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Silver C++ Developer Documentation

Discord

Index

Vectors

Vectors

Vector classes provide basic vector arithmetic operations and predefined directional vectors for 3D space.

Class: Vector2

Description: The Vec2 class represents a vector in 2D space with x and y components. It supports basic vector arithmetic operations such as addition, subtraction, and scalar multiplication.

Vector2(int x, int y) // Creates a 2D vector with specified x and y components.

Conversion to Vec3: Vec2 can automatically convert to Vec3. When converted, the z component of the resulting Vec3 is set to 0.

Class: Vec3

Description: The Vec3 class represents a vector in 3D space with x, y, and z components. It supports vector addition, subtraction, and scalar multiplication, and includes predefined directional vectors for common directions like up, down, left, right, forward, and backward.

Constructors:

Vector3(int x, int y, int z) // Creates a 3D vector with specified x, y, and z components.

Predefined Directions:

Vector3::up() // Returns a vector (0, -1, 0) representing the upward direction.
Vector3::down() // Returns a vector (0, 1, 0) representing the downward direction.
Vector3::left() // Returns a vector (-1, 0, 0) representing the left direction.
Vector3::right() // Returns a vector (1, 0, 0) representing the right direction.
Vector3::forward() // Returns a vector (0, 0, 1) representing the forward direction.
Vector3::backward() // Returns a vector (0, 0, -1) representing the backward direction.
Vector3::zero() // Returns a vector (0, 0, 0) representing the origin or no movement.

Vector2::up() // Returns a vector (0, -1) representing the upward direction.
Vector2::down() // Returns a vector (0, 1) representing the downward direction.
Vector2::left() // Returns a vector (-1, 0) representing the left direction.
Vector2::right() // Returns a vector (1, 0) representing the right direction.

Example:

Vector2 v1(3, 4);
Vector3 v2(1, 2, 3);
Vector3 result = v1 + v2 + vec3.up; // Result is (4, 5, 3)

Warning: In Silver C++, Negative Y represents up and Positive Y represents down.

Functions

Camera

NOTE: All camera-related functions are in the namespace 'Camera'

You can use this function to set the camera position:

void setCam2(Vector2 pos, Vector2 scale);
void setCam3(Vector3 pos, Vector3 scale);

Example usage:

Silver::Camera::setCam2(Vector2(10,10),Vector2(20,30)); // Does not change Z pos and scale
Silver::Camera::setCam3(Vector3(3,2,4),Vector3(6,6,8)); 

This sets the camera position to the first parameter pos, and the camera size to the second parameter scale.

There are a variety of functions to control the camera:

void setCameraFlip(bool x, bool y); // true: Flipped, false: Normal
void flipCamera(bool x, bool y); // true: Toggle, false: Leave it
void pivotCamera(int angle); // Set camera's rotation
void addPivotCamera(int angle); // Adds to the camera's current rotation
void shakeCamera(float intensity); //Shakes the camera
void zoomCamera(Vector3 v); // Changes the camera scale
void moveCamera(Vector3 v); // Moves the camera in a certain offset

To print the camera's view you can use the following function

void Silver::Camera::printCam();

Example usage:

while (1) {
  silver.camera.printCam();
  silver.wait(1000);
}

If you don't want to use a while loop or need better efficiency, you can use:

Silver::Camera::startVideo(1); // Starts video at 1 frame per second

To stop the video:

Silver::Camera::stopVideo();

Advanced Camera Functions & Cells

Null Object Replacement (🟫): Displayed when a cell has no objects.

You can configure these using:

void configCameraException(string n); // n = null object replacement

And if you want to set the world bounds, you can use the following function: `void setWorldBounds(Vector3 world);` This sets the world bounds to `Vector3 world`. However, this does not change the minimum X and Y coordinates to
stay in the world.

Cell Size: The default cell size is 2. You can adjust the cell size using:

void cell(int c);

Debugging

When you render the camera, debugging something to the console is difficult.
Then, you can use the Silver::debug function.
Example:

Silver::debug("Hello World!","d");

"d" is for debug, and there are other types of debugs.
"w" : Warning
"p" or "d" : Debug
"s" : Subtraction
"q" : Question
"e" : Error
You can put a name of a .ico file instead of those abbreviations
You can use capital letters when you write those abbreviations

How this using this function will notify you
屏幕截图 2024-11-18 162942

Object Declaration

To draw objects on the map, use the following functions:

void draw(Vector3 pos, std::string c); 
void Line(Vector3 start, Vector3 end, std::string c);
void Rectangle(Vector3 topLeft, int width, int height, std::string c); 
void Circle(Vector3 center, int radius, std::string c); 
void CircleHollow(Vector3 center, int radius, std::string c);
void Oval(Vector3 center, int radiusX, int radiusY, string c);
void OvalHollow(Vector3 center, int radiusX, int radiusY, string c);

void sprayRectangle(int spawns, Vector3 center, Vector3 scale, string c);
void sprayOval(int spawns, Vector3 center, Vector3 scale, string c);
void spray(int spawns, Vector3 center, int range, string c);
void sprayLine(int spawns, Vector3 start, Vector3 end, string c);

Drawing functions are in class 'Drawing' and can accessed with 'draw'
Example usage:

Silver::Drawing::draw(Vector3(2,4,3),"#");

Object Declaration

To create an object, you can use the following function:

void createEmptyPrefab(const string name);
void createPrefab(const std::string name, const std::string shape);

createPrefab creates an object named name and will look like shape.
createEmptyPrefab creates an object named name and will not be shown.

If you create an object, you can use one of these functions:

int placeObject(string objectName, int number, Vector3 position); // Places an object in the world
int addObject(string objectName, Vector3 position); // Places an object in the world with a unique number
int put(string objectName, Vector3 position); // Places an object in the world with number 0.

int unoccupiedNumber(string objectName); // Returns a number that is not currently being used by any object with the same name (

When an object gets placed on the map, it requires a number. Also, some of the 2 objects might have the same number.

Silver::place("player", 1, Vector2(10, 10));
Silver::place("player", 1, Vector2(10, 11)); // This is allowed

Objects are numbered for unique identification and manipulation within the world. So you can use the void put(string objectName, Vector3 position); function if the number doesn't matter much.
Also, placing related functions like placeObject, addObject, and put return an integer. That integer is used in most of the operations.

void Line(Vector3 start, Vector3 end, string name, int number);
void Rectangle(Vector3 topLeft, int width, int height, string name, int number);
void Circle(Vector3 center, int radius, string name, int number);
void CircleHollow(Vector3 center, int radius, string name, int number);
void Oval(Vector3 center, int radiusX, int radiusY, string name, int number);
void OvalHollow(Vector3 center, int radiusX, int radiusY, string name, int number);

void sprayRectangle(int spawns, Vector3 center, Vector3 scale, string name, int number);
void sprayOval(int spawns, Vector3 center, Vector3 scale, string name, int number);
void spray(int spawns, Vector3 center, int range, string name, int number);
void sprayLine(int spawns, Vector3 start, Vector3 end, string name, int number);

Use these functions (Not in class Drawing) to place the same object in a certain shape.

Object Movement

void moveObjectXY(const variant < int, vector < int >> objectID, Vector3 pos);
void moveObjectX(const variant < int, vector < int >> objectID, int x_offset);
void moveObjectY(const variant < int, vector < int >> objectID, int y_offset);
void moveObjectPosition(const variant < int, vector < int >> objectID, Vector3 pos);

void setObjectXY(const variant < int, vector < int >> objectID, Vector3 pos);
void setObjectX(const variant < int, vector < int >> objectID, Vector3 pos);
void setObjectY(const variant < int, vector < int >> objectID, Vector3 pos);
void setObjectPosition(const variant < int, vector < int >> objectID, Vector3 pos);
void setObjectPositionToSprite(const variant < int, vector < int >> objectIDs, int spriteID);

void setObjectRandom(const variant < int, vector < int >> objectID,
const pair < int, int > & xRange,
const pair < int, int > & yRange);

void glideObjectPositionToSprite(const variant < int, vector < int >> objectIDs, int spriteID, float speed);
void glideObjectX(const variant < int, vector < int >> & ids, int x_offset, float speed, ...);
void glideObjectY(const variant < int, vector < int >> & ids, int y_offset, float speed, ...);
void glideObjectPositionToSprite(const variant < int, vector < int >> objectIDs, int spriteID, float speed);

void glideObjectRandom(const variant < int, vector < int >> & ids,
const pair < int, int > & xRange,
const pair < int, int > & yRange, float speed);

void glideObjectXY(const variant < int, vector < int >> & ids,
const Vector3 & offset, float speed, ...);

Check movements.md for more information

General Functions

These are some useful functions that could be used frequently in game development.

void kill(variant<int, vector<int>> objIDs);
void revive(variant<int, vector<int>> objIDs);

void destroy(variant<int, vector<int>> objIDs);

The kill Function removes the object from the workspace and revive function returns it.
To delete the object completely, use the destroy function.

mesh * getMesh(int objID);
mesh getMeshValue(int objID);

The getMesh function Returns a pointer to the mesh of a specific object. The getMeshValue function Returns the mesh of a specific object.

void hold ();
void wait (float time);

hold function waits forever, preventing the program from ending.
wait function waits for a certain amount of time (milliseconds)

bool isAlive(int obj);
vector < int > all();
vector < int > seek(string objectName);
vector < int > findObjects(string name, variant < vector < int > , int > number);

isAlive function checks if an object exists.
all function returns all object IDs that exist in the current workspace
findObject function takes two inputs:

A name (string) of an object. A vector of numbers (or a single number). It returns a vector of object IDs (int). These IDs correspond to objects in the workspace that match the specified name and any specified numbers.