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/* Copyright (c) 2014 The Chromium OS Authors. All rights reserved.
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
/* Motion sense module to read from various motion sensors. */
#include "accelgyro.h"
#include "chipset.h"
#include "common.h"
#include "console.h"
#include "gesture.h"
#include "hooks.h"
#include "host_command.h"
#include "lid_angle.h"
#include "math_util.h"
#include "motion_lid.h"
#include "motion_sense.h"
#include "power.h"
#include "timer.h"
#include "task.h"
#include "util.h"
/* Console output macros */
#define CPUTS(outstr) cputs(CC_MOTION_LID, outstr)
#define CPRINTS(format, args...) cprints(CC_MOTION_LID, format, ## args)
#define CPRINTF(format, args...) cprintf(CC_MOTION_LID, format, ## args)
/* Current acceleration vectors and current lid angle. */
static int lid_angle_deg;
static int lid_angle_is_reliable;
/*
* Angle threshold for how close the hinge aligns with gravity before
* considering the lid angle calculation unreliable. For computational
* efficiency, value is given unit-less, so if you want the threshold to be
* at 15 degrees, the value would be cos(15 deg) = 0.96593.
*/
#define HINGE_ALIGNED_WITH_GRAVITY_THRESHOLD FLOAT_TO_FP(0.96593)
/*
* Define the accelerometer orientation matrices based on the standard
* reference frame in use (note: accel data is converted to standard ref
* frame before calculating lid angle).
*/
#ifdef CONFIG_ACCEL_STD_REF_FRAME_OLD
const struct accel_orientation acc_orient = {
/* Hinge aligns with y axis. */
.rot_hinge_90 = {
{ 0, 0, FLOAT_TO_FP(1)},
{ 0, FLOAT_TO_FP(1), 0},
{ FLOAT_TO_FP(-1), 0, 0}
},
.rot_hinge_180 = {
{ FLOAT_TO_FP(-1), 0, 0},
{ 0, FLOAT_TO_FP(1), 0},
{ 0, 0, FLOAT_TO_FP(-1)}
},
.hinge_axis = {0, 1, 0},
};
#else
const struct accel_orientation acc_orient = {
/* Hinge aligns with x axis. */
.rot_hinge_90 = {
{ FLOAT_TO_FP(1), 0, 0},
{ 0, 0, FLOAT_TO_FP(1)},
{ 0, FLOAT_TO_FP(-1), 0}
},
.rot_hinge_180 = {
{ FLOAT_TO_FP(1), 0, 0},
{ 0, FLOAT_TO_FP(-1), 0},
{ 0, 0, FLOAT_TO_FP(-1)}
},
.hinge_axis = {1, 0, 0},
};
#endif
/* Pointer to constant acceleration orientation data. */
const struct accel_orientation * const p_acc_orient = &acc_orient;
struct motion_sensor_t *accel_base =
&motion_sensors[CONFIG_LID_ANGLE_SENSOR_BASE];
struct motion_sensor_t *accel_lid =
&motion_sensors[CONFIG_LID_ANGLE_SENSOR_LID];
/**
* Calculate the lid angle using two acceleration vectors, one recorded in
* the base and one in the lid.
*
* @param base Base accel vector
* @param lid Lid accel vector
* @param lid_angle Pointer to location to store lid angle result
*
* @return flag representing if resulting lid angle calculation is reliable.
*/
static int calculate_lid_angle(const vector_3_t base, const vector_3_t lid,
int *lid_angle)
{
vector_3_t v;
fp_t ang_lid_to_base, cos_lid_90, cos_lid_270;
fp_t lid_to_base, base_to_hinge;
fp_t denominator;
int reliable = 1;
/*
* The angle between lid and base is:
* acos((cad(base, lid) - cad(base, hinge)^2) /(1 - cad(base, hinge)^2))
* where cad() is the cosine_of_angle_diff() function.
*
* Make sure to check for divide by 0.
*/
lid_to_base = cosine_of_angle_diff(base, lid);
base_to_hinge = cosine_of_angle_diff(base, p_acc_orient->hinge_axis);
/*
* If hinge aligns too closely with gravity, then result may be
* unreliable.
*/
if (fp_abs(base_to_hinge) > HINGE_ALIGNED_WITH_GRAVITY_THRESHOLD)
reliable = 0;
base_to_hinge = fp_sq(base_to_hinge);
/* Check divide by 0. */
denominator = FLOAT_TO_FP(1.0) - base_to_hinge;
if (fp_abs(denominator) < FLOAT_TO_FP(0.01)) {
*lid_angle = 0;
return 0;
}
ang_lid_to_base = arc_cos(fp_div(lid_to_base - base_to_hinge,
denominator));
/*
* The previous calculation actually has two solutions, a positive and
* a negative solution. To figure out the sign of the answer, calculate
* the cosine of the angle between the actual lid angle and the
* estimated vector if the lid were open to 90 deg, cos_lid_90. Also
* calculate the cosine of the angle between the actual lid angle and
* the estimated vector if the lid were open to 270 deg,
* cos_lid_270. The smaller of the two angles represents which one is
* closer. If the lid is closer to the estimated 270 degree vector then
* the result is negative, otherwise it is positive.
*/
rotate(base, p_acc_orient->rot_hinge_90, v);
cos_lid_90 = cosine_of_angle_diff(v, lid);
rotate(v, p_acc_orient->rot_hinge_180, v);
cos_lid_270 = cosine_of_angle_diff(v, lid);
/*
* Note that cos_lid_90 and cos_lid_270 are not in degrees, because
* the arc_cos() was never performed. But, since arc_cos() is
* monotonically decreasing, we can do this comparison without ever
* taking arc_cos(). But, since the function is monotonically
* decreasing, the logic of this comparison is reversed.
*/
if (cos_lid_270 > cos_lid_90)
ang_lid_to_base = -ang_lid_to_base;
/* Place lid angle between 0 and 360 degrees. */
if (ang_lid_to_base < 0)
ang_lid_to_base += FLOAT_TO_FP(360);
/*
* Round to nearest int by adding 0.5. Note, only works because lid
* angle is known to be positive.
*/
*lid_angle = FP_TO_INT(ang_lid_to_base + FLOAT_TO_FP(0.5));
return reliable;
}
int motion_lid_get_angle(void)
{
if (lid_angle_is_reliable)
return lid_angle_deg;
else
return LID_ANGLE_UNRELIABLE;
}
/*
* Calculate lid angle and massage the results
*/
void motion_lid_calc(void)
{
#ifndef CONFIG_ACCEL_STD_REF_FRAME_OLD
/*
* rotate lid vector by 180 deg to be in the right coordinate frame
* because calculate_lid_angle assumes when the lid is closed, that
* the lid and base accelerometer data matches
*/
vector_3_t lid = { accel_lid->xyz[X],
accel_lid->xyz[Y] * -1,
accel_lid->xyz[Z] * -1};
/* Calculate angle of lid accel. */
lid_angle_is_reliable = calculate_lid_angle(
accel_base->xyz, lid,
&lid_angle_deg);
#else
/* Calculate angle of lid accel. */
lid_angle_is_reliable = calculate_lid_angle(
accel_base->xyz, accel_lid->xyz,
&lid_angle_deg);
#endif
#ifdef CONFIG_LID_ANGLE_UPDATE
lid_angle_update(motion_lid_get_angle());
#endif
}
/*****************************************************************************/
/* Host commands */
int host_cmd_motion_lid(struct host_cmd_handler_args *args)
{
const struct ec_params_motion_sense *in = args->params;
struct ec_response_motion_sense *out = args->response;
switch (in->cmd) {
case MOTIONSENSE_CMD_KB_WAKE_ANGLE:
#ifdef CONFIG_LID_ANGLE_UPDATE
/* Set new keyboard wake lid angle if data arg has value. */
if (in->kb_wake_angle.data != EC_MOTION_SENSE_NO_VALUE)
lid_angle_set_wake_angle(in->kb_wake_angle.data);
out->kb_wake_angle.ret = lid_angle_get_wake_angle();
#else
out->kb_wake_angle.ret = 0;
#endif
args->response_size = sizeof(out->kb_wake_angle);
break;
case MOTIONSENSE_CMD_LID_ANGLE:
#ifdef CONFIG_LID_ANGLE
out->lid_angle.value = motion_lid_get_angle();
args->response_size = sizeof(out->lid_angle);
#else
return EC_RES_INVALID_PARAM;
#endif
break;
default:
return EC_RES_INVALID_PARAM;
}
return EC_RES_SUCCESS;
}
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