08281a9d69
* Fix #146: Add configuration options to selectively disable built-in functions Add new Options enum values (No_Stdlib, No_IO, No_Prelude, No_JSON) that allow users to control which parts of the standard library are registered. Std_Lib::library() now accepts an options vector, and the ChaiScript convenience class forwards its options to the library builder. This enables use cases where only custom functions should be exposed to script users. Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com> * Address review: split Options into Options and Library_Options enums Separate system-level options (No_Load_Modules, Load_Modules, No_External_Scripts, External_Scripts) from library-level options (No_Stdlib, No_IO, No_Prelude, No_JSON) into two distinct enum types. Add Library_Options as a parameter to the ChaiScript constructor. Update tests to demonstrate both ChaiScript_Basic (explicit Std_Lib::library call) and ChaiScript (library options via constructor parameter) usage. Requested by @lefticus in PR #642 review. Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com> * Add cheatsheet documentation for Options and Library_Options Documents the two-enum configuration system: Options (engine-level: load_module, use, eval_file) and Library_Options (stdlib-level: No_Stdlib, No_IO, No_Prelude, No_JSON), with usage examples for both ChaiScript and ChaiScript_Basic constructors. Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com> --------- Co-authored-by: leftibot <leftibot@users.noreply.github.com> Co-authored-by: Claude Opus 4.6 (1M context) <noreply@anthropic.com>
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ChaiScript Versioning
ChaiScript tries to follow the Semantic Versioning scheme. This basically means:
- Major Version Number: API changes / breaking changes
- Minor Version Number: New Features
- Patch Version Number: Minor changes / enhancements
Initializing ChaiScript
chaiscript::ChaiScript chai; // initializes ChaiScript, adding the standard ChaiScript types (map, string, ...)
Note that ChaiScript cannot be used as a global / static object unless it is being compiled with CHAISCRIPT_NO_THREADS.
Engine Options (Options)
Engine-level options control which scripting capabilities are exposed. These are passed as a std::vector<Options> to the ChaiScript or ChaiScript_Basic constructor.
| Option | Effect |
|---|---|
Options::Load_Modules |
Enables load_module() in scripts (default) |
Options::No_Load_Modules |
Disables load_module() |
Options::External_Scripts |
Enables use() and eval_file() in scripts (default) |
Options::No_External_Scripts |
Disables use() and eval_file() |
// Sandboxed engine: no dynamic module loading, no external script evaluation
chaiscript::ChaiScript chai({}, {},
{chaiscript::Options::No_Load_Modules, chaiscript::Options::No_External_Scripts});
Library Options (Library_Options)
Library-level options control which parts of the standard library are registered. These are passed as a std::vector<Library_Options>.
| Option | Effect |
|---|---|
Library_Options::No_Stdlib |
Disables the entire standard library (types, I/O, prelude, JSON — everything) |
Library_Options::No_IO |
Disables print_string and println_string (and the prelude's print/puts wrappers) |
Library_Options::No_Prelude |
Disables the ChaiScript prelude (print, puts, filter, map, foldl, join, etc.) |
Library_Options::No_JSON |
Disables from_json and to_json |
With the ChaiScript convenience class, pass library options as the fourth constructor parameter:
// No I/O functions
chaiscript::ChaiScript chai({}, {}, chaiscript::default_options(),
{chaiscript::Library_Options::No_IO});
// No JSON support
chaiscript::ChaiScript chai({}, {}, chaiscript::default_options(),
{chaiscript::Library_Options::No_JSON});
// Completely bare engine — no stdlib at all
chaiscript::ChaiScript chai({}, {}, chaiscript::default_options(),
{chaiscript::Library_Options::No_Stdlib});
// Combine both: no external scripts and no I/O
chaiscript::ChaiScript chai({}, {},
{chaiscript::Options::No_Load_Modules, chaiscript::Options::No_External_Scripts},
{chaiscript::Library_Options::No_IO});
With ChaiScript_Basic, pass library options directly to Std_Lib::library():
chaiscript::ChaiScript_Basic chai(
chaiscript::Std_Lib::library({chaiscript::Library_Options::No_IO}),
create_chaiscript_parser(),
{}, {},
{chaiscript::Options::No_Load_Modules, chaiscript::Options::No_External_Scripts});
Note: No_Prelude disables the prelude script which defines convenience functions like print (which wraps print_string). If you disable the prelude but not I/O, print_string and println_string are still available.
Adding Things To The Engine
Adding a Function / Method / Member
General
chai.add(chaiscript::fun(&function_name), "function_name");
chai.add(chaiscript::fun(&Class::method_name), "method_name");
chai.add(chaiscript::fun(&Class::member_name), "member_name");
Bound Member Functions
chai.add(chaiscript::fun(&Class::method_name, Class_instance_ptr), "method_name");
chai.add(chaiscript::fun(&Class::member_name, Class_instance_ptr), "member_name");
With Overloads
Preferred
chai.add(chaiscript::fun<ReturnType (ParamType1, ParamType2)>(&function_with_overloads), "function_name");
Alternative
chai.add(chaiscript::fun(static_cast<ReturnType (*)(ParamType1, ParamType2)>(&function_with_overloads)), "function_name");
This overload technique is also used when exposing base members using derived type
struct Base
{
int data;
};
struct Derived : public Base
{};
chai.add(chaiscript::fun(static_cast<int(Derived::*)>(&Derived::data)), "data");
Lambda
chai.add(
chaiscript::fun<std::function<std::string (bool)>>(
[](bool type) {
if (type) { return "x"; }
else { return "y"; }
}), "function_name");
Constructors
chai.add(chaiscript::constructor<MyType ()>(), "MyType");
chai.add(chaiscript::constructor<MyType (const MyType &)>(), "MyType");
Adding Types
It's not strictly necessary to add types, but it helps with many things. Cloning, better errors, etc.
chai.add(chaiscript::user_type<MyClass>(), "MyClass");
Adding Type Conversions
User-defined type conversions are possible, defined in either script or in C++.
ChaiScript Defined Conversions
Function objects (including lambdas) can be used to add type conversions from inside of ChaiScript:
add_type_conversion(type("string"), type("Type_Info"), fun(s) { return type(s); });
C++ Defined Conversions
Invoking a C++ type conversion possible with static_cast
chai.add(chaiscript::type_conversion<T, bool>());
Calling a user-defined type conversion that takes a lambda
chai.add(chaiscript::type_conversion<TestBaseType, Type2>([](const TestBaseType &t_bt) { /* return converted thing */ }));
Class Hierarchies
If you want objects to be convertable between base and derived classes, you must tell ChaiScript about the relationship.
chai.add(chaiscript::base_class<Base, Derived>());
If you have multiple classes in your inheritance graph, you will probably want to tell ChaiScript about all relationships.
chai.add(chaiscript::base_class<Base, Derived>());
chai.add(chaiscript::base_class<Derived, MoreDerived>());
chai.add(chaiscript::base_class<Base, MoreDerived>());
Helpers
A helper function exists for strongly typed and ChaiScript Vector function conversion definition:
chai.add(chaiscript::vector_conversion<std::vector<int>>());
A helper function also exists for strongly typed and ChaiScript Map function conversion definition:
chai.add(chaiscript::map_conversion<std::map<std::string, int>>());
This allows you to pass a ChaiScript function to a function requiring std::vector<int>
Adding Objects
add — Thread-Local Scoped Variables
add adds an object to the current thread's local scope. The variable is only visible in the
thread that added it. If the variable already exists in the current scope, it is overwritten.
chai.add(chaiscript::var(somevar), "somevar"); // copied in
chai.add(chaiscript::var(std::ref(somevar)), "somevar"); // by reference, shared between C++ and chai
auto shareddouble = std::make_shared<double>(4.3);
chai.add(chaiscript::var(shareddouble), "shareddouble"); // by shared_ptr, shared between C++ and chai
chai.add(chaiscript::const_var(somevar), "somevar"); // copied in and made const
add_global / add_global_const / set_global — Global Shared Variables
Global variables are shared between all threads and are visible from any scope (including inside functions). Use these when you need a variable accessible everywhere.
chai.add_global_const(chaiscript::const_var(somevar), "somevar"); // global const, throws if value is non-const or object already exists
chai.add_global(chaiscript::var(somevar), "somevar"); // global non-const, throws if object already exists
chai.set_global(chaiscript::var(somevar), "somevar"); // global non-const, overwrites existing or creates new
Summary of Differences
| Method | Scope | Thread Safety | If Name Exists |
|---|---|---|---|
add |
Thread-local, current scope | Not shared between threads | Overwrites |
add_global |
Global, all scopes and threads | Mutex-protected, shared between threads | Throws exception |
add_global_const |
Global, all scopes and threads | Mutex-protected, shared between threads | Throws exception |
set_global |
Global, all scopes and threads | Mutex-protected, shared between threads | Overwrites |
Adding Namespaces
Namespaces will not be populated until import is called.
This saves memory and computing costs if a namespace is not imported into every ChaiScript instance.
chai.register_namespace([](chaiscript::Namespace& math) {
math["pi"] = chaiscript::const_var(3.14159);
math["sin"] = chaiscript::var(chaiscript::fun([](const double x) { return sin(x); })); },
"math");
Import namespace in ChaiScript
import("math")
print(math.pi) // prints 3.14159
Using STL
ChaiScript recognizes many types from STL, but you have to add specific instantiation yourself.
typedef std::vector<std::pair<int, std::string>> data_list;
data_list my_list{ make_pair(0, "Hello"), make_pair(1, "World") };
chai.add(chaiscript::bootstrap::standard_library::vector_type<data_list>("DataList"));
chai.add(chaiscript::bootstrap::standard_library::pair_type<data_list::value_type>("DataElement"));
chai.add(chaiscript::var(&my_list), "data_list");
chai.eval(R"_(
for(var i=0; i<data_list.size(); ++i)
{
print(to_string(data_list[i].first) + " " + data_list[i].second)
}
)_");
Executing Script
General
chai.eval("print(\"Hello World\")");
chai.eval(R"(print("Hello World"))");
Unboxing Return Values
Returns values are of the type Boxed_Value which is meant to be opaque to the programmer. Use one of the unboxing methods to access the internal data.
Prefered
chai.eval<double>("5.3 + 2.1"); // returns 7.4 as a C++ double
Alternative
auto v = chai.eval("5.3 + 2.1");
chai.boxed_cast<double>(v); // extracts double value from boxed_value and applies known conversions
chaiscript::boxed_cast<double>(v); // free function version, does not know about conversions
Converting Between Algebraic Types
chaiscript::Boxed_Number(chai.eval("5.3 + 2.1")).get_as<int>(); // works with any number type
// which is equivalent to, but much more automatic than:
static_cast<int>(chai.eval<double>("5.3+2.1")); // this version only works if we know that it's a double
Conversion Caveats
Conversion to std::shared_ptr<T> & is supported for function calls, but if you attempt to keep a reference to a shared_ptr<> you might invoke undefined behavior
// ok this is supported, you can register it with chaiscript engine
void nullify_shared_ptr(std::shared_ptr<int> &t) {
t = nullptr
}
int main()
{
// do some stuff and create a chaiscript instance
std::shared_ptr<int> &ptr = chai.eval<std::shared_ptr<int> &>(somevalue);
// DO NOT do this. Taking a non-const reference to a shared_ptr is not
// supported and causes undefined behavior in the chaiscript engine
}
Sharing Values
double &d = chai.eval("var i = 5.2; i"); // d is now a reference to i in the script
std::shared_ptr<double> d = chai.eval("var i = 5.2; i"); // same result but reference counted
d = 3;
chai.eval("print(i)"); // prints 3
Catching Eval Errors
try {
chai.eval("2.3 + \"String\"");
} catch (const chaiscript::exception::eval_error &e) {
std::cout << "Error\n" << e.pretty_print() << '\n';
}
Catching Errors Thrown From Script
try {
chai.eval("throw(runtime_error(\"error\"))", chaiscript::exception_specification<int, double, float, const std::string &, const std::exception &>());
} catch (const double e) {
} catch (int) {
} catch (float) {
} catch (const std::string &) {
} catch (const std::exception &e) {
// This is the one that will be called in the specific throw() above
}
Sharing Functions
auto p = chai.eval<std::function<std::string (double)>>("to_string");
p(5); // calls chaiscript's 'to_string' function, returning std::string("5")
Note: backtick treats operators as normal functions
auto p = chai.eval<std::function<int (int, int)>>("`+`");
p(5, 6); // calls chaiscript's '+' function, returning 11
auto p = chai.eval<std::function<std::string (int, double)>>("fun(x,y) { to_string(x) + to_string(y); }");
p(3,4.2); // evaluates the lambda function, returning the string "34.2" to C++
Language Reference
Variables
var i; // uninitialized variable, can take any value on first assignment;
auto j; // equiv to var
var k = 5; // initialized to 5 (integer)
var l := k; // reference to k
auto &m = k; // reference to k
global g = 5; // creates a global variable. If global already exists, it is not re-added
global g = 2; // global 'g' now equals 2
global g2;
if (g2.is_var_undef()) { g2 = 4; } // only initialize g2 once, if global decl hit more than once
GLOBAL g3; // all upper case version also accepted
Looping
// c-style for loops
for (var i = 0; i < 100; ++i) { print(i); }
// while
while (some_condition()) { /* do something */ }
// ranged for
for (i : [1, 2, 3]) { print(i); }
Each of the loop styles can be broken using the break statement. For example:
while (some_condition()) {
/* do something */
if (another_condition()) { break; }
}
Conditionals
if (expression) { }
// C++17-style init-if blocks
// Value of 'statement' is scoped for entire `if` block
if (statement; expression) { }
Switch Statements
var myvalue = 2
switch (myvalue) {
case (1) {
print("My Value is 1");
break;
}
case (2) {
print("My Value is 2");
break;
}
default {
print("My Value is something else.";
}
}
Built-in Types
There are a number of built-in types that are part of ChaiScript.
Vectors and Maps
var v = [1,2,3u,4ll,"16", `+`]; // creates vector of heterogenous values
var m = ["a":1, "b":2]; // map of string:value pairs
// Add a value to the vector by value.
v.push_back(123);
// Add an object to the vector by reference.
v.push_back_ref(m);
Numbers
Floating point values default to double type and integers default to int type. All C++ suffixes
such as f, ll, u as well as scientific notation are supported
1.0 // double
1.0f // float
1.0l // long double
1 // int
1u // unsigned int
1ul // unsigned long
1ull // unsigned long long
Literals are automatically sized, just as in C++. For example: 10000000000 is > 32bits and the appropriate type is used to hold it
on your platform.
Functions
Note that any type of ChaiScript function can be passed freely to C++ and automatically
converted into a std::function object.
General
def myfun(x, y) { x + y; } // last statement in body is the return value
def myfun(x, y) { return x + y; } // equiv
Optionally Typed
def myfun(x, int y) { x + y; } // requires y to be an int
With Guards
def myfun(x, int y) : y > 5 { x - y; } // only called if y > 5
Methods
Methods and functions are mostly equivalent
def string::add(int y) { this + to_string(y); }
def add(string s, int y) { s + to_string(y); } //equiv functionality
// calling new function/method
"a".add(1); // returns a1
add("a", 1); // returns a1, either calling syntax works with either def above
Lambdas
var l = fun(x) { x * 15; }
l(2) // returns 30
var a = 13
var m = fun[a](x) { x * a; }
m(3); // a was captured (by reference), returns 39
var n = bind(fun(x,y) { x * y; }, _, 10);
n(2); // returns 20
ChaiScript Defined Types (Classes)
ChaiScript supports user-defined types using the class keyword. Classes can have attributes,
constructors, methods, guards, and operator overloads. There is no inheritance between
ChaiScript-defined types, but C++ class hierarchies can be exposed (see Class Hierarchies above).
Class Definition (Block Syntax)
Define a type with attributes, a constructor, and methods inside a class block.
The keywords var, attr, and auto are interchangeable for declaring attributes.
class Rectangle {
var width
var height
def Rectangle(w, h) { this.width = w; this.height = h; }
def Rectangle() { this.width = 0; this.height = 0; }
def area() { this.width * this.height; }
}
var r = Rectangle(3, 4)
print(r.area()) // prints 12
Class Definition (Open Syntax)
Equivalently, attributes and methods can be defined outside a block using the TypeName:: prefix.
attr Circle::radius
def Circle::Circle(r) { this.radius = r; }
def Circle::circumference() { 2.0 * 3.14159 * this.radius; }
Methods can also be added to an existing class after its initial definition:
def Rectangle::perimeter() { 2 * (this.width + this.height); }
Using
var m = Rectangle(5, 10)
print(m.area()) // prints 50 — method call syntax
print(area(m)) // prints 50 — function call syntax (equivalent)
Constructor and Method Guards
Constructors and methods can have guard expressions (after :) that control which
overload is selected at call time.
class Clamped {
var value
def Clamped(x) : x >= 0 { this.value = x; }
def Clamped(x) { this.value = 0; } // fallback when guard fails
}
Clamped(5).value // 5
Clamped(-3).value // 0
class Abs {
var x
def Abs(v) { this.x = v; }
def get() : this.x >= 0 { this.x; }
def get() { -this.x; }
}
Operator Overloading
Operators can be overloaded on user-defined types using backtick-quoted operator names.
class Vec2 {
var x
var y
def Vec2(x, y) { this.x = x; this.y = y; }
def `+`(other) { Vec2(this.x + other.x, this.y + other.y); }
}
var v = Vec2(1, 2) + Vec2(3, 4) // v.x == 4, v.y == 6
Operators can also be overloaded as free functions with guards:
def `-`(a, b) : is_type(a, "Vec2") && is_type(b, "Vec2") {
Vec2(a.x - b.x, a.y - b.y)
}
Cloning Objects
Use clone() to create a deep copy of a ChaiScript-defined object.
var original = Rectangle(10, 20)
var copy = clone(original)
copy.width = 99
print(original.width) // still 10
Dynamic Objects
All ChaiScript defined types and generic Dynamic_Object support dynamic parameters
var o = Dynamic_Object();
o.f = fun(x) { print(x); }
o.f(3); // prints "3"
Implicit 'this' is allowed:
var o = Dynamic_Object();
o.x = 3;
o.f = fun(y) { print(this.x + y); }
o.f(10); // prints 13
Namespaces
Namespaces in ChaiScript are Dynamic Objects with global scope
namespace("math") // create a new namespace
math.square = fun(x) { x * x } // add a function to the "math" namespace
math.sum_squares = fun(x, y) { math.square(x) + math.square(y) }
print(math.square(4)) // prints 16
print(math.sum_squares(2, 5)) // prints 29
Option Explicit
If you want to disable dynamic parameter definitions, you can set_explicit.
class My_Class {
def My_Class() {
this.set_explicit(true);
this.x = 2; // this would fail with explicit set to true
}
};
method_missing
A function of the signature method_missing(object, name, param1, param2, param3) will be called if an appropriate
method cannot be found
def method_missing(int i, string name, Vector v) {
print("method_missing(${i}, ${name}), ${v.size()} params");
}
5.bob(1,2,3); // prints "method_missing(5, bob, 3 params)"
method_missing signature can be either 2 parameters or 3 parameters. If the signature contains two parameters
it is treated as a property. If the property contains a function then additional parameters are passed to
the contained function.
If both a 2 parameter and a 3 parameter signature match, the 3 parameter function always wins.
Context
__LINE__Current file line number__FILE__Full path of current file__CLASS__Name of current class__FUNC__Name of current function
Built-in Functions
Evaluation
eval("4 + 5") // dynamically eval script string and returns value of last statement
eval_file("filename") // evals file and returns value of last statement
use("filename") // evals file exactly once and returns value of last statement
// if the file had already been 'used' nothing happens and undefined is returned
Both use and eval_file search the 'usepaths' passed to the ChaiScript constructor
Reflection and Introspection
ChaiScript provides built-in reflection capabilities for inspecting types, functions, and objects at runtime.
Type Inspection
type_name(x) // returns the type name of a value as a string
is_type(x, "typename") // returns true if x is of the named type
type("typename") // returns a Type_Info object for the named type
// Examples
type_name(1) // "int"
type_name("hello") // "string"
is_type(1, "int") // true
is_type(1, "string") // false
Object Inspection Methods
Every object in ChaiScript supports these methods:
x.get_type_info() // returns a Type_Info object for the value
x.is_type("string") // returns true if x is of the named type
x.is_type(string_type) // returns true if x matches the Type_Info
x.is_var_const() // returns true if x is immutable
x.is_var_null() // returns true if x is a null pointer
x.is_var_pointer() // returns true if x is stored as a pointer
x.is_var_reference() // returns true if x is stored as a reference
x.is_var_undef() // returns true if x is undefined
Type_Info
Type_Info objects describe a type. You can get them via type("typename") or x.get_type_info().
var ti = type("int")
ti.name() // ChaiScript registered name, e.g. "int"
ti.cpp_name() // mangled C++ type name
ti.cpp_bare_name() // C++ name without const/pointer/reference
ti.bare_equal(other) // true if types match ignoring const/ptr/ref
ti.is_type_const() // true if type is const
ti.is_type_reference() // true if type is a reference
ti.is_type_void() // true if type is void
ti.is_type_undef() // true if type is undefined
ti.is_type_pointer() // true if type is a pointer
ti.is_type_arithmetic() // true if type is arithmetic (int, double, etc.)
Built-in type constants are available: int_type, double_type, string_type, bool_type, Object_type, Function_type, vector_type, map_type.
Function Introspection
Function objects support these introspection methods:
f.get_arity() // number of parameters (-1 for variadic)
f.get_param_types() // Vector of Type_Info (first element is return type)
f.get_contained_functions() // Vector of overloaded functions (empty if not a conglomerate)
f.has_guard() // true if the function has a guard condition
f.get_guard() // returns the guard function (throws if none)
f.get_annotation() // returns the annotation description
f.call([param1, param2]) // call the function with a vector of parameters
// Examples
def my_func(a, b) { return a + b; }
my_func.get_arity() // 2
my_func.has_guard() // false
def guarded(x) : x > 0 { return x; }
guarded.has_guard() // true
guarded.get_guard().get_arity() // 1
// Calling functions dynamically
`+`.call([1, 2]) // 3
System Introspection
get_functions() // returns a Map of all registered functions (name -> function)
get_objects() // returns a Map of all scripting objects (name -> value)
function_exists("f") // returns true if a function named "f" is registered
call_exists(`f`, args) // returns true if f can be called with the given args
dump_system() // prints all registered functions to stdout
dump_object(x) // prints information about a value to stdout
// Examples
var funcs = get_functions()
funcs["print"] // the print function object
function_exists("print") // true
call_exists(`+`, 1, 2) // true
Dynamic_Object Reflection
ChaiScript-defined classes are Dynamic_Objects internally. They support:
obj.get_type_name() // returns the ChaiScript class name (e.g. "MyClass")
obj.get_attrs() // returns a Map of all attributes
obj.has_attr("name") // returns true if the attribute exists
obj.get_attr("name") // returns the value of the attribute
obj.set_explicit(true) // disables dynamic attribute creation
obj.is_explicit() // returns true if explicit mode is enabled
// Example
class MyClass {
var x
def MyClass() { this.x = 10; }
}
var m = MyClass()
m.get_type_name() // "MyClass"
m.get_attrs() // map containing "x" -> 10
type_name(m) // "Dynamic_Object" (the underlying C++ type)
m.is_type("MyClass") // true (checks the ChaiScript class name)
JSON
from_jsonconverts a JSON string into its strongly typed (map, vector, int, double, string) representationsto_jsonconverts a ChaiScript object (either aObjector one of map, vector, int, double, string) tree into its JSON string representation
Extras
ChaiScript itself does not provide a link to the math functions defined in <cmath>. You can either add them yourself, or use the ChaiScript_Extras helper library. (Which also provides some additional string functions.)