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/* SPDX-License-Identifier: LGPL-2.1-or-later */
/*
* Copyright (C) 2021, Red Hat
*
* af.cpp - IPU3 auto focus algorithm
*/
#include "af.h"
#include <algorithm>
#include <chrono>
#include <cmath>
#include <fcntl.h>
#include <numeric>
#include <sys/ioctl.h>
#include <sys/stat.h>
#include <sys/types.h>
#include <unistd.h>
#include <linux/videodev2.h>
#include <libcamera/base/log.h>
#include <libcamera/ipa/core_ipa_interface.h>
#include "libipa/histogram.h"
/**
* \file af.h
*/
/*
* Static variables from ChromiumOS Intel Camera HAL and ia_imaging library:
* - https://chromium.googlesource.com/chromiumos/platform/arc-camera/+/master/hal/intel/psl/ipu3/statsConverter/ipu3-stats.h
* - https://chromium.googlesource.com/chromiumos/platform/camera/+/refs/heads/main/hal/intel/ipu3/include/ia_imaging/af_public.h
*/
/** The minimum horizontal grid dimension. */
static constexpr uint8_t kAfMinGridWidth = 16;
/** The minimum vertical grid dimension. */
static constexpr uint8_t kAfMinGridHeight = 16;
/** The maximum horizontal grid dimension. */
static constexpr uint8_t kAfMaxGridWidth = 32;
/** The maximum vertical grid dimension. */
static constexpr uint8_t kAfMaxGridHeight = 24;
/** The minimum value of Log2 of the width of the grid cell. */
static constexpr uint16_t kAfMinGridBlockWidth = 4;
/** The minimum value of Log2 of the height of the grid cell. */
static constexpr uint16_t kAfMinGridBlockHeight = 3;
/** The maximum value of Log2 of the width of the grid cell. */
static constexpr uint16_t kAfMaxGridBlockWidth = 6;
/** The maximum value of Log2 of the height of the grid cell. */
static constexpr uint16_t kAfMaxGridBlockHeight = 6;
/** The number of blocks in vertical axis per slice. */
static constexpr uint16_t kAfDefaultHeightPerSlice = 2;
namespace libcamera {
using namespace std::literals::chrono_literals;
namespace ipa::ipu3::algorithms {
LOG_DEFINE_CATEGORY(IPU3Af)
/**
* Maximum focus steps of the VCM control
* \todo should be obtained from the VCM driver
*/
static constexpr uint32_t kMaxFocusSteps = 1023;
/* Minimum focus step for searching appropriate focus */
static constexpr uint32_t kCoarseSearchStep = 30;
static constexpr uint32_t kFineSearchStep = 1;
/* Max ratio of variance change, 0.0 < kMaxChange < 1.0 */
static constexpr double kMaxChange = 0.5;
/* The numbers of frame to be ignored, before performing focus scan. */
static constexpr uint32_t kIgnoreFrame = 10;
/* Fine scan range 0 < kFineRange < 1 */
static constexpr double kFineRange = 0.05;
/* Settings for IPU3 AF filter */
static struct ipu3_uapi_af_filter_config afFilterConfigDefault = {
.y1_coeff_0 = { 0, 1, 3, 7 },
.y1_coeff_1 = { 11, 13, 1, 2 },
.y1_coeff_2 = { 8, 19, 34, 242 },
.y1_sign_vec = 0x7fdffbfe,
.y2_coeff_0 = { 0, 1, 6, 6 },
.y2_coeff_1 = { 13, 25, 3, 0 },
.y2_coeff_2 = { 25, 3, 177, 254 },
.y2_sign_vec = 0x4e53ca72,
.y_calc = { 8, 8, 8, 8 },
.nf = { 0, 9, 0, 9, 0 },
};
/**
* \class Af
* \brief An auto-focus algorithm based on IPU3 statistics
*
* This algorithm is used to determine the position of the lens to make a
* focused image. The IPU3 AF processing block computes the statistics that
* are composed by two types of filtered value and stores in a AF buffer.
* Typically, for a clear image, it has a relatively higher contrast than a
* blurred one. Therefore, if an image with the highest contrast can be
* found through the scan, the position of the len indicates to a clearest
* image.
*/
Af::Af()
: focus_(0), bestFocus_(0), currentVariance_(0.0), previousVariance_(0.0),
coarseCompleted_(false), fineCompleted_(false)
{
}
/**
* \copydoc libcamera::ipa::Algorithm::prepare
*/
void Af::prepare(IPAContext &context, ipu3_uapi_params *params)
{
const struct ipu3_uapi_grid_config &grid = context.configuration.af.afGrid;
params->acc_param.af.grid_cfg = grid;
params->acc_param.af.filter_config = afFilterConfigDefault;
/* Enable AF processing block */
params->use.acc_af = 1;
}
/**
* \brief Configure the Af given a configInfo
* \param[in] context The shared IPA context
* \param[in] configInfo The IPA configuration data
* \return 0 on success, a negative error code otherwise
*/
int Af::configure(IPAContext &context, const IPAConfigInfo &configInfo)
{
struct ipu3_uapi_grid_config &grid = context.configuration.af.afGrid;
grid.width = kAfMinGridWidth;
grid.height = kAfMinGridHeight;
grid.block_width_log2 = kAfMinGridBlockWidth;
grid.block_height_log2 = kAfMinGridBlockHeight;
/*
* \todo - while this clamping code is effectively a no-op, it satisfies
* the compiler that the constant definitions of the hardware limits
* are used, and paves the way to support dynamic grid sizing in the
* future. While the block_{width,height}_log2 remain assigned to the
* minimum, this code should be optimized out by the compiler.
*/
grid.width = std::clamp(grid.width, kAfMinGridWidth, kAfMaxGridWidth);
grid.height = std::clamp(grid.height, kAfMinGridHeight, kAfMaxGridHeight);
grid.block_width_log2 = std::clamp(grid.block_width_log2,
kAfMinGridBlockWidth,
kAfMaxGridBlockWidth);
grid.block_height_log2 = std::clamp(grid.block_height_log2,
kAfMinGridBlockHeight,
kAfMaxGridBlockHeight);
grid.height_per_slice = kAfDefaultHeightPerSlice;
/* Position the AF grid in the center of the BDS output. */
Rectangle bds(configInfo.bdsOutputSize);
Size gridSize(grid.width << grid.block_width_log2,
grid.height << grid.block_height_log2);
/*
* \todo - Support request metadata
* - Set the ROI based on any input controls in the request
* - Return the AF ROI as metadata in the Request
*/
Rectangle roi = gridSize.centeredTo(bds.center());
Point start = roi.topLeft();
/* x_start and y_start should be even */
grid.x_start = utils::alignDown(start.x, 2);
grid.y_start = utils::alignDown(start.y, 2);
grid.y_start |= IPU3_UAPI_GRID_Y_START_EN;
/* Initial max focus step */
maxStep_ = kMaxFocusSteps;
/* Initial frame ignore counter */
afIgnoreFrameReset();
/* Initial focus value */
context.activeState.af.focus = 0;
/* Maximum variance of the AF statistics */
context.activeState.af.maxVariance = 0;
/* The stable AF value flag. if it is true, the AF should be in a stable state. */
context.activeState.af.stable = false;
return 0;
}
/**
* \brief AF coarse scan
* \param[in] context The shared IPA context
*
* Find a near focused image using a coarse step. The step is determined by
* kCoarseSearchStep.
*/
void Af::afCoarseScan(IPAContext &context)
{
if (coarseCompleted_)
return;
if (afNeedIgnoreFrame())
return;
if (afScan(context, kCoarseSearchStep)) {
coarseCompleted_ = true;
context.activeState.af.maxVariance = 0;
focus_ = context.activeState.af.focus -
(context.activeState.af.focus * kFineRange);
context.activeState.af.focus = focus_;
previousVariance_ = 0;
maxStep_ = std::clamp(focus_ + static_cast<uint32_t>((focus_ * kFineRange)),
0U, kMaxFocusSteps);
}
}
/**
* \brief AF fine scan
* \param[in] context The shared IPA context
*
* Find an optimum lens position with moving 1 step for each search.
*/
void Af::afFineScan(IPAContext &context)
{
if (!coarseCompleted_)
return;
if (afNeedIgnoreFrame())
return;
if (afScan(context, kFineSearchStep)) {
context.activeState.af.stable = true;
fineCompleted_ = true;
}
}
/**
* \brief AF reset
* \param[in] context The shared IPA context
*
* Reset all the parameters to start over the AF process.
*/
void Af::afReset(IPAContext &context)
{
if (afNeedIgnoreFrame())
return;
context.activeState.af.maxVariance = 0;
context.activeState.af.focus = 0;
focus_ = 0;
context.activeState.af.stable = false;
ignoreCounter_ = kIgnoreFrame;
previousVariance_ = 0.0;
coarseCompleted_ = false;
fineCompleted_ = false;
maxStep_ = kMaxFocusSteps;
}
/**
* \brief AF variance comparison.
* \param[in] context The IPA context
* \param[in] min_step The VCM movement step.
*
* We always pick the largest variance to replace the previous one. The image
* with a larger variance also indicates it is a clearer image than previous
* one. If we find a negative derivative, we return immediately.
*
* \return True, if it finds a AF value.
*/
bool Af::afScan(IPAContext &context, int min_step)
{
if (focus_ > maxStep_) {
/* If reach the max step, move lens to the position. */
context.activeState.af.focus = bestFocus_;
return true;
} else {
/*
* Find the maximum of the variance by estimating its
* derivative. If the direction changes, it means we have
* passed a maximum one step before.
*/
if ((currentVariance_ - context.activeState.af.maxVariance) >=
-(context.activeState.af.maxVariance * 0.1)) {
/*
* Positive and zero derivative:
* The variance is still increasing. The focus could be
* increased for the next comparison. Also, the max variance
* and previous focus value are updated.
*/
bestFocus_ = focus_;
focus_ += min_step;
context.activeState.af.focus = focus_;
context.activeState.af.maxVariance = currentVariance_;
} else {
/*
* Negative derivative:
* The variance starts to decrease which means the maximum
* variance is found. Set focus step to previous good one
* then return immediately.
*/
context.activeState.af.focus = bestFocus_;
return true;
}
}
previousVariance_ = currentVariance_;
LOG(IPU3Af, Debug) << " Previous step is "
<< bestFocus_
<< " Current step is "
<< focus_;
return false;
}
/**
* \brief Determine the frame to be ignored.
* \return Return True if the frame should be ignored, false otherwise
*/
bool Af::afNeedIgnoreFrame()
{
if (ignoreCounter_ == 0)
return false;
else
ignoreCounter_--;
return true;
}
/**
* \brief Reset frame ignore counter.
*/
void Af::afIgnoreFrameReset()
{
ignoreCounter_ = kIgnoreFrame;
}
/**
* \brief Estimate variance
* \param[in] y_items The AF filter data set from the IPU3 statistics buffer
* \param[in] isY1 Selects between filter Y1 or Y2 to calculate the variance
*
* Calculate the mean of the data set provided by \a y_item, and then calculate
* the variance of that data set from the mean.
*
* The operation can work on one of two sets of values contained within the
* y_item data set supplied by the IPU3. The two data sets are the results of
* both the Y1 and Y2 filters which are used to support coarse (Y1) and fine
* (Y2) calculations of the contrast.
*
* \return The variance of the values in the data set \a y_item selected by \a isY1
*/
double Af::afEstimateVariance(Span<const y_table_item_t> y_items, bool isY1)
{
uint32_t total = 0;
double mean;
double var_sum = 0;
for (auto y : y_items)
total += isY1 ? y.y1_avg : y.y2_avg;
mean = total / y_items.size();
for (auto y : y_items) {
double avg = isY1 ? y.y1_avg : y.y2_avg;
var_sum += pow(avg - mean, 2);
}
return var_sum / y_items.size();
}
/**
* \brief Determine out-of-focus situation.
* \param[in] context The IPA context.
*
* Out-of-focus means that the variance change rate for a focused and a new
* variance is greater than a threshold.
*
* \return True if the variance threshold is crossed indicating lost focus,
* false otherwise
*/
bool Af::afIsOutOfFocus(IPAContext &context)
{
const uint32_t diff_var = std::abs(currentVariance_ -
context.activeState.af.maxVariance);
const double var_ratio = diff_var / context.activeState.af.maxVariance;
LOG(IPU3Af, Debug) << "Variance change rate: "
<< var_ratio
<< " Current VCM step: "
<< context.activeState.af.focus;
if (var_ratio > kMaxChange)
return true;
else
return false;
}
/**
* \brief Determine the max contrast image and lens position.
* \param[in] context The IPA context.
* \param[in] frameContext The current frame context
* \param[in] stats The statistics buffer of IPU3.
*
* Ideally, a clear image also has a relatively higher contrast. So, every
* image for each focus step should be tested to find an optimal focus step.
*
* The Hill Climbing Algorithm[1] is used to find the maximum variance of the
* AF statistics which is the AF output of IPU3. The focus step is increased
* then the variance of the AF statistics are estimated. If it finds the
* negative derivative we have just passed the peak, and we infer that the best
* focus is found.
*
* [1] Hill Climbing Algorithm, https://en.wikipedia.org/wiki/Hill_climbing
*/
void Af::process(IPAContext &context, [[maybe_unused]] IPAFrameContext *frameContext,
const ipu3_uapi_stats_3a *stats)
{
/* Evaluate the AF buffer length */
uint32_t afRawBufferLen = context.configuration.af.afGrid.width *
context.configuration.af.afGrid.height;
ASSERT(afRawBufferLen < IPU3_UAPI_AF_Y_TABLE_MAX_SIZE);
Span<const y_table_item_t> y_items(reinterpret_cast<const y_table_item_t *>(&stats->af_raw_buffer.y_table),
afRawBufferLen);
/*
* Calculate the mean and the variance of AF statistics for a given grid.
* For coarse: y1 are used.
* For fine: y2 results are used.
*/
currentVariance_ = afEstimateVariance(y_items, !coarseCompleted_);
if (!context.activeState.af.stable) {
afCoarseScan(context);
afFineScan(context);
} else {
if (afIsOutOfFocus(context))
afReset(context);
else
afIgnoreFrameReset();
}
}
REGISTER_IPA_ALGORITHM(Af, "Af")
} /* namespace ipa::ipu3::algorithms */
} /* namespace libcamera */
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