docs/specs/INTEL_shader_atomic_float_minmax.txt - third_party/mesa - Git at Google

 Name

     INTEL_shader_atomic_float_minmax

 Name Strings

     GL_INTEL_shader_atomic_float_minmax

 Contact

     Ian Romanick (ian . d . romanick 'at' intel . com)

 Contributors


 Status

     In progress

 Version

     Last Modified Date: 06/22/2018
     Revision: 4

 Number

     TBD

 Dependencies

     OpenGL 4.2, OpenGL ES 3.1, ARB_shader_storage_buffer_object, or
     ARB_compute_shader is required.

     This extension is written against version 4.60 of the OpenGL Shading
     Language Specification.

 Overview

     This extension provides GLSL built-in functions allowing shaders to
     perform atomic read-modify-write operations to floating-point buffer
     variables and shared variables.  Minimum, maximum, exchange, and
     compare-and-swap are enabled.


 New Procedures and Functions

     None.

 New Tokens

     None.

 IP Status

     None.

 Modifications to the OpenGL Shading Language Specification, Version 4.60

     Including the following line in a shader can be used to control the
     language features described in this extension:

       #extension GL_INTEL_shader_atomic_float_minmax : <behavior>

     where <behavior> is as specified in section 3.3.

     New preprocessor #defines are added to the OpenGL Shading Language:

       #define GL_INTEL_shader_atomic_float_minmax   1

 Additions to Chapter 8 of the OpenGL Shading Language Specification
 (Built-in Functions)

     Modify Section 8.11, "Atomic Memory Functions"

     (add a new row after the existing "atomicMin" table row, p. 179)

         float atomicMin(inout float mem, float data)


         Computes a new value by taking the minimum of the value of data and
         the contents of mem.  If one of these is an IEEE signaling NaN (i.e.,
         a NaN with the most-significant bit of the mantissa cleared), it is
         always considered smaller.  If one of these is an IEEE quiet NaN
         (i.e., a NaN with the most-significant bit of the mantissa set), it is
         always considered larger.  If both are IEEE quiet NaNs or both are
         IEEE signaling NaNs, the result of the comparison is undefined.

     (add a new row after the exiting "atomicMax" table row, p. 179)

         float atomicMax(inout float mem, float data)

         Computes a new value by taking the maximum of the value of data and
         the contents of mem.  If one of these is an IEEE signaling NaN (i.e.,
         a NaN with the most-significant bit of the mantissa cleared), it is
         always considered larger.  If one of these is an IEEE quiet NaN (i.e.,
         a NaN with the most-significant bit of the mantissa set), it is always
         considered smaller.  If both are IEEE quiet NaNs or both are IEEE
         signaling NaNs, the result of the comparison is undefined.

     (add to "atomicExchange" table cell, p. 180)

         float atomicExchange(inout float mem, float data)

     (add to "atomicCompSwap" table cell, p. 180)

         float atomicCompSwap(inout float mem, float compare, float data)

 Interactions with OpenGL 4.6 and ARB_gl_spirv

     If OpenGL 4.6 or ARB_gl_spirv is supported, then
     SPV_INTEL_shader_atomic_float_minmax must also be supported.

     The AtomicFloatMinmaxINTEL capability is available whenever the OpenGL or
     OpenGL ES implementation supports INTEL_shader_atomic_float_minmax.

 Issues

     1) Why call this extension INTEL_shader_atomic_float_minmax?

     RESOLVED: Several other extensions already set the precedent of
     VENDOR_shader_atomic_float and VENDOR_shader_atomic_float64 for extensions
     that enable floating-point atomic operations.  Using that as a base for
     the name seems logical.

     There already exists NV_shader_atomic_float, but the two extensions have
     nearly zero overlap in functionality.  NV_shader_atomic_float adds
     atomicAdd and image atomic operations that currently shipping Intel GPUs
     do not support.  Calling this extension INTEL_shader_atomic_float would
     likely have been confusing.

     Adding something to describe the actual functions added by this extension
     seemed reasonable.  INTEL_shader_atomic_float_compare was considered, but
     that name was deemed to be not properly descriptive.  Calling this
     extension INTEL_shader_atomic_float_min_max_exchange_compswap is right
     out.

     2) What atomic operations should we support for floating-point targets?

     RESOLVED.  Exchange, min, max, and compare-swap make sense, and these are
     all supported by the hardware.  Future extensions may add other functions.

     For buffer variables and shared variables it is not possible to bit-cast
     the memory location in GLSL, so existing integer operations, such as
     atomicOr, cannot be used.  However, the underlying hardware implementation
     can do this by treating the memory as an integer.  It would be possible to
     implement atomicNegate using this technique with atomicXor.  It is unclear
     whether this provides any actual utility.

     3) What should be said about the NaN behavior?

     RESOLVED.  There are several aspects of NaN behavior that should be
     documented in this extension.  However, some of this behavior varies based
     on NaN concepts that do not exist in the GLSL specification.

     * atomicCompSwap performs the comparison as the floating-point equality
       operator (==).  That is, if either 'mem' or 'compare' is NaN, the
       comparison result is always false.

     * atomicMin and atomicMax implement the IEEE specification with respect to
       NaN.  IEEE considers two different kinds of NaN: signaling NaN and quiet
       NaN.  A quiet NaN has the most significant bit of the mantissa set, and
       a signaling NaN does not.  This concept does not exist in SPIR-V,
       Vulkan, or OpenGL.  Let qNaN denote a quiet NaN and sNaN denote a
       signaling NaN.  atomicMin and atomicMax specifically implement

       - fmin(qNaN, x) = fmin(x, qNaN) = fmax(qNaN, x) = fmax(x, qNaN) = x
       - fmin(sNaN, x) = fmin(x, sNaN) = fmax(sNaN, x) = fmax(x, sNaN) = sNaN
       - fmin(sNaN, qNaN) = fmin(qNaN, sNaN) = fmax(sNaN, qNaN) =
         fmax(qNaN, sNaN) = sNaN
       - fmin(sNaN, sNaN) = sNaN.  This specification does not define which of
         the two arguments is stored.
       - fmax(sNaN, sNaN) = sNaN.  This specification does not define which of
         the two arguments is stored.
       - fmin(qNaN, qNaN) = qNaN.  This specification does not define which of
         the two arguments is stored.
       - fmax(qNaN, qNaN) = qNaN.  This specification does not define which of
         the two arguments is stored.

     Further details are available in the Skylake Programmer's Reference
     Manuals available at
     https://01.org/linuxgraphics/documentation/hardware-specification-prms.

     4) What about atomicMin and atomicMax with (+0.0, -0.0) or (-0.0, +0.0)
     arguments?

     RESOLVED.  atomicMin should store -0.0, and atomicMax should store +0.0.
     Due to a known issue in shipping Skylake GPUs, the incorrectly signed 0 is
     stored.  This behavior may change in later GPUs.

 Revision History

     Rev  Date        Author    Changes
     ---  ----------  --------  ---------------------------------------------
       1  04/19/2018  idr       Initial version
       2  05/05/2018  idr       Describe interactions with the capabilities
                                added by SPV_INTEL_shader_atomic_float_minmax.
       3  05/29/2018  idr       Remove mention of 64-bit float support.
       4  06/22/2018  idr       Resolve issue #2.
                                Add issue #3 (regarding NaN behavior).
                                Add issue #4 (regarding atomicMin(-0, +0).
	Name

	INTEL_shader_atomic_float_minmax

	Name Strings

	GL_INTEL_shader_atomic_float_minmax

	Contact

	Ian Romanick (ian . d . romanick 'at' intel . com)

	Contributors


	Status

	In progress

	Version

	Last Modified Date: 06/22/2018
	Revision: 4

	Number

	TBD

	Dependencies

	OpenGL 4.2, OpenGL ES 3.1, ARB_shader_storage_buffer_object, or
	ARB_compute_shader is required.

	This extension is written against version 4.60 of the OpenGL Shading
	Language Specification.

	Overview

	This extension provides GLSL built-in functions allowing shaders to
	perform atomic read-modify-write operations to floating-point buffer
	variables and shared variables. Minimum, maximum, exchange, and
	compare-and-swap are enabled.


	New Procedures and Functions

	None.

	New Tokens

	None.

	IP Status

	None.

	Modifications to the OpenGL Shading Language Specification, Version 4.60

	Including the following line in a shader can be used to control the
	language features described in this extension:

	#extension GL_INTEL_shader_atomic_float_minmax : <behavior>

	where <behavior> is as specified in section 3.3.

	New preprocessor #defines are added to the OpenGL Shading Language:

	#define GL_INTEL_shader_atomic_float_minmax 1

	Additions to Chapter 8 of the OpenGL Shading Language Specification
	(Built-in Functions)

	Modify Section 8.11, "Atomic Memory Functions"

	(add a new row after the existing "atomicMin" table row, p. 179)

	float atomicMin(inout float mem, float data)


	Computes a new value by taking the minimum of the value of data and
	the contents of mem. If one of these is an IEEE signaling NaN (i.e.,
	a NaN with the most-significant bit of the mantissa cleared), it is
	always considered smaller. If one of these is an IEEE quiet NaN
	(i.e., a NaN with the most-significant bit of the mantissa set), it is
	always considered larger. If both are IEEE quiet NaNs or both are
	IEEE signaling NaNs, the result of the comparison is undefined.

	(add a new row after the exiting "atomicMax" table row, p. 179)

	float atomicMax(inout float mem, float data)

	Computes a new value by taking the maximum of the value of data and
	the contents of mem. If one of these is an IEEE signaling NaN (i.e.,
	a NaN with the most-significant bit of the mantissa cleared), it is
	always considered larger. If one of these is an IEEE quiet NaN (i.e.,
	a NaN with the most-significant bit of the mantissa set), it is always
	considered smaller. If both are IEEE quiet NaNs or both are IEEE
	signaling NaNs, the result of the comparison is undefined.

	(add to "atomicExchange" table cell, p. 180)

	float atomicExchange(inout float mem, float data)

	(add to "atomicCompSwap" table cell, p. 180)

	float atomicCompSwap(inout float mem, float compare, float data)

	Interactions with OpenGL 4.6 and ARB_gl_spirv

	If OpenGL 4.6 or ARB_gl_spirv is supported, then
	SPV_INTEL_shader_atomic_float_minmax must also be supported.

	The AtomicFloatMinmaxINTEL capability is available whenever the OpenGL or
	OpenGL ES implementation supports INTEL_shader_atomic_float_minmax.

	Issues

	1) Why call this extension INTEL_shader_atomic_float_minmax?

	RESOLVED: Several other extensions already set the precedent of
	VENDOR_shader_atomic_float and VENDOR_shader_atomic_float64 for extensions
	that enable floating-point atomic operations. Using that as a base for
	the name seems logical.

	There already exists NV_shader_atomic_float, but the two extensions have
	nearly zero overlap in functionality. NV_shader_atomic_float adds
	atomicAdd and image atomic operations that currently shipping Intel GPUs
	do not support. Calling this extension INTEL_shader_atomic_float would
	likely have been confusing.

	Adding something to describe the actual functions added by this extension
	seemed reasonable. INTEL_shader_atomic_float_compare was considered, but
	that name was deemed to be not properly descriptive. Calling this
	extension INTEL_shader_atomic_float_min_max_exchange_compswap is right
	out.

	2) What atomic operations should we support for floating-point targets?

	RESOLVED. Exchange, min, max, and compare-swap make sense, and these are
	all supported by the hardware. Future extensions may add other functions.

	For buffer variables and shared variables it is not possible to bit-cast
	the memory location in GLSL, so existing integer operations, such as
	atomicOr, cannot be used. However, the underlying hardware implementation
	can do this by treating the memory as an integer. It would be possible to
	implement atomicNegate using this technique with atomicXor. It is unclear
	whether this provides any actual utility.

	3) What should be said about the NaN behavior?

	RESOLVED. There are several aspects of NaN behavior that should be
	documented in this extension. However, some of this behavior varies based
	on NaN concepts that do not exist in the GLSL specification.

	* atomicCompSwap performs the comparison as the floating-point equality
	operator (==). That is, if either 'mem' or 'compare' is NaN, the
	comparison result is always false.

	* atomicMin and atomicMax implement the IEEE specification with respect to
	NaN. IEEE considers two different kinds of NaN: signaling NaN and quiet
	NaN. A quiet NaN has the most significant bit of the mantissa set, and
	a signaling NaN does not. This concept does not exist in SPIR-V,
	Vulkan, or OpenGL. Let qNaN denote a quiet NaN and sNaN denote a
	signaling NaN. atomicMin and atomicMax specifically implement

	- fmin(qNaN, x) = fmin(x, qNaN) = fmax(qNaN, x) = fmax(x, qNaN) = x
	- fmin(sNaN, x) = fmin(x, sNaN) = fmax(sNaN, x) = fmax(x, sNaN) = sNaN
	- fmin(sNaN, qNaN) = fmin(qNaN, sNaN) = fmax(sNaN, qNaN) =
	fmax(qNaN, sNaN) = sNaN
	- fmin(sNaN, sNaN) = sNaN. This specification does not define which of
	the two arguments is stored.
	- fmax(sNaN, sNaN) = sNaN. This specification does not define which of
	the two arguments is stored.
	- fmin(qNaN, qNaN) = qNaN. This specification does not define which of
	the two arguments is stored.
	- fmax(qNaN, qNaN) = qNaN. This specification does not define which of
	the two arguments is stored.

	Further details are available in the Skylake Programmer's Reference
	Manuals available at
	https://01.org/linuxgraphics/documentation/hardware-specification-prms.

	4) What about atomicMin and atomicMax with (+0.0, -0.0) or (-0.0, +0.0)
	arguments?

	RESOLVED. atomicMin should store -0.0, and atomicMax should store +0.0.
	Due to a known issue in shipping Skylake GPUs, the incorrectly signed 0 is
	stored. This behavior may change in later GPUs.

	Revision History

	Rev Date Author Changes
	--- ---------- -------- ---------------------------------------------
	1 04/19/2018 idr Initial version
	2 05/05/2018 idr Describe interactions with the capabilities
	added by SPV_INTEL_shader_atomic_float_minmax.
	3 05/29/2018 idr Remove mention of 64-bit float support.
	4 06/22/2018 idr Resolve issue #2.
	Add issue #3 (regarding NaN behavior).
	Add issue #4 (regarding atomicMin(-0, +0).