Mesa Subset Specification
Tungsten Graphics, Inc.
February 26, 2003
Copyright © 2002-2003 by Tungsten Graphics, Inc.,
Cedar Park, Texas. All Rights Reserved.
Permission is granted to make and distribute verbatim copies of this
document provided the copyright notice and this permission notice are
preserved on all copies.
OpenGL is a trademark of Silicon
Graphics, Inc..
1. Introduction
This document describes a subset of the Mesa implemented by Tungsten
Graphics, Inc. for embedded devices. Prior to reading this
document the reader should be familiar with the OpenGL 1.2.1
specification dated April 1, 1999 (available from http://www.opengl.org/developers/documentation/specs.html.)
Experience with OpenGL programming is highly advisable.
Tungsten Graphics, Inc. is working with industry standards
organizations +in an attempt to standardize this Mesa subset and any
other possible subsets +as a result of this work.
Appendix A contains a list of issues of which some may not be resolved.
To summarize, the following major features of Mesa are omitted from the
subset:
- Vertex arrays
- Texture coordinate generation
- Lighting
- Point size
- Polygon stipple
- DrawPixels, CopyPixels, PixelZoom
- 1-D and 3-D textures
- CopyTex[Sub]Image
- Fog
- Depth test
- Color Index mode
- Accumulation buffer
- Feedback mode
- Evaluators
- Push/Pop attributes
- Display lists
Further reductions are made at a lower level of detail.
Mesa function names are printed in bold
face. Function parameters are printed in italics.
The Tungsten Graphics, Inc. Mesa subset library is hereafter
referred to as the subset.
2. Primitive Specification
2.1 glBegin, glEnd and glVertex Commands
The basic rendering primitives are points, lines and triangles.
Quadrilaterals and polygons are composed of triangles.
Primitives are drawn with the glBegin
and glEnd commands and a subset
of the glVertex commands:
void glBegin(GLenummode)
void glEnd(void)
void glVertex2f(GLfloat x, GLfloat y)
void glVertex2fv(const GLfloat
*v)
void glVertex3f(GLfloat x, GLfloat y, GLfloat z)
void glVertex3fv(const GLfloat
*v)
The mode parameter to glBegin may be one of the following
GL_POINTS - a series of individual
points
GL_LINES - a series of disjoint line segments
GL_LINE_STRIP - series of connected line segments
GL_LINE_LOOP - a closed loop of line segments
GL_TRIANGLES - a series of individual triangles
GL_TRIANGLE_STRIP - a connected strip of triangles
GL_TRIANGLE_FAN - a sequence of triangles all sharing a common vertex
GL_QUADS - a sequence of individual quadrilaterals
GL_QUAD_STRIP - a connected strip of quadrilaterals
GL_POLYGON - a closed, convex polygon
The glVertex commands take two
or three floating point coordinates, or a pointer to an array of two or
three floating point coordinates. Vertices are actually 4-element
homogeneous coordinates. The fourth component, unspecified by the
subset's glVertex commands, is
one.
2.2 Other Per-vertex Commands
The glColor and glTexCoord commands may be used to
specify colors and texture coordinates for each vertex:
void glColor3f(GLfloatred, GLfloat green, GLfloat blue)
void glColor3fv(const GLfloat *rgb)
void glColor4f(GLfloat red, GLfloat green, GLfloat blue, GLfloat alpha)
void glColor4fv(const GLfloat *rgba)
void glTexCoord2f(GLfloat s, GLfloat t)
void glTexCoord2fv(const
GLfloat *c)
The glColor commands specify
the color and optionally, the alpha value, for subsequent vertices.
For the glColor3 commands,
alpha is set to one.
The glTexCoord2 commands
specify the texture coordinate for subsequent vertices. Texture
coordinates are actually four-component coordinates: (s, t, r, q).
The glTexCoord2 commands
set s and t explicitly. The r and q components are zero and one,
respectively.
Only glVertex, glColor and glTexCoord commands are allowed
between glBegin and glEnd. Calling any other
command between glBegin and glEnd will result in the error
GL_INVALID_OPERATION.
2.3 Unsupported Commands
None of the following commands related to primitive specification are
supported by the subset:
Per-Vertex commands:
glVertex2d,
glVertex2i, glVertex2s, glVertex3d, glVertex3i, glVertex3s, glVertex4d,
glVertex4i, glVertex4s, glVertex2dv, glVertex2iv, glVertex2sv,
glVertex3dv, glVertex3iv, glVertex3sv, glVertex4dv, glVertex4iv,
glVertex4sv,
glNormal3b, glNormal3d, glNormal3f, glNormal3i, glNormal3s, glNormal3bv, glNormal3dv, glNormal3fv,
glNormal3iv, glNormal3sv,
glIndexd, glIndexf, glIndexi, glIndexs, glIndexub, glIndexdv,
glIndexfv, glIndexiv, glIndexsv, glIndexubv,
glColor3b, glColor3d, glColor3i, glColor3s, glColor3ub, glColor3ui,
glColor3us, glColor3bv,
glColor3dv, glColor3iv, glColor3sv, glColor3ubv, glColor3uiv,
glColor3usv, lColor4b,
glColor4d, glColor4i, glColor4s, glColor4ub, glColor4ui, glColor4us, glColor4bv, glColor4dv, glColor4iv,
glColor4sv, glColor4ubv, glColor4uiv, glColor4usv,
glTexCoord1d, glTexCoord1f,
glTexCoord1i, glTexCoord1s, glTexCoord2d, glTexCoord2i, glTexCoord2s,
glTexCoord3d, glTexCoord3f, glTexCoord3i, glTexCoord3s, glTexCoord4d,
glTexCoord4f, glTexCoord4i, glTexCoord4s, glTexCoord1dv, glTexCoord1fv,
glTexCoord1iv, glTexCoord1sv, glTexCoord2dv, glTexCoord2iv,
glTexCoord2sv, glTexCoord3dv, glTexCoord3fv, glTexCoord3iv,
glTexCoord3sv, glTexCoord4dv, glTexCoord4fv, glTexCoord4iv,
glTexCoord4sv,
glEdgeFlag, glEdgeFlagv
Vertex array commands:
glVertexPointer,
glColorPointer, glIndexPointer, glTexCoordPointer, glEdgeFlagPointer,
glNormalPointer, glInterleavedArrays, glArrayElement, glDrawArrays,
glDrawElements, glDrawRangeElements, glEnableClientState,
glDisableClientState
Rectangle commands:
glRects,
glRecti, glRectf, glRectd, glRectsv, glRectiv, glRectfv, glRectdv,
Lighting commands:
glMaterialf,
glMateriali, glMaterialfv, glMaterialiv
Evaluator commands:
glEvalCoord1d,
glEvalCoord1f, glEvalCoord1dv, glEvalCoord1fv, glEvalCoord2d, glEvalCoord2f,
glEvalCoord2dv, glEvalCoord2fv,
glEvalPoint1, glEvalPoint2
3. Coordinate Transformation
3.1 Vertex Transformation
Vertex coordinates are transformed by the current modelview and
projection matrices then mapped to window coordinates as specified by
the viewport. The following coordinate transformation commands are
supported by the subset
glMatrixMode(GLenum mode)
glLoadIdentity(void)
glPushMatrix(void)
glPopMatrix(void)
glLoadMatrixf(const GLfloat *m)
glMultMatrixf(const GLfloat *m)
glRotatef(GLfloat angle, GLfloat x, GLfloat y, GLfloat z)
glTranslatef(GLfloat x, GLfloat y, GLfloat z)
glScalef(GLfloat x, GLfloat y, GLfloat z)
glFrustum(GLdouble left, GLdouble right, GLdouble bottom, GLdouble top, GLdouble near, GLdouble far)
glOrtho(GLdouble left, GLdouble right, GLdouble bottom, GLdouble top, GLdouble near, GLdouble far)
glViewport(GLint x, GLint y, GLsize width, GLsizei height)
The glMatrixMode command
specifies the current matrix.
The mode parameter may be GL_MODELVIEW or GL_PROJECTION to specify
the modelview matrix or projection matrix. Subsequent matrix
commands will effect the current matrix. Also associated with the
modelview and projection matrices are a modelview matrix stack and
projection matrix stack.
The glLoadIdentity command
replaces the current matrix with the identity matrix. The matrix
elements are specified in column-major order.
The glPushMatrix command pushes
a copy of the current matrix onto either the modelview matrix stack or
the projection matrix stack. The glPopMatrix
command replaces the current matrix with a copy of the top matrix off
the modelview matrix stack or projection matrix stack, the pops the
stack. Matrix stacks are useful for traversing and rendering
hierarchical models.
The glMultMatrixf command
post-multiplies the current matrix by the specified matrix. The
matrix elements are specified in column-major order.
The glRotatef command
post-multiplies the current matrix by a rotation matrix defined by the
angle and rotation axis defined by x, y and z.
The glTranslatef command
post-multiplies the current matrix by a translation matrix defined by
the x, y and z translation parameters.
The glScalef command
post-multiplies the current matrix by a scaling matrix defined by the x, y and z scale factors.
The glFrustum command
post-multiplies the current matrix by a perspective projection matrix.
The near and far values specify the position of
the hither and yon Z-axis clipping planes. The left, right, bottom and top parameters are the X and Y
extents at the near clipping plane. glFrustum is normally used to modify
the projection matrix.
The glOrtho command
post-multiplies the current matrix by an orthographic projection matrix.
The near and far values specify the position of
the hither and yon Z-axis clipping planes. The left, right, bottom and top parameters specify the X and
Y-axis clipping planes. glOrtho
is normally used to modify the projection matrix.
The glViewport command
specifies the mapping of coordinates from normalized device coordinates
to window coordinates. The x
and y parameters specify the
viewport's lower-left corner in the window and the width and height parameters specify the size
of the viewport. glViewport
does not effect the current matrix.
A coordinate transformed to window coordinates is hereafter known as (xw,
yw, zw).
3.2 Clipping
View-volume clipping automatically discards or trims primitives which
lie completely or partially outside of the view volume specified by glFrustum and glOrtho. Note that the glViewport command does not define a
clipping region.
Clipping occurs in clip coordinate
space - the coordinates produced after applying the projection
matrix.
3.3 Current Raster Position
The current raster position specifies the location for drawing images
with glBitmap. The current
raster position is set with the commands:
void glRasterPos2f(GLfloatx, GLfloat y)
void glRasterPos2fv(const
GLfloat *v)
void glRasterPos2i(GLint x, GLint y)
void glRasterPos2iv(const
GLint *v)
glRasterPos specifies a
4-component coordinate (x, y, 0, 1). The coordinate is processed
like a vertex; it is transformed by the modelview matrix, the projection
matrix and mapped to the viewport. The resulting window coordinate
is stored as the current raster position. The coordinate is
clipped-tested against the frustum like a vertex. If the
coordinate is clipped, then the current raster position becomes invalid
and subsequent glBitmap commands
have no effect.
glRasterPos also updates the
current raster color and current raster texture coordinates. The
current raster color is updated (copied) from the current color (as
specified by glColor).
The current raster texture coordinate is updated (copied) from the
current texture coordinate (as specified by glTexCoord).
3.4 Unsupported Commands
The following commands related to vertex transformation are not
supported by the subset:
User-defined clip plane commands:
glClipPlane
Lighting and material commands:
glLightModeli,
glLightModelf, glLightModeliv,
glLightModelfv, glLightf,
glLighti, glLightfv, glLightiv, glColorMaterial
Automatic texture coordinate generation
commands:
glTexGend,
glTexGenf, glTexGeni, glTexGendv,
glTexGenfv, glTexGeniv,
Double-valued commands:
glLoadMatrixd,
glMultMatrixd, glRotated, glTranslated, glScaled
Depth Range command:
glDepthRange
(the near value is always 0.0 and the far value is always 1.0)
Extra RasterPos commands:
glRasterPos2d,
glRasterPos2s, glRasterPos3d, glRasterPos3f, glRasterPos3i,
glRasterPos3s, glRasterPos4d, glRasterPos4f, glRasterPos4i,
glRasterPos4s, glRasterPos2dv, glRasterPos2sv, glRasterPos3dv,
glRasterPos3fv, glRasterPos3iv, glRasterPos3sv, glRasterPos4dv,
glRasterPos4fv, glRasterPos4iv, glRasterPos4sv
4. Rasterization
This section describes the commands and options for drawing points,
lines, triangles and bitmaps. Rasterization
is the term for the process which produces fragments from the geometric
description of a primitive (a point, line, polygon or bitmap). For
example, given the two coordinates for the end-points of a line segment,
rasterization determines which pixels in the frame buffer are modified
to draw the line. A
fragment is a tuple which consists of a window coordinate, colors and
texture coordinates. The fragments produced by rasterization are
subsequently processed by the per-fragment operations described later.
4.1 Point Rasterization
Points are rendered with the command sequence glBegin(GL_POINTS), glVertex, ... glEnd. The window coordinate (xw,
yw, zw) is truncated to rasterize the point.
The truncated coordinate with its associated color and texture
coordinate is sent as a single fragment to the per-fragment processing
stages.
The glPointSize command is not
supported; only 1-pixel points are supported.
Point smoothing (antialiasing) is also not supported.
4.2 Line Rasterization
Lines are rendered with the command sequence glBegin(mode), glVertex, glVertex, ... glEnd where mode is one of GL_LINES,
GL_LINE_STRIP or GL_LINE_LOOP. Lines are rasterized as described
in the OpenGL specification. Note that OpenGL specifies the half-open convention for drawing
lines: the last fragment in a line segment is omitted so that endpoint
pixels shared by two line segments will only be drawn once instead of
twice.
4.2.1 Line Width
The width of lines can be controlled by
void glLineWidth(GLfloatwidth)
where width is the line width
in pixels. The width defaults to 1.0. Attempting to set the
width to a value less than or equal to zero will raise the error
GL_INVALID_VALUE.
4.2.2 Line Stipple
Lines may be stippled (i.e. dashed) with the command
glLineStipple(GLintfactor, GLushort pattern)
pattern describes an on/off
pattern for the fragments produced by rasterization and factor specifies how many subsequent
fragments are kept or culled for each pattern bit. Line stippling
can be enabled or disabled by the commands glEnable(GL_LINE_STIPPLE) and glDisable(GL_LINE_STIPPLE).
4.2.3 Line Antialiasing
Lines may be antialiased. For antialiased lines, each fragment
produced by rasterization is assigned a coverage value which describes how
much of the fragment's area is considered to be inside the line. Later, the
alpha value of each fragment is multiplied by the coverage value.
By blending the fragments into the frame buffer, the edges of
lines appear smoothed.
Line antialiasing can be enabled or disabled with the commands glEnable(GL_LINE_SMOOTH) and glDisable(GL_LINE_SMOOTH).
4.3 Polygon Rasterization
Polygons, quadrilaterals and triangles share the same polygon
rasterization options.
Triangles are rendered by the command sequence glBegin(mode),glVertex, glVertex, ... glEnd where mode may be one of GL_TRIANGLES,
GL_TRIANGLE_STRIP or GL_TRIANGLE_FAN.
For GL_TRIANGLES mode, the number of vertices should be a multiple
of three - extra vertices will be ignored. For GL_TRIANGLE_STRIP
and GL_TRIANGLE_FAN, at least three vertices should be specified.
If less than three are specified, nothing is drawn.
Quadrilaterals are rendered by
the command sequence glBegin(mode),glVertex, glVertex, ... glEnd where mode may be one of GL_QUADS or
GL_QUAD_STRIP. For
GL_QUADS, the number of vertices should be a multiple of four - extra
vertices will be ignored. For GL_QUAD_STRIP, the number of
vertices should be even and at least four. Extra vertices (one)
will be ignored.
Convex polygons are rendered
by the command sequence glBegin(GL_POLYGON),glVertex, glVertex, ... glEnd.
If less than three vertices are specified, nothing is drawn.
4.3.1 Polygon Orientation
The winding order of vertices
(clockwise or counter-clockwise) is significant. It is used to
determine the front-facing or back-facing orientation of polygons.
By default, a front-facing polygon's vertices are in
counter-clockwise order (in window coordinates). Figures 2.4 and
2.5 of the OpenGL 1.2.1 specification illustrate the winding order for
front-facing triangles and quadrilaterals, respectively.
The command
void glFrontFace(GLenum mode)
specifies whether clockwise or counter-clockwise winding indicates a
front-facing polygon. If mode
is GL_CW then polygons with clockwise winding are front-facing. If mode is GL_CCW then polygons with
counter-clockwise winding are front-facing. The default value is
GL_CCW. If mode is not
GL_CCW or GL_CW then the error GL_INVALID_ENUM will be raised.
4.3.2 Polygon Culling
Polygons may be culled (discarded) depending on whether they are
front-facing or back-facing. The command
void
glCullFace(GLenum mode)
specifies whether front-facing, back-facing or all polygons should be
culled. If mode is
GL_FRONT then front-facing polygons will be culled. If mode is GL_BACK then back-facing
polygons will be culled. Otherwise, if mode
is GL_FRONT_AND_BACK then all polygons will be culled. Any other
value for mode will raise the
error GL_INVALID_ENUM.
Polygon culling is enabled and disabled with the commands glEnable(GL_CULL_FACE) and glDisable(GL_CULL_FACE),
respectively.
4.3.3 Polygon Antialiasing
Polygons may be antialiased in order to smooth their edges.
Polygon antialiasing is enabled and disabled with the commands glEnable(GL_POLYGON_SMOOTH) and glDisable(GL_POLYGON_SMOOTH).
When polygon antialiasing is enabled each fragment produced by polygon,
triangle and quadrilateral rasterization will be given a coverage value which indicates how
much of the fragment is covered by the polygon. Fragments
completely inside the polygon have coverage 1.0. Fragments
completely outside the polygon have zero coverage (in theory).
Fragments which intersect the polygon's edge have a coverage value
in the range (0, 1).
The fragment's alpha value is multiplied by the coverage value.
By enabling the appropriate blending mode, polygon edges will
appear smoothed.
4.4 Shading
The command
void glShadeModel(GLenummode)
determines whether colors are interpolated between vertices during
rasterization. If mode is
GL_FLAT then vertex colors are not interpolated. The color used
for drawing lines, triangles and quadrilaterals is that of the last
vertex used to specify each primitive. For polygons, the color of
the first vertex specifies the color for the entire polygon. If mode is GL_SMOOTH then vertex colors
are linearly interpolated to produce the fragment colors.
4.5 Bitmap Rasterization
A bitmap is a monochromatic, binary image in which each image element
(or pixel) is represented by one bit. Fragments are only generated
for the bits (pixels) which are set. Bitmaps are commonly used to
draw text (glyphs) and markers.
A bitmap is drawn with the command
void glBitmap(GLsizeiwidth, GLsizei height, GLfloat xOrig, GLfloat yOrig, GLfloat xMove, GLfloat yMove, const GLubyte *image)
width and height specify the image size in
pixels. xOrig and yOrig specify the bitmap origin.
xMove and yMove are added to the current
raster position after the bitmap is rasterized. image is a pointer to the bitmap
data.
If the current raster position is not valid, glBitmap has no effect.
4.5.1 Bitmap Unpacking
The first step in bitmap rendering is unpacking.
Unpacking is the process of extracting image data from
client memory subject to byte swapping, non-default row strides, etc.
The unpacking parameters are specified with the command
void
glPixelStorei(GLenum pname, GLint value)
The following unpacking parameters may be set:
Parameter (pname)
|
Value (value)
|
Default
|
GL_UNPACK_ROW_LENGTH
|
Width of the image in memory, in
pixels.
|
0
|
GL_UNPACK_LSB_FIRST
|
GL_FALSE indicates that the most
significant bit is unpacked first from each byte. GL_TRUE
indicates that the least significant bit is unpacked first from each
byte.
|
GL_FALSE
|
The GL_UNPACK_ROW_LENGTH specifies the stride (in pixels) for advancing
from one row of the image to the next. If it's zero, the width parameter to glBitmap specifies the width of the
image in memory.
GL_UNPACK_LSB_FIRST determines whether the least significant or most
significant bit in each byte is unpacked first. Unpacking occurs
in left to right order (in image space).
The value of bit (i, j) of the image (where i is the image row and j is
the image column) is found as follows:
rowLength = (GL_UNPACK_ROW_LENGTH != 0)
? GL_UNPACK_ROW_LENGTH : width;
byte = image[((rowLength + 7)
/ 8) * i + j / 8];
if (GL_UNPACK_LSB_FIRST != 0)
bitMask = 1 << (j % 8);
else
bitMask = 128 >> (j % 8);
if (byte & bitMask)
bit = 1;
else
bit = 0;
4.5.2 Rasterization
If the current raster position is (xrp, yrp, zrp,
wrp), then the bitmap is rasterized according to the
following algorithm:
for (j = 0; j < height;
j++) {
for (i = 0; i < width;
i++) {
if (bit(i,j)) {
fragment.x =
floor(xrp - xOrig)
+ i;
fragment.y =
floor(yrp - yOrig)
+ j;
fragment.color
= GL_CURRENT_RASTER_COLOR;
fragment.texture = GL_CURRENT_RASTER_TEXTURE_COORDS;
ProcessFragment(fragment)
}
}
}
After the bitmap has been rendered the current raster position is
updated as follows:
xrp = xrp + xMove
yrp = yrp + yMove
4.5.3 Per-fragment Operations
XXX supported? See issue in appendix A.
4.6 Unsupported Commands
The following commands related to rasterization are not supported by
the subset.
Point commands:
glPointSize
Polygon commands:
glPolygonStipple
glPolygonOffset
glPolygonMode
Pixel storage commands:
glPixelStoref
5. Texture Mapping
There are four elements to texture mapping: texture coordinate
specification, texture image specification, texture sampling and texture
application.
Texture mapping is enabled and disabled with the commands glEnable(GL_TEXTURE_2D) and glDisable(GL_TEXTURE_2D).
5.1 Texture Image Specification
A texture image is specified with the command:
void glTexImage2D(GLenum target, GLint level, GLint internalFormat, GLsizei width, GLsizei height, GLint border, GLenum format, GLenum type, const GLvoid *pixels )
target must be GL_TEXTURE_2D.
level indicates the
mipmap level for mipmap textures. internalFormat
is a hint to indicate the preferred internal storage format for the
texture. width and height indicate the image size in
pixels (or texels). border must
be zero. format and type describe the pixel format and
data type for the incoming image. pixels
points to the incoming texture image. These parameters are
described in more detail below.
5.1.1 Texture Image Size and Mipmaps
Texture images must have dimensions (width and height) that are powers
of two. For example: 256 x 256, 32 x 1024, 1 x 8, etc. That is, it
must be the case that width =
2n and height = 2m
for some positive integers n and m.
Mipmapping is a method of antialiasing or filtering textures to improve
their appearance. A mipmap is a set of images consisting of a base
image and a set of filtered, reduced-resolution images. If the
base image (level=0) is of
width 2n and height 2m then the level 1 image must
be of width 2n-1 and height 2m-1. Each mipmap
level is half the width and height of the previous level, or at least
one. The last mipmap level has a width and height of one.
The following is an example of a mipmap's image levels:
mipmap level
|
width
|
height
|
0
|
256
|
64
|
1
|
128
|
32
|
2
|
64
|
16
|
3
|
32
|
8
|
4
|
16
|
4
|
5
|
8
|
2
|
6
|
4
|
1
|
7
|
2
|
1
|
8
|
1
|
1
|
If the width or height parameters are not powers of
two, the error GL_INVALID_VALUE is raised. If the image levels in
a mipmap do not satisfy the restrictions listed above the texture is
considered to be inconsistent
and the system will behave as if the texturing is disabled.
5.1.2 Texture Image Formats and Unpacking
The glTexImage2D command's format and type parameters describe the format
of the incoming texture image. Accepted values for format are GL_INTENSITY, GL_RGB and
GL_RGBA. The type
parameter must be GL_UNSIGNED_BYTE. Pixel component values are
thus in the range 0 through 255.
If format is GL_INTENSITY then
the image has one byte per pixel which specifies the pixel's red, green,
blue and alpha values.
If format is GL_RGB then the
image has three bytes per pixel which specify the pixel's red, green and
blue values (in that order). The alpha value defaults to 255.
If format is GL_RGBA then the
image has four bytes per pixel which specify the pixel's red, green,
blue and alpha values (in that order).
The command
void
glPixelStorei(GLenum pname,
GLint value)
controls the unpacking of texture image data from client memory. pname may be GL_UNPACK_ROW_LENGTH to
indicate the stride, in pixels, between subsequent rows of the image in
client memory. If GL_UNPACK_ROW_LENGTH is zero (the default) then
the width parameter to glTexImage2D determines the stride.
5.1.3 Internal Texture Format
glTexImage2D converts the incoming
texture image to one of the supported internal texture formats.
The internalFormat parameter
indicates the desired internal format for the texture and may be either
GL_INTENSITY8, GL_RGB5 or GL_RGBA8.
If internalFormat is
GL_INTENSITY8 then the texture has one byte per texel (texture element)
which indicates the texel's intensity (or brightness). The
intensity is obtained from the incoming image's red channel.
If internalFormat is GL_RGB5
then the texture is stored with two bytes per texel: 5 bits per
red value, 5 bits per green value and 5 bits per blue value.
If internalFormat is
GL_RGBA8 then the texture is stored with four bytes per texel: 8
bits for each of the red, green, blue and alpha values.
The internal format is also significant to texture application (see
section 5.4).
5.2 Texture Coordinates
Texture coordinates control the mapping from local polygon space to
texture image space. Texture coordinates are set for each vertex
with the glTexCoord commands.
During line and polygon rasterization the vertex's texture
coordinates are interpolated across the primitive to produce a texture
coordinate for each fragment. The fragment texture coordinates are
used to sample the current texture image.
Texture coordinates are normally in the range [0, 1]. Values
outside that range are processed according to the texture wrap mode. The
texture wrap mode is set with the command
void glTexParameteri(GLenum target, GLenum pname, GLint value)
target must be GL_TEXTURE_2D.
If pname is
GL_TEXTURE_WRAP_S or GL_TEXTURE_WRAP_T then value must be either
GL_CLAMP_TO_EDGE or GL_REPEAT.
For GL_CLAMP_TO_EDGE, texture coordinates are effectively clamped to
the interval [0, 1].
For GL_REPEAT, the integer part of texture coordinates is ignored; only
the fractional part of the texture coordinates is used. This
allows texture images to repeated or tiled across an object.
5.3 Texture Sampling
Texture sampling is the process of using texture coordinates to extract
a color from the texture image. Multiple, weighted samples may be
taken from the texture and combined during the filtering step.
During texture coordinate interpolation a level of detail value (lambda) is
computed for each fragment. For a mipmapped texture, lambda
determines which level (or levels) of the mipmap will be sampled to
obtain the texture color.
If lambda indicates that multiple texels map to a single screen pixel,
then the texture minification
filter will be used. Otherwise, if lambda indicates that a single
texel maps to multiple screen pixels, then the texture magnification filter will be used.
5.3.1 Texture Minification
The texture minification filter is set with the glTexParameteri command by setting target to GL_TEXTURE_2D, setting pname to GL_TEXTURE_MIN_FILTER and
setting value to GL_NEAREST,
GL_LINEAR, GL_NEAREST_MIPMAP_NEAREST,
GL_NEAREST_MIPMAP_LINEAR, GL_LINEAR_MIPMAP_NEAREST or
GL_LINEAR_MIPMAP_LINEAR.
GL_NEAREST samples the texel nearest the texture coordinate in the
level 0 texture image.
GL_LINEAR samples the four texels around the texture coordinate in the
level 0 texture image. The four texels are linearly weighted to
compute the final texel value.
GL_NEAREST_MIPMAP_NEAREST samples the texel nearest the texture
coordinate in the level N texture image. N is the level of detail
and is computed by the partial derivatives of the texture coordinates
with respect to the window coordinates.
GL_NEAREST_MIPMAP_LINEAR samples two texels nearest the texture
coordinates in the level N and N+1 texture images. The two texels
are linearly weighted to compute the final texel value. N is the
level of detail and is computed by the partial derivatives of the
texture coordinates with respect to the window coordinates.
GL_LINEAR_MIPMAP_NEAREST samples four texels around the texture
coordinate in the level N texture image. The four texels are
linearly weighted to compute the final texel value. N is the level
of detail and is computed by the partial derivatives of the texture
coordinates with respect to the window coordinates.
GL_LINEAR_MIPMAP_LINEAR samples four texels around the texture
coordinate in the level N texture image and four texels around the
texture coordinate in the level N+1 texture image. The eight
texels are linearly weighted to compute the final texel value. N
is the level of detail and is computed by the partial derivatives of the
texture coordinates with respect to the window coordinates.
Filter modes other than GL_LINEAR and GL_NEAREST requires that the
texture have a complete set of mipmaps. If the mipmap is
incomplete, it is as if texturing is disabled.
5.3.2 Texture Magnification
The texture magnification filter is set with the glTexParameteri command
by setting target to
GL_TEXTURE_2D, setting pname to
GL_TEXTURE_MAG_FILTER and setting value
to GL_NEAREST or GL_LINEAR.
GL_NEAREST samples the texel nearest the texture coordinate in the
level 0 texture image.
GL_LINEAR samples the four texels around the texture coordinate in the
level 0 texture image. The four texels are linearly weighted to
compute the final texel value.
5.4 Texture Application
The sampled texture value is combined with the incoming fragment color
to produce a new fragment color. The fragment and texture colors
are combined according to the texture environment mode and the current
texture's base internal format. The texture environment mode is
set with the command
void
glTexEnvi(GLenum target,
GLenum pname, GLint value)
target must be GL_TEXTURE_ENV.
If pname is
GL_TEXTURE_ENV_MODE then value
must be one of GL_REPLACE, GL_MODULATE, GL_DECAL, or GL_BLEND.
There is also a texture environment
color that can factor into texture application. The texture
environment color can be set with the command
void
glTexEnvfv(GLenum target,
GLenum pname, const GLfloat *value)
target must be GL_TEXTURE_ENV.
If pname is
GL_TEXTURE_ENV_COLOR then value must
point to an array of four values which specify the red, green, blue,
and alpha values of the texture environment color. The values are
clamped to the range [0, 1]. The default color is (0, 0, 0, 0).
The following table describes the arithmetic used for each combination
of environment mode and base internal format. (Rf, Gf, Bf, Af) is
the incoming fragment color. (Rt, Gt, Bt, At) is the sampled
texture color. Lt is the sampled texture luminance. 'It' is the sampled texture
intensity. (Rc, Gc, Bc, Ac) is the texture environment color.
(Rv, Gv, Bv, Av) is the resulting value.
Base Internal Format
|
GL_REPLACE
|
GL_MODULATE
|
GL_DECAL
|
GL_BLEND
|
GL_INTENSITY
|
Rv = It
Gv = It
Bv = It
Bf = It
|
Rv = Rf * It
Gv = Gf * It
Bv = Bf * It
Av = Af * It |
undefined
|
Rv = Rf*(1-It) + Rc*It
Gv = Gf*(1-It) + Gc*It
Bv = Bf*(1-It) + Bc*It
Av = Af*(1-It) + Ac*It |
GL_RGB
|
Rv = Rt
Gv = Gt
Bv = Bt
Av = Af
|
Rv = Rf * Rt
Gv = Gf * Gt
Bv = Bf * Bt
Av = Af
|
Rv = Rt
Gv = Gt
Bv = Bt
Av = Af |
Rv = Rf*(1-Rt) + Rc*Rt
Gv = Gf*(1-Gt) + Gc*Gt
Bv = Bf*(1-Bt) + Bc*Bt
Av = Af |
GL_RGBA
|
Rv = Rt
Gv = Gt
Bv = Bt
Av = At
|
Rv = Rf * Rt
Gv = Gf * Gt
Bv = Bf * Bt
Av = Af * At |
Rv = Rf*(1-At) + Rt*At
Gv = Gf*(1-At) + Gt*At
Bv = Bf*(1-At) + Bt*At
Av = Af
|
Rv = Rf*(1-Rt) + Rc*Rt
Gv = Gf*(1-Gt) + Gc*Gt
Bv = Bf*(1-Bt) + Bc*Bt
Av = Af*At |
5.5 Texture Objects
Texture objects encapsulate a set of texture images (mipmap) and
related state into a named object. This facilitates use of
multiple textures in an application. Texture objects are named
with GLuints (unsigned integers). There is a default texture
object with the name/identifier zero which can never be deleted.
5.5.1 Creating Texture Objects
A texture object is created by binding a new GLuint identifier to the
GL_TEXTURE_2D target with the command:
void glBindTexture(GLenum target, GLuint textureID)
target must be GL_TEXTURE_2D.
textureID may be any
unsigned integer. If textureID
does not name an existing texture object, a new texture object with that
ID will be created, initialized to the default state. Whether the
ID is new or existed previously, that named texture object is bound as
the current texture object.
Subsequent glTexParameter andglTexImage2D calls will effect the
current texture object.
5.5.2 Deleting Texture Objects
One or more texture objects may be deleted with the command:
void glDeleteTextures(GLsizein, const GLuint *textureIDs)
textureIDs is an array of n texture IDs. The named
texture objects will be deleted. If the current texture object is
deleted the default texture object (number 0) will be bound as the
current texture object.
5.5.3 Allocating Texture Object Identifiers
A list of new, unused texture IDs can be obtained by calling the command
void glGenTextures(GLsizei n, GLuint *textureIDs)
An array of n unused texture
IDs will be returned in the textureIDs
array.
6. Per-fragment Operations
The fragments produced by rasterization are subjected to a number of
operations which either modify the fragment or test the fragment
(discarding the fragment if the test fails.) This chapter
describes the per-fragment operations. They are presented in the
order in which they're performed. If a fragment fails a test it is
discarded and not subjected to subsequent tests or modifications.
6.1 Scissor Test
The scissor test limits rendering to a 2-D rectangular region of the
framebuffer. The command
void glScissor(GLintx, GLint y, GLsizei width, GLsizei height)
defines a clipping region with the lower-left corner at (x, y) and the given width and height. The scissor test is
enabled and disabled with the command glEnable(GL_SCISSOR_TEST)
and glDisable(GL_SCISSOR_TEST).
If the incoming fragment's position is (xf, yf)
then the fragment will pass the test if x <= xf < x + width and y <= yf < y + height. Otherwise, the
fragment is discarded.
If width or height is less than zero the error
GL_INVALID_VALUE is raised. The default scissor rectangle bounds
are (0, 0, w, h) where w is the initial window width and h is the
initial window height. The scissor test is disabled by default.
6.2 Alpha Test
The alpha test compares the fragment's alpha value against a reference
value and discards the fragment if the comparison fails. The test
is specified by the command
void glAlphaFunc(GLenummode, GLclampf reference)
mode specifies an inequality
and reference specifies a value
to compare against. The following table lists all possible
modes and the
corresponding test:
Comparison mode
|
The test passes if
|
GL_LESS
|
alpha < reference
|
GL_LEQUAL
|
alpha <= reference |
GL_GREATER
|
alpha > reference |
GL_GEQUAL
|
alpha >= reference |
GL_EQUAL
|
alpha == reference |
GL_NOTEQUAL
|
alpha != reference |
GL_NEVER
|
never pass
|
GL_ALWAYS
|
always passes
|
The reference parameter is
clamped to the range [0, 1].
The alpha test is enabled and disabled with the commands glEnable(GL_ALPHA_TEST) and glDisable(GL_ALPHA_TEST).
The default mode is GL_ALWAYS and the default reference value is 0.
6.3 Stencil Test
The stencil buffer stores an N-bit integer value for each pixel in the
frame buffer. The stencil test compares the stencil buffer value
at the fragment's position to a reference value and possibly discards
the fragment based on the outcome. Furthermore, the stencil buffer
value may be updated or modified depending on the outcome. If
there is no stencil buffer the stencil test is bypassed.
Stenciling is controlled by the commands
void glStencilFunc(GLenumfunc, GLint ref, GLuint mask)
void glStencilOp(GLenum stencilFail, GLenum depthTestFail, GLenum depthTestPass)
The glStencilFunc command controls the
stencil test while glStencilOp
command controls the how the stencil buffer is updated/modified after
the test.
ref is clamped to the range [0,
2N-1] where N is the number of bits per stencil value in the
stencil buffer.
The following table lists all possible values for the func parameter and when the stencil
test will pass. Both the stencil buffer value and the stencil
reference value are bit-wise ANDed with the mask parameter before the test.
Stencil func value
|
Stencil test passes if
|
GL_LESS
|
(ref&mask) < (stencil buffer value
& mask)
|
GL_LEQUAL
|
(ref
& mask) <= (stencil
buffer value & mask) |
GL_GREATER
|
(ref
& mask) > (stencil
buffer value & mask) |
GL_GEQUAL
|
(ref
& mask) >= (stencil
buffer value & mask) |
GL_EQUAL
|
(ref
& mask) == (stencil
buffer value & mask) |
GL_NOTEQUAL
|
(ref
& mask) != (stencil
buffer value & mask) |
GL_NEVER
|
never passes
|
GL_ALWAYS
|
always passes
|
If the stencil test passes, the fragment is passed to the next
per-fragment operation. Otherwise, if the stencil test fails, the
value in the stencil buffer is updated according to the value of the stencilFail parameter to glStencilOp.
stencilFail
value
|
New stencil buffer value
|
GL_KEEP
|
originalValue
|
GL_ZERO
|
0
|
GL_INVERT
|
BitWiseInvert(originalValue)
i.e. ~originalValue
|
GL_REPLACE
|
ref
|
GL_INCR
|
originalValue + 1, clamped to
[0, 2N-1] |
GL_DECR
|
originalValue - 1, clamped to
[0, 2N-1] |
The depthTestFail and depthTestPass parameters to glStencilOp are ignored. Values
for func and stencilFail other than those listed
in the table will cause the error GL_INVALID_ENUM to be raised.
The stencil test is enabled and disabled with the commands glEnable(GL_STENCIL_TEST) and glDisable(GL_STENCIL_TEST).
The default stencil function is GL_ALWAYS. The default stencil
reference value is 0. The default stencil mask is ~0. The
default stencil fail operation is GL_KEEP.
Values written into the stencil buffer are masked with the command
void glStencilMask(GLuintmask)
Only the bits which are set in mask
will be modified in the stencil buffer when written to. If each
stencil buffer value has N bits, only the least significant N bits of mask are relevant. The default
stencil mask is ~0.
6.4 Blending and Logicop
Blending or a logic operation combines the incoming fragment color with
the destination frame buffer color according to a blending equation or
bit-wise Boolean logical operation.
Blending is enabled and disabled with the commands glEnable(GL_BLEND) and glDisable(GL_BLEND).
The logic operation is enabled and disabled with the commands glEnable(GL_LOGIC_OP) and glDisable(GL_LOGIC_OP).
If both blending and the logic operation are enabled, the logic
operation has higher priority; blending is bypassed.
6.4.1 Logic Op
The command
void glLogicop(GLenummode)
Specifies the Boolean logic operation for combining the incoming
fragment color with the destination frame buffer color. Both the
incoming fragment color and destination frame buffer colors are
interpreted as four-tuples of unsigned integer color components in the
range [0, 2N-1] where N is the number of bits per color
channel. N may not be the same for all color channels.
The following table lists all values for mode and the boolean arithmetic used
to combine the incoming fragment color value (src) with the destination framebuffer
color value (dst). Standard ANSI C operators used.
LogicOp mode
|
Resulting channel value
|
GL_CLEAR
|
0
|
GL_SET
|
~0
|
GL_COPY
|
src
|
GL_COPY_INVERTED
|
~s
|
GL_NOOP
|
dst
|
GL_INVERT
|
~dst
|
GL_AND
|
src & dst
|
GL_NAND
|
~(src & dst)
|
GL_AND_REVERSE
|
src & ~dst
|
GL_AND_INVERTED
|
~src & dst
|
GL_OR
|
src | dst
|
GL_NOR
|
~(src | dst)
|
GL_OR_REVERSE
|
src | ~dst
|
GL_OR_INVERTED
|
~src | dst
|
GL_XOR
|
src ^ dst
|
GL_EQUIV
|
~(src ^ dst)
|
The fragment's color is replaced by the result of the logic operation.
Specifying any value for mode
other than those listed in the above table will cause the error
GL_INVALID_ENUM to be raised.
The default value for mode is
GL_COPY. The logic operation is disabled by default.
6.4.2 Blending
The command
void glBlendFunc(GLenumsrcTerm, GLenum dstTerm)
specifies the terms of the blending equation. If Cf = (Rf, Gf,
Bf, Af) is the incoming fragment color and Cb = (Rb, Gb, Bb, Ab) is the
frame buffer color, then the resulting color Cv = (Rv, Gv, Bv, Av) is
computed by:
Cv = Cf * srcTerm + Cb * dstTerm
All possible values for srcTerm
and the corresponding arithmetic term are listed in the following table:
srcTerm
|
srcTermArithmetic
|
GL_ZERO
|
(0, 0, 0, 0)
|
GL_ONE
|
(1, 1, 1, 1)
|
GL_DST_COLOR
|
(Rb, Gb, Bb, Ab)
|
GL_ONE_MINUS_DST_COLOR
|
(1-Rb, 1-Gb, 1-Bb, 1-Ab)
|
GL_SRC_ALPHA
|
(Af, Af, Af, AF)
|
GL_ONE_MINUS_SRC_ALPHA
|
(1-Af, 1-Af, 1-Af, 1-Af)
|
GL_DST_ALPHA
|
(Ab, Ab, Ab, Ab)
|
GL_ONE_MINUS_DST_ALPHA
|
(1-Ab, 1-Ab, 1-Ab, 1-Ab)
|
GL_SRC_ALPHA_SATURATE
|
(m, m, m, 1) where m = MIN(Af,
1-Ab)
|
All possible values for srcTerm
and the corresponding arithmetic term are listed in the following table:
dstTerm
|
dstTermArithmetic
|
GL_ZERO
|
(0, 0, 0, 0)
|
GL_ONE
|
(1, 1, 1, 1)
|
GL_SRC_COLOR
|
(Rf, Gf, Bf, Af)
|
GL_ONE_MINUS_SRC_COLOR
|
(1-Rf, 1-Gf, 1-Bf, 1-Af)
|
GL_SRC_ALPHA
|
(Af, Af, Af, AF)
|
GL_ONE_MINUS_SRC_ALPHA
|
(1-Af, 1-Af, 1-Af, 1-Af)
|
GL_DST_ALPHA
|
(Ab, Ab, Ab, Ab)
|
GL_ONE_MINUS_DST_ALPHA
|
(1-Ab, 1-Ab, 1-Ab, 1-Ab)
|
The fragment's color is replaced by the result of the blending equation.
Values for srcTerm and dstTerm other than those listed in
the table will cause the error GL_INVALID_ENUM to be raised.
The default value for srcTerm
is GL_ONE. The default value for dstTerm
is GL_ZERO. Blending is disabled by default.
6.5 Color Mask
The final fragment color is written into the current color buffer at
the end of the per-fragment operations. Normally, all color
channels in the frame buffer are replaced with the final fragment color.
However, the command
void glColorMask(GLbooleanredMask, GLboolean greenMask, GLboolean blueMask, GLboolean alphaMask)
allows selective writing to individual color channels. If redMask is GL_TRUE then writing to
the red color channel is enabled, otherwise it's disabled.
Similarly, the green, blue and alpha channels can also be masked.
Initially all four mask values are GL_TRUE.
Color masking is not enabled/disabled with the glEnable/glDisable commands.
7. Frame Buffer Operations
The frame buffer is considered to be a two-dimensional array of pixels.
The frame buffer is also organized into layers or logical buffers.
There may be a front color buffer, back color buffer and stencil
buffer. A double-buffered frame buffer has both a front color
buffer and back color buffer. A single-buffered framebuffer only
has a front color buffer. Each pixel in a color buffer has a red,
green and blue value and an optional alpha value.
7.1 Clearing Buffers
Buffers are cleared (set to uniform values) with the command
void glClear(GLbitfieldbuffers)
buffers is a bitmask for which
the value may be the bitwise-OR of the values GL_COLOR_BUFFER_BIT and
GL_STENCIL_BUFFER_BIT. If the GL_COLOR_BUFFER_BIT bit is
specified, the current color buffer will be cleared. If the
GL_STENCIL_BUFFER_BIT bit is specified, the stencil buffer will be
cleared.
The current color buffer is specified with the command
void glDrawBuffer(GLenum buffer)
buffer may be either GL_FRONT,
GL_BACK or GL_NONE. GL_FRONT indicates that the front color buffer
will be modified by glClear and
any drawing command. GL_BACK indicates that the back color buffer
will be modified by glClear and
any drawing command. GL_NONE indicates that neither color buffer
will be modified by glClear or
any drawing command. GL_BACK is only valid for double-buffered
frame buffers.
The current scissor rectangle, set by the glScissor command, effects glClear, limiting
the clear to the scissor rectangle, if it's enabled. Furthermore, only the color channels enabled by glColorMask will be effected by glClear(GL_COLOR_BUFFER_BIT).
Likewise, only the stencil bits enabled by glStencilMask will be effected by glClear(GL_STENCIL_BUFFER_BIT).
The current clear color is set with the command
void glClearColor(GLclampfred, GLclampf green, GLclampf blue, GLclampf alpha)
Subsequent calls to glClear
will use the color (red, green, blue,
alpha) to clear the front or back color buffers.
The current stencil clear value is set with the command
void glClearStencil(GLintclearValue)
If the stencil buffer is N bits deep, the least significant N bits of clearValue will be used to clear the
stencil buffer.
8. Other Features
8.1 Frame Buffer Readback
A rectangular region of pixels can be read from the frame buffer and
placed in client memory with the command
void glReadPixels(GLintx, GLint y, GLsizei width, GLsizei height, GLenum format, GLenum type, GLvoid *data)
x and y specify the coordinate of the
lower-left corner of the region to read and width and height specify the size of the
rectangular region to read. format
specifies the format of image data and must be either GL_RGB or
GL_RGBA. type specify the
data type of the image data and must be either GL_UNSIGNED_BYTE or
GL_FLOAT. Other values for format
or type will cause the error
GL_INVALID_ENUM to be raised.
The framebuffer may contain 3-component colors (red, green, blue) or
4-component colors (red, green, blue, alpha). If an alpha channel
is not present, alpha values default to 1.0.
The frame buffer color components (red, green, blue, alpha) are either
converted to 8-bit unsigned integers in the range[0, 255] if type is GL_UNSIGNED_BYTE or
converted to floating point values in the range [0, 1] if type is GL_FLOAT. The (red,
green, blue, alpha) tuples are then stored as GL_RGB triplets (by
dropping the alpha component) or GL_RGBA quadruples in client memory.
Image data is packed into
client memory according to the pixel packing parameters which are set by
the command
void glPixelStorei(GLenum pname, GLint value)
pname must be
GL_PACK_ROW_LENGTH. value
indicates the stride (in pixels) between subsequent rows in the
destination image. If GL_PACK_ROW_LENGTH is zero (the default)
then the width parameter to glReadPixels indicates the row stride.
Pixel readback takes place as follows:
if (GL_PACK_ROW_LENGTH == 0)
rowLength = width;
else
rowLength = GL_PACK_ROW_LENGTH
if (format == GL_RGB) {
for (i = 0; i < height;
i++) {
for (j = 0; j < width; j++) {
k = (i *
rowLength + j) * 3;
data[k+0] = FrameBuffer(x + j, y + i).red;
data[k+1] = FrameBuffer(x + j, y + i).green;
data[k+2] = FrameBuffer(x + j, y + i).blue;
}
}
}
else {
for (i = 0; i < height;
i++) {
for (j = 0; j < width; j++) {
k = (i *
rowLength + j) * 4;
data[k+0] = FrameBuffer(x + j, y + i).red;
data[k+1] = FrameBuffer(x + j, y + i).green;
data[k+2] = FrameBuffer(x + j, y + i).blue;
data[k+3] = FrameBuffer(x + j, y + i).alpha;
}
}
}
The function FrameBuffer(c, r)
returns the pixel in the frame buffer at column c of row r. data is considered to be either a
GLubyte pointer or a GLfloat pointer, depending on the type parameter. Similarly, the
FrameBuffer function returns either GLubyte values in the range [0, 255]
or GLfloat values in the range [0,1], depending on the type parameter.
Pixels may be read from either the front or back color buffer.
The command
void glReadBuffer(GLenumbuffer)
specifies the source for reading images with glReadPixels. If buffer is GL_FRONT then front color
buffer is the source. If buffer
is GL_BACK then the back color buffer is the source. It is illegal
to specify GL_BACK when the color buffer is not double buffered.
Any invalid value for buffer
will raise the error GL_INVALID_ENUM.
The default read source is GL_BACK if the frame buffer is double
buffered. Otherwise, the default read source is GL_FRONT.
8.2 Selection Mode
Selection mode is typically used to implement picking: determining which
primitive(s) are present at particular window positions. The
command
GLint glRenderMode(GLenummode)
is used to enable selection mode. If mode is GL_SELECTION the graphics
library is put into selection mode. If mode is GL_RENDER the graphic
library is put into normal rendering mode. Any other value for mode will raise the error
GL_INVALID_ENUM.
When in selection mode rendering commands will not effect the
framebuffer. Instead, a record of the primitives that would have
been drawn is placed in the selection buffer. The selection buffer
is specified with the command
void glSelectionBuffer(GLsizein, GLuint *buffer)
buffer is an array of n
unsigned integers. No more than n
values will be placed in the buffer.
The name stack is a stack
(LIFO) of unsigned integer names. The following commands
manipulate the name stack:
void glInitNames(void)
void glPushName(GLuint name)
void glPopName(void)
void glLoadName(GLuint name)
glInitNames resets the name
stack to an empty state. glPushName pushes the given name value onto the stack. glPopName pops the top name from the
stack. glLoadName replaces the top value on
the stack with the specified name.
Stack underflow and overflow conditions cause the errors
GL_STACK_OVERFLOW and GL_STACK_UNDERFLOW to be raised.
While in selection mode, primitives (points, lines, polygons) are
transformed and clip-tested normally. Primitives which aren't
discarded by clipping cause the hit data to be updated. The hit
data consists of three pieces of information: a hit flag, a minimum Z
value and a maximum Z value. First, the hit flag is set.
Then, for each of the primitive's vertices, the vertex Z value is
compared to the minimum and maximum Z values. The minimum Z value
is updated if the vertex's Z value is less than the minimum Z value.
The maximum Z value is updated if the vertex's Z value is greater
than the maximum Z value.
When any of glInitNames, glPushName, glPopName, glLoadName or glRenderMode are called and the hit
flag is set, a hit record is
written to the selection buffer.
A hit record consists of a sequence of unsigned integers. The
first value is the size of the name stack. The second value is the
minimum Z value multiplied by 232-1. The third value is
the maximum Z value multiplied by 232-1. The remaining
values are the values in the name stack, in bottom to top order.
The hit flag is cleared after a hit record is written to the
selection buffer. Hit records are places sequentially into the
selection buffer until it is full or selection mode is terminated.
Selection mode is terminated by calling glRenderMode(GL_RENDER). The
return value of glRenderMode
will be -1 if the selection buffer overflowed. Otherwise, the
return value will indicate the number of values written into the
selection buffer.
8.3 Synchronization
The command
void glFlush(void)
makes the graphics library to flush all pending graphics commands.
The command
void glFinish(void)
makes the graphics library flush the command queue and wait until those
commands are completed. glFlush
will not return until all previous graphics commands have been fully
completed.
These commands are typically used to force completion of rendering to
the front color buffer. Otherwise, rendering to the front color
buffer may not appear. The swapbuffers
command (part of the window system binding library) does an implicit
flush before swapping the front and back color buffers. The glReadPixels command also does an
implicit flush before reading pixel data from the frame buffer.
9. State Queries
The current value of nearly all library state variables can be queried.
This chapter describes the commands used for querying the value of
state variables.
9.1 General State Queries
The command
void glGetFloatv(GLenumpname, GLfloat *values)
returns the value(s) of the state variable specified by pname. The following table
lists all accepted values for pname
and a description of the value(s). Specifying any other value for pname causes the error
GL_INVALID_ENUM to be raised.
Variable (pname)
|
Number of values
|
Value(s) Description
|
GL_ALPHA_BITS
|
1
|
Number of bits per alpha value
in the frame buffer.
|
GL_ALPHA_TEST
|
1
|
Zero if the alpha test is
disabled.
One if the alpha test is enabled.
|
GL_ALPHA_TEST_FUNC
|
1
|
The alpha test function.
|
GL_BLEND
|
1
|
Zero if blending is disabled.
One if blending is enabled.
|
GL_BLEND_DST
|
1
|
Blend destination function/term.
|
GL_BLEND_SRC
|
1
|
Blend source function/term.
|
GL_BLUE_BITS
|
1
|
Number of bits per blue value in
the frame buffer.
|
GL_COLOR_CLEAR_VALUE
|
4
|
Clear color (red, green, blue,
alpha).
|
GL_COLOR_WRITE_MASK
|
4
|
Color buffer writemask (red,
green, blue, alpha).
Zero if writing is disabled.
One if writing is enabled.
|
GL_CULL_FACE
|
1
|
Zero if polygon culling is
disabled.
One if polygon culling is enabled.
|
GL_CULL_FACE_MODE
|
1
|
Polygon cull mode: GL_FRONT,
GL_BACK or GL_FRONT_AND_BACK.
|
GL_CURRENT_COLOR
|
4
|
Current color (red, green, blue,
alpha).
|
GL_CURRENT_RASTER_COLOR
|
4
|
Current raster position color
(red, green, blue, alpha).
|
GL_CURRENT_RASTER_TEXTURE_COORDS
|
4
|
Current raster position texture
coordinates (s, t, r, q).
|
GL_CURRENT_RASTER_POSITION
|
4
|
Current raster position (x, y,
z, w).
|
GL_CURRENT_POSITION_VALID
|
1
|
Zero if current raster position
is invalid.
One if current raster position is valid.
|
GL_CURRENT_TEXTURE_COORDS
|
4
|
Current texture coordinates (s,
t, r, q)
|
GL_DOUBLEBUFFER
|
1
|
Zero if color buffer is
single-buffered.
One if color buffer is double-buffered.
|
GL_DRAW_BUFFER
|
1
|
Current color draw buffer:
GL_FRONT or GL_BACK.
|
| GL_FRONT_FACE |
1
|
Polygon front-face winding:
GL_CW or GL_CCW.
|
GL_GREEN_BITS
|
1
|
Number of bits per green value
in the frame buffer.
|
GL_LINE_SMOOTH
|
1
|
Zero if line smoothing is
disabled.
One if line smoothing is enabled.
|
GL_LINE_STIPPLE
|
1
|
Zero if line stippling is
disabled.
One if line stippling is enabled.
|
GL_LINE_STIPPLE_PATTERN
|
1
|
Line stipple pattern.
|
GL_LINE_STIPPLE_REPEAT
|
1
|
Line stipple repeat factor.
|
GL_LINE_WIDTH
|
1
|
Line width in pixels.
|
GL_LINE_WIDTH_GRANULARITY
|
1
|
Aliased line width granularity.
|
GL_LINE_WIDTH_RANGE
|
2
|
Minimum and maximum aliased line
widths.
|
GL_ALIASED_LINE_WIDTH_RANGE
|
2
|
Minimum and maximum antialiased
line widths. |
GL_COLOR_LOGIC_OP
|
1
|
Zero if logicop is disabled.
One if logicop is enabled.
|
GL_LOGIC_OP_MODE
|
1
|
Logicop function.
|
GL_MATRIX_MODE
|
1
|
Matrix mode: GL_MODELVIEW or
GL_PROJECTION.
|
GL_MAX_MODELVIEW_STACK_DEPTH
|
1
|
Maximum size of the modelview
matrix stack.
|
GL_MAX_NAME_STACK_DEPTH
|
1
|
Maximum size of the selection
name stack.
|
GL_MAX_PROJECTION_STACK_DEPTH
|
1
|
Maximum size of the projection
matrix stack.
|
GL_MAX_TEXTURE_SIZE
|
1
|
Maximum 2D texture image width
and height.
|
GL_MAX_VIEWPORT_DIMS
|
2 |
Maximum viewport width and
height in pixels.
|
GL_MODELVIEW_MATRIX
|
16
|
Current/top modelview matrix
values.
|
GL_MODELVIEW_MATRIX_STACK_DEPTH
|
1
|
Current size of the modelview
matrix stack.
|
GL_NAME_STACK_DEPTH
|
1
|
Current size of the selection
name stack.
|
GL_PACK_ROW_LENGTH
|
1
|
Pixel packing row length.
|
GL_POLYGON_SMOOTH
|
1
|
Zero if polygon smoothing is
disabled.
One if polygon smoothing is enabled.
|
GL_PROJECTION_MATRIX
|
16
|
Current/top projection matrix
values.
|
GL_PROJECTION_STACK_DEPTH
|
1
|
Current size of projection
matrix stack.
|
GL_READ_BUFFER
|
1
|
Current read buffer: GL_FRONT or
GL_BACK.
|
GL_RED_BITS
|
1
|
Number of bits per red value in
the frame buffer.
|
GL_RENDER_MODE
|
1
|
Current rendering mode:
GL_RENDER or GL_SELECTION.
|
GL_RGBA_MODE
|
1
|
Always one.
|
GL_SCISSOR_BOX
|
4
|
Scissor box (x, y, width,
height).
|
GL_SCISSOR_TEST
|
1
|
Zero if scissor test is disabled.
One if scissor test is enabled.
|
GL_SELECTION_BUFFER_SIZE
|
1
|
Size of selection buffer.
|
GL_SHADE_MODEL
|
1
|
Shade model: GL_FLAT or
GL_SMOOTH.
|
GL_STENCIL_BITS
|
1
|
Number of bits per stencil value
in the frame buffer.
|
GL_STENCIL_CLEAR_VALUE
|
1
|
Stencil buffer clear value.
|
GL_STENCIL_FAIL
|
1
|
Stencil fail operation.
|
GL_STENCIL_FUNC
|
1
|
Stencil function.
|
GL_STENCIL_REF
|
1
|
Stencil reference value.
|
GL_STENCIL_TEST
|
1
|
Zero if stencil test is disabled.
One if stencil test is enabled.
|
GL_STENCIL_VALUE_MASK
|
1
|
Stencil mask value.
|
GL_STENCIL_WRITE_MASK
|
1
|
Stencil buffer write mask.
|
GL_TEXTURE_2D
|
1
|
Zero if 2D texture mapping is
disabled.
One if 2D texture mapping is enabled.
|
| GL_TEXTURE_BINDING_2D |
1
|
Name of currently bound 2D
texture object.
|
GL_TEXTURE_ENV_COLOR
|
4
|
Texture environment color (red,
green, blue, alpha).
|
GL_TEXTURE_ENV_MODE
|
1
|
Texture environment mode.
|
GL_UNPACK_ROW_LENGTH
|
1
|
Pixel unpacking row length.
|
GL_UNPACK_LSB_FIRST
|
1
|
Zero if most significant bit is
unpacked first for bitmaps.
One if least significant bit is unpacked first for bitmaps.
|
GL_VIEWPORT
|
4
|
Current viewport (x, y, width,
height).
|
9.2 String Queries
The command
const GLubyte *glGetString(GLenum name)
is used to query string-valued values. The legal values for name are described in the following
table:
name
|
Return value
|
GL_VERSION
|
The library version, such as
"1.2".
|
GL_RENDERER
|
The renderer, such as "Mesa DRI
Radeon".
|
GL_VENDOR
|
The vendor of this
implementation, such as "Tungsten Graphics, Inc."
|
GL_EXTENSIONS
|
A white-space separated list of
the supported extensions. |
9.3 Error Queries
The command
GLenum glGetError(void)
returns the current error code. The current error code will be
set by a GL command when an error condition has been detected. If
the current error code is already set, subsequent errors will not be
recorded. The error code is reset/cleared to GL_NO_ERROR when glGetError returns. The
following error codes are possible:
Error code
|
Meaning
|
GL_NO_ERROR
|
No error has been recorded.
|
GL_INVALID_ENUM
|
An enum parameter had an invalid
value.
|
GL_INVALID_VALUE
|
A numeric parameter had an
invalid value.
|
GL_INVALID_OPERATION
|
A function was called when not
legal to do so.
|
GL_STACK_OVERFLOW
|
The current transformation
matrix stack is full.
|
GL_STACK_UNDERFLOW
|
The current transformation
matrix stack is empty.
|
GL_OUT_OF_MEMORY
|
The system ran out of dynamic
memory.
|
10. Unsupported Features
This section lists other features and functions which are not supported
and not previously discussed.
10.1 Feedback Mode
Feedback mode and the following related functions are not supported.
glFeedbackBuffer
glPassThrough
10.2 1D and 3D Textures
Only 2D texture images are supported. The following functions
used to specify 1D and 3D texture images are not supported:
glTexImage1D
glTexImage3D
glTexSubImage1D
glTexSubImage3D
glCopyTexImage1D
glCopyTexSubImage1D
glCopyTexSubImage3D
10.3 Alternate Texture Image Commands
Texture images may only be specified with glTexImage2D. The following
alternate texture image commands are not supported:
glTexSubImage2D
glCopyTexImage2D
glCopyTexSubImage2D
10.4 Proxy Textures
Proxy textures are not supported and the GL_PROXY_TEXTURE_2D token is
not supported by any function.
10.5 Other Texture Commands
The following commands related to texture mapping are not supported by
the subset:
glPrioritizeTextures
glAreTexturesResident
glIsTexture
glTexEnviv
glTexEnvf
glTexParameterf
glTexParameteriv
glTexParameterfv
10.6 Copy and Draw Pixels
The following commands are not supported:
glDrawPixels
glCopyPixels
glPixelZoom
10.7 Color Index Mode
Color index mode and the following related commands are not supported:
glIndexub
glIndexi
glIndexs
glIndexf
glIndexd
glIndexubv
glIndexiv
glIndexsv
glIndexfv
glIndexdv
glIndexMask
glClearIndex
glIndexPointer
10.8 Pixel Transfer Operations
The pixel transfer operations (scale, bias, look-up table, etc) are not
supported and the following commands are omitted:
glPixelTransferf
glPixelTransferi
glPixelMapfv
glPixelMapuiv
glPixelMapusv
glGetPixelMapfv
glGetPixelMapuiv
glGetPixelMapusv
10.9 Hints
Hints and the following related command is not supported:
glHint
10.10 State Query Commands
The following state query commands are not supported:
glGetBooleanv
glGetIntegerv
glGetDoublev
glGetPointerv
glGetTexEnvi
glGetTexEnvf
glGetTexParameteriv
glGetTexParameterfv
glGetTexLevelParameteriv
glGetTexLevelParameterfv
glGetTexImage
glGetClipPlane
10.11 Attribute Stacks
State attribute stacks and the following related commands are not
supported:
glPushAttrib
glPopAtttrib
10.12 Double-Valued Functions
All functions which take double-precision floating point values, but
for which there is an equivalent single-precision valued function, are
omitted. This includes, but is not limited to:
glVertex2d
glVertex2dv
glVertex3d
glVertex3dv
glVertex4d
glVertex4dv
glColor3d
glColor3dv
glColor4d
glColor4dv
glTexCoord1d
glTexCoord1dv
glTexCoord2d
glTexCoord2dv
glTexCoord3d
glTexCoord3dv
glTexCoord4d
glTexCoord4dv
glRasterPos2d
glRasterPos2dv
glRasterPos3d
glRasterPos3dv
glRasterPos4d
glRasterPos4dv
glLoadMatrixd
glMultMatrixd
glScaled
glRotated
glTranslated
glRectd
glRectdv
10.13 Evaluators
Evaluators and the following related commands are not supported:
glMap1f
glMap2d
glMap2f
glGetMapdv
glGetMapfv
glGetMapiv
glEvalCoord1d
glEvalCoord1f
glEvalCoord1dv
glEvalCoord1fv
glEvalCoord2d
glEvalCoord2f
glEvalCoord2dv
glEvalCoord2fv
glMapGrid1d
glMapGrid1f
glMapGrid2d
glMapGrid2f
glEvalPoint1
glEvalPoint2
glEvalMesh1
glEvalMesh2
10.14 Display Lists
Display lists and the following related commands are not supported:
glIsList
glDeleteLists
glGenLists
glNewList
glEndList
glCallList
glCallLists
glListBase
10.15 Accumulation Buffer
The accumulation buffer and the following related commands are not
supported:
glAccum
glClearAccum
10.16 Fog
Fog and the following related commands are not supported:
glFogi
glFogf
glFogiv
glFogfv
10.17 Depth Test
Depth testing and the following related commands are not supported:
glDepthFunc
glDepthMask
glDepthRange
glClearDepth
10.18 Imaging Subset
The OpenGL imaging subset (which implements features such as
convolution, histogram, min/max recording, color matrix and color
tables) is not supported.
Appendix A: Issues
This appendix lists documentation and subset issues with their current
status. For items which are still open, the documentation (above)
follows the recommended solution.
A.1 Vertex Arrays
Should vertex arrays be supported? Is there a performance
advantage?
RESOLUTION: No, there isn't enough of a performance advantage to
justify them.
A.2 Polygon Antialiasing and Edge Flags
Should edge flags be supported for antialiasing?
Edge flags don't effect antialiasing, at least not normally. A
number of approaches to antialiasing have been summarized in email.
RECOMMENDATION: don't support edge flags. They don't effect
polygon antialiasing.
RESOLUTION: closed, as of 26 Feb 2003.
A.3 glRasterPos vs. glWindowPos
Should glRasterPos and/or glWindowPos commands be supported?
RESOLUTION: Closed: implement glRasterPos commands, but not glWindowPos
commands.
A.4 GL_IBM_rasterpos_clip extension
Should the GL_IBM_rasterpos_clip extension be implemented?
RESOLUTION: No. It's not required.
A.5 Image Formats and Types
Which image formats and types should be supported for glTexImage2D and glReadPixels?
OpenGL specifies a large
variety of image formats and data types. Only a few are commonly
used.
RECOMMENDATION: we propose a subset:
For glTexImage2D only allow type=GL_UNSIGNED_BYTE and format=GL_RGBA, GL_RGB,
GL_INTENSITY. Only allow internalFormat
to be GL_RGBA, GL_RGB or GL_INTENSITY as well. Basically, only
support image formats/types that are directly supported by the Radeon
hardware. This will allow glTexImage2D
to basically just use memcpy to
copy texture images.
For glReadPixels, only allow type = GL_UNSIGNED_BYTE or GL_FLOAT.
Only allow format =
GL_RGB or GL_RGBA. This is just enough to support the OpenGL
conformance tests.
RESOLUTION: open
A.6 Texture Environment Modes
Which texture environment modes should be supported? OpenGL 1.2
has GL_REPLACE, GL_MODULATE, GL_DECAL and GL_BLEND. GL_DECAL isn't
defined for all base internal texture formats. GL_ADD is another
useful mode. Perhaps drop GL_DECAL mode and add GL_ADD mode.
RECOMMENDATION: implement the standard modes GL_REPLACE, GL_MODULATE,
GL_DECAL and GL_BLEND.
RESOLUTION: open
A.7 Truncated Mipmaps and LOD Control
Should we support the GL_TEXTURE_BASE_LEVEL, GL_TEXTURE_MAX_LEVEL,
GL_TEXTURE_MIN_LOD and GL_TEXTURE_MAX_LOD texture parameters?
RECOMMENDATION: We propose omitting these features at this time,
in the interest of simplifying the driver.
RESOLUTION: open
A.8 Texture Priorities and Residency
Should the subset support texture priorities via glPrioritizeTextures and the glAreTexturesResident command?
RECOMMENDATION: Few applications use these features and
functions. We propose omitting them to simplify the driver.
RESOLUTION: open
A.9 Pixel Pack/Unpack Alignment Control
Should we support the GL_PACK_ALIGNMENT and GL_UNPACK_ALIGNMENT options?
These are used to align pixel data addresses to 1, 2 and 4-byte
multiples for glBitmap, glTexImage2D
and glReadPixels. These
aren't strictly needed since the user can provide a 1, 2 or 4-byte
aligned address and appropriate GL_PACK_ROW_LENGTH or
GL_UNPACK_ROW_LENGTH values instead.
RECOMMENDATION: We recommend omitting them to simplify the driver.
RESOLUTION: open
A.10 Pixel Pack/Unpack Skip Rows/Pixels Control
Should we support the GL_UNPACK_SKIP_PIXELS, GL_UNPACK_SKIP_ROWS,
GL_PACK_SKIP_PIXELS and GL_PACK_SKIP_ROWS options for pixel
unpacking/packing?
These options aren't really needed since the user can adjust the start
address and GL_PACK/UNPACK_ROW_LENGTH parameters to achieve the same
effect.
RECOMMENDATION: omit these parameters.
RESOLUTION: open
A.11 Texture State Queries
Should we support the command glGetTexEnvi/fv,
glGetTexParameteri/fv and glGetTexLevelParameteri/fv?
RECOMMENDATION: No. They're seldom needed and their
implementation is several hundred lines of code in length.
RESOLUTION: open
A.12 glGetIntegerv, glGetBooleanv and glGetDoublev
Should we support the commands glGetIntegerv,
glGetBooleanv and glGetDoublev
in addition to glGetFloatv?
RECOMMENDATION: Omit the boolean, integer and double-valued
functions. All state values which can be queried by these commands can
be expressed as floating point values and queried with glGetFloatv. The
implementation of the other three commands involves many lines of code.
RESOLUTION: open
A.13 glBitmap and Per-Fragment Operations
Should bitmaps rendered with glBitmap
be subjected to the per-fragment operations?
If bitmaps are implemented with points it will be easy to implement the
per-fragment operations. Otherwise, it could be difficult.
RECOMMENDATION: Implement glBitmap by drawing points/pixels with
the hardware. This will make supporting the per-fragments
trivially easy. Also, it makes portrait-mode display relatively
easy.
RESOLUTION: open
A.14 Reduced gl.h Header File
Should we produce a reduced gl.h header file which only defines the
tokens and functions which are implemented by the subset?
RECOMMENDATION: yes. It would be a useful reference to
programmers to quickly determine which functions and tokens are
supported.
RESOLUTION: open
A.15 glPolygonMode
Is glPolygonMode needed?
RECOMMENDATION: No. Omit it.
RESOLUTION: closed, as of 26 Feb 2003