Gl.BlendFunc (gb.opengl)

Static Sub BlendFunc ( SrcFactor As Integer, DstFactor As Integer )

Specify pixel arithmetic.

Parameters

sfactor: Specifies how the red, green, blue, and alpha source blending factors are computed. The initial value is Gl.ONE.
dfactor: Specifies how the red, green, blue, and alpha destination blending factors are computed. The following symbolic constants are accepted: Gl.ZERO, Gl.ONE, Gl.SRC_COLOR, Gl.ONE_MINUS_SRC_COLOR, Gl.DST_COLOR, Gl.ONE_MINUS_DST_COLOR, Gl.SRC_ALPHA, Gl.ONE_MINUS_SRC_ALPHA, Gl.DST_ALPHA, Gl.ONE_MINUS_DST_ALPHA. Gl.CONSTANT_COLOR, Gl.ONE_MINUS_CONSTANT_COLOR, Gl.CONSTANT_ALPHA, and Gl.ONE_MINUS_CONSTANT_ALPHA. The initial value is Gl.ZERO.

Description

Pixels can be drawn using a function that blends the incoming (source) RGBA values with the RGBA values that are already in the frame buffer (the destination values). Blending is initially disabled. Use Gl.Enable and Gl.Disable with argument Gl.BLEND to enable and disable blending.

Gl.BlendFunc defines the operation of blending when it is enabled. sfactor specifies which method is used to scale the source color components. dfactor specifies which method is used to scale the destination color components. Both parameters must be one of the following symbolic constants: Gl.ZERO, Gl.ONE, Gl.SRC_COLOR, Gl.ONE_MINUS_SRC_COLOR, Gl.DST_COLOR, Gl.ONE_MINUS_DST_COLOR, Gl.SRC_ALPHA, Gl.ONE_MINUS_SRC_ALPHA, Gl.DST_ALPHA, Gl.ONE_MINUS_DST_ALPHA, Gl.CONSTANT_COLOR, Gl.ONE_MINUS_CONSTANT_COLOR, Gl.CONSTANT_ALPHA, Gl.ONE_MINUS_CONSTANT_ALPHA, Gl.SRC_ALPHA_SATURATE, Gl.SRC1_COLOR, Gl.ONE_MINUS_SRC1_COLOR, Gl.SRC1_ALPHA, and Gl.ONE_MINUS_SRC1_ALPHA. The possible methods are described in the following table. Each method defines four scale factors, one each for red, green, blue, and alpha. In the table and in subsequent equations, first source, second source and destination color components are referred to as

(R_{s0}, G_{s0}, B_{s0}, A_{s0})

(R_{s1}, G_{s1}, B_{s1}, A_{s1})

and

(R_{d}, G_{d}, B_{d}, A_{d})

, respectively. The color specified by Gl.BlendColor is referred to as

(R_{c}, G_{c}, B_{c}, A_{c})

. They are understood to have integer values between 0 and

(k_{R}, k_{G}, k_{B}, k_{A})

, where

k_{c} 2^{m_{c}} - 1

and

(m_{R}, m_{G}, m_{B}, m_{A})

is the number of red, green, blue, and alpha bitplanes.

Source and destination scale factors are referred to as

(s_{R}, s_{G}, s_{B}, s_{A})

and

(d_{R}, d_{G}, d_{B}, d_{A})

. The scale factors described in the table, denoted

(f_{R}, f_{G}, f_{B}, f_{A})

, represent either source or destination factors. All scale factors have range

[/0, 1]

Parameter	$(f_{R}, f_{G}, f_{B}, f_{A})$
Gl.ZERO	$(0, 0, 0, 0)$
Gl.ONE	$(1, 1, 1, 1)$
Gl.SRC_COLOR	$(\frac{R_{s0}}{k_{R}}, \frac{G_{s0}}{k_{G}}, \frac{B_{s0}}{k_{B}}, \frac{A_{s0}}{k_{A}})$
Gl.ONE_MINUS_SRC_COLOR	$(1, 1, 1, 1) - (\frac{R_{s0}}{k_{R}}, \frac{G_{s0}}{k_{G}}, \frac{B_{s0}}{k_{B}}, \frac{A_{s0}}{k_{A}})$
Gl.DST_COLOR	$(\frac{R_{d}}{k_{R}}, \frac{G_{d}}{k_{G}}, \frac{B_{d}}{k_{B}}, \frac{A_{d}}{k_{A}})$
Gl.ONE_MINUS_DST_COLOR	$(1, 1, 1, 1) - (\frac{R_{d}}{k_{R}}, \frac{G_{d}}{k_{G}}, \frac{B_{d}}{k_{B}}, \frac{A_{d}}{k_{A}})$
Gl.SRC_ALPHA	$(\frac{A_{s0}}{k_{A}}, \frac{A_{s0}}{k_{A}}, \frac{A_{s0}}{k_{A}}, \frac{A_{s0}}{k_{A}})$
Gl.ONE_MINUS_SRC_ALPHA	$(1, 1, 1, 1) - (\frac{A_{s0}}{k_{A}}, \frac{A_{s0}}{k_{A}}, \frac{A_{s0}}{k_{A}}, \frac{A_{s0}}{k_{A}})$
Gl.DST_ALPHA	$(\frac{A_{d}}{k_{A}}, \frac{A_{d}}{k_{A}}, \frac{A_{d}}{k_{A}}, \frac{A_{d}}{k_{A}})$
Gl.ONE_MINUS_DST_ALPHA	$(1, 1, 1, 1) - (\frac{A_{d}}{k_{A}}, \frac{A_{d}}{k_{A}}, \frac{A_{d}}{k_{A}}, \frac{A_{d}}{k_{A}})$
Gl.CONSTANT_COLOR	$(R_{c}, G_{c}, B_{c}, A_{c})$
Gl.ONE_MINUS_CONSTANT_COLOR	$(1, 1, 1, 1) - (R_{c}, G_{c}, B_{c}, A_{c})$
Gl.CONSTANT_ALPHA	$(A_{c}, A_{c}, A_{c}, A_{c})$
Gl.ONE_MINUS_CONSTANT_ALPHA	$(1, 1, 1, 1) - (A_{c}, A_{c}, A_{c}, A_{c})$
Gl.SRC_ALPHA_SATURATE	$(i, i, i, 1)$
Gl.SRC1_COLOR	$(\frac{R_{s1}}{k_{R}}, \frac{G_{s1}}{k_{G}}, \frac{B_{s1}}{k_{B}}, \frac{A_{s1}}{k_{A}})$
Gl.ONE_MINUS_SRC1_COLOR	$(1, 1, 1, 1) - (\frac{R_{s1}}{k_{R}}, \frac{G_{s1}}{k_{G}}, \frac{B_{s1}}{k_{B}}, \frac{A_{s1}}{k_{A}})$
Gl.SRC1_ALPHA	$(\frac{A_{s1}}{k_{A}}, \frac{A_{s1}}{k_{A}}, \frac{A_{s1}}{k_{A}}, \frac{A_{s1}}{k_{A}})$
Gl.ONE_MINUS_SRC1_ALPHA	$(1, 1, 1, 1) - (\frac{A_{s1}}{k_{A}}, \frac{A_{s1}}{k_{A}}, \frac{A_{s1}}{k_{A}}, \frac{A_{s1}}{k_{A}})$

In the table,

i \frac{\min (A_{s}, k_{A} - A_{d})}{k_{A}}

To determine the blended RGBA values of a pixel, the system uses the following equations:

R_{d} \min (k_{R}, R_{s} s_{R} + R_{d} d_{R})

G_{d} \min (k_{G}, G_{s} s_{G} + G_{d} d_{G})

B_{d} \min (k_{B}, B_{s} s_{B} + B_{d} d_{B})

A_{d} \min (k_{A}, A_{s} s_{A} + A_{d} d_{A})

Despite the apparent precision of the above equations, blending arithmetic is not exactly specified, because blending operates with imprecise integer color values. However, a blend factor that should be equal to 1 is guaranteed not to modify its multiplicand, and a blend factor equal to 0 reduces its multiplicand to 0. For example, when sfactor is Gl.SRC_ALPHA, dfactor is Gl.ONE_MINUS_SRC_ALPHA, and

A_{s}

is equal to

k_{A}

, the equations reduce to simple replacement:

R_{d} R_{s}

G_{d} G_{s}

B_{d} B_{s}

A_{d} A_{s}

Examples

Transparency is best implemented using blend function (Gl.SRC_ALPHA, Gl.ONE_MINUS_SRC_ALPHA) with primitives sorted from farthest to nearest. Note that this transparency calculation does not require the presence of alpha bitplanes in the frame buffer.

Blend function (Gl.SRC_ALPHA, Gl.ONE_MINUS_SRC_ALPHA) is also useful for rendering antialiased points and lines in arbitrary order.

Polygon antialiasing is optimized using blend function (Gl.SRC_ALPHA_SATURATE, Gl.ONE) with polygons sorted from nearest to farthest. (See the Gl.Enable, Gl.Disable reference page and the Gl.POLYGON_SMOOTH argument for information on polygon antialiasing.) Destination alpha bitplanes, which must be present for this blend function to operate correctly, store the accumulated coverage.

Notes

Incoming (source) alpha is correctly thought of as a material opacity, ranging from 1.0 (

K_{A}

), representing complete opacity, to 0.0 (0), representing complete transparency.

When more than one color buffer is enabled for drawing, the GL performs blending separately for each enabled buffer, using the contents of that buffer for destination color. (See Gl.DrawBuffer.)

When dual source blending is enabled (i.e., one of the blend factors requiring the second color input is used), the maximum number of enabled draw buffers is given by Gl.MAX_DUAL_SOURCE_DRAW_BUFFERS, which may be lower than Gl.MAX_DRAW_BUFFERS.

Errors

Gl.INVALID_ENUM is generated if either sfactor or dfactor is not an accepted value.

Associated Gets

Gl.Get with argument Gl.BLEND_SRC

Gl.Get with argument Gl.BLEND_DST

Gl.IsEnabled with argument Gl.BLEND