is an alias for inline function "return".

let mut vm = VM::new();
vm.apply(Value::from(42.0).unwrap()).unwrap();
vm.call(".".to_string()).unwrap();
let val = vm.stack.pull_from_workbench().unwrap();
assert_eq!(val.cast_float().unwrap(), 42.0 as f64);

This alias was previously defined in stdlib/create aliases.rs as

let _ = vm.register_alias(".".to_string(), "return".to_string());

First, I am appying a Value::float to VM, that is pushed this value to the stack. Then I am calling for function "." Alias is getting resolved and inline function "return" defined in TS is called. As expected, we can pull the value from vm.stack Workbench.

Alias Context Inline name Description
. TS return Pull value from current stack and push it to Workbench
! VM execute Execute inline function referred by PTR
Commit count: 87

cargo fmt