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kernel/eka/euser/maths/um_sin.cpp
author Mike Kinghan <mikek@symbian.org>
Tue, 16 Nov 2010 14:39:21 +0000
branchGCC_SURGE
changeset 303 9b85206a602c
parent 0 a41df078684a
permissions -rw-r--r--
We need a way to pass flags to rombuilds in Raptor via extension flm interfaces, so that the CPP pass of the rom input files can be informed what toolchain we are building with and conditionally include or exclude files depending on whether the toolchain could build them.

// Copyright (c) 1995-2009 Nokia Corporation and/or its subsidiary(-ies).
// All rights reserved.
// This component and the accompanying materials are made available
// under the terms of the License "Eclipse Public License v1.0"
// which accompanies this distribution, and is available
// at the URL "http://www.eclipse.org/legal/epl-v10.html".
//
// Initial Contributors:
// Nokia Corporation - initial contribution.
//
// Contributors:
//
// Description:
// e32\euser\maths\um_sin.cpp
// Floating point sine and cosine functions
// 
//

#include "um_std.h"

#if defined(__USE_VFP_MATH) && !defined(__CPU_HAS_VFP)
#error	__USE_VFP_MATH was defined but not __CPU_HAS_VFP - impossible combination, check variant.mmh 
#endif


#ifndef __USE_VFP_MATH

LOCAL_D const TUint32 SinCoeffs[] =
	{
	0x2168C235,0xC90FDAA2,0x80000000,	// polynomial approximation to sin(pi*x)
	0x2DF200BF,0xA55DE731,0x80010001,	// for |x| <= 0.25
	0xAC273AA1,0xA335E33B,0x80000000,
	0x5AB23F44,0x99696671,0x7FFE0001,
	0xD585EAFE,0xA83C17D9,0x7FFB0000,
	0xA30DE7AD,0xF1802BAC,0x7FF70001,
	0xF57FD821,0xF1F6A1C9,0x7FF30000
	};

LOCAL_D const TUint32 CosCoeffs[] =
	{
	0x00000000,0x80000000,0x7FFF0000,	// polynomial approximation to cos(pi*x)
	0xF22EF286,0x9DE9E64D,0x80010001,	// for |x| <= 0.25
	0xDAD59F90,0x81E0F840,0x80010000,
	0xE4E45144,0xAAE9E3F1,0x7FFF0001,
	0x3232D733,0xF0FA8342,0x7FFC0000,
	0x03E16BB8,0xD368F6A3,0x7FF90001,
	0x712FD084,0xFCE66DE2,0x7FF50000,
	0x9E5353EE,0xD94951B0,0x7FF10001
	};

LOCAL_D const TUint32 PiInvdata[] = {0x4E44152A,0xA2F9836E,0x7FFD0000};			// 1/pi
LOCAL_D const TUint32 Halfdata[] = {0x00000000,0x80000000,0x7FFE0000};			// 0.5
LOCAL_D const TUint32 Onedata[] = {0x00000000,0x80000000,0x7FFF0000};			// 1.0

LOCAL_C TInt CalcSinCos(TReal& aTrg, TRealX& aSrc, TBool aCos)
	{
	// Calculate sin(aSrc) if aCos=false or cos(aSrc) if aCos=true
	// and write result to aTrg.
	// Algorithm:
	//		Divide aSrc by pi and throw away integer part, but change sign
	//			of result if integer part odd. Replace aSrc with remainder.
	//			( use identities	sin(x+n*pi)=(-1)^n*sin(x)
	//								cos(x+n*pi)=(-1)^n*cos(x) )
	//		If aSrc>=0.5 replace aSrc with 1-aSrc, and change sign of result
	//			if cos required.
	//			( use identities sin(pi-x)=sin(x), cos(pi-x)=-cos(x) )
	//		If aSrc>=0.25 replace aSrc with 0.5-aSrc and swap sin and cos
	//			( use identities sin(pi/2-x)=cos(x), cos(pi/2-x)=sin(x) )
	//		Use polynomial approximation to evaluate sin(pi*x) or cos(pi*x)
	//		for |x|<=0.25

	const TRealX& One = *(const TRealX*)Onedata;
	const TRealX& Half = *(const TRealX*)Halfdata;
	const TRealX& PiInv = *(const TRealX*)PiInvdata;

	TRealX y;
	aSrc*=PiInv;
	TInt n=(TInt)aSrc;
	if (n<KMaxTInt && n>KMinTInt)
		{
		aSrc-=TRealX(n);
		TInt sign=0;
		if (!aCos)
			sign=aSrc.iSign & 1;
		sign^=n;
		aSrc.iSign=0;
		if (aSrc.iExp>=0x7FFE)			// if remainder>=pi/2
			{
			aSrc=One-aSrc;
			if (aCos)
				sign^=1;
			}
		if (aSrc.iExp>=0x7FFD)			// if remainder>=pi/4
			{
			aSrc=Half-aSrc;				// take complementary angle
			aCos=!aCos;					// and swap sin and cos
			}
		if (aCos)
			Math::PolyX(y,aSrc*aSrc,7,(const TRealX*)CosCoeffs);
		else
			{
			Math::PolyX(y,aSrc*aSrc,6,(const TRealX*)SinCoeffs);
			y*=aSrc;
			}
		if (sign & 1)
			y=-y;
		return y.GetTReal(aTrg);
		}
	return KErrArgument;
	}




EXPORT_C TInt Math::Sin(TReal& aTrg, const TReal& aSrc)
/**
Calculates the sine of a number.

@param aTrg A reference containing the result. 
@param aSrc The argument of the sin function in radians.

@return KErrNone if successful, otherwise another of
        the system-wide error codes.
*/
	{
	TRealX x;
	TInt r=x.Set(aSrc);
	if (r==KErrNone)
		r=CalcSinCos(aTrg,x,EFalse);
	if (r==KErrNone)
		return r;
	SetNaN(aTrg);
	return KErrArgument;
	}




EXPORT_C TInt Math::Cos(TReal& aTrg, const TReal& aSrc)
/**
Calculates the cosine of a number.

@param aTrg A reference containing the result. 
@param aSrc The argument of the cos function in radians

@return KErrNone if successful, otherwise another of
        the system-wide error codes.
*/
	{
	TRealX x;
	TInt r=x.Set(aSrc);
	if (r==KErrNone)
		r=CalcSinCos(aTrg,x,ETrue);
	if (r==KErrNone)
		return r;
	SetNaN(aTrg);
	return KErrArgument;
	}

#else // __USE_VFP_MATH

// definitions come from RVCT math library
extern "C" TReal sin(TReal);
extern "C" TReal cos(TReal);

EXPORT_C TInt Math::Sin(TReal& aTrg, const TReal& aSrc)
	{
	if (aSrc<KMaxTInt && aSrc>KMinTInt)
		{
		aTrg = sin(aSrc);
		if (Math::IsFinite(aTrg))
			return KErrNone;
		}
	SetNaN(aTrg);
	return KErrArgument;
	}

EXPORT_C TInt Math::Cos(TReal& aTrg, const TReal& aSrc)
	{
	if (aSrc<KMaxTInt && aSrc>KMinTInt)
		{
		aTrg = cos(aSrc);
		if (Math::IsFinite(aTrg))
			return KErrNone;
		}
	SetNaN(aTrg);
	return KErrArgument;
	}

#endif
FCL/sf/os/kernelhwsrv