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|
TGSI
====
TGSI, Tungsten Graphics Shader Infrastructure, is an intermediate language
for describing shaders. Since Gallium is inherently shaderful, shaders are
an important part of the API. TGSI is the only intermediate representation
used by all drivers.
Basics
------
All TGSI instructions, known as *opcodes*, operate on arbitrary-precision
floating-point four-component vectors. An opcode may have up to one
destination register, known as *dst*, and between zero and three source
registers, called *src0* through *src2*, or simply *src* if there is only
one.
Some instructions, like :opcode:`I2F`, permit re-interpretation of vector
components as integers. Other instructions permit using registers as
two-component vectors with double precision; see :ref:`Double Opcodes`.
When an instruction has a scalar result, the result is usually copied into
each of the components of *dst*. When this happens, the result is said to be
*replicated* to *dst*. :opcode:`RCP` is one such instruction.
Instruction Set
---------------
Core ISA
^^^^^^^^^^^^^^^^^^^^^^^^^
These opcodes are guaranteed to be available regardless of the driver being
used.
.. opcode:: ARL - Address Register Load
.. math::
dst.x = \lfloor src.x\rfloor
dst.y = \lfloor src.y\rfloor
dst.z = \lfloor src.z\rfloor
dst.w = \lfloor src.w\rfloor
.. opcode:: MOV - Move
.. math::
dst.x = src.x
dst.y = src.y
dst.z = src.z
dst.w = src.w
.. opcode:: LIT - Light Coefficients
.. math::
dst.x = 1
dst.y = max(src.x, 0)
dst.z = (src.x > 0) ? max(src.y, 0)^{clamp(src.w, -128, 128))} : 0
dst.w = 1
.. opcode:: RCP - Reciprocal
This instruction replicates its result.
.. math::
dst = \frac{1}{src.x}
.. opcode:: RSQ - Reciprocal Square Root
This instruction replicates its result.
.. math::
dst = \frac{1}{\sqrt{|src.x|}}
.. opcode:: EXP - Approximate Exponential Base 2
.. math::
dst.x = 2^{\lfloor src.x\rfloor}
dst.y = src.x - \lfloor src.x\rfloor
dst.z = 2^{src.x}
dst.w = 1
.. opcode:: LOG - Approximate Logarithm Base 2
.. math::
dst.x = \lfloor\log_2{|src.x|}\rfloor
dst.y = \frac{|src.x|}{2^{\lfloor\log_2{|src.x|}\rfloor}}
dst.z = \log_2{|src.x|}
dst.w = 1
.. opcode:: MUL - Multiply
.. math::
dst.x = src0.x \times src1.x
dst.y = src0.y \times src1.y
dst.z = src0.z \times src1.z
dst.w = src0.w \times src1.w
.. opcode:: ADD - Add
.. math::
dst.x = src0.x + src1.x
dst.y = src0.y + src1.y
dst.z = src0.z + src1.z
dst.w = src0.w + src1.w
.. opcode:: DP3 - 3-component Dot Product
This instruction replicates its result.
.. math::
dst = src0.x \times src1.x + src0.y \times src1.y + src0.z \times src1.z
.. opcode:: DP4 - 4-component Dot Product
This instruction replicates its result.
.. math::
dst = src0.x \times src1.x + src0.y \times src1.y + src0.z \times src1.z + src0.w \times src1.w
.. opcode:: DST - Distance Vector
.. math::
dst.x = 1
dst.y = src0.y \times src1.y
dst.z = src0.z
dst.w = src1.w
.. opcode:: MIN - Minimum
.. math::
dst.x = min(src0.x, src1.x)
dst.y = min(src0.y, src1.y)
dst.z = min(src0.z, src1.z)
dst.w = min(src0.w, src1.w)
.. opcode:: MAX - Maximum
.. math::
dst.x = max(src0.x, src1.x)
dst.y = max(src0.y, src1.y)
dst.z = max(src0.z, src1.z)
dst.w = max(src0.w, src1.w)
.. opcode:: SLT - Set On Less Than
.. math::
dst.x = (src0.x < src1.x) ? 1 : 0
dst.y = (src0.y < src1.y) ? 1 : 0
dst.z = (src0.z < src1.z) ? 1 : 0
dst.w = (src0.w < src1.w) ? 1 : 0
.. opcode:: SGE - Set On Greater Equal Than
.. math::
dst.x = (src0.x >= src1.x) ? 1 : 0
dst.y = (src0.y >= src1.y) ? 1 : 0
dst.z = (src0.z >= src1.z) ? 1 : 0
dst.w = (src0.w >= src1.w) ? 1 : 0
.. opcode:: MAD - Multiply And Add
.. math::
dst.x = src0.x \times src1.x + src2.x
dst.y = src0.y \times src1.y + src2.y
dst.z = src0.z \times src1.z + src2.z
dst.w = src0.w \times src1.w + src2.w
.. opcode:: SUB - Subtract
.. math::
dst.x = src0.x - src1.x
dst.y = src0.y - src1.y
dst.z = src0.z - src1.z
dst.w = src0.w - src1.w
.. opcode:: LRP - Linear Interpolate
.. math::
dst.x = src0.x \times src1.x + (1 - src0.x) \times src2.x
dst.y = src0.y \times src1.y + (1 - src0.y) \times src2.y
dst.z = src0.z \times src1.z + (1 - src0.z) \times src2.z
dst.w = src0.w \times src1.w + (1 - src0.w) \times src2.w
.. opcode:: CND - Condition
.. math::
dst.x = (src2.x > 0.5) ? src0.x : src1.x
dst.y = (src2.y > 0.5) ? src0.y : src1.y
dst.z = (src2.z > 0.5) ? src0.z : src1.z
dst.w = (src2.w > 0.5) ? src0.w : src1.w
.. opcode:: DP2A - 2-component Dot Product And Add
.. math::
dst.x = src0.x \times src1.x + src0.y \times src1.y + src2.x
dst.y = src0.x \times src1.x + src0.y \times src1.y + src2.x
dst.z = src0.x \times src1.x + src0.y \times src1.y + src2.x
dst.w = src0.x \times src1.x + src0.y \times src1.y + src2.x
.. opcode:: FRC - Fraction
.. math::
dst.x = src.x - \lfloor src.x\rfloor
dst.y = src.y - \lfloor src.y\rfloor
dst.z = src.z - \lfloor src.z\rfloor
dst.w = src.w - \lfloor src.w\rfloor
.. opcode:: CLAMP - Clamp
.. math::
dst.x = clamp(src0.x, src1.x, src2.x)
dst.y = clamp(src0.y, src1.y, src2.y)
dst.z = clamp(src0.z, src1.z, src2.z)
dst.w = clamp(src0.w, src1.w, src2.w)
.. opcode:: FLR - Floor
This is identical to :opcode:`ARL`.
.. math::
dst.x = \lfloor src.x\rfloor
dst.y = \lfloor src.y\rfloor
dst.z = \lfloor src.z\rfloor
dst.w = \lfloor src.w\rfloor
.. opcode:: ROUND - Round
.. math::
dst.x = round(src.x)
dst.y = round(src.y)
dst.z = round(src.z)
dst.w = round(src.w)
.. opcode:: EX2 - Exponential Base 2
This instruction replicates its result.
.. math::
dst = 2^{src.x}
.. opcode:: LG2 - Logarithm Base 2
This instruction replicates its result.
.. math::
dst = \log_2{src.x}
.. opcode:: POW - Power
This instruction replicates its result.
.. math::
dst = src0.x^{src1.x}
.. opcode:: XPD - Cross Product
.. math::
dst.x = src0.y \times src1.z - src1.y \times src0.z
dst.y = src0.z \times src1.x - src1.z \times src0.x
dst.z = src0.x \times src1.y - src1.x \times src0.y
dst.w = 1
.. opcode:: ABS - Absolute
.. math::
dst.x = |src.x|
dst.y = |src.y|
dst.z = |src.z|
dst.w = |src.w|
.. opcode:: RCC - Reciprocal Clamped
This instruction replicates its result.
XXX cleanup on aisle three
.. math::
dst = (1 / src.x) > 0 ? clamp(1 / src.x, 5.42101e-020, 1.884467e+019) : clamp(1 / src.x, -1.884467e+019, -5.42101e-020)
.. opcode:: DPH - Homogeneous Dot Product
This instruction replicates its result.
.. math::
dst = src0.x \times src1.x + src0.y \times src1.y + src0.z \times src1.z + src1.w
.. opcode:: COS - Cosine
This instruction replicates its result.
.. math::
dst = \cos{src.x}
.. opcode:: DDX - Derivative Relative To X
.. math::
dst.x = partialx(src.x)
dst.y = partialx(src.y)
dst.z = partialx(src.z)
dst.w = partialx(src.w)
.. opcode:: DDY - Derivative Relative To Y
.. math::
dst.x = partialy(src.x)
dst.y = partialy(src.y)
dst.z = partialy(src.z)
dst.w = partialy(src.w)
.. opcode:: KILP - Predicated Discard
discard
.. opcode:: PK2H - Pack Two 16-bit Floats
TBD
.. opcode:: PK2US - Pack Two Unsigned 16-bit Scalars
TBD
.. opcode:: PK4B - Pack Four Signed 8-bit Scalars
TBD
.. opcode:: PK4UB - Pack Four Unsigned 8-bit Scalars
TBD
.. opcode:: RFL - Reflection Vector
.. math::
dst.x = 2 \times (src0.x \times src1.x + src0.y \times src1.y + src0.z \times src1.z) / (src0.x \times src0.x + src0.y \times src0.y + src0.z \times src0.z) \times src0.x - src1.x
dst.y = 2 \times (src0.x \times src1.x + src0.y \times src1.y + src0.z \times src1.z) / (src0.x \times src0.x + src0.y \times src0.y + src0.z \times src0.z) \times src0.y - src1.y
dst.z = 2 \times (src0.x \times src1.x + src0.y \times src1.y + src0.z \times src1.z) / (src0.x \times src0.x + src0.y \times src0.y + src0.z \times src0.z) \times src0.z - src1.z
dst.w = 1
.. note::
Considered for removal.
.. opcode:: SEQ - Set On Equal
.. math::
dst.x = (src0.x == src1.x) ? 1 : 0
dst.y = (src0.y == src1.y) ? 1 : 0
dst.z = (src0.z == src1.z) ? 1 : 0
dst.w = (src0.w == src1.w) ? 1 : 0
.. opcode:: SFL - Set On False
This instruction replicates its result.
.. math::
dst = 0
.. note::
Considered for removal.
.. opcode:: SGT - Set On Greater Than
.. math::
dst.x = (src0.x > src1.x) ? 1 : 0
dst.y = (src0.y > src1.y) ? 1 : 0
dst.z = (src0.z > src1.z) ? 1 : 0
dst.w = (src0.w > src1.w) ? 1 : 0
.. opcode:: SIN - Sine
This instruction replicates its result.
.. math::
dst = \sin{src.x}
.. opcode:: SLE - Set On Less Equal Than
.. math::
dst.x = (src0.x <= src1.x) ? 1 : 0
dst.y = (src0.y <= src1.y) ? 1 : 0
dst.z = (src0.z <= src1.z) ? 1 : 0
dst.w = (src0.w <= src1.w) ? 1 : 0
.. opcode:: SNE - Set On Not Equal
.. math::
dst.x = (src0.x != src1.x) ? 1 : 0
dst.y = (src0.y != src1.y) ? 1 : 0
dst.z = (src0.z != src1.z) ? 1 : 0
dst.w = (src0.w != src1.w) ? 1 : 0
.. opcode:: STR - Set On True
This instruction replicates its result.
.. math::
dst = 1
.. opcode:: TEX - Texture Lookup
TBD
.. opcode:: TXD - Texture Lookup with Derivatives
TBD
.. opcode:: TXP - Projective Texture Lookup
TBD
.. opcode:: UP2H - Unpack Two 16-Bit Floats
TBD
.. note::
Considered for removal.
.. opcode:: UP2US - Unpack Two Unsigned 16-Bit Scalars
TBD
.. note::
Considered for removal.
.. opcode:: UP4B - Unpack Four Signed 8-Bit Values
TBD
.. note::
Considered for removal.
.. opcode:: UP4UB - Unpack Four Unsigned 8-Bit Scalars
TBD
.. note::
Considered for removal.
.. opcode:: X2D - 2D Coordinate Transformation
.. math::
dst.x = src0.x + src1.x \times src2.x + src1.y \times src2.y
dst.y = src0.y + src1.x \times src2.z + src1.y \times src2.w
dst.z = src0.x + src1.x \times src2.x + src1.y \times src2.y
dst.w = src0.y + src1.x \times src2.z + src1.y \times src2.w
.. note::
Considered for removal.
.. opcode:: ARA - Address Register Add
TBD
.. note::
Considered for removal.
.. opcode:: ARR - Address Register Load With Round
.. math::
dst.x = round(src.x)
dst.y = round(src.y)
dst.z = round(src.z)
dst.w = round(src.w)
.. opcode:: BRA - Branch
pc = target
.. note::
Considered for removal.
.. opcode:: CAL - Subroutine Call
push(pc)
pc = target
.. opcode:: RET - Subroutine Call Return
pc = pop()
Potential restrictions:
* Only occurs at end of function.
.. opcode:: SSG - Set Sign
.. math::
dst.x = (src.x > 0) ? 1 : (src.x < 0) ? -1 : 0
dst.y = (src.y > 0) ? 1 : (src.y < 0) ? -1 : 0
dst.z = (src.z > 0) ? 1 : (src.z < 0) ? -1 : 0
dst.w = (src.w > 0) ? 1 : (src.w < 0) ? -1 : 0
.. opcode:: CMP - Compare
.. math::
dst.x = (src0.x < 0) ? src1.x : src2.x
dst.y = (src0.y < 0) ? src1.y : src2.y
dst.z = (src0.z < 0) ? src1.z : src2.z
dst.w = (src0.w < 0) ? src1.w : src2.w
.. opcode:: KIL - Conditional Discard
.. math::
if (src.x < 0 || src.y < 0 || src.z < 0 || src.w < 0)
discard
endif
.. opcode:: SCS - Sine Cosine
.. math::
dst.x = \cos{src.x}
dst.y = \sin{src.x}
dst.z = 0
dst.y = 1
.. opcode:: TXB - Texture Lookup With Bias
TBD
.. opcode:: NRM - 3-component Vector Normalise
.. math::
dst.x = src.x / (src.x \times src.x + src.y \times src.y + src.z \times src.z)
dst.y = src.y / (src.x \times src.x + src.y \times src.y + src.z \times src.z)
dst.z = src.z / (src.x \times src.x + src.y \times src.y + src.z \times src.z)
dst.w = 1
.. opcode:: DIV - Divide
.. math::
dst.x = \frac{src0.x}{src1.x}
dst.y = \frac{src0.y}{src1.y}
dst.z = \frac{src0.z}{src1.z}
dst.w = \frac{src0.w}{src1.w}
.. opcode:: DP2 - 2-component Dot Product
This instruction replicates its result.
.. math::
dst = src0.x \times src1.x + src0.y \times src1.y
.. opcode:: TXL - Texture Lookup With LOD
TBD
.. opcode:: BRK - Break
TBD
.. opcode:: IF - If
TBD
.. opcode:: ELSE - Else
TBD
.. opcode:: ENDIF - End If
TBD
.. opcode:: PUSHA - Push Address Register On Stack
push(src.x)
push(src.y)
push(src.z)
push(src.w)
.. note::
Considered for cleanup.
.. note::
Considered for removal.
.. opcode:: POPA - Pop Address Register From Stack
dst.w = pop()
dst.z = pop()
dst.y = pop()
dst.x = pop()
.. note::
Considered for cleanup.
.. note::
Considered for removal.
Compute ISA
^^^^^^^^^^^^^^^^^^^^^^^^
These opcodes are primarily provided for special-use computational shaders.
Support for these opcodes indicated by a special pipe capability bit (TBD).
XXX so let's discuss it, yeah?
.. opcode:: CEIL - Ceiling
.. math::
dst.x = \lceil src.x\rceil
dst.y = \lceil src.y\rceil
dst.z = \lceil src.z\rceil
dst.w = \lceil src.w\rceil
.. opcode:: I2F - Integer To Float
.. math::
dst.x = (float) src.x
dst.y = (float) src.y
dst.z = (float) src.z
dst.w = (float) src.w
.. opcode:: NOT - Bitwise Not
.. math::
dst.x = ~src.x
dst.y = ~src.y
dst.z = ~src.z
dst.w = ~src.w
.. opcode:: TRUNC - Truncate
.. math::
dst.x = trunc(src.x)
dst.y = trunc(src.y)
dst.z = trunc(src.z)
dst.w = trunc(src.w)
.. opcode:: SHL - Shift Left
.. math::
dst.x = src0.x << src1.x
dst.y = src0.y << src1.x
dst.z = src0.z << src1.x
dst.w = src0.w << src1.x
.. opcode:: SHR - Shift Right
.. math::
dst.x = src0.x >> src1.x
dst.y = src0.y >> src1.x
dst.z = src0.z >> src1.x
dst.w = src0.w >> src1.x
.. opcode:: AND - Bitwise And
.. math::
dst.x = src0.x & src1.x
dst.y = src0.y & src1.y
dst.z = src0.z & src1.z
dst.w = src0.w & src1.w
.. opcode:: OR - Bitwise Or
.. math::
dst.x = src0.x | src1.x
dst.y = src0.y | src1.y
dst.z = src0.z | src1.z
dst.w = src0.w | src1.w
.. opcode:: MOD - Modulus
.. math::
dst.x = src0.x \bmod src1.x
dst.y = src0.y \bmod src1.y
dst.z = src0.z \bmod src1.z
dst.w = src0.w \bmod src1.w
.. opcode:: XOR - Bitwise Xor
.. math::
dst.x = src0.x \oplus src1.x
dst.y = src0.y \oplus src1.y
dst.z = src0.z \oplus src1.z
dst.w = src0.w \oplus src1.w
.. opcode:: SAD - Sum Of Absolute Differences
.. math::
dst.x = |src0.x - src1.x| + src2.x
dst.y = |src0.y - src1.y| + src2.y
dst.z = |src0.z - src1.z| + src2.z
dst.w = |src0.w - src1.w| + src2.w
.. opcode:: TXF - Texel Fetch
TBD
.. opcode:: TXQ - Texture Size Query
TBD
.. opcode:: CONT - Continue
TBD
.. note::
Support for CONT is determined by a special capability bit,
``TGSI_CONT_SUPPORTED``. See :ref:`Screen` for more information.
Geometry ISA
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
These opcodes are only supported in geometry shaders; they have no meaning
in any other type of shader.
.. opcode:: EMIT - Emit
TBD
.. opcode:: ENDPRIM - End Primitive
TBD
GLSL ISA
^^^^^^^^^^
These opcodes are part of :term:`GLSL`'s opcode set. Support for these
opcodes is determined by a special capability bit, ``GLSL``.
.. opcode:: BGNLOOP - Begin a Loop
TBD
.. opcode:: BGNSUB - Begin Subroutine
TBD
.. opcode:: ENDLOOP - End a Loop
TBD
.. opcode:: ENDSUB - End Subroutine
TBD
.. opcode:: NOP - No Operation
Do nothing.
.. opcode:: NRM4 - 4-component Vector Normalise
This instruction replicates its result.
.. math::
dst = \frac{src.x}{src.x \times src.x + src.y \times src.y + src.z \times src.z + src.w \times src.w}
ps_2_x
^^^^^^^^^^^^
XXX wait what
.. opcode:: CALLNZ - Subroutine Call If Not Zero
TBD
.. opcode:: IFC - If
TBD
.. opcode:: BREAKC - Break Conditional
TBD
.. _doubleopcodes:
Double ISA
^^^^^^^^^^^^^^^
The double-precision opcodes reinterpret four-component vectors into
two-component vectors with doubled precision in each component.
Support for these opcodes is XXX undecided. :T
.. opcode:: DADD - Add
.. math::
dst.xy = src0.xy + src1.xy
dst.zw = src0.zw + src1.zw
.. opcode:: DDIV - Divide
.. math::
dst.xy = src0.xy / src1.xy
dst.zw = src0.zw / src1.zw
.. opcode:: DSEQ - Set on Equal
.. math::
dst.xy = src0.xy == src1.xy ? 1.0F : 0.0F
dst.zw = src0.zw == src1.zw ? 1.0F : 0.0F
.. opcode:: DSLT - Set on Less than
.. math::
dst.xy = src0.xy < src1.xy ? 1.0F : 0.0F
dst.zw = src0.zw < src1.zw ? 1.0F : 0.0F
.. opcode:: DFRAC - Fraction
.. math::
dst.xy = src.xy - \lfloor src.xy\rfloor
dst.zw = src.zw - \lfloor src.zw\rfloor
.. opcode:: DFRACEXP - Convert Number to Fractional and Integral Components
.. math::
dst0.xy = frexp(src.xy, dst1.xy)
dst0.zw = frexp(src.zw, dst1.zw)
.. opcode:: DLDEXP - Multiple Number by Integral Power of 2
.. math::
dst.xy = ldexp(src0.xy, src1.xy)
dst.zw = ldexp(src0.zw, src1.zw)
.. opcode:: DMIN - Minimum
.. math::
dst.xy = min(src0.xy, src1.xy)
dst.zw = min(src0.zw, src1.zw)
.. opcode:: DMAX - Maximum
.. math::
dst.xy = max(src0.xy, src1.xy)
dst.zw = max(src0.zw, src1.zw)
.. opcode:: DMUL - Multiply
.. math::
dst.xy = src0.xy \times src1.xy
dst.zw = src0.zw \times src1.zw
.. opcode:: DMAD - Multiply And Add
.. math::
dst.xy = src0.xy \times src1.xy + src2.xy
dst.zw = src0.zw \times src1.zw + src2.zw
.. opcode:: DRCP - Reciprocal
.. math::
dst.xy = \frac{1}{src.xy}
dst.zw = \frac{1}{src.zw}
.. opcode:: DSQRT - Square Root
.. math::
dst.xy = \sqrt{src.xy}
dst.zw = \sqrt{src.zw}
Explanation of symbols used
------------------------------
Functions
^^^^^^^^^^^^^^
:math:`|x|` Absolute value of `x`.
:math:`\lceil x \rceil` Ceiling of `x`.
clamp(x,y,z) Clamp x between y and z.
(x < y) ? y : (x > z) ? z : x
:math:`\lfloor x\rfloor` Floor of `x`.
:math:`\log_2{x}` Logarithm of `x`, base 2.
max(x,y) Maximum of x and y.
(x > y) ? x : y
min(x,y) Minimum of x and y.
(x < y) ? x : y
partialx(x) Derivative of x relative to fragment's X.
partialy(x) Derivative of x relative to fragment's Y.
pop() Pop from stack.
:math:`x^y` `x` to the power `y`.
push(x) Push x on stack.
round(x) Round x.
trunc(x) Truncate x, i.e. drop the fraction bits.
Keywords
^^^^^^^^^^^^^
discard Discard fragment.
pc Program counter.
target Label of target instruction.
Other tokens
---------------
Declaration
^^^^^^^^^^^
Declares a register that is will be referenced as an operand in Instruction
tokens.
File field contains register file that is being declared and is one
of TGSI_FILE.
UsageMask field specifies which of the register components can be accessed
and is one of TGSI_WRITEMASK.
Interpolate field is only valid for fragment shader INPUT register files.
It specifes the way input is being interpolated by the rasteriser and is one
of TGSI_INTERPOLATE.
If Dimension flag is set to 1, a Declaration Dimension token follows.
If Semantic flag is set to 1, a Declaration Semantic token follows.
CylindricalWrap bitfield is only valid for fragment shader INPUT register
files. It specifies which register components should be subject to cylindrical
wrapping when interpolating by the rasteriser. If TGSI_CYLINDRICAL_WRAP_X
is set to 1, the X component should be interpolated according to cylindrical
wrapping rules.
Declaration Semantic
^^^^^^^^^^^^^^^^^^^^^^^^
Follows Declaration token if Semantic bit is set.
Since its purpose is to link a shader with other stages of the pipeline,
it is valid to follow only those Declaration tokens that declare a register
either in INPUT or OUTPUT file.
SemanticName field contains the semantic name of the register being declared.
There is no default value.
SemanticIndex is an optional subscript that can be used to distinguish
different register declarations with the same semantic name. The default value
is 0.
The meanings of the individual semantic names are explained in the following
sections.
TGSI_SEMANTIC_POSITION
""""""""""""""""""""""
Position, sometimes known as HPOS or WPOS for historical reasons, is the
location of the vertex in space, in ``(x, y, z, w)`` format. ``x``, ``y``, and ``z``
are the Cartesian coordinates, and ``w`` is the homogenous coordinate and used
for the perspective divide, if enabled.
As a vertex shader output, position should be scaled to the viewport. When
used in fragment shaders, position will be in window coordinates. The convention
used depends on the FS_COORD_ORIGIN and FS_COORD_PIXEL_CENTER properties.
XXX additionally, is there a way to configure the perspective divide? it's
accelerated on most chipsets AFAIK...
Position, if not specified, usually defaults to ``(0, 0, 0, 1)``, and can
be partially specified as ``(x, y, 0, 1)`` or ``(x, y, z, 1)``.
XXX usually? can we solidify that?
TGSI_SEMANTIC_COLOR
"""""""""""""""""""
Colors are used to, well, color the primitives. Colors are always in
``(r, g, b, a)`` format.
If alpha is not specified, it defaults to 1.
TGSI_SEMANTIC_BCOLOR
""""""""""""""""""""
Back-facing colors are only used for back-facing polygons, and are only valid
in vertex shader outputs. After rasterization, all polygons are front-facing
and COLOR and BCOLOR end up occupying the same slots in the fragment, so
all BCOLORs effectively become regular COLORs in the fragment shader.
TGSI_SEMANTIC_FOG
"""""""""""""""""
The fog coordinate historically has been used to replace the depth coordinate
for generation of fog in dedicated fog blocks. Gallium, however, does not use
dedicated fog acceleration, placing it entirely in the fragment shader
instead.
The fog coordinate should be written in ``(f, 0, 0, 1)`` format. Only the first
component matters when writing from the vertex shader; the driver will ensure
that the coordinate is in this format when used as a fragment shader input.
TGSI_SEMANTIC_PSIZE
"""""""""""""""""""
PSIZE, or point size, is used to specify point sizes per-vertex. It should
be in ``(s, 0, 0, 1)`` format, where ``s`` is the (possibly clamped) point size.
Only the first component matters when writing from the vertex shader.
When using this semantic, be sure to set the appropriate state in the
:ref:`rasterizer` first.
TGSI_SEMANTIC_GENERIC
"""""""""""""""""""""
Generic semantics are nearly always used for texture coordinate attributes,
in ``(s, t, r, q)`` format. ``t`` and ``r`` may be unused for certain kinds
of lookups, and ``q`` is the level-of-detail bias for biased sampling.
These attributes are called "generic" because they may be used for anything
else, including parameters, texture generation information, or anything that
can be stored inside a four-component vector.
TGSI_SEMANTIC_NORMAL
""""""""""""""""""""
Vertex normal; could be used to implement per-pixel lighting for legacy APIs
that allow mixing fixed-function and programmable stages.
TGSI_SEMANTIC_FACE
""""""""""""""""""
FACE is the facing bit, to store the facing information for the fragment
shader. ``(f, 0, 0, 1)`` is the format. The first component will be positive
when the fragment is front-facing, and negative when the component is
back-facing.
TGSI_SEMANTIC_EDGEFLAG
""""""""""""""""""""""
XXX no clue
Properties
^^^^^^^^^^^^^^^^^^^^^^^^
Properties are general directives that apply to the whole TGSI program.
FS_COORD_ORIGIN
"""""""""""""""
Specifies the fragment shader TGSI_SEMANTIC_POSITION coordinate origin.
The default value is UPPER_LEFT.
If UPPER_LEFT, the position will be (0,0) at the upper left corner and
increase downward and rightward.
If LOWER_LEFT, the position will be (0,0) at the lower left corner and
increase upward and rightward.
OpenGL defaults to LOWER_LEFT, and is configurable with the
GL_ARB_fragment_coord_conventions extension.
DirectX 9/10 use UPPER_LEFT.
FS_COORD_PIXEL_CENTER
"""""""""""""""""""""
Specifies the fragment shader TGSI_SEMANTIC_POSITION pixel center convention.
The default value is HALF_INTEGER.
If HALF_INTEGER, the fractionary part of the position will be 0.5
If INTEGER, the fractionary part of the position will be 0.0
Note that this does not affect the set of fragments generated by
rasterization, which is instead controlled by gl_rasterization_rules in the
rasterizer.
OpenGL defaults to HALF_INTEGER, and is configurable with the
GL_ARB_fragment_coord_conventions extension.
DirectX 9 uses INTEGER.
DirectX 10 uses HALF_INTEGER.
Texture Sampling and Texture Formats
------------------------------------
This table shows how texture image components are returned as (x,y,z,w) tuples
by TGSI texture instructions, such as :opcode:`TEX`, :opcode:`TXD`, and
:opcode:`TXP`. For reference, OpenGL and Direct3D conventions are shown as
well.
+--------------------+--------------+--------------------+--------------+
| Texture Components | Gallium | OpenGL | Direct3D 9 |
+====================+==============+====================+==============+
| R | (r, 0, 0, 1) | (r, 0, 0, 1) | (r, 1, 1, 1) |
+--------------------+--------------+--------------------+--------------+
| RG | (r, g, 0, 1) | (r, g, 0, 1) | (r, g, 1, 1) |
+--------------------+--------------+--------------------+--------------+
| RGB | (r, g, b, 1) | (r, g, b, 1) | (r, g, b, 1) |
+--------------------+--------------+--------------------+--------------+
| RGBA | (r, g, b, a) | (r, g, b, a) | (r, g, b, a) |
+--------------------+--------------+--------------------+--------------+
| A | (0, 0, 0, a) | (0, 0, 0, a) | (0, 0, 0, a) |
+--------------------+--------------+--------------------+--------------+
| L | (l, l, l, 1) | (l, l, l, 1) | (l, l, l, 1) |
+--------------------+--------------+--------------------+--------------+
| LA | (l, l, l, a) | (l, l, l, a) | (l, l, l, a) |
+--------------------+--------------+--------------------+--------------+
| I | (i, i, i, i) | (i, i, i, i) | N/A |
+--------------------+--------------+--------------------+--------------+
| UV | XXX TBD | (0, 0, 0, 1) | (u, v, 1, 1) |
| | | [#envmap-bumpmap]_ | |
+--------------------+--------------+--------------------+--------------+
| Z | XXX TBD | (z, z, z, 1) | (0, z, 0, 1) |
| | | [#depth-tex-mode]_ | |
+--------------------+--------------+--------------------+--------------+
.. [#envmap-bumpmap] http://www.opengl.org/registry/specs/ATI/envmap_bumpmap.txt
.. [#depth-tex-mode] the default is (z, z, z, 1) but may also be (0, 0, 0, z)
or (z, z, z, z) depending on the value of GL_DEPTH_TEXTURE_MODE.
|