1 files changed, 389 insertions, 0 deletions
diff --git a/libsensors/akmdfs/AKFS_APIs.c b/libsensors/akmdfs/AKFS_APIs.c
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+++ b/libsensors/akmdfs/AKFS_APIs.c
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+/******************************************************************************
+ *
+ * Copyright (C) 2012 Asahi Kasei Microdevices Corporation, Japan
+ *
+ * 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 "AKFS_Common.h"
+#include "AKFS_Disp.h"
+#include "AKFS_FileIO.h"
+#include "AKFS_APIs.h"
+
+#ifdef WIN32
+#include "AK8975_LinuxDriver.h"
+#endif
+
+static AK8975PRMS g_prms;
+
+/*!
+  Initialize library. At first, 0 is set to all parameters.  After that, some
+  parameters, which should not be 0, are set to specific value. Some of initial
+  values can be customized by editing the file \c "AKFS_CSpec.h".
+  @return The return value is #AKM_SUCCESS.
+  @param[in] hpat Specify a layout pattern number.  The number is determined
+  according to the mount orientation of the magnetometer.
+  @param[in] regs[3] Specify the ASA values which are read out from
+  fuse ROM.  regs[0] is ASAX, regs[1] is ASAY, regs[2] is ASAZ.
+ */
+int16 AKFS_Init(
+	const	AKFS_PATNO	hpat,
+	const	uint8		regs[]
+)
+{
+	AKMDATA(AKMDATA_DUMP, "%s: hpat=%d, r[0]=0x%02X, r[1]=0x%02X, r[2]=0x%02X\n",
+		__FUNCTION__, hpat, regs[0], regs[1], regs[2]);
+
+	/* Set 0 to the AK8975 structure. */
+	memset(&g_prms, 0, sizeof(AK8975PRMS));
+
+	/* Sensitivity */
+	g_prms.mfv_hs.u.x = AK8975_HSENSE_DEFAULT;
+	g_prms.mfv_hs.u.y = AK8975_HSENSE_DEFAULT;
+	g_prms.mfv_hs.u.z = AK8975_HSENSE_DEFAULT;
+	g_prms.mfv_as.u.x = AK8975_ASENSE_DEFAULT;
+	g_prms.mfv_as.u.y = AK8975_ASENSE_DEFAULT;
+	g_prms.mfv_as.u.z = AK8975_ASENSE_DEFAULT;
+
+	/* Initialize variables that initial value is not 0. */
+	g_prms.mi_hnaveV = CSPEC_HNAVE_V;
+	g_prms.mi_hnaveD = CSPEC_HNAVE_D;
+	g_prms.mi_anaveV = CSPEC_ANAVE_V;
+	g_prms.mi_anaveD = CSPEC_ANAVE_D;
+
+	/* Copy ASA values */
+	g_prms.mi_asa.u.x = regs[0];
+	g_prms.mi_asa.u.y = regs[1];
+	g_prms.mi_asa.u.z = regs[2];
+
+	/* Copy layout pattern */
+	g_prms.m_hpat = hpat;
+
+	return AKM_SUCCESS;
+}
+
+/*!
+  Release resources. This function is for future expansion.
+  @return The return value is #AKM_SUCCESS.
+ */
+int16 AKFS_Release(void)
+{
+	return AKM_SUCCESS;
+}
+
+/*
+  This function is called just before a measurement sequence starts.
+  This function reads parameters from file, then initializes algorithm
+  parameters.
+  @return The return value is #AKM_SUCCESS.
+  @param[in] path Specify a path to the settings file.
+ */
+int16 AKFS_Start(
+	const char* path
+)
+{
+	AKMDATA(AKMDATA_DUMP, "%s: path=%s\n", __FUNCTION__, path);
+
+	/* Read setting files from a file */
+	if (AKFS_LoadParameters(&g_prms, path) != AKM_SUCCESS) {
+		AKMERROR_STR("AKFS_Load");
+	}
+
+	/* Initialize buffer */
+	AKFS_InitBuffer(AKFS_HDATA_SIZE, g_prms.mfv_hdata);
+	AKFS_InitBuffer(AKFS_HDATA_SIZE, g_prms.mfv_hvbuf);
+	AKFS_InitBuffer(AKFS_ADATA_SIZE, g_prms.mfv_adata);
+	AKFS_InitBuffer(AKFS_ADATA_SIZE, g_prms.mfv_avbuf);
+
+	/* Initialize for AOC */
+	AKFS_InitAOC(&g_prms.m_aocv);
+	/* Initialize magnetic status */
+	g_prms.mi_hstatus = 0;
+
+	return AKM_SUCCESS;
+}
+
+/*!
+  This function is called when a measurement sequence is done.
+  This fucntion writes parameters to file.
+  @return The return value is #AKM_SUCCESS.
+  @param[in] path Specify a path to the settings file.
+ */
+int16 AKFS_Stop(
+	const char* path
+)
+{
+	AKMDATA(AKMDATA_DUMP, "%s: path=%s\n", __FUNCTION__, path);
+
+	/* Write setting files to a file */
+	if (AKFS_SaveParameters(&g_prms, path) != AKM_SUCCESS) {
+		AKMERROR_STR("AKFS_Save");
+	}
+
+	return AKM_SUCCESS;
+}
+
+/*!
+  This function is called when new magnetometer data is available.  The output
+  vector format and coordination system follow the Android definition.
+  @return The return value is #AKM_SUCCESS.
+   Otherwise the return value is #AKM_FAIL.
+  @param[in] mag A set of measurement data from magnetometer.  X axis value
+   should be in mag[0], Y axis value should be in mag[1], Z axis value should be 
+   in mag[2].
+  @param[in] status A status of magnetometer.  This status indicates the result
+   of measurement data, i.e. overflow, success or fail, etc.
+  @param[out] vx X axis value of magnetic field vector.
+  @param[out] vy Y axis value of magnetic field vector.
+  @param[out] vz Z axis value of magnetic field vector.
+  @param[out] accuracy Accuracy of magnetic field vector.
+ */
+int16 AKFS_Get_MAGNETIC_FIELD(
+	const	int16		mag[3],
+	const	int16		status,
+			AKFLOAT*	vx,
+			AKFLOAT*	vy,
+			AKFLOAT*	vz,
+			int16*		accuracy
+)
+{
+	int16 akret;
+	int16 aocret;
+	AKFLOAT radius;
+
+	AKMDATA(AKMDATA_DUMP, "%s: m[0]=%d, m[1]=%d, m[2]=%d, st=%d\n",
+		__FUNCTION__, mag[0], mag[1], mag[2], status);
+
+	/* Decomposition */
+	/* Sensitivity adjustment, i.e. multiply ASA, is done in this function. */
+	akret = AKFS_DecompAK8975(
+		mag,
+		status,
+		&g_prms.mi_asa,
+		AKFS_HDATA_SIZE,
+		g_prms.mfv_hdata
+	);
+	if(akret == AKFS_ERROR) {
+		AKMERROR;
+		return AKM_FAIL;
+	}
+
+	/* Adjust coordination */
+	akret = AKFS_Rotate(
+		g_prms.m_hpat,
+		&g_prms.mfv_hdata[0]
+	);
+	if (akret == AKFS_ERROR) {
+		AKMERROR;
+		return AKM_FAIL;
+	}
+
+	/* AOC for magnetometer */
+	/* Offset estimation is done in this function */
+	aocret = AKFS_AOC(
+		&g_prms.m_aocv,
+		g_prms.mfv_hdata,
+		&g_prms.mfv_ho
+	);
+
+	/* Subtract offset */
+	/* Then, a magnetic vector, the unit is uT, is stored in mfv_hvbuf. */
+	akret = AKFS_VbNorm(
+		AKFS_HDATA_SIZE,
+		g_prms.mfv_hdata,
+		1,
+		&g_prms.mfv_ho,
+		&g_prms.mfv_hs,
+		AK8975_HSENSE_TARGET,
+		AKFS_HDATA_SIZE,
+		g_prms.mfv_hvbuf
+	);
+	if(akret == AKFS_ERROR) {
+		AKMERROR;
+		return AKM_FAIL;
+	}
+
+	/* Averaging */
+	akret = AKFS_VbAve(
+		AKFS_HDATA_SIZE,
+		g_prms.mfv_hvbuf,
+		CSPEC_HNAVE_V,
+		&g_prms.mfv_hvec
+	);
+	if (akret == AKFS_ERROR) {
+		AKMERROR;
+		return AKM_FAIL;
+	}
+
+	/* Check the size of magnetic vector */
+	radius = AKFS_SQRT(
+			(g_prms.mfv_hvec.u.x * g_prms.mfv_hvec.u.x) +
+			(g_prms.mfv_hvec.u.y * g_prms.mfv_hvec.u.y) +
+			(g_prms.mfv_hvec.u.z * g_prms.mfv_hvec.u.z));
+
+	if (radius > AKFS_GEOMAG_MAX) {
+		g_prms.mi_hstatus = 0;
+	} else {
+		if (aocret) {
+			g_prms.mi_hstatus = 3;
+		}
+	}
+
+	*vx = g_prms.mfv_hvec.u.x;
+	*vy = g_prms.mfv_hvec.u.y;
+	*vz = g_prms.mfv_hvec.u.z;
+	*accuracy = g_prms.mi_hstatus;
+
+	/* Debug output */
+	AKMDATA(AKMDATA_MAG, "Mag(%d):%8.2f, %8.2f, %8.2f\n",
+			*accuracy, *vx, *vy, *vz);
+
+	return AKM_SUCCESS;
+}
+
+/*!
+  This function is called when new accelerometer data is available.  The output
+  vector format and coordination system follow the Android definition.
+  @return The return value is #AKM_SUCCESS when function succeeds. Otherwise
+   the return value is #AKM_FAIL.
+  @param[in] acc A set of measurement data from accelerometer.  X axis value
+   should be in acc[0], Y axis value should be in acc[1], Z axis value should be 
+   in acc[2].
+  @param[in] status A status of accelerometer.  This status indicates the result
+   of acceleration data, i.e. overflow, success or fail, etc.
+  @param[out] vx X axis value of acceleration vector.
+  @param[out] vy Y axis value of acceleration vector.
+  @param[out] vz Z axis value of acceleration vector.
+  @param[out] accuracy Accuracy of acceleration vector.
+  This value is always 3.
+ */
+int16 AKFS_Get_ACCELEROMETER(
+	const   int16		acc[3],
+	const	int16		status,
+			AKFLOAT*	vx,
+			AKFLOAT*	vy,
+			AKFLOAT*	vz,
+			int16*		accuracy
+)
+{
+	int16 akret;
+
+	AKMDATA(AKMDATA_DUMP, "%s: a[0]=%d, a[1]=%d, a[2]=%d, st=%d\n",
+		__FUNCTION__, acc[0], acc[1], acc[2], status);
+
+	/* Save data to buffer */
+	AKFS_BufShift(
+		AKFS_ADATA_SIZE,
+		1,
+		g_prms.mfv_adata
+	);
+	g_prms.mfv_adata[0].u.x = acc[0];
+	g_prms.mfv_adata[0].u.y = acc[1];
+	g_prms.mfv_adata[0].u.z = acc[2];
+
+	/* Subtract offset, adjust sensitivity */
+	/* As a result, a unit of acceleration data in mfv_avbuf is '1G = 9.8' */
+	akret = AKFS_VbNorm(
+		AKFS_ADATA_SIZE,
+		g_prms.mfv_adata,
+		1,
+		&g_prms.mfv_ao,
+		&g_prms.mfv_as,
+		AK8975_ASENSE_TARGET,
+		AKFS_ADATA_SIZE,
+		g_prms.mfv_avbuf
+	);
+	if(akret == AKFS_ERROR) {
+		AKMERROR;
+		return AKM_FAIL;
+	}
+
+	/* Averaging */
+	akret = AKFS_VbAve(
+		AKFS_ADATA_SIZE,
+		g_prms.mfv_avbuf,
+		CSPEC_ANAVE_V,
+		&g_prms.mfv_avec
+	);
+	if (akret == AKFS_ERROR) {
+		AKMERROR;
+		return AKM_FAIL;
+	}
+
+	/* Adjust coordination */
+	/* It is not needed. Because, the data from AK8975 driver is already
+	   follows Android coordinate system. */
+
+	*vx = g_prms.mfv_avec.u.x;
+	*vy = g_prms.mfv_avec.u.y;
+	*vz = g_prms.mfv_avec.u.z;
+	*accuracy = 3;
+
+	/* Debug output */
+	AKMDATA(AKMDATA_ACC, "Acc(%d):%8.2f, %8.2f, %8.2f\n",
+			*accuracy, *vx, *vy, *vz);
+
+	return AKM_SUCCESS;
+}
+
+/*!
+  Get orientation sensor's elements. The vector format and coordination system
+   follow the Android definition.  Before this function is called, magnetic
+   field vector and acceleration vector should be stored in the buffer by 
+   calling #AKFS_Get_MAGNETIC_FIELD and #AKFS_Get_ACCELEROMETER.
+  @return The return value is #AKM_SUCCESS when function succeeds. Otherwise
+   the return value is #AKM_FAIL.
+  @param[out] azimuth Azimuthal angle in degree.
+  @param[out] pitch Pitch angle in degree.
+  @param[out] roll Roll angle in degree.
+  @param[out] accuracy Accuracy of orientation sensor.
+ */
+int16 AKFS_Get_ORIENTATION(
+			AKFLOAT*	azimuth,
+			AKFLOAT*	pitch,
+			AKFLOAT*	roll,
+			int16*		accuracy
+)
+{
+	int16 akret;
+
+	/* Azimuth calculation */
+	/* Coordination system follows the Android coordination. */
+	akret = AKFS_Direction(
+		AKFS_HDATA_SIZE,
+		g_prms.mfv_hvbuf,
+		CSPEC_HNAVE_D,
+		AKFS_ADATA_SIZE,
+		g_prms.mfv_avbuf,
+		CSPEC_ANAVE_D,
+		&g_prms.mf_azimuth,
+		&g_prms.mf_pitch,
+		&g_prms.mf_roll
+	);
+
+	if(akret == AKFS_ERROR) {
+		AKMERROR;
+		return AKM_FAIL;
+	}
+	*azimuth  = g_prms.mf_azimuth;
+	*pitch    = g_prms.mf_pitch;
+	*roll     = g_prms.mf_roll;
+	*accuracy = g_prms.mi_hstatus;
+
+	/* Debug output */
+	AKMDATA(AKMDATA_ORI, "Ori(%d):%8.2f, %8.2f, %8.2f\n",
+			*accuracy, *azimuth, *pitch, *roll);
+
+	return AKM_SUCCESS;
+}
+