doc/testspecs/GLES3/functional.shaders.builtin_functions.precision.txt - third_party/vulkan-cts - Git at Google

 -------------------------------------------------------------------------
 drawElements Quality Program Test Specification
 -----------------------------------------------

 Copyright 2014 The Android Open Source Project

 Licensed under the Apache License, Version 2.0 (the "License");
 you may not use this file except in compliance with the License.
 You may obtain a copy of the License at

      http://www.apache.org/licenses/LICENSE-2.0

 Unless required by applicable law or agreed to in writing, software
 distributed under the License is distributed on an "AS IS" BASIS,
 WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 See the License for the specific language governing permissions and
 limitations under the License.
 -------------------------------------------------------------------------
     Precision tests for built-in functions

 Tests:
  + dEQP-GLES3.functional.shaders.builtin_functions.precision.*


 These tests check that the GLSL built-in numerical functions produce
 results that are compliant with the range and precision requirements in
 the GLSL ES specification.

 The tests operate by calling the functions with predefined (mostly
 random) input values in either the vertex or the fragment shader. The
 result is stored in a transform feedback buffer or in a framebuffer
 pixel, and then read and compared to a reference interval of acceptable
 values. Functions are tested with all possible vector and matrix sizes.
 In the test log floating point numbers are printed out as hexadecimal
 constants of the form used in e.g. C99.

 Where the GLSL specification does not specify a particular precision,
 the tests try to make reasonable requirements. When behavior at
 infinities hasn't been otherwise specified, C99 Appendix F is used as a
 reference. Moreover, the highp precision requirements have been adapted
 to lowp and mediump precisions even though the GLSL specification
 doesn't provide any guarantees about them. For instance, mediump and
 lowp operations are expected to produce either an infinity or the
 maximum/minimum value on overflow.

 The acceptable results are constrained further by only allowing values
 from within the codomain of the function. Thus, for instance, sin(x) is
 not allowed to return a number greater than 1 even when when the nominal
 error bound would be greater.

 A number of functions have been defined as derived forms. This means
 that they are required to produce only results that their expansions
 could produce, given the precision requirements for the constituent

 operations.

 * Arithmetic operations

 These are as defined in the GLSL ES specification.

 | operation | precision | domain                      |
 |-----------+-----------+-----------------------------|
 | x + y     | < 1 ULP   |                             |
 | x / y     | 2.5 ULP   | 2^-126 <= abs(y) <= 2^127-1 |
 | x - y     | < 1 ULP   |                             |
 | x * y     | < 1 ULP   |                             |


 * Trigonometric functions

 The precisions for trigonometric functions have been adapted from OpenCL
 fast relaxed math and half-float specifications. Hyperbolic functions
 take their precisions from standard formulae as derived forms.

 Primitives:

 | function   | precision      | domain              | prec qual     |
 |------------+----------------+---------------------+---------------|
 | sin(x)     | 2^-11          | -pi <= x <= pi      | highp         |
 |            | 2^-12 * abs(x) | elsewhere           | highp         |
 |            | 2 ULP          |                     | mediump, lowp |
 | cos(x)     | 2^-11          | -pi <= x <= pi      | highp         |
 |            | 2^-12 * abs(x) | elsewhere           | highp         |
 |            | 2 ULP          |                     | mediump, lowp |
 | asin(x)    | 4 ULP          | -1 <= x <= 1        | highp         |
 |            | 2 ULP          | -1 <= x <= 1        | mediump, lowp |
 | acos(x)    | 4 ULP          | -1 <= x <= 1        | highp         |
 |            | 2 ULP          | -1 <= x <= 1        | mediump, lowp |
 | atan(x, y) | 6 ULP          | !(x == 0 && y == 0) | highp         |
 |            | 2 ULP          | !(x == 0 && y == 0) | mediump, lowp |
 | atan(x)    | 5 ULP          |                     | highp         |
 |            | 2 ULP          |                     | mediump, lowp |

 Derived functions:

 | function   | defined as                       |
 |------------+----------------------------------|
 | radians(x) | (pi / 180.0) * x                 |
 | degrees(x) | (180.0 / pi) * x                 |
 | tan(x)     | sin(x) * (1.0 / cos(x))          |
 | sinh(x)    | (exp(x) - exp(-x)) / 2.0         |
 | cosh(x)    | (exp(x) + exp(-x)) / 2.0         |
 | tanh(x)    | sinh(x) / cosh(x)                |
 | asinh(x)   | log(x + sqrt(x * x + 1.0))       |
 | acosh(x)   | log(x + sqrt((x+1.0) * (x-1.0))) |
 | atanh(x)   | 0.5 * log(1.0 + x / (1.0 - x))   |


 * Exponential functions

 The precisions for exponential functions for mediump and lowp have been
 adapted from the OpenCL half-float specification.

 Primitives:

 | function       | precision            | domain               | prec qual |
 |----------------+----------------------+----------------------+-----------|
 | exp(x)         | (3 + 2 * abs(x)) ULP |                      | highp     |
 |                | (2 + 2 * abs(x)) ULP |                      | mediump   |
 |                | 2 ULP                |                      | lowp      |
 | log(x)         | 2^-21                | 0.5 <= x && x <= 0.5 | highp     |
 |                | 3 ULP                | elsewhere            | highp     |
 |                | 2^-7                 | 0.5 <= x && x <= 0.5 | mediump   |
 |                | 2 ULP                | elsewhere            | mediump   |
 |                | 2 ULP                |                      | lowp      |
 | exp(x)         | (3 + 2 * abs(x)) ULP |                      | highp     |
 |                | (2 + 2 * abs(x)) ULP |                      | mediump   |
 |                | 2 ULP                |                      | lowp      |
 | log2(x)        | 2^-21                | 0.5 <= x && x <= 0.5 | highp     |
 |                | 3 ULP                | elsewhere            | highp     |
 |                | 2^-7                 | 0.5 <= x && x <= 0.5 | mediump   |
 |                | 2 ULP                | elsewhere            | mediump   |
 |                | 2 ULP                |                      | lowp      |
 | inversesqrt(x) | 2 ULP                |                      |           |

 Derived functions:

 | function | defined as           |
 |----------+----------------------|
 | pow(x)   | exp2(y * log2(x))    |
 | sqrt(x)  | 1.0 / inversesqrt(x) |


 * Common functions

 The operations that don't do any arithmetic are required to produce
 exact results. The round() function is allowed to round in either
 direction on a tie.

 Primitives:

 | function         | precision |
 |------------------+-----------|
 | abs(x)           |         0 |
 | sign(x)          |         0 |
 | floor(x)         |         0 |
 | trunc(x)         |         0 |
 | round(x)         |   special |
 | roundEven(x)     |         0 |
 | ceil(x)          |         0 |
 | modf(x, i)       |         0 |
 | min(x, y)        |         0 |
 | max(x, y)        |         0 |
 | clamp(x, lo, hi) |         0 |
 | step(edge, x)    |         0 |

 Derived functions:

 | function              | defined as                                     |
 |-----------------------+------------------------------------------------|
 | fract(x)              | x - floor(x)                                   |
 | mod(x, y)             | x - y * floor(x / y)                           |
 | mix(x, y, a)          | x * (1 - a) + y * a                            |
 | smoothstep(e0, e1, x) | { float t = clamp((x - e0) / (e1 - e0),0,1);   |
 |                       |   return t * t * (3 - 2*t);                  } |


 * Geometric and matrix functions

 These are generally defined as derived forms with reference algorithms.
 For determinant and inverse operations only 2x2 matrices are tested:
 there are a number of possible algorithms for larger matrices, and the
 specification does not provide precision requirements for these operations.
	-------------------------------------------------------------------------
	drawElements Quality Program Test Specification
	-----------------------------------------------

	Copyright 2014 The Android Open Source Project

	Licensed under the Apache License, Version 2.0 (the "License");
	you may not use this file except in compliance with the License.
	You may obtain a copy of the License at

	http://www.apache.org/licenses/LICENSE-2.0

	Unless required by applicable law or agreed to in writing, software
	distributed under the License is distributed on an "AS IS" BASIS,
	WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	See the License for the specific language governing permissions and
	limitations under the License.
	-------------------------------------------------------------------------
	Precision tests for built-in functions

	Tests:
	+ dEQP-GLES3.functional.shaders.builtin_functions.precision.*


	These tests check that the GLSL built-in numerical functions produce
	results that are compliant with the range and precision requirements in
	the GLSL ES specification.

	The tests operate by calling the functions with predefined (mostly
	random) input values in either the vertex or the fragment shader. The
	result is stored in a transform feedback buffer or in a framebuffer
	pixel, and then read and compared to a reference interval of acceptable
	values. Functions are tested with all possible vector and matrix sizes.
	In the test log floating point numbers are printed out as hexadecimal
	constants of the form used in e.g. C99.

	Where the GLSL specification does not specify a particular precision,
	the tests try to make reasonable requirements. When behavior at
	infinities hasn't been otherwise specified, C99 Appendix F is used as a
	reference. Moreover, the highp precision requirements have been adapted
	to lowp and mediump precisions even though the GLSL specification
	doesn't provide any guarantees about them. For instance, mediump and
	lowp operations are expected to produce either an infinity or the
	maximum/minimum value on overflow.

	The acceptable results are constrained further by only allowing values
	from within the codomain of the function. Thus, for instance, sin(x) is
	not allowed to return a number greater than 1 even when when the nominal
	error bound would be greater.

	A number of functions have been defined as derived forms. This means
	that they are required to produce only results that their expansions
	could produce, given the precision requirements for the constituent

	operations.

	* Arithmetic operations

	These are as defined in the GLSL ES specification.

	\| operation \| precision \| domain \|
	\|-----------+-----------+-----------------------------\|
	\| x + y \| < 1 ULP \| \|
	\| x / y \| 2.5 ULP \| 2^-126 <= abs(y) <= 2^127-1 \|
	\| x - y \| < 1 ULP \| \|
	\| x * y \| < 1 ULP \| \|


	* Trigonometric functions

	The precisions for trigonometric functions have been adapted from OpenCL
	fast relaxed math and half-float specifications. Hyperbolic functions
	take their precisions from standard formulae as derived forms.

	Primitives:

	\| function \| precision \| domain \| prec qual \|
	\|------------+----------------+---------------------+---------------\|
	\| sin(x) \| 2^-11 \| -pi <= x <= pi \| highp \|
	\| \| 2^-12 * abs(x) \| elsewhere \| highp \|
	\| \| 2 ULP \| \| mediump, lowp \|
	\| cos(x) \| 2^-11 \| -pi <= x <= pi \| highp \|
	\| \| 2^-12 * abs(x) \| elsewhere \| highp \|
	\| \| 2 ULP \| \| mediump, lowp \|
	\| asin(x) \| 4 ULP \| -1 <= x <= 1 \| highp \|
	\| \| 2 ULP \| -1 <= x <= 1 \| mediump, lowp \|
	\| acos(x) \| 4 ULP \| -1 <= x <= 1 \| highp \|
	\| \| 2 ULP \| -1 <= x <= 1 \| mediump, lowp \|
	\| atan(x, y) \| 6 ULP \| !(x == 0 && y == 0) \| highp \|
	\| \| 2 ULP \| !(x == 0 && y == 0) \| mediump, lowp \|
	\| atan(x) \| 5 ULP \| \| highp \|
	\| \| 2 ULP \| \| mediump, lowp \|

	Derived functions:

	\| function \| defined as \|
	\|------------+----------------------------------\|
	\| radians(x) \| (pi / 180.0) * x \|
	\| degrees(x) \| (180.0 / pi) * x \|
	\| tan(x) \| sin(x) * (1.0 / cos(x)) \|
	\| sinh(x) \| (exp(x) - exp(-x)) / 2.0 \|
	\| cosh(x) \| (exp(x) + exp(-x)) / 2.0 \|
	\| tanh(x) \| sinh(x) / cosh(x) \|
	\| asinh(x) \| log(x + sqrt(x * x + 1.0)) \|
	\| acosh(x) \| log(x + sqrt((x+1.0) * (x-1.0))) \|
	\| atanh(x) \| 0.5 * log(1.0 + x / (1.0 - x)) \|


	* Exponential functions

	The precisions for exponential functions for mediump and lowp have been
	adapted from the OpenCL half-float specification.

	Primitives:

	\| function \| precision \| domain \| prec qual \|
	\|----------------+----------------------+----------------------+-----------\|
	\| exp(x) \| (3 + 2 * abs(x)) ULP \| \| highp \|
	\| \| (2 + 2 * abs(x)) ULP \| \| mediump \|
	\| \| 2 ULP \| \| lowp \|
	\| log(x) \| 2^-21 \| 0.5 <= x && x <= 0.5 \| highp \|
	\| \| 3 ULP \| elsewhere \| highp \|
	\| \| 2^-7 \| 0.5 <= x && x <= 0.5 \| mediump \|
	\| \| 2 ULP \| elsewhere \| mediump \|
	\| \| 2 ULP \| \| lowp \|
	\| exp(x) \| (3 + 2 * abs(x)) ULP \| \| highp \|
	\| \| (2 + 2 * abs(x)) ULP \| \| mediump \|
	\| \| 2 ULP \| \| lowp \|
	\| log2(x) \| 2^-21 \| 0.5 <= x && x <= 0.5 \| highp \|
	\| \| 3 ULP \| elsewhere \| highp \|
	\| \| 2^-7 \| 0.5 <= x && x <= 0.5 \| mediump \|
	\| \| 2 ULP \| elsewhere \| mediump \|
	\| \| 2 ULP \| \| lowp \|
	\| inversesqrt(x) \| 2 ULP \| \| \|

	Derived functions:

	\| function \| defined as \|
	\|----------+----------------------\|
	\| pow(x) \| exp2(y * log2(x)) \|
	\| sqrt(x) \| 1.0 / inversesqrt(x) \|


	* Common functions

	The operations that don't do any arithmetic are required to produce
	exact results. The round() function is allowed to round in either
	direction on a tie.

	Primitives:

	\| function \| precision \|
	\|------------------+-----------\|
	\| abs(x) \| 0 \|
	\| sign(x) \| 0 \|
	\| floor(x) \| 0 \|
	\| trunc(x) \| 0 \|
	\| round(x) \| special \|
	\| roundEven(x) \| 0 \|
	\| ceil(x) \| 0 \|
	\| modf(x, i) \| 0 \|
	\| min(x, y) \| 0 \|
	\| max(x, y) \| 0 \|
	\| clamp(x, lo, hi) \| 0 \|
	\| step(edge, x) \| 0 \|

	Derived functions:

	\| function \| defined as \|
	\|-----------------------+------------------------------------------------\|
	\| fract(x) \| x - floor(x) \|
	\| mod(x, y) \| x - y * floor(x / y) \|
	\| mix(x, y, a) \| x * (1 - a) + y * a \|
	\| smoothstep(e0, e1, x) \| { float t = clamp((x - e0) / (e1 - e0),0,1); \|
	\| \| return t * t * (3 - 2*t); } \|


	* Geometric and matrix functions

	These are generally defined as derived forms with reference algorithms.
	For determinant and inverse operations only 2x2 matrices are tested:
	there are a number of possible algorithms for larger matrices, and the
	specification does not provide precision requirements for these operations.