dbus-sdr/sensorutils.cpp - openbmc/phosphor-host-ipmid - Gitiles

 /*
 // Copyright (c) 2017 2018 Intel Corporation
 //
 // 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.
 */

 #include "dbus-sdr/sensorutils.hpp"

 #include <algorithm>
 #include <cmath>
 #include <iostream>

 namespace ipmi
 {

 // Helper function to avoid repeated complicated expression
 static bool baseInRange(double base)
 {
     auto min10 = static_cast<double>(minInt10);
     auto max10 = static_cast<double>(maxInt10);

     return ((base >= min10) && (base <= max10));
 }

 // Helper function for internal use by getSensorAttributes()
 // Ensures floating-point "base" is within bounds,
 // and adjusts integer exponent "expShift" accordingly.
 // To minimize data loss when later truncating to integer,
 // the floating-point "base" will be as large as possible,
 // but still within the bounds (minInt10,maxInt10).
 // The bounds of "expShift" are (minInt4,maxInt4).
 // Consider this equation: n = base * (10.0 ** expShift)
 // This function will try to maximize "base",
 // adjusting "expShift" to keep the value "n" unchanged,
 // while keeping base and expShift within bounds.
 // Returns true if successful, modifies values in-place
 static bool scaleFloatExp(double& base, int8_t& expShift)
 {
     // Comparing with zero should be OK, zero is special in floating-point
     // If base is exactly zero, no adjustment of the exponent is necessary
     if (base == 0.0)
     {
         return true;
     }

     // As long as base value is within allowed range, expand precision
     // This will help to avoid loss when later rounding to integer
     while (baseInRange(base))
     {
         if (expShift <= minInt4)
         {
             // Already at the minimum expShift, can not decrement it more
             break;
         }

         // Multiply by 10, but shift decimal point to the left, no net change
         base *= 10.0;
         --expShift;
     }

     // As long as base value is *not* within range, shrink precision
     // This will pull base value closer to zero, thus within range
     while (!(baseInRange(base)))
     {
         if (expShift >= maxInt4)
         {
             // Already at the maximum expShift, can not increment it more
             break;
         }

         // Divide by 10, but shift decimal point to the right, no net change
         base /= 10.0;
         ++expShift;
     }

     // If the above loop was not able to pull it back within range,
     // the base value is beyond what expShift can represent, return false.
     return baseInRange(base);
 }

 // Helper function for internal use by getSensorAttributes()
 // Ensures integer "ibase" is no larger than necessary,
 // by normalizing it so that the decimal point shift is in the exponent,
 // whenever possible.
 // This provides more consistent results,
 // as many equivalent solutions are collapsed into one consistent solution.
 // If integer "ibase" is a clean multiple of 10,
 // divide it by 10 (this is lossless), so it is closer to zero.
 // Also modify floating-point "dbase" at the same time,
 // as both integer and floating-point base share the same expShift.
 // Example: (ibase=300, expShift=2) becomes (ibase=3, expShift=4)
 // because the underlying value is the same: 200*(10**2) == 2*(10**4)
 // Always successful, modifies values in-place
 static void normalizeIntExp(int16_t& ibase, int8_t& expShift, double& dbase)
 {
     for (;;)
     {
         // If zero, already normalized, ensure exponent also zero
         if (ibase == 0)
         {
             expShift = 0;
             break;
         }

         // If not cleanly divisible by 10, already normalized
         if ((ibase % 10) != 0)
         {
             break;
         }

         // If exponent already at max, already normalized
         if (expShift >= maxInt4)
         {
             break;
         }

         // Bring values closer to zero, correspondingly shift exponent,
         // without changing the underlying number that this all represents,
         // similar to what is done by scaleFloatExp().
         // The floating-point base must be kept in sync with the integer base,
         // as both floating-point and integer share the same exponent.
         ibase /= 10;
         dbase /= 10.0;
         ++expShift;
     }
 }

 // The IPMI equation:
 // y = (Mx + (B * 10^(bExp))) * 10^(rExp)
 // Section 36.3 of this document:
 // https://www.intel.com/content/dam/www/public/us/en/documents/product-briefs/ipmi-second-gen-interface-spec-v2-rev1-1.pdf
 //
 // The goal is to exactly match the math done by the ipmitool command,
 // at the other side of the interface:
 // https://github.com/ipmitool/ipmitool/blob/42a023ff0726c80e8cc7d30315b987fe568a981d/lib/ipmi_sdr.c#L360
 //
 // To use with Wolfram Alpha, make all variables single letters
 // bExp becomes E, rExp becomes R
 // https://www.wolframalpha.com/input/?i=y%3D%28%28M*x%29%2B%28B*%2810%5EE%29%29%29*%2810%5ER%29
 bool getSensorAttributes(const double max, const double min, int16_t& mValue,
                          int8_t& rExp, int16_t& bValue, int8_t& bExp,
                          bool& bSigned)
 {
     if (!(std::isfinite(min)))
     {
         std::cerr << "getSensorAttributes: Min value is unusable\n";
         return false;
     }
     if (!(std::isfinite(max)))
     {
         std::cerr << "getSensorAttributes: Max value is unusable\n";
         return false;
     }

     // Because NAN has already been tested for, this comparison works
     if (max <= min)
     {
         std::cerr << "getSensorAttributes: Max must be greater than min\n";
         return false;
     }

     // Given min and max, we must solve for M, B, bExp, rExp
     // y comes in from D-Bus (the actual sensor reading)
     // x is calculated from y by scaleIPMIValueFromDouble() below
     // If y is min, x should equal = 0 (or -128 if signed)
     // If y is max, x should equal 255 (or 127 if signed)
     double fullRange = max - min;
     double lowestX;

     rExp = 0;
     bExp = 0;

     // TODO(): The IPMI document is ambiguous, as to whether
     // the resulting byte should be signed or unsigned,
     // essentially leaving it up to the caller.
     // The document just refers to it as "raw reading",
     // or "byte of reading", without giving further details.
     // Previous code set it signed if min was less than zero,
     // so I'm sticking with that, until I learn otherwise.
     if (min < 0.0)
     {
         // TODO(): It would be worth experimenting with the range (-127,127),
         // instead of the range (-128,127), because this
         // would give good symmetry around zero, and make results look better.
         // Divide by 254 instead of 255, and change -128 to -127 elsewhere.
         bSigned = true;
         lowestX = -128.0;
     }
     else
     {
         bSigned = false;
         lowestX = 0.0;
     }

     // Step 1: Set y to (max - min), set x to 255, set B to 0, solve for M
     // This works, regardless of signed or unsigned,
     // because total range is the same.
     double dM = fullRange / 255.0;

     // Step 2: Constrain M, and set rExp accordingly
     if (!(scaleFloatExp(dM, rExp)))
     {
         std::cerr << "getSensorAttributes: Multiplier range exceeds scale (M="
                   << dM << ", rExp=" << (int)rExp << ")\n";
         return false;
     }

     mValue = static_cast<int16_t>(std::round(dM));

     normalizeIntExp(mValue, rExp, dM);

     // The multiplier can not be zero, for obvious reasons
     if (mValue == 0)
     {
         std::cerr << "getSensorAttributes: Multiplier range below scale\n";
         return false;
     }

     // Step 3: set y to min, set x to min, keep M and rExp, solve for B
     // If negative, x will be -128 (the most negative possible byte), not 0

     // Solve the IPMI equation for B, instead of y
     // https://www.wolframalpha.com/input/?i=solve+y%3D%28%28M*x%29%2B%28B*%2810%5EE%29%29%29*%2810%5ER%29+for+B
     // B = 10^(-rExp - bExp) (y - M 10^rExp x)
     // TODO(): Compare with this alternative solution from SageMathCell
     // https://sagecell.sagemath.org/?z=eJyrtC1LLNJQr1TX5KqAMCuATF8I0xfIdIIwnYDMIteKAggPxAIKJMEFkiACxfk5Zaka0ZUKtrYKGhq-CloKFZoK2goaTkCWhqGBgpaWAkilpqYmQgBklmasjoKTJgDAECTH&lang=sage&interacts=eJyLjgUAARUAuQ==
     double dB = std::pow(10.0, ((-rExp) - bExp)) *
                 (min - ((dM * std::pow(10.0, rExp) * lowestX)));

     // Step 4: Constrain B, and set bExp accordingly
     if (!(scaleFloatExp(dB, bExp)))
     {
         std::cerr << "getSensorAttributes: Offset (B=" << dB
                   << ", bExp=" << (int)bExp
                   << ") exceeds multiplier scale (M=" << dM
                   << ", rExp=" << (int)rExp << ")\n";
         return false;
     }

     bValue = static_cast<int16_t>(std::round(dB));

     normalizeIntExp(bValue, bExp, dB);

     // Unlike the multiplier, it is perfectly OK for bValue to be zero
     return true;
 }

 uint8_t scaleIPMIValueFromDouble(const double value, const int16_t mValue,
                                  const int8_t rExp, const int16_t bValue,
                                  const int8_t bExp, const bool bSigned)
 {
     // Avoid division by zero below
     if (mValue == 0)
     {
         throw std::out_of_range("Scaling multiplier is uninitialized");
     }

     auto dM = static_cast<double>(mValue);
     auto dB = static_cast<double>(bValue);

     // Solve the IPMI equation for x, instead of y
     // https://www.wolframalpha.com/input/?i=solve+y%3D%28%28M*x%29%2B%28B*%2810%5EE%29%29%29*%2810%5ER%29+for+x
     // x = (10^(-rExp) (y - B 10^(rExp + bExp)))/M and M 10^rExp!=0
     // TODO(): Compare with this alternative solution from SageMathCell
     // https://sagecell.sagemath.org/?z=eJyrtC1LLNJQr1TX5KqAMCuATF8I0xfIdIIwnYDMIteKAggPxAIKJMEFkiACxfk5Zaka0ZUKtrYKGhq-CloKFZoK2goaTkCWhqGBgpaWAkilpqYmQgBklmasDlAlAMB8JP0=&lang=sage&interacts=eJyLjgUAARUAuQ==
     double dX =
         (std::pow(10.0, -rExp) * (value - (dB * std::pow(10.0, rExp + bExp)))) /
         dM;

     auto scaledValue = static_cast<int32_t>(std::round(dX));

     int32_t minClamp;
     int32_t maxClamp;

     // Because of rounding and integer truncation of scaling factors,
     // sometimes the resulting byte is slightly out of range.
     // Still allow this, but clamp the values to range.
     if (bSigned)
     {
         minClamp = std::numeric_limits<int8_t>::lowest();
         maxClamp = std::numeric_limits<int8_t>::max();
     }
     else
     {
         minClamp = std::numeric_limits<uint8_t>::lowest();
         maxClamp = std::numeric_limits<uint8_t>::max();
     }

     auto clampedValue = std::clamp(scaledValue, minClamp, maxClamp);

     // This works for both signed and unsigned,
     // because it is the same underlying byte storage.
     return static_cast<uint8_t>(clampedValue);
 }

 uint8_t getScaledIPMIValue(const double value, const double max,
                            const double min)
 {
     int16_t mValue = 0;
     int8_t rExp = 0;
     int16_t bValue = 0;
     int8_t bExp = 0;
     bool bSigned = false;

     bool result =
         getSensorAttributes(max, min, mValue, rExp, bValue, bExp, bSigned);
     if (!result)
     {
         throw std::runtime_error("Illegal sensor attributes");
     }

     return scaleIPMIValueFromDouble(value, mValue, rExp, bValue, bExp, bSigned);
 }

 } // namespace ipmi
	/*
	// Copyright (c) 2017 2018 Intel Corporation
	//
	// 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.
	*/

	#include "dbus-sdr/sensorutils.hpp"

	#include <algorithm>
	#include <cmath>
	#include <iostream>

	namespace ipmi
	{

	// Helper function to avoid repeated complicated expression
	static bool baseInRange(double base)
	{
	auto min10 = static_cast<double>(minInt10);
	auto max10 = static_cast<double>(maxInt10);

	return ((base >= min10) && (base <= max10));
	}

	// Helper function for internal use by getSensorAttributes()
	// Ensures floating-point "base" is within bounds,
	// and adjusts integer exponent "expShift" accordingly.
	// To minimize data loss when later truncating to integer,
	// the floating-point "base" will be as large as possible,
	// but still within the bounds (minInt10,maxInt10).
	// The bounds of "expShift" are (minInt4,maxInt4).
	// Consider this equation: n = base * (10.0 ** expShift)
	// This function will try to maximize "base",
	// adjusting "expShift" to keep the value "n" unchanged,
	// while keeping base and expShift within bounds.
	// Returns true if successful, modifies values in-place
	static bool scaleFloatExp(double& base, int8_t& expShift)
	{
	// Comparing with zero should be OK, zero is special in floating-point
	// If base is exactly zero, no adjustment of the exponent is necessary
	if (base == 0.0)
	{
	return true;
	}

	// As long as base value is within allowed range, expand precision
	// This will help to avoid loss when later rounding to integer
	while (baseInRange(base))
	{
	if (expShift <= minInt4)
	{
	// Already at the minimum expShift, can not decrement it more
	break;
	}

	// Multiply by 10, but shift decimal point to the left, no net change
	base *= 10.0;
	--expShift;
	}

	// As long as base value is not within range, shrink precision
	// This will pull base value closer to zero, thus within range
	while (!(baseInRange(base)))
	{
	if (expShift >= maxInt4)
	{
	// Already at the maximum expShift, can not increment it more
	break;
	}

	// Divide by 10, but shift decimal point to the right, no net change
	base /= 10.0;
	++expShift;
	}

	// If the above loop was not able to pull it back within range,
	// the base value is beyond what expShift can represent, return false.
	return baseInRange(base);
	}

	// Helper function for internal use by getSensorAttributes()
	// Ensures integer "ibase" is no larger than necessary,
	// by normalizing it so that the decimal point shift is in the exponent,
	// whenever possible.
	// This provides more consistent results,
	// as many equivalent solutions are collapsed into one consistent solution.
	// If integer "ibase" is a clean multiple of 10,
	// divide it by 10 (this is lossless), so it is closer to zero.
	// Also modify floating-point "dbase" at the same time,
	// as both integer and floating-point base share the same expShift.
	// Example: (ibase=300, expShift=2) becomes (ibase=3, expShift=4)
	// because the underlying value is the same: 200(102) == 2(10**4)
	// Always successful, modifies values in-place
	static void normalizeIntExp(int16_t& ibase, int8_t& expShift, double& dbase)
	{
	for (;;)
	{
	// If zero, already normalized, ensure exponent also zero
	if (ibase == 0)
	{
	expShift = 0;
	break;
	}

	// If not cleanly divisible by 10, already normalized
	if ((ibase % 10) != 0)
	{
	break;
	}

	// If exponent already at max, already normalized
	if (expShift >= maxInt4)
	{
	break;
	}

	// Bring values closer to zero, correspondingly shift exponent,
	// without changing the underlying number that this all represents,
	// similar to what is done by scaleFloatExp().
	// The floating-point base must be kept in sync with the integer base,
	// as both floating-point and integer share the same exponent.
	ibase /= 10;
	dbase /= 10.0;
	++expShift;
	}
	}

	// The IPMI equation:
	// y = (Mx + (B * 10^(bExp))) * 10^(rExp)
	// Section 36.3 of this document:
	// https://www.intel.com/content/dam/www/public/us/en/documents/product-briefs/ipmi-second-gen-interface-spec-v2-rev1-1.pdf
	//
	// The goal is to exactly match the math done by the ipmitool command,
	// at the other side of the interface:
	// https://github.com/ipmitool/ipmitool/blob/42a023ff0726c80e8cc7d30315b987fe568a981d/lib/ipmi_sdr.c#L360
	//
	// To use with Wolfram Alpha, make all variables single letters
	// bExp becomes E, rExp becomes R
	// https://www.wolframalpha.com/input/?i=y%3D%28%28Mx%29%2B%28B%2810%5EE%29%29%29*%2810%5ER%29
	bool getSensorAttributes(const double max, const double min, int16_t& mValue,
	int8_t& rExp, int16_t& bValue, int8_t& bExp,
	bool& bSigned)
	{
	if (!(std::isfinite(min)))
	{
	std::cerr << "getSensorAttributes: Min value is unusable\n";
	return false;
	}
	if (!(std::isfinite(max)))
	{
	std::cerr << "getSensorAttributes: Max value is unusable\n";
	return false;
	}

	// Because NAN has already been tested for, this comparison works
	if (max <= min)
	{
	std::cerr << "getSensorAttributes: Max must be greater than min\n";
	return false;
	}

	// Given min and max, we must solve for M, B, bExp, rExp
	// y comes in from D-Bus (the actual sensor reading)
	// x is calculated from y by scaleIPMIValueFromDouble() below
	// If y is min, x should equal = 0 (or -128 if signed)
	// If y is max, x should equal 255 (or 127 if signed)
	double fullRange = max - min;
	double lowestX;

	rExp = 0;
	bExp = 0;

	// TODO(): The IPMI document is ambiguous, as to whether
	// the resulting byte should be signed or unsigned,
	// essentially leaving it up to the caller.
	// The document just refers to it as "raw reading",
	// or "byte of reading", without giving further details.
	// Previous code set it signed if min was less than zero,
	// so I'm sticking with that, until I learn otherwise.
	if (min < 0.0)
	{
	// TODO(): It would be worth experimenting with the range (-127,127),
	// instead of the range (-128,127), because this
	// would give good symmetry around zero, and make results look better.
	// Divide by 254 instead of 255, and change -128 to -127 elsewhere.
	bSigned = true;
	lowestX = -128.0;
	}
	else
	{
	bSigned = false;
	lowestX = 0.0;
	}

	// Step 1: Set y to (max - min), set x to 255, set B to 0, solve for M
	// This works, regardless of signed or unsigned,
	// because total range is the same.
	double dM = fullRange / 255.0;

	// Step 2: Constrain M, and set rExp accordingly
	if (!(scaleFloatExp(dM, rExp)))
	{
	std::cerr << "getSensorAttributes: Multiplier range exceeds scale (M="
	<< dM << ", rExp=" << (int)rExp << ")\n";
	return false;
	}

	mValue = static_cast<int16_t>(std::round(dM));

	normalizeIntExp(mValue, rExp, dM);

	// The multiplier can not be zero, for obvious reasons
	if (mValue == 0)
	{
	std::cerr << "getSensorAttributes: Multiplier range below scale\n";
	return false;
	}

	// Step 3: set y to min, set x to min, keep M and rExp, solve for B
	// If negative, x will be -128 (the most negative possible byte), not 0

	// Solve the IPMI equation for B, instead of y
	// https://www.wolframalpha.com/input/?i=solve+y%3D%28%28Mx%29%2B%28B%2810%5EE%29%29%29*%2810%5ER%29+for+B
	// B = 10^(-rExp - bExp) (y - M 10^rExp x)
	// TODO(): Compare with this alternative solution from SageMathCell
	// https://sagecell.sagemath.org/?z=eJyrtC1LLNJQr1TX5KqAMCuATF8I0xfIdIIwnYDMIteKAggPxAIKJMEFkiACxfk5Zaka0ZUKtrYKGhq-CloKFZoK2goaTkCWhqGBgpaWAkilpqYmQgBklmasjoKTJgDAECTH&lang=sage&interacts=eJyLjgUAARUAuQ==
	double dB = std::pow(10.0, ((-rExp) - bExp)) *
	(min - ((dM * std::pow(10.0, rExp) * lowestX)));

	// Step 4: Constrain B, and set bExp accordingly
	if (!(scaleFloatExp(dB, bExp)))
	{
	std::cerr << "getSensorAttributes: Offset (B=" << dB
	<< ", bExp=" << (int)bExp
	<< ") exceeds multiplier scale (M=" << dM
	<< ", rExp=" << (int)rExp << ")\n";
	return false;
	}

	bValue = static_cast<int16_t>(std::round(dB));

	normalizeIntExp(bValue, bExp, dB);

	// Unlike the multiplier, it is perfectly OK for bValue to be zero
	return true;
	}

	uint8_t scaleIPMIValueFromDouble(const double value, const int16_t mValue,
	const int8_t rExp, const int16_t bValue,
	const int8_t bExp, const bool bSigned)
	{
	// Avoid division by zero below
	if (mValue == 0)
	{
	throw std::out_of_range("Scaling multiplier is uninitialized");
	}

	auto dM = static_cast<double>(mValue);
	auto dB = static_cast<double>(bValue);

	// Solve the IPMI equation for x, instead of y
	// https://www.wolframalpha.com/input/?i=solve+y%3D%28%28Mx%29%2B%28B%2810%5EE%29%29%29*%2810%5ER%29+for+x
	// x = (10^(-rExp) (y - B 10^(rExp + bExp)))/M and M 10^rExp!=0
	// TODO(): Compare with this alternative solution from SageMathCell
	// https://sagecell.sagemath.org/?z=eJyrtC1LLNJQr1TX5KqAMCuATF8I0xfIdIIwnYDMIteKAggPxAIKJMEFkiACxfk5Zaka0ZUKtrYKGhq-CloKFZoK2goaTkCWhqGBgpaWAkilpqYmQgBklmasDlAlAMB8JP0=&lang=sage&interacts=eJyLjgUAARUAuQ==
	double dX =
	(std::pow(10.0, -rExp) * (value - (dB * std::pow(10.0, rExp + bExp)))) /
	dM;

	auto scaledValue = static_cast<int32_t>(std::round(dX));

	int32_t minClamp;
	int32_t maxClamp;

	// Because of rounding and integer truncation of scaling factors,
	// sometimes the resulting byte is slightly out of range.
	// Still allow this, but clamp the values to range.
	if (bSigned)
	{
	minClamp = std::numeric_limits<int8_t>::lowest();
	maxClamp = std::numeric_limits<int8_t>::max();
	}
	else
	{
	minClamp = std::numeric_limits<uint8_t>::lowest();
	maxClamp = std::numeric_limits<uint8_t>::max();
	}

	auto clampedValue = std::clamp(scaledValue, minClamp, maxClamp);

	// This works for both signed and unsigned,
	// because it is the same underlying byte storage.
	return static_cast<uint8_t>(clampedValue);
	}

	uint8_t getScaledIPMIValue(const double value, const double max,
	const double min)
	{
	int16_t mValue = 0;
	int8_t rExp = 0;
	int16_t bValue = 0;
	int8_t bExp = 0;
	bool bSigned = false;

	bool result =
	getSensorAttributes(max, min, mValue, rExp, bValue, bExp, bSigned);
	if (!result)
	{
	throw std::runtime_error("Illegal sensor attributes");
	}

	return scaleIPMIValueFromDouble(value, mValue, rExp, bValue, bExp, bSigned);
	}

	} // namespace ipmi