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linux / linux / kernel / git / brauner / linux / 647412daeb454b6dad12a6c6961ab90aac9e5d29 / . / drivers / staging / media / atomisp / pci / runtime / inputfifo / src / inputfifo.c
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// SPDX-License-Identifier: GPL-2.0
/*
* Support for Intel Camera Imaging ISP subsystem.
* Copyright (c) 2010 - 2015, Intel Corporation.
*
* This program is free software; you can redistribute it and/or modify it
* under the terms and conditions of the GNU General Public License,
* version 2, as published by the Free Software Foundation.
*
* This program is distributed in the hope it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
* more details.
*/
#include "platform_support.h"
#include "ia_css_inputfifo.h"
#include "device_access.h"
#define __INLINE_SP__
#include "sp.h"
#define __INLINE_ISP__
#include "isp.h"
#define __INLINE_IRQ__
#include "irq.h"
#define __INLINE_FIFO_MONITOR__
#include "fifo_monitor.h"
#define __INLINE_EVENT__
#include "event_fifo.h"
#define __INLINE_SP__
#if !defined(HAS_NO_INPUT_SYSTEM)
#include "input_system.h" /* MIPI_PREDICTOR_NONE,... */
#endif
#include "assert_support.h"
/* System independent */
#include "sh_css_internal.h"
#if !defined(HAS_NO_INPUT_SYSTEM)
#include "ia_css_isys.h"
#endif
#define HBLANK_CYCLES (187)
#define MARKER_CYCLES (6)
#if !defined(HAS_NO_INPUT_SYSTEM)
#include <hive_isp_css_streaming_to_mipi_types_hrt.h>
#endif
/* The data type is used to send special cases:
* yuv420: odd lines (1, 3 etc) are twice as wide as even
* lines (0, 2, 4 etc).
* rgb: for two pixels per clock, the R and B values are sent
* to output_0 while only G is sent to output_1. This means
* that output_1 only gets half the number of values of output_0.
* WARNING: This type should also be used for Legacy YUV420.
* regular: used for all other data types (RAW, YUV422, etc)
*/
enum inputfifo_mipi_data_type {
inputfifo_mipi_data_type_regular,
inputfifo_mipi_data_type_yuv420,
inputfifo_mipi_data_type_yuv420_legacy,
inputfifo_mipi_data_type_rgb,
};
#if !defined(HAS_NO_INPUT_SYSTEM)
static unsigned int inputfifo_curr_ch_id, inputfifo_curr_fmt_type;
#endif
struct inputfifo_instance {
unsigned int ch_id;
enum atomisp_input_format input_format;
bool two_ppc;
bool streaming;
unsigned int hblank_cycles;
unsigned int marker_cycles;
unsigned int fmt_type;
enum inputfifo_mipi_data_type type;
};
#if !defined(HAS_NO_INPUT_SYSTEM)
/*
* Maintain a basic streaming to Mipi administration with ch_id as index
* ch_id maps on the "Mipi virtual channel ID" and can have value 0..3
*/
#define INPUTFIFO_NR_OF_S2M_CHANNELS (4)
static struct inputfifo_instance
inputfifo_inst_admin[INPUTFIFO_NR_OF_S2M_CHANNELS];
/* Streaming to MIPI */
static unsigned int inputfifo_wrap_marker(
/* static inline unsigned inputfifo_wrap_marker( */
unsigned int marker)
{
return marker |
(inputfifo_curr_ch_id << HIVE_STR_TO_MIPI_CH_ID_LSB) |
(inputfifo_curr_fmt_type << _HIVE_STR_TO_MIPI_FMT_TYPE_LSB);
}
static inline void
_sh_css_fifo_snd(unsigned int token)
{
while (!can_event_send_token(STR2MIPI_EVENT_ID))
udelay(1);
event_send_token(STR2MIPI_EVENT_ID, token);
return;
}
static void inputfifo_send_data_a(
/* static inline void inputfifo_send_data_a( */
unsigned int data)
{
unsigned int token = (1 << HIVE_STR_TO_MIPI_VALID_A_BIT) |
(data << HIVE_STR_TO_MIPI_DATA_A_LSB);
_sh_css_fifo_snd(token);
return;
}
static void inputfifo_send_data_b(
/* static inline void inputfifo_send_data_b( */
unsigned int data)
{
unsigned int token = (1 << HIVE_STR_TO_MIPI_VALID_B_BIT) |
(data << _HIVE_STR_TO_MIPI_DATA_B_LSB);
_sh_css_fifo_snd(token);
return;
}
static void inputfifo_send_data(
/* static inline void inputfifo_send_data( */
unsigned int a,
unsigned int b)
{
unsigned int token = ((1 << HIVE_STR_TO_MIPI_VALID_A_BIT) |
(1 << HIVE_STR_TO_MIPI_VALID_B_BIT) |
(a << HIVE_STR_TO_MIPI_DATA_A_LSB) |
(b << _HIVE_STR_TO_MIPI_DATA_B_LSB));
_sh_css_fifo_snd(token);
return;
}
static void inputfifo_send_sol(void)
/* static inline void inputfifo_send_sol(void) */
{
hrt_data token = inputfifo_wrap_marker(
1 << HIVE_STR_TO_MIPI_SOL_BIT);
_sh_css_fifo_snd(token);
return;
}
static void inputfifo_send_eol(void)
/* static inline void inputfifo_send_eol(void) */
{
hrt_data token = inputfifo_wrap_marker(
1 << HIVE_STR_TO_MIPI_EOL_BIT);
_sh_css_fifo_snd(token);
return;
}
static void inputfifo_send_sof(void)
/* static inline void inputfifo_send_sof(void) */
{
hrt_data token = inputfifo_wrap_marker(
1 << HIVE_STR_TO_MIPI_SOF_BIT);
_sh_css_fifo_snd(token);
return;
}
static void inputfifo_send_eof(void)
/* static inline void inputfifo_send_eof(void) */
{
hrt_data token = inputfifo_wrap_marker(
1 << HIVE_STR_TO_MIPI_EOF_BIT);
_sh_css_fifo_snd(token);
return;
}
static void inputfifo_send_ch_id_and_fmt_type(
/* static inline
void inputfifo_send_ch_id_and_fmt_type( */
unsigned int ch_id,
unsigned int fmt_type)
{
hrt_data token;
inputfifo_curr_ch_id = ch_id & _HIVE_ISP_CH_ID_MASK;
inputfifo_curr_fmt_type = fmt_type & _HIVE_ISP_FMT_TYPE_MASK;
/* we send an zero marker, this will wrap the ch_id and
* fmt_type automatically.
*/
token = inputfifo_wrap_marker(0);
_sh_css_fifo_snd(token);
return;
}
static void inputfifo_send_empty_token(void)
/* static inline void inputfifo_send_empty_token(void) */
{
hrt_data token = inputfifo_wrap_marker(0);
_sh_css_fifo_snd(token);
return;
}
static void inputfifo_start_frame(
/* static inline void inputfifo_start_frame( */
unsigned int ch_id,
unsigned int fmt_type)
{
inputfifo_send_ch_id_and_fmt_type(ch_id, fmt_type);
inputfifo_send_sof();
return;
}
static void inputfifo_end_frame(
unsigned int marker_cycles)
{
unsigned int i;
for (i = 0; i < marker_cycles; i++)
inputfifo_send_empty_token();
inputfifo_send_eof();
return;
}
static void inputfifo_send_line2(
const unsigned short *data,
unsigned int width,
const unsigned short *data2,
unsigned int width2,
unsigned int hblank_cycles,
unsigned int marker_cycles,
unsigned int two_ppc,
enum inputfifo_mipi_data_type type)
{
unsigned int i, is_rgb = 0, is_legacy = 0;
assert(data);
assert((data2) || (width2 == 0));
if (type == inputfifo_mipi_data_type_rgb)
is_rgb = 1;
if (type == inputfifo_mipi_data_type_yuv420_legacy)
is_legacy = 1;
for (i = 0; i < hblank_cycles; i++)
inputfifo_send_empty_token();
inputfifo_send_sol();
for (i = 0; i < marker_cycles; i++)
inputfifo_send_empty_token();
for (i = 0; i < width; i++, data++) {
/* for RGB in two_ppc, we only actually send 2 pixels per
* clock in the even pixels (0, 2 etc). In the other cycles,
* we only send 1 pixel, to data[0].
*/
unsigned int send_two_pixels = two_ppc;
if ((is_rgb || is_legacy) && (i % 3 == 2))
send_two_pixels = 0;
if (send_two_pixels) {
if (i + 1 == width) {
/* for jpg (binary) copy, this can occur
* if the file contains an odd number of bytes.
*/
inputfifo_send_data(
data[0], 0);
} else {
inputfifo_send_data(
data[0], data[1]);
}
/* Additional increment because we send 2 pixels */
data++;
i++;
} else if (two_ppc && is_legacy) {
inputfifo_send_data_b(data[0]);
} else {
inputfifo_send_data_a(data[0]);
}
}
for (i = 0; i < width2; i++, data2++) {
/* for RGB in two_ppc, we only actually send 2 pixels per
* clock in the even pixels (0, 2 etc). In the other cycles,
* we only send 1 pixel, to data2[0].
*/
unsigned int send_two_pixels = two_ppc;
if ((is_rgb || is_legacy) && (i % 3 == 2))
send_two_pixels = 0;
if (send_two_pixels) {
if (i + 1 == width2) {
/* for jpg (binary) copy, this can occur
* if the file contains an odd number of bytes.
*/
inputfifo_send_data(
data2[0], 0);
} else {
inputfifo_send_data(
data2[0], data2[1]);
}
/* Additional increment because we send 2 pixels */
data2++;
i++;
} else if (two_ppc && is_legacy) {
inputfifo_send_data_b(data2[0]);
} else {
inputfifo_send_data_a(data2[0]);
}
}
for (i = 0; i < hblank_cycles; i++)
inputfifo_send_empty_token();
inputfifo_send_eol();
return;
}
static void
inputfifo_send_line(const unsigned short *data,
unsigned int width,
unsigned int hblank_cycles,
unsigned int marker_cycles,
unsigned int two_ppc,
enum inputfifo_mipi_data_type type)
{
assert(data);
inputfifo_send_line2(data, width, NULL, 0,
hblank_cycles,
marker_cycles,
two_ppc,
type);
}
/* Send a frame of data into the input network via the GP FIFO.
* Parameters:
* - data: array of 16 bit values that contains all data for the frame.
* - width: width of a line in number of subpixels, for yuv420 it is the
* number of Y components per line.
* - height: height of the frame in number of lines.
* - ch_id: channel ID.
* - fmt_type: format type.
* - hblank_cycles: length of horizontal blanking in cycles.
* - marker_cycles: number of empty cycles after start-of-line and before
* end-of-frame.
* - two_ppc: boolean, describes whether to send one or two pixels per clock
* cycle. In this mode, we sent pixels N and N+1 in the same cycle,
* to IF_PRIM_A and IF_PRIM_B respectively. The caller must make
* sure the input data has been formatted correctly for this.
* For example, for RGB formats this means that unused values
* must be inserted.
* - yuv420: boolean, describes whether (non-legacy) yuv420 data is used. In
* this mode, the odd lines (1,3,5 etc) are half as long as the
* even lines (2,4,6 etc).
* Note that the first line is odd (1) and the second line is even
* (2).
*
* This function does not do any reordering of pixels, the caller must make
* sure the data is in the righ format. Please refer to the CSS receiver
* documentation for details on the data formats.
*/
static void inputfifo_send_frame(
const unsigned short *data,
unsigned int width,
unsigned int height,
unsigned int ch_id,
unsigned int fmt_type,
unsigned int hblank_cycles,
unsigned int marker_cycles,
unsigned int two_ppc,
enum inputfifo_mipi_data_type type)
{
unsigned int i;
assert(data);
inputfifo_start_frame(ch_id, fmt_type);
for (i = 0; i < height; i++) {
if ((type == inputfifo_mipi_data_type_yuv420) &&
(i & 1) == 1) {
inputfifo_send_line(data, 2 * width,
hblank_cycles,
marker_cycles,
two_ppc, type);
data += 2 * width;
} else {
inputfifo_send_line(data, width,
hblank_cycles,
marker_cycles,
two_ppc, type);
data += width;
}
}
inputfifo_end_frame(marker_cycles);
return;
}
static enum inputfifo_mipi_data_type inputfifo_determine_type(
enum atomisp_input_format input_format)
{
enum inputfifo_mipi_data_type type;
type = inputfifo_mipi_data_type_regular;
if (input_format == ATOMISP_INPUT_FORMAT_YUV420_8_LEGACY) {
type =
inputfifo_mipi_data_type_yuv420_legacy;
} else if (input_format == ATOMISP_INPUT_FORMAT_YUV420_8 ||
input_format == ATOMISP_INPUT_FORMAT_YUV420_10 ||
input_format == ATOMISP_INPUT_FORMAT_YUV420_16) {
type =
inputfifo_mipi_data_type_yuv420;
} else if (input_format >= ATOMISP_INPUT_FORMAT_RGB_444 &&
input_format <= ATOMISP_INPUT_FORMAT_RGB_888) {
type =
inputfifo_mipi_data_type_rgb;
}
return type;
}
static struct inputfifo_instance *inputfifo_get_inst(
unsigned int ch_id)
{
return &inputfifo_inst_admin[ch_id];
}
void ia_css_inputfifo_send_input_frame(
const unsigned short *data,
unsigned int width,
unsigned int height,
unsigned int ch_id,
enum atomisp_input_format input_format,
bool two_ppc)
{
unsigned int fmt_type, hblank_cycles, marker_cycles;
enum inputfifo_mipi_data_type type;
assert(data);
hblank_cycles = HBLANK_CYCLES;
marker_cycles = MARKER_CYCLES;
ia_css_isys_convert_stream_format_to_mipi_format(input_format,
MIPI_PREDICTOR_NONE,
&fmt_type);
type = inputfifo_determine_type(input_format);
inputfifo_send_frame(data, width, height,
ch_id, fmt_type, hblank_cycles, marker_cycles,
two_ppc, type);
}
void ia_css_inputfifo_start_frame(
unsigned int ch_id,
enum atomisp_input_format input_format,
bool two_ppc)
{
struct inputfifo_instance *s2mi;
s2mi = inputfifo_get_inst(ch_id);
s2mi->ch_id = ch_id;
ia_css_isys_convert_stream_format_to_mipi_format(input_format,
MIPI_PREDICTOR_NONE,
&s2mi->fmt_type);
s2mi->two_ppc = two_ppc;
s2mi->type = inputfifo_determine_type(input_format);
s2mi->hblank_cycles = HBLANK_CYCLES;
s2mi->marker_cycles = MARKER_CYCLES;
s2mi->streaming = true;
inputfifo_start_frame(ch_id, s2mi->fmt_type);
return;
}
void ia_css_inputfifo_send_line(
unsigned int ch_id,
const unsigned short *data,
unsigned int width,
const unsigned short *data2,
unsigned int width2)
{
struct inputfifo_instance *s2mi;
assert(data);
assert((data2) || (width2 == 0));
s2mi = inputfifo_get_inst(ch_id);
/* Set global variables that indicate channel_id and format_type */
inputfifo_curr_ch_id = (s2mi->ch_id) & _HIVE_ISP_CH_ID_MASK;
inputfifo_curr_fmt_type = (s2mi->fmt_type) & _HIVE_ISP_FMT_TYPE_MASK;
inputfifo_send_line2(data, width, data2, width2,
s2mi->hblank_cycles,
s2mi->marker_cycles,
s2mi->two_ppc,
s2mi->type);
}
void ia_css_inputfifo_send_embedded_line(
unsigned int ch_id,
enum atomisp_input_format data_type,
const unsigned short *data,
unsigned int width)
{
struct inputfifo_instance *s2mi;
unsigned int fmt_type;
assert(data);
s2mi = inputfifo_get_inst(ch_id);
ia_css_isys_convert_stream_format_to_mipi_format(data_type,
MIPI_PREDICTOR_NONE, &fmt_type);
/* Set format_type for metadata line. */
inputfifo_curr_fmt_type = fmt_type & _HIVE_ISP_FMT_TYPE_MASK;
inputfifo_send_line(data, width, s2mi->hblank_cycles, s2mi->marker_cycles,
s2mi->two_ppc, inputfifo_mipi_data_type_regular);
}
void ia_css_inputfifo_end_frame(
unsigned int ch_id)
{
struct inputfifo_instance *s2mi;
s2mi = inputfifo_get_inst(ch_id);
/* Set global variables that indicate channel_id and format_type */
inputfifo_curr_ch_id = (s2mi->ch_id) & _HIVE_ISP_CH_ID_MASK;
inputfifo_curr_fmt_type = (s2mi->fmt_type) & _HIVE_ISP_FMT_TYPE_MASK;
/* Call existing HRT function */
inputfifo_end_frame(s2mi->marker_cycles);
s2mi->streaming = false;
return;
}
#endif /* #if !defined(HAS_NO_INPUT_SYSTEM) */