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linux/drivers/gpu/drm/amd/display/include/fixed31_32.h
Samson Tam f822007034 drm/amd/display: remove dc dependencies from SPL library 
[Why]
Make SPL library dc-independent so it can be reused by other
 components

[How]
Create separate set of fixed31_32 calls in SPL
Make all inputs and outputs to SPL use primitive types
For ratios and inits, return as uint32 from SPL.  So
 add conversion from uint32 back to fixed point in
 SPL-to-dc translate function

Reviewed-by: Relja Vojvodic <relja.vojvodic@amd.com>
Signed-off-by: Jerry Zuo <jerry.zuo@amd.com>
Signed-off-by: Samson Tam <samson.tam@amd.com>
Tested-by: Daniel Wheeler <daniel.wheeler@amd.com>
Signed-off-by: Alex Deucher <alexander.deucher@amd.com>
2024-07-23 17:07:12 -04:00

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/*
* Copyright 2012-15 Advanced Micro Devices, Inc.
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE COPYRIGHT HOLDER(S) OR AUTHOR(S) BE LIABLE FOR ANY CLAIM, DAMAGES OR
* OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
* ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
* OTHER DEALINGS IN THE SOFTWARE.
*
* Authors: AMD
*
*/
#ifndef __DAL_FIXED31_32_H__
#define __DAL_FIXED31_32_H__
#ifndef LLONG_MAX
#define LLONG_MAX 9223372036854775807ll
#endif
#ifndef LLONG_MIN
#define LLONG_MIN (-LLONG_MAX - 1ll)
#endif
#define FIXED31_32_BITS_PER_FRACTIONAL_PART 32
#ifndef LLONG_MIN
#define LLONG_MIN (1LL<<63)
#endif
#ifndef LLONG_MAX
#define LLONG_MAX (-1LL>>1)
#endif
/*
* @brief
* Arithmetic operations on real numbers
* represented as fixed-point numbers.
* There are: 1 bit for sign,
* 31 bit for integer part,
* 32 bits for fractional part.
*
* @note
* Currently, overflows and underflows are asserted;
* no special result returned.
*/
struct fixed31_32 {
long long value;
};
/*
* @brief
* Useful constants
*/
static const struct fixed31_32 dc_fixpt_zero = { 0 };
static const struct fixed31_32 dc_fixpt_epsilon = { 1LL };
static const struct fixed31_32 dc_fixpt_half = { 0x80000000LL };
static const struct fixed31_32 dc_fixpt_one = { 0x100000000LL };
/*
* @brief
* Initialization routines
*/
/*
* @brief
* result = numerator / denominator
*/
struct fixed31_32 dc_fixpt_from_fraction(long long numerator, long long denominator);
/*
* @brief
* result = arg
*/
static inline struct fixed31_32 dc_fixpt_from_int(int arg)
{
struct fixed31_32 res;
res.value = (long long) arg << FIXED31_32_BITS_PER_FRACTIONAL_PART;
return res;
}
/*
* @brief
* Unary operators
*/
/*
* @brief
* result = -arg
*/
static inline struct fixed31_32 dc_fixpt_neg(struct fixed31_32 arg)
{
struct fixed31_32 res;
res.value = -arg.value;
return res;
}
/*
* @brief
* result = abs(arg) := (arg >= 0) ? arg : -arg
*/
static inline struct fixed31_32 dc_fixpt_abs(struct fixed31_32 arg)
{
if (arg.value < 0)
return dc_fixpt_neg(arg);
else
return arg;
}
/*
* @brief
* Binary relational operators
*/
/*
* @brief
* result = arg1 < arg2
*/
static inline bool dc_fixpt_lt(struct fixed31_32 arg1, struct fixed31_32 arg2)
{
return arg1.value < arg2.value;
}
/*
* @brief
* result = arg1 <= arg2
*/
static inline bool dc_fixpt_le(struct fixed31_32 arg1, struct fixed31_32 arg2)
{
return arg1.value <= arg2.value;
}
/*
* @brief
* result = arg1 == arg2
*/
static inline bool dc_fixpt_eq(struct fixed31_32 arg1, struct fixed31_32 arg2)
{
return arg1.value == arg2.value;
}
/*
* @brief
* result = min(arg1, arg2) := (arg1 <= arg2) ? arg1 : arg2
*/
static inline struct fixed31_32 dc_fixpt_min(struct fixed31_32 arg1, struct fixed31_32 arg2)
{
if (arg1.value <= arg2.value)
return arg1;
else
return arg2;
}
/*
* @brief
* result = max(arg1, arg2) := (arg1 <= arg2) ? arg2 : arg1
*/
static inline struct fixed31_32 dc_fixpt_max(struct fixed31_32 arg1, struct fixed31_32 arg2)
{
if (arg1.value <= arg2.value)
return arg2;
else
return arg1;
}
/*
* @brief
* | min_value, when arg <= min_value
* result = | arg, when min_value < arg < max_value
* | max_value, when arg >= max_value
*/
static inline struct fixed31_32 dc_fixpt_clamp(
struct fixed31_32 arg,
struct fixed31_32 min_value,
struct fixed31_32 max_value)
{
if (dc_fixpt_le(arg, min_value))
return min_value;
else if (dc_fixpt_le(max_value, arg))
return max_value;
else
return arg;
}
/*
* @brief
* Binary shift operators
*/
/*
* @brief
* result = arg << shift
*/
static inline struct fixed31_32 dc_fixpt_shl(struct fixed31_32 arg, unsigned char shift)
{
ASSERT(((arg.value >= 0) && (arg.value <= LLONG_MAX >> shift)) ||
((arg.value < 0) && (arg.value >= ~(LLONG_MAX >> shift))));
arg.value = arg.value << shift;
return arg;
}
/*
* @brief
* result = arg >> shift
*/
static inline struct fixed31_32 dc_fixpt_shr(struct fixed31_32 arg, unsigned char shift)
{
bool negative = arg.value < 0;
if (negative)
arg.value = -arg.value;
arg.value = arg.value >> shift;
if (negative)
arg.value = -arg.value;
return arg;
}
/*
* @brief
* Binary additive operators
*/
/*
* @brief
* result = arg1 + arg2
*/
static inline struct fixed31_32 dc_fixpt_add(struct fixed31_32 arg1, struct fixed31_32 arg2)
{
struct fixed31_32 res;
ASSERT(((arg1.value >= 0) && (LLONG_MAX - arg1.value >= arg2.value)) ||
((arg1.value < 0) && (LLONG_MIN - arg1.value <= arg2.value)));
res.value = arg1.value + arg2.value;
return res;
}
/*
* @brief
* result = arg1 + arg2
*/
static inline struct fixed31_32 dc_fixpt_add_int(struct fixed31_32 arg1, int arg2)
{
return dc_fixpt_add(arg1, dc_fixpt_from_int(arg2));
}
/*
* @brief
* result = arg1 - arg2
*/
static inline struct fixed31_32 dc_fixpt_sub(struct fixed31_32 arg1, struct fixed31_32 arg2)
{
struct fixed31_32 res;
ASSERT(((arg2.value >= 0) && (LLONG_MIN + arg2.value <= arg1.value)) ||
((arg2.value < 0) && (LLONG_MAX + arg2.value >= arg1.value)));
res.value = arg1.value - arg2.value;
return res;
}
/*
* @brief
* result = arg1 - arg2
*/
static inline struct fixed31_32 dc_fixpt_sub_int(struct fixed31_32 arg1, int arg2)
{
return dc_fixpt_sub(arg1, dc_fixpt_from_int(arg2));
}
/*
* @brief
* Binary multiplicative operators
*/
/*
* @brief
* result = arg1 * arg2
*/
struct fixed31_32 dc_fixpt_mul(struct fixed31_32 arg1, struct fixed31_32 arg2);
/*
* @brief
* result = arg1 * arg2
*/
static inline struct fixed31_32 dc_fixpt_mul_int(struct fixed31_32 arg1, int arg2)
{
return dc_fixpt_mul(arg1, dc_fixpt_from_int(arg2));
}
/*
* @brief
* result = square(arg) := arg * arg
*/
struct fixed31_32 dc_fixpt_sqr(struct fixed31_32 arg);
/*
* @brief
* result = arg1 / arg2
*/
static inline struct fixed31_32 dc_fixpt_div_int(struct fixed31_32 arg1, long long arg2)
{
return dc_fixpt_from_fraction(arg1.value, dc_fixpt_from_int((int)arg2).value);
}
/*
* @brief
* result = arg1 / arg2
*/
static inline struct fixed31_32 dc_fixpt_div(struct fixed31_32 arg1, struct fixed31_32 arg2)
{
return dc_fixpt_from_fraction(arg1.value, arg2.value);
}
/*
* @brief
* Reciprocal function
*/
/*
* @brief
* result = reciprocal(arg) := 1 / arg
*
* @note
* No special actions taken in case argument is zero.
*/
struct fixed31_32 dc_fixpt_recip(struct fixed31_32 arg);
/*
* @brief
* Trigonometric functions
*/
/*
* @brief
* result = sinc(arg) := sin(arg) / arg
*
* @note
* Argument specified in radians,
* internally it's normalized to [-2pi...2pi] range.
*/
struct fixed31_32 dc_fixpt_sinc(struct fixed31_32 arg);
/*
* @brief
* result = sin(arg)
*
* @note
* Argument specified in radians,
* internally it's normalized to [-2pi...2pi] range.
*/
struct fixed31_32 dc_fixpt_sin(struct fixed31_32 arg);
/*
* @brief
* result = cos(arg)
*
* @note
* Argument specified in radians
* and should be in [-2pi...2pi] range -
* passing arguments outside that range
* will cause incorrect result!
*/
struct fixed31_32 dc_fixpt_cos(struct fixed31_32 arg);
/*
* @brief
* Transcendent functions
*/
/*
* @brief
* result = exp(arg)
*
* @note
* Currently, function is verified for abs(arg) <= 1.
*/
struct fixed31_32 dc_fixpt_exp(struct fixed31_32 arg);
/*
* @brief
* result = log(arg)
*
* @note
* Currently, abs(arg) should be less than 1.
* No normalization is done.
* Currently, no special actions taken
* in case of invalid argument(s). Take care!
*/
struct fixed31_32 dc_fixpt_log(struct fixed31_32 arg);
/*
* @brief
* Power function
*/
/*
* @brief
* result = pow(arg1, arg2)
*
* @note
* Currently, abs(arg1) should be less than 1. Take care!
*/
static inline struct fixed31_32 dc_fixpt_pow(struct fixed31_32 arg1, struct fixed31_32 arg2)
{
if (arg1.value == 0)
return arg2.value == 0 ? dc_fixpt_one : dc_fixpt_zero;
return dc_fixpt_exp(
dc_fixpt_mul(
dc_fixpt_log(arg1),
arg2));
}
/*
* @brief
* Rounding functions
*/
/*
* @brief
* result = floor(arg) := greatest integer lower than or equal to arg
*/
static inline int dc_fixpt_floor(struct fixed31_32 arg)
{
unsigned long long arg_value = arg.value > 0 ? arg.value : -arg.value;
if (arg.value >= 0)
return (int)(arg_value >> FIXED31_32_BITS_PER_FRACTIONAL_PART);
else
return -(int)(arg_value >> FIXED31_32_BITS_PER_FRACTIONAL_PART);
}
/*
* @brief
* result = round(arg) := integer nearest to arg
*/
static inline int dc_fixpt_round(struct fixed31_32 arg)
{
unsigned long long arg_value = arg.value > 0 ? arg.value : -arg.value;
const long long summand = dc_fixpt_half.value;
ASSERT(LLONG_MAX - (long long)arg_value >= summand);
arg_value += summand;
if (arg.value >= 0)
return (int)(arg_value >> FIXED31_32_BITS_PER_FRACTIONAL_PART);
else
return -(int)(arg_value >> FIXED31_32_BITS_PER_FRACTIONAL_PART);
}
/*
* @brief
* result = ceil(arg) := lowest integer greater than or equal to arg
*/
static inline int dc_fixpt_ceil(struct fixed31_32 arg)
{
unsigned long long arg_value = arg.value > 0 ? arg.value : -arg.value;
const long long summand = dc_fixpt_one.value -
dc_fixpt_epsilon.value;
ASSERT(LLONG_MAX - (long long)arg_value >= summand);
arg_value += summand;
if (arg.value >= 0)
return (int)(arg_value >> FIXED31_32_BITS_PER_FRACTIONAL_PART);
else
return -(int)(arg_value >> FIXED31_32_BITS_PER_FRACTIONAL_PART);
}
/* the following two function are used in scaler hw programming to convert fixed
* point value to format 2 bits from integer part and 19 bits from fractional
* part. The same applies for u0d19, 0 bits from integer part and 19 bits from
* fractional
*/
unsigned int dc_fixpt_u4d19(struct fixed31_32 arg);
unsigned int dc_fixpt_u3d19(struct fixed31_32 arg);
unsigned int dc_fixpt_u2d19(struct fixed31_32 arg);
unsigned int dc_fixpt_u0d19(struct fixed31_32 arg);
unsigned int dc_fixpt_clamp_u0d14(struct fixed31_32 arg);
unsigned int dc_fixpt_clamp_u0d10(struct fixed31_32 arg);
int dc_fixpt_s4d19(struct fixed31_32 arg);
static inline struct fixed31_32 dc_fixpt_truncate(struct fixed31_32 arg, unsigned int frac_bits)
{
bool negative = arg.value < 0;
if (frac_bits >= FIXED31_32_BITS_PER_FRACTIONAL_PART) {
ASSERT(frac_bits == FIXED31_32_BITS_PER_FRACTIONAL_PART);
return arg;
}
if (negative)
arg.value = -arg.value;
arg.value &= (~0ULL) << (FIXED31_32_BITS_PER_FRACTIONAL_PART - frac_bits);
if (negative)
arg.value = -arg.value;
return arg;
}
struct fixed31_32 dc_fixpt_from_ux_dy(unsigned int value, unsigned int integer_bits, unsigned int fractional_bits);
struct fixed31_32 dc_fixpt_from_int_dy(unsigned int int_value,
unsigned int frac_value,
unsigned int integer_bits,
unsigned int fractional_bits);
#endif
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