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What i have now


#define QUAD_POS_COMP 3

typedef struct quad_pos
 GLfloat x, y, z;

#define SIZE_QUAD_POS = sizeof(quad_pos) * QUAD_VERT_COUNT

static QUAD_BUFFER = 0;

void init_quad_buffer()
 quad_pos* pos_data = malloc(SIZE_QUAD_POS);

 pos_data[0].x = -1.0f;
 pos_data[0].y = -1.0f;
 pos_data[0].z = 0.0f;

 pos_data[1].x = 1.0f;
 pos_data[1].y = -1.0f;
 pos_data[1].z = 0.0f;

 pos_data[2].x = -1.0f;
 pos_data[2].y = 1.0f;
 pos_data[2].z = 0.0f;

 pos_data[3].x = 1.0f;
 pos_data[3].y = 1.0f;
 pos_data[3].z = 0.0f;


void get_quad_buffer
  return QUAD_BUFFER;

And drawning (part of it)

glBindBuffer(GL_ARRAY_BUFFER, get_quad_buffer());
glEnableVertexAttribArray(ss->attrib[0]);//attrib[o] is vertex pos
glVertexAttribPointer(ss->attrib[0], QUAD_POS_COMP, GL_FLOAT, GL_FALSE, 0, 0);

Scaling, translating and rotating achieved with matrices and shaders, so yes this buffer never changes for every sprite.

But why we need to use GL_float for just -1.0, 1.0? GL_Byte will be enough.

 typedef struct quad_pos
 GLbyte x, y, z;

void init_quad_buffer()
 quad_pos* pos_data = malloc(SIZE_QUAD_POS);

 pos_data[0].x = -1;
 pos_data[0].y = -1;
 pos_data[0].z = 0;


  glVertexAttribPointer(ss->attrib[0], QUAD_POS_COMP, GL_BYTE, GL_FALSE, 0, 0);

Question 1: Do i need normalize set to GL_TRUE?
Question 2: GLclampf and GLfloat both 4 byted floats, but color values are from 0.0 to 1.0 so if i put them in GLbyte too (val/256, so 255 for 1.0, 128 for 0.5, 0 for 0) do i need GL_TRUE for normalize in glVertexAttribPointer?
Question 3: Do i really need padding in vertex data/other data? Adding fictitious pos_data.g, just for sizeof(pos_data) = 16 == Good for gpu?

share|improve this question
up vote 1 down vote accepted

But why we need to use GL_float for just -1.0, 1.0? GL_Byte will be enough.

Please note this is not true in general, in most cases you will need a float for precision. And if you only have so few values and so simple geometry, the odds are quite high that there even isn't a reason at all to optimize it to glByte in the first place. You likely have very few vertices at all, so why would you want to save storage on them? This sounds like a very good example of premature optimization (I know, it's an overused term).

Now, for your actual questions:

  1. No, not if you want the same functionality, if normalize is false, the -1 will convert to -1.0f, if it is true it will be more something like -0.0078125f (or -1/128.0f). So if you want to keep the same scale, you don't want it normalized.
  2. Where do you get the idea that GLclampf and GLfloat are 8-byte floats? They are usually 4 byte floats. If you want to pass in RGB colors through vertex attributes, yes you should normalize them as OpenGL expects color components to be in the range [0.0f,1.0f]. But again: why don't you simply pass them as floats? What do you think to gain? In a simple game you probably have not enough colors to notice the difference and in a non-simple game you're more likely to be using textures.
  3. Of this I am not sure. I know it was true for old GPU's (and I mean almost 10y back), but I don't know of any recent claims that this would actually improve something. And in any case, the best-known alignment was to prop all vertex-attributes for one vertex together into (a multiple of) 32 bytes, and that was for ATI cards. Byte alignment might be necessary for some trickier things/extensions, but I do not think you need to worry about it just yet.
share|improve this answer

In general, you could always aim for the half-float (16bit float) extensions to save memory.

Your implementation looks like causing some draw-call overhead. Normalizing (on the fly!) will cause additional overhead. For drawing multiple instances of this constant quad, I recommend the following to speed things up:

  • Implementation of a geometry-shader; let it generate, transform and emit the 4 vertices of the quad for you.
  • instanced drawing with a transform-buffer using a texture buffer object (TBO) containing the transform matrices for each quad instance (each matrix column will be accessed using the builtin uniform 'gl_InstanceID').
    Supply the matrices via vertex attribute arrays (probably faster). These two approaches can be implemented upon the same buffer data layout (just an array of matrices)
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