Getting started

This guide takes you through writing a simple application using GLFW 3. The application will create a window and OpenGL context, render a rotating triangle and exit when the user closes the window or presses Escape. This guide will introduce a few of the most commonly used functions, but there are many more.

This guide assumes no experience with earlier versions of GLFW. If you have used GLFW 2 in the past, read Moving from GLFW 2 to 3, as some functions behave differently in GLFW 3.

Step by step

Including the GLFW header

In the source files of your application where you use GLFW, you need to include its header file.

#include <GLFW/glfw3.h>
The header of the GLFW 3 API.

This header provides all the constants, types and function prototypes of the GLFW API.

By default it also includes the OpenGL header from your development environment. On some platforms this header only supports older versions of OpenGL. The most extreme case is Windows, where it typically only supports OpenGL 1.2.

Most programs will instead use an extension loader library and include its header. This example uses files generated by glad. The GLFW header can detect most such headers if they are included first and will then not include the one from your development environment.

#include <glad/gl.h>
#include <GLFW/glfw3.h>

To make sure there will be no header conflicts, you can define GLFW_INCLUDE_NONE before the GLFW header to explicitly disable inclusion of the development environment header. This also allows the two headers to be included in any order.

#define GLFW_INCLUDE_NONE
#include <GLFW/glfw3.h>
#include <glad/gl.h>

Initializing and terminating GLFW

Before you can use most GLFW functions, the library must be initialized. On successful initialization, GLFW_TRUE is returned. If an error occurred, GLFW_FALSE is returned.

if (!glfwInit())
{
// Initialization failed
}
int glfwInit(void)
Initializes the GLFW library.

Note that GLFW_TRUE and GLFW_FALSE are and will always be one and zero.

When you are done using GLFW, typically just before the application exits, you need to terminate GLFW.

void glfwTerminate(void)
Terminates the GLFW library.

This destroys any remaining windows and releases any other resources allocated by GLFW. After this call, you must initialize GLFW again before using any GLFW functions that require it.

Setting an error callback

Most events are reported through callbacks, whether it's a key being pressed, a GLFW window being moved, or an error occurring. Callbacks are C functions (or C++ static methods) that are called by GLFW with arguments describing the event.

In case a GLFW function fails, an error is reported to the GLFW error callback. You can receive these reports with an error callback. This function must have the signature below but may do anything permitted in other callbacks.

void error_callback(int error, const char* description)
{
fprintf(stderr, "Error: %s\n", description);
}

Callback functions must be set, so GLFW knows to call them. The function to set the error callback is one of the few GLFW functions that may be called before initialization, which lets you be notified of errors both during and after initialization.

glfwSetErrorCallback(error_callback);
GLFWerrorfun glfwSetErrorCallback(GLFWerrorfun callback)
Sets the error callback.

Creating a window and context

The window and its OpenGL context are created with a single call to glfwCreateWindow, which returns a handle to the created combined window and context object

GLFWwindow* window = glfwCreateWindow(640, 480, "My Title", NULL, NULL);
if (!window)
{
// Window or OpenGL context creation failed
}
GLFWwindow * glfwCreateWindow(int width, int height, const char *title, GLFWmonitor *monitor, GLFWwindow *share)
Creates a window and its associated context.
struct GLFWwindow GLFWwindow
Opaque window object.
Definition: glfw3.h:1186

This creates a 640 by 480 windowed mode window with an OpenGL context. If window or OpenGL context creation fails, NULL will be returned. You should always check the return value. While window creation rarely fails, context creation depends on properly installed drivers and may fail even on machines with the necessary hardware.

By default, the OpenGL context GLFW creates may have any version. You can require a minimum OpenGL version by setting the GLFW_CONTEXT_VERSION_MAJOR and GLFW_CONTEXT_VERSION_MINOR hints before creation. If the required minimum version is not supported on the machine, context (and window) creation fails.

GLFWwindow* window = glfwCreateWindow(640, 480, "My Title", NULL, NULL);
if (!window)
{
// Window or context creation failed
}
#define GLFW_CONTEXT_VERSION_MINOR
Context client API minor version hint and attribute.
Definition: glfw3.h:962
void glfwWindowHint(int hint, int value)
Sets the specified window hint to the desired value.
#define GLFW_CONTEXT_VERSION_MAJOR
Context client API major version hint and attribute.
Definition: glfw3.h:956

The window handle is passed to all window related functions and is provided to along to all window related callbacks, so they can tell which window received the event.

When a window and context is no longer needed, destroy it.

void glfwDestroyWindow(GLFWwindow *window)
Destroys the specified window and its context.

Once this function is called, no more events will be delivered for that window and its handle becomes invalid.

Making the OpenGL context current

Before you can use the OpenGL API, you must have a current OpenGL context.

void glfwMakeContextCurrent(GLFWwindow *window)
Makes the context of the specified window current for the calling thread.

The context will remain current until you make another context current or until the window owning the current context is destroyed.

If you are using an extension loader library to access modern OpenGL then this is when to initialize it, as the loader needs a current context to load from. This example uses glad, but the same rule applies to all such libraries.

gladLoadGL(glfwGetProcAddress);
GLFWglproc glfwGetProcAddress(const char *procname)
Returns the address of the specified function for the current context.

Checking the window close flag

Each window has a flag indicating whether the window should be closed.

When the user attempts to close the window, either by pressing the close widget in the title bar or using a key combination like Alt+F4, this flag is set to 1. Note that the window isn't actually closed, so you are expected to monitor this flag and either destroy the window or give some kind of feedback to the user.

while (!glfwWindowShouldClose(window))
{
// Keep running
}
int glfwWindowShouldClose(GLFWwindow *window)
Checks the close flag of the specified window.

You can be notified when the user is attempting to close the window by setting a close callback with glfwSetWindowCloseCallback. The callback will be called immediately after the close flag has been set.

You can also set it yourself with glfwSetWindowShouldClose. This can be useful if you want to interpret other kinds of input as closing the window, like for example pressing the Escape key.

Receiving input events

Each window has a large number of callbacks that can be set to receive all the various kinds of events. To receive key press and release events, create a key callback function.

static void key_callback(GLFWwindow* window, int key, int scancode, int action, int mods)
{
if (key == GLFW_KEY_ESCAPE && action == GLFW_PRESS)
}
#define GLFW_TRUE
One.
Definition: glfw3.h:313
#define GLFW_PRESS
The key or mouse button was pressed.
Definition: glfw3.h:339
#define GLFW_KEY_ESCAPE
Definition: glfw3.h:447
void glfwSetWindowShouldClose(GLFWwindow *window, int value)
Sets the close flag of the specified window.

The key callback, like other window related callbacks, are set per-window.

glfwSetKeyCallback(window, key_callback);
GLFWkeyfun glfwSetKeyCallback(GLFWwindow *window, GLFWkeyfun callback)
Sets the key callback.

In order for event callbacks to be called when events occur, you need to process events as described below.

Rendering with OpenGL

Once you have a current OpenGL context, you can use OpenGL normally. In this tutorial, a multi-colored rotating triangle will be rendered. The framebuffer size needs to be retrieved for glViewport.

int width, height;
glfwGetFramebufferSize(window, &width, &height);
glViewport(0, 0, width, height);
void glfwGetFramebufferSize(GLFWwindow *window, int *width, int *height)
Retrieves the size of the framebuffer of the specified window.

You can also set a framebuffer size callback using glfwSetFramebufferSizeCallback and be notified when the size changes.

The details of how to render with OpenGL is outside the scope of this tutorial, but there are many excellent resources for learning modern OpenGL. Here are a few of them:

These all happen to use GLFW, but OpenGL itself works the same whatever API you use to create the window and context.

Reading the timer

To create smooth animation, a time source is needed. GLFW provides a timer that returns the number of seconds since initialization. The time source used is the most accurate on each platform and generally has micro- or nanosecond resolution.

double time = glfwGetTime();
double glfwGetTime(void)
Returns the GLFW time.

Swapping buffers

GLFW windows by default use double buffering. That means that each window has two rendering buffers; a front buffer and a back buffer. The front buffer is the one being displayed and the back buffer the one you render to.

When the entire frame has been rendered, the buffers need to be swapped with one another, so the back buffer becomes the front buffer and vice versa.

void glfwSwapBuffers(GLFWwindow *window)
Swaps the front and back buffers of the specified window.

The swap interval indicates how many frames to wait until swapping the buffers, commonly known as vsync. By default, the swap interval is zero, meaning buffer swapping will occur immediately. On fast machines, many of those frames will never be seen, as the screen is still only updated typically 60-75 times per second, so this wastes a lot of CPU and GPU cycles.

Also, because the buffers will be swapped in the middle the screen update, leading to screen tearing.

For these reasons, applications will typically want to set the swap interval to one. It can be set to higher values, but this is usually not recommended, because of the input latency it leads to.

void glfwSwapInterval(int interval)
Sets the swap interval for the current context.

This function acts on the current context and will fail unless a context is current.

Processing events

GLFW needs to communicate regularly with the window system both in order to receive events and to show that the application hasn't locked up. Event processing must be done regularly while you have visible windows and is normally done each frame after buffer swapping.

There are two methods for processing pending events; polling and waiting. This example will use event polling, which processes only those events that have already been received and then returns immediately.

void glfwPollEvents(void)
Processes all pending events.

This is the best choice when rendering continually, like most games do. If instead you only need to update your rendering once you have received new input, glfwWaitEvents is a better choice. It waits until at least one event has been received, putting the thread to sleep in the meantime, and then processes all received events. This saves a great deal of CPU cycles and is useful for, for example, many kinds of editing tools.

Putting it together

Now that you know how to initialize GLFW, create a window and poll for keyboard input, it's possible to create a simple program.

This program creates a 640 by 480 windowed mode window and starts a loop that clears the screen, renders a triangle and processes events until the user either presses Escape or closes the window.

#include <glad/gl.h>
#define GLFW_INCLUDE_NONE
#include <GLFW/glfw3.h>
#include "linmath.h"
#include <stdlib.h>
#include <stdio.h>
static const struct
{
float x, y;
float r, g, b;
} vertices[3] =
{
{ -0.6f, -0.4f, 1.f, 0.f, 0.f },
{ 0.6f, -0.4f, 0.f, 1.f, 0.f },
{ 0.f, 0.6f, 0.f, 0.f, 1.f }
};
static const char* vertex_shader_text =
"#version 110\n"
"uniform mat4 MVP;\n"
"attribute vec3 vCol;\n"
"attribute vec2 vPos;\n"
"varying vec3 color;\n"
"void main()\n"
"{\n"
" gl_Position = MVP * vec4(vPos, 0.0, 1.0);\n"
" color = vCol;\n"
"}\n";
static const char* fragment_shader_text =
"#version 110\n"
"varying vec3 color;\n"
"void main()\n"
"{\n"
" gl_FragColor = vec4(color, 1.0);\n"
"}\n";
static void error_callback(int error, const char* description)
{
fprintf(stderr, "Error: %s\n", description);
}
static void key_callback(GLFWwindow* window, int key, int scancode, int action, int mods)
{
if (key == GLFW_KEY_ESCAPE && action == GLFW_PRESS)
}
int main(void)
{
GLFWwindow* window;
GLuint vertex_buffer, vertex_shader, fragment_shader, program;
GLint mvp_location, vpos_location, vcol_location;
glfwSetErrorCallback(error_callback);
if (!glfwInit())
exit(EXIT_FAILURE);
window = glfwCreateWindow(640, 480, "Simple example", NULL, NULL);
if (!window)
{
exit(EXIT_FAILURE);
}
glfwSetKeyCallback(window, key_callback);
gladLoadGL(glfwGetProcAddress);
// NOTE: OpenGL error checks have been omitted for brevity
glGenBuffers(1, &vertex_buffer);
glBindBuffer(GL_ARRAY_BUFFER, vertex_buffer);
glBufferData(GL_ARRAY_BUFFER, sizeof(vertices), vertices, GL_STATIC_DRAW);
vertex_shader = glCreateShader(GL_VERTEX_SHADER);
glShaderSource(vertex_shader, 1, &vertex_shader_text, NULL);
glCompileShader(vertex_shader);
fragment_shader = glCreateShader(GL_FRAGMENT_SHADER);
glShaderSource(fragment_shader, 1, &fragment_shader_text, NULL);
glCompileShader(fragment_shader);
program = glCreateProgram();
glAttachShader(program, vertex_shader);
glAttachShader(program, fragment_shader);
glLinkProgram(program);
mvp_location = glGetUniformLocation(program, "MVP");
vpos_location = glGetAttribLocation(program, "vPos");
vcol_location = glGetAttribLocation(program, "vCol");
glEnableVertexAttribArray(vpos_location);
glVertexAttribPointer(vpos_location, 2, GL_FLOAT, GL_FALSE,
sizeof(vertices[0]), (void*) 0);
glEnableVertexAttribArray(vcol_location);
glVertexAttribPointer(vcol_location, 3, GL_FLOAT, GL_FALSE,
sizeof(vertices[0]), (void*) (sizeof(float) * 2));
while (!glfwWindowShouldClose(window))
{
float ratio;
int width, height;
mat4x4 m, p, mvp;
glfwGetFramebufferSize(window, &width, &height);
ratio = width / (float) height;
glViewport(0, 0, width, height);
glClear(GL_COLOR_BUFFER_BIT);
mat4x4_identity(m);
mat4x4_rotate_Z(m, m, (float) glfwGetTime());
mat4x4_ortho(p, -ratio, ratio, -1.f, 1.f, 1.f, -1.f);
mat4x4_mul(mvp, p, m);
glUseProgram(program);
glUniformMatrix4fv(mvp_location, 1, GL_FALSE, (const GLfloat*) mvp);
glDrawArrays(GL_TRIANGLES, 0, 3);
glfwSwapBuffers(window);
}
exit(EXIT_SUCCESS);
}

The program above can be found in the source package as examples/simple.c and is compiled along with all other examples when you build GLFW. If you built GLFW from the source package then you already have this as simple.exe on Windows, simple on Linux or simple.app on macOS.

This tutorial used only a few of the many functions GLFW provides. There are guides for each of the areas covered by GLFW. Each guide will introduce all the functions for that category.

You can access reference documentation for any GLFW function by clicking it and the reference for each function links to related functions and guide sections.

The tutorial ends here. Once you have written a program that uses GLFW, you will need to compile and link it. How to do that depends on the development environment you are using and is best explained by the documentation for that environment. To learn about the details that are specific to GLFW, see Building applications.