diff options
Diffstat (limited to 'drivers/staging/media/tegra-video/tegra210.c')
-rw-r--r-- | drivers/staging/media/tegra-video/tegra210.c | 1131 |
1 files changed, 1131 insertions, 0 deletions
diff --git a/drivers/staging/media/tegra-video/tegra210.c b/drivers/staging/media/tegra-video/tegra210.c new file mode 100644 index 000000000..d58370a84 --- /dev/null +++ b/drivers/staging/media/tegra-video/tegra210.c @@ -0,0 +1,1131 @@ +// SPDX-License-Identifier: GPL-2.0-only +/* + * Copyright (C) 2020 NVIDIA CORPORATION. All rights reserved. + */ + +/* + * This source file contains Tegra210 supported video formats, + * VI and CSI SoC specific data, operations and registers accessors. + */ +#include <linux/bitfield.h> +#include <linux/clk.h> +#include <linux/clk/tegra.h> +#include <linux/delay.h> +#include <linux/host1x.h> +#include <linux/kthread.h> + +#include "csi.h" +#include "vi.h" + +#define TEGRA_VI_SYNCPT_WAIT_TIMEOUT msecs_to_jiffies(200) + +/* Tegra210 VI registers */ +#define TEGRA_VI_CFG_VI_INCR_SYNCPT 0x000 +#define VI_CFG_VI_INCR_SYNCPT_COND(x) (((x) & 0xff) << 8) +#define VI_CSI_PP_FRAME_START(port) (5 + (port) * 4) +#define VI_CSI_MW_ACK_DONE(port) (7 + (port) * 4) +#define TEGRA_VI_CFG_VI_INCR_SYNCPT_CNTRL 0x004 +#define VI_INCR_SYNCPT_NO_STALL BIT(8) +#define TEGRA_VI_CFG_VI_INCR_SYNCPT_ERROR 0x008 +#define TEGRA_VI_CFG_CG_CTRL 0x0b8 +#define VI_CG_2ND_LEVEL_EN 0x1 + +/* Tegra210 VI CSI registers */ +#define TEGRA_VI_CSI_SW_RESET 0x000 +#define TEGRA_VI_CSI_SINGLE_SHOT 0x004 +#define SINGLE_SHOT_CAPTURE 0x1 +#define TEGRA_VI_CSI_IMAGE_DEF 0x00c +#define BYPASS_PXL_TRANSFORM_OFFSET 24 +#define IMAGE_DEF_FORMAT_OFFSET 16 +#define IMAGE_DEF_DEST_MEM 0x1 +#define TEGRA_VI_CSI_IMAGE_SIZE 0x018 +#define IMAGE_SIZE_HEIGHT_OFFSET 16 +#define TEGRA_VI_CSI_IMAGE_SIZE_WC 0x01c +#define TEGRA_VI_CSI_IMAGE_DT 0x020 +#define TEGRA_VI_CSI_SURFACE0_OFFSET_MSB 0x024 +#define TEGRA_VI_CSI_SURFACE0_OFFSET_LSB 0x028 +#define TEGRA_VI_CSI_SURFACE1_OFFSET_MSB 0x02c +#define TEGRA_VI_CSI_SURFACE1_OFFSET_LSB 0x030 +#define TEGRA_VI_CSI_SURFACE2_OFFSET_MSB 0x034 +#define TEGRA_VI_CSI_SURFACE2_OFFSET_LSB 0x038 +#define TEGRA_VI_CSI_SURFACE0_STRIDE 0x054 +#define TEGRA_VI_CSI_SURFACE1_STRIDE 0x058 +#define TEGRA_VI_CSI_SURFACE2_STRIDE 0x05c +#define TEGRA_VI_CSI_SURFACE_HEIGHT0 0x060 +#define TEGRA_VI_CSI_ERROR_STATUS 0x084 + +/* Tegra210 CSI Pixel Parser registers: Starts from 0x838, offset 0x0 */ +#define TEGRA_CSI_INPUT_STREAM_CONTROL 0x000 +#define CSI_SKIP_PACKET_THRESHOLD_OFFSET 16 +#define TEGRA_CSI_PIXEL_STREAM_CONTROL0 0x004 +#define CSI_PP_PACKET_HEADER_SENT BIT(4) +#define CSI_PP_DATA_IDENTIFIER_ENABLE BIT(5) +#define CSI_PP_WORD_COUNT_SELECT_HEADER BIT(6) +#define CSI_PP_CRC_CHECK_ENABLE BIT(7) +#define CSI_PP_WC_CHECK BIT(8) +#define CSI_PP_OUTPUT_FORMAT_STORE (0x3 << 16) +#define CSI_PPA_PAD_LINE_NOPAD (0x2 << 24) +#define CSI_PP_HEADER_EC_DISABLE (0x1 << 27) +#define CSI_PPA_PAD_FRAME_NOPAD (0x2 << 28) +#define TEGRA_CSI_PIXEL_STREAM_CONTROL1 0x008 +#define CSI_PP_TOP_FIELD_FRAME_OFFSET 0 +#define CSI_PP_TOP_FIELD_FRAME_MASK_OFFSET 4 +#define TEGRA_CSI_PIXEL_STREAM_GAP 0x00c +#define PP_FRAME_MIN_GAP_OFFSET 16 +#define TEGRA_CSI_PIXEL_STREAM_PP_COMMAND 0x010 +#define CSI_PP_ENABLE 0x1 +#define CSI_PP_DISABLE 0x2 +#define CSI_PP_RST 0x3 +#define CSI_PP_SINGLE_SHOT_ENABLE (0x1 << 2) +#define CSI_PP_START_MARKER_FRAME_MAX_OFFSET 12 +#define TEGRA_CSI_PIXEL_STREAM_EXPECTED_FRAME 0x014 +#define TEGRA_CSI_PIXEL_PARSER_INTERRUPT_MASK 0x018 +#define TEGRA_CSI_PIXEL_PARSER_STATUS 0x01c + +/* Tegra210 CSI PHY registers */ +/* CSI_PHY_CIL_COMMAND_0 offset 0x0d0 from TEGRA_CSI_PIXEL_PARSER_0_BASE */ +#define TEGRA_CSI_PHY_CIL_COMMAND 0x0d0 +#define CSI_A_PHY_CIL_NOP 0x0 +#define CSI_A_PHY_CIL_ENABLE 0x1 +#define CSI_A_PHY_CIL_DISABLE 0x2 +#define CSI_A_PHY_CIL_ENABLE_MASK 0x3 +#define CSI_B_PHY_CIL_NOP (0x0 << 8) +#define CSI_B_PHY_CIL_ENABLE (0x1 << 8) +#define CSI_B_PHY_CIL_DISABLE (0x2 << 8) +#define CSI_B_PHY_CIL_ENABLE_MASK (0x3 << 8) + +#define TEGRA_CSI_CIL_PAD_CONFIG0 0x000 +#define BRICK_CLOCK_A_4X (0x1 << 16) +#define BRICK_CLOCK_B_4X (0x2 << 16) +#define TEGRA_CSI_CIL_PAD_CONFIG1 0x004 +#define TEGRA_CSI_CIL_PHY_CONTROL 0x008 +#define CLK_SETTLE_MASK GENMASK(13, 8) +#define THS_SETTLE_MASK GENMASK(5, 0) +#define TEGRA_CSI_CIL_INTERRUPT_MASK 0x00c +#define TEGRA_CSI_CIL_STATUS 0x010 +#define TEGRA_CSI_CILX_STATUS 0x014 +#define TEGRA_CSI_CIL_SW_SENSOR_RESET 0x020 + +#define TEGRA_CSI_PATTERN_GENERATOR_CTRL 0x000 +#define PG_MODE_OFFSET 2 +#define PG_ENABLE 0x1 +#define PG_DISABLE 0x0 +#define TEGRA_CSI_PG_BLANK 0x004 +#define PG_VBLANK_OFFSET 16 +#define TEGRA_CSI_PG_PHASE 0x008 +#define TEGRA_CSI_PG_RED_FREQ 0x00c +#define PG_RED_VERT_INIT_FREQ_OFFSET 16 +#define PG_RED_HOR_INIT_FREQ_OFFSET 0 +#define TEGRA_CSI_PG_RED_FREQ_RATE 0x010 +#define TEGRA_CSI_PG_GREEN_FREQ 0x014 +#define PG_GREEN_VERT_INIT_FREQ_OFFSET 16 +#define PG_GREEN_HOR_INIT_FREQ_OFFSET 0 +#define TEGRA_CSI_PG_GREEN_FREQ_RATE 0x018 +#define TEGRA_CSI_PG_BLUE_FREQ 0x01c +#define PG_BLUE_VERT_INIT_FREQ_OFFSET 16 +#define PG_BLUE_HOR_INIT_FREQ_OFFSET 0 +#define TEGRA_CSI_PG_BLUE_FREQ_RATE 0x020 +#define TEGRA_CSI_PG_AOHDR 0x024 +#define TEGRA_CSI_CSI_SW_STATUS_RESET 0x214 +#define TEGRA_CSI_CLKEN_OVERRIDE 0x218 + +#define TEGRA210_CSI_PORT_OFFSET 0x34 +#define TEGRA210_CSI_CIL_OFFSET 0x0f4 +#define TEGRA210_CSI_TPG_OFFSET 0x18c + +#define CSI_PP_OFFSET(block) ((block) * 0x800) +#define TEGRA210_VI_CSI_BASE(x) (0x100 + (x) * 0x100) + +/* Tegra210 VI registers accessors */ +static void tegra_vi_write(struct tegra_vi_channel *chan, unsigned int addr, + u32 val) +{ + writel_relaxed(val, chan->vi->iomem + addr); +} + +static u32 tegra_vi_read(struct tegra_vi_channel *chan, unsigned int addr) +{ + return readl_relaxed(chan->vi->iomem + addr); +} + +/* Tegra210 VI_CSI registers accessors */ +static void vi_csi_write(struct tegra_vi_channel *chan, u8 portno, + unsigned int addr, u32 val) +{ + void __iomem *vi_csi_base; + + vi_csi_base = chan->vi->iomem + TEGRA210_VI_CSI_BASE(portno); + + writel_relaxed(val, vi_csi_base + addr); +} + +static u32 vi_csi_read(struct tegra_vi_channel *chan, u8 portno, + unsigned int addr) +{ + void __iomem *vi_csi_base; + + vi_csi_base = chan->vi->iomem + TEGRA210_VI_CSI_BASE(portno); + + return readl_relaxed(vi_csi_base + addr); +} + +/* + * Tegra210 VI channel capture operations + */ +static int tegra_channel_capture_setup(struct tegra_vi_channel *chan, + u8 portno) +{ + u32 height = chan->format.height; + u32 width = chan->format.width; + u32 format = chan->fmtinfo->img_fmt; + u32 data_type = chan->fmtinfo->img_dt; + u32 word_count = (width * chan->fmtinfo->bit_width) / 8; + u32 bypass_pixel_transform = BIT(BYPASS_PXL_TRANSFORM_OFFSET); + + /* + * VI Pixel transformation unit converts source pixels data format + * into selected destination pixel format and aligns properly while + * interfacing with memory packer. + * This pixel transformation should be enabled for YUV and RGB + * formats and should be bypassed for RAW formats as RAW formats + * only support direct to memory. + */ + if (chan->pg_mode || data_type == TEGRA_IMAGE_DT_YUV422_8 || + data_type == TEGRA_IMAGE_DT_RGB888) + bypass_pixel_transform = 0; + + /* + * For x8 source streaming, the source image is split onto two x4 ports + * with left half to first x4 port and right half to second x4 port. + * So, use split width and corresponding word count for each x4 port. + */ + if (chan->numgangports > 1) { + width = width >> 1; + word_count = (width * chan->fmtinfo->bit_width) / 8; + } + + vi_csi_write(chan, portno, TEGRA_VI_CSI_ERROR_STATUS, 0xffffffff); + vi_csi_write(chan, portno, TEGRA_VI_CSI_IMAGE_DEF, + bypass_pixel_transform | + (format << IMAGE_DEF_FORMAT_OFFSET) | + IMAGE_DEF_DEST_MEM); + vi_csi_write(chan, portno, TEGRA_VI_CSI_IMAGE_DT, data_type); + vi_csi_write(chan, portno, TEGRA_VI_CSI_IMAGE_SIZE_WC, word_count); + vi_csi_write(chan, portno, TEGRA_VI_CSI_IMAGE_SIZE, + (height << IMAGE_SIZE_HEIGHT_OFFSET) | width); + return 0; +} + +static void tegra_channel_vi_soft_reset(struct tegra_vi_channel *chan, + u8 portno) +{ + /* disable clock gating to enable continuous clock */ + tegra_vi_write(chan, TEGRA_VI_CFG_CG_CTRL, 0); + /* + * Soft reset memory client interface, pixel format logic, sensor + * control logic, and a shadow copy logic to bring VI to clean state. + */ + vi_csi_write(chan, portno, TEGRA_VI_CSI_SW_RESET, 0xf); + usleep_range(100, 200); + vi_csi_write(chan, portno, TEGRA_VI_CSI_SW_RESET, 0x0); + + /* enable back VI clock gating */ + tegra_vi_write(chan, TEGRA_VI_CFG_CG_CTRL, VI_CG_2ND_LEVEL_EN); +} + +static void tegra_channel_capture_error_recover(struct tegra_vi_channel *chan, + u8 portno) +{ + struct v4l2_subdev *subdev; + u32 val; + + /* + * Recover VI and CSI hardware blocks in case of missing frame start + * events due to source not streaming or noisy csi inputs from the + * external source or many outstanding frame start or MW_ACK_DONE + * events which can cause CSI and VI hardware hang. + * This helps to have a clean capture for next frame. + */ + val = vi_csi_read(chan, portno, TEGRA_VI_CSI_ERROR_STATUS); + dev_dbg(&chan->video.dev, "TEGRA_VI_CSI_ERROR_STATUS 0x%08x\n", val); + vi_csi_write(chan, portno, TEGRA_VI_CSI_ERROR_STATUS, val); + + val = tegra_vi_read(chan, TEGRA_VI_CFG_VI_INCR_SYNCPT_ERROR); + dev_dbg(&chan->video.dev, + "TEGRA_VI_CFG_VI_INCR_SYNCPT_ERROR 0x%08x\n", val); + tegra_vi_write(chan, TEGRA_VI_CFG_VI_INCR_SYNCPT_ERROR, val); + + /* recover VI by issuing software reset and re-setup for capture */ + tegra_channel_vi_soft_reset(chan, portno); + tegra_channel_capture_setup(chan, portno); + + /* recover CSI block */ + subdev = tegra_channel_get_remote_csi_subdev(chan); + tegra_csi_error_recover(subdev); +} + +static struct tegra_channel_buffer * +dequeue_buf_done(struct tegra_vi_channel *chan) +{ + struct tegra_channel_buffer *buf = NULL; + + spin_lock(&chan->done_lock); + if (list_empty(&chan->done)) { + spin_unlock(&chan->done_lock); + return NULL; + } + + buf = list_first_entry(&chan->done, + struct tegra_channel_buffer, queue); + if (buf) + list_del_init(&buf->queue); + spin_unlock(&chan->done_lock); + + return buf; +} + +static void release_buffer(struct tegra_vi_channel *chan, + struct tegra_channel_buffer *buf, + enum vb2_buffer_state state) +{ + struct vb2_v4l2_buffer *vb = &buf->buf; + + vb->sequence = chan->sequence++; + vb->field = V4L2_FIELD_NONE; + vb->vb2_buf.timestamp = ktime_get_ns(); + vb2_buffer_done(&vb->vb2_buf, state); +} + +static void tegra_channel_vi_buffer_setup(struct tegra_vi_channel *chan, + u8 portno, u32 buf_offset, + struct tegra_channel_buffer *buf) +{ + int bytesperline = chan->format.bytesperline; + u32 sizeimage = chan->format.sizeimage; + + /* program buffer address by using surface 0 */ + vi_csi_write(chan, portno, TEGRA_VI_CSI_SURFACE0_OFFSET_MSB, + ((u64)buf->addr + buf_offset) >> 32); + vi_csi_write(chan, portno, TEGRA_VI_CSI_SURFACE0_OFFSET_LSB, + buf->addr + buf_offset); + vi_csi_write(chan, portno, TEGRA_VI_CSI_SURFACE0_STRIDE, bytesperline); + + if (chan->fmtinfo->fourcc != V4L2_PIX_FMT_NV16) + return; + /* + * Program surface 1 for UV plane with offset sizeimage from Y plane. + */ + vi_csi_write(chan, portno, TEGRA_VI_CSI_SURFACE1_OFFSET_MSB, + (((u64)buf->addr + sizeimage / 2) + buf_offset) >> 32); + vi_csi_write(chan, portno, TEGRA_VI_CSI_SURFACE1_OFFSET_LSB, + buf->addr + sizeimage / 2 + buf_offset); + vi_csi_write(chan, portno, TEGRA_VI_CSI_SURFACE1_STRIDE, bytesperline); +} + +static int tegra_channel_capture_frame(struct tegra_vi_channel *chan, + struct tegra_channel_buffer *buf) +{ + u32 thresh, value, frame_start, mw_ack_done; + u32 fs_thresh[GANG_PORTS_MAX]; + u8 *portnos = chan->portnos; + int gang_bpl = (chan->format.width >> 1) * chan->fmtinfo->bpp; + u32 buf_offset; + bool capture_timedout = false; + int err, i; + + for (i = 0; i < chan->numgangports; i++) { + /* + * Align buffers side-by-side for all consecutive x4 ports + * in gang ports using bytes per line based on source split + * width. + */ + buf_offset = i * roundup(gang_bpl, SURFACE_ALIGN_BYTES); + tegra_channel_vi_buffer_setup(chan, portnos[i], buf_offset, + buf); + + /* + * Tegra VI block interacts with host1x syncpt to synchronize + * programmed condition and hardware operation for capture. + * Frame start and Memory write acknowledge syncpts has their + * own FIFO of depth 2. + * + * Syncpoint trigger conditions set through VI_INCR_SYNCPT + * register are added to HW syncpt FIFO and when HW triggers, + * syncpt condition is removed from the FIFO and counter at + * syncpoint index will be incremented by the hardware and + * software can wait for counter to reach threshold to + * synchronize capturing frame with hardware capture events. + */ + + /* increase channel syncpoint threshold for FRAME_START */ + thresh = host1x_syncpt_incr_max(chan->frame_start_sp[i], 1); + fs_thresh[i] = thresh; + + /* Program FRAME_START trigger condition syncpt request */ + frame_start = VI_CSI_PP_FRAME_START(portnos[i]); + value = VI_CFG_VI_INCR_SYNCPT_COND(frame_start) | + host1x_syncpt_id(chan->frame_start_sp[i]); + tegra_vi_write(chan, TEGRA_VI_CFG_VI_INCR_SYNCPT, value); + + /* increase channel syncpoint threshold for MW_ACK_DONE */ + thresh = host1x_syncpt_incr_max(chan->mw_ack_sp[i], 1); + buf->mw_ack_sp_thresh[i] = thresh; + + /* Program MW_ACK_DONE trigger condition syncpt request */ + mw_ack_done = VI_CSI_MW_ACK_DONE(portnos[i]); + value = VI_CFG_VI_INCR_SYNCPT_COND(mw_ack_done) | + host1x_syncpt_id(chan->mw_ack_sp[i]); + tegra_vi_write(chan, TEGRA_VI_CFG_VI_INCR_SYNCPT, value); + } + + /* enable single shot capture after all ganged ports are ready */ + for (i = 0; i < chan->numgangports; i++) + vi_csi_write(chan, portnos[i], TEGRA_VI_CSI_SINGLE_SHOT, + SINGLE_SHOT_CAPTURE); + + for (i = 0; i < chan->numgangports; i++) { + /* + * Wait for syncpt counter to reach frame start event threshold + */ + err = host1x_syncpt_wait(chan->frame_start_sp[i], fs_thresh[i], + TEGRA_VI_SYNCPT_WAIT_TIMEOUT, &value); + if (err) { + capture_timedout = true; + /* increment syncpoint counter for timedout events */ + host1x_syncpt_incr(chan->frame_start_sp[i]); + spin_lock(&chan->sp_incr_lock[i]); + host1x_syncpt_incr(chan->mw_ack_sp[i]); + spin_unlock(&chan->sp_incr_lock[i]); + /* clear errors and recover */ + tegra_channel_capture_error_recover(chan, portnos[i]); + } + } + + if (capture_timedout) { + dev_err_ratelimited(&chan->video.dev, + "frame start syncpt timeout: %d\n", err); + release_buffer(chan, buf, VB2_BUF_STATE_ERROR); + return err; + } + + /* move buffer to capture done queue */ + spin_lock(&chan->done_lock); + list_add_tail(&buf->queue, &chan->done); + spin_unlock(&chan->done_lock); + + /* wait up kthread for capture done */ + wake_up_interruptible(&chan->done_wait); + + return 0; +} + +static void tegra_channel_capture_done(struct tegra_vi_channel *chan, + struct tegra_channel_buffer *buf) +{ + enum vb2_buffer_state state = VB2_BUF_STATE_DONE; + u32 value; + bool capture_timedout = false; + int ret, i; + + for (i = 0; i < chan->numgangports; i++) { + /* + * Wait for syncpt counter to reach MW_ACK_DONE event threshold + */ + ret = host1x_syncpt_wait(chan->mw_ack_sp[i], + buf->mw_ack_sp_thresh[i], + TEGRA_VI_SYNCPT_WAIT_TIMEOUT, &value); + if (ret) { + capture_timedout = true; + state = VB2_BUF_STATE_ERROR; + /* increment syncpoint counter for timedout event */ + spin_lock(&chan->sp_incr_lock[i]); + host1x_syncpt_incr(chan->mw_ack_sp[i]); + spin_unlock(&chan->sp_incr_lock[i]); + } + } + + if (capture_timedout) + dev_err_ratelimited(&chan->video.dev, + "MW_ACK_DONE syncpt timeout: %d\n", ret); + release_buffer(chan, buf, state); +} + +static int chan_capture_kthread_start(void *data) +{ + struct tegra_vi_channel *chan = data; + struct tegra_channel_buffer *buf; + unsigned int retries = 0; + int err = 0; + + while (1) { + /* + * Source is not streaming if error is non-zero. + * So, do not dequeue buffers on error and let the thread sleep + * till kthread stop signal is received. + */ + wait_event_interruptible(chan->start_wait, + kthread_should_stop() || + (!list_empty(&chan->capture) && + !err)); + + if (kthread_should_stop()) + break; + + /* dequeue the buffer and start capture */ + spin_lock(&chan->start_lock); + if (list_empty(&chan->capture)) { + spin_unlock(&chan->start_lock); + continue; + } + + buf = list_first_entry(&chan->capture, + struct tegra_channel_buffer, queue); + list_del_init(&buf->queue); + spin_unlock(&chan->start_lock); + + err = tegra_channel_capture_frame(chan, buf); + if (!err) { + retries = 0; + continue; + } + + if (retries++ > chan->syncpt_timeout_retry) + vb2_queue_error(&chan->queue); + else + err = 0; + } + + return 0; +} + +static int chan_capture_kthread_finish(void *data) +{ + struct tegra_vi_channel *chan = data; + struct tegra_channel_buffer *buf; + + while (1) { + wait_event_interruptible(chan->done_wait, + !list_empty(&chan->done) || + kthread_should_stop()); + + /* dequeue buffers and finish capture */ + buf = dequeue_buf_done(chan); + while (buf) { + tegra_channel_capture_done(chan, buf); + buf = dequeue_buf_done(chan); + } + + if (kthread_should_stop()) + break; + } + + return 0; +} + +static int tegra210_vi_start_streaming(struct vb2_queue *vq, u32 count) +{ + struct tegra_vi_channel *chan = vb2_get_drv_priv(vq); + struct media_pipeline *pipe = &chan->video.pipe; + u32 val; + u8 *portnos = chan->portnos; + int ret, i; + + tegra_vi_write(chan, TEGRA_VI_CFG_CG_CTRL, VI_CG_2ND_LEVEL_EN); + + /* clear syncpt errors */ + val = tegra_vi_read(chan, TEGRA_VI_CFG_VI_INCR_SYNCPT_ERROR); + tegra_vi_write(chan, TEGRA_VI_CFG_VI_INCR_SYNCPT_ERROR, val); + + /* + * Sync point FIFO full stalls the host interface. + * Setting NO_STALL will drop INCR_SYNCPT methods when fifos are + * full and the corresponding condition bits in INCR_SYNCPT_ERROR + * register will be set. + * This allows SW to process error recovery. + */ + tegra_vi_write(chan, TEGRA_VI_CFG_VI_INCR_SYNCPT_CNTRL, + VI_INCR_SYNCPT_NO_STALL); + + /* start the pipeline */ + ret = video_device_pipeline_start(&chan->video, pipe); + if (ret < 0) + goto error_pipeline_start; + + /* clear csi errors and do capture setup for all ports in gang mode */ + for (i = 0; i < chan->numgangports; i++) { + val = vi_csi_read(chan, portnos[i], TEGRA_VI_CSI_ERROR_STATUS); + vi_csi_write(chan, portnos[i], TEGRA_VI_CSI_ERROR_STATUS, val); + + tegra_channel_capture_setup(chan, portnos[i]); + } + + ret = tegra_channel_set_stream(chan, true); + if (ret < 0) + goto error_set_stream; + + chan->sequence = 0; + + /* start kthreads to capture data to buffer and return them */ + chan->kthread_start_capture = kthread_run(chan_capture_kthread_start, + chan, "%s:0", + chan->video.name); + if (IS_ERR(chan->kthread_start_capture)) { + ret = PTR_ERR(chan->kthread_start_capture); + chan->kthread_start_capture = NULL; + dev_err(&chan->video.dev, + "failed to run capture start kthread: %d\n", ret); + goto error_kthread_start; + } + + chan->kthread_finish_capture = kthread_run(chan_capture_kthread_finish, + chan, "%s:1", + chan->video.name); + if (IS_ERR(chan->kthread_finish_capture)) { + ret = PTR_ERR(chan->kthread_finish_capture); + chan->kthread_finish_capture = NULL; + dev_err(&chan->video.dev, + "failed to run capture finish kthread: %d\n", ret); + goto error_kthread_done; + } + + return 0; + +error_kthread_done: + kthread_stop(chan->kthread_start_capture); +error_kthread_start: + tegra_channel_set_stream(chan, false); +error_set_stream: + video_device_pipeline_stop(&chan->video); +error_pipeline_start: + tegra_channel_release_buffers(chan, VB2_BUF_STATE_QUEUED); + return ret; +} + +static void tegra210_vi_stop_streaming(struct vb2_queue *vq) +{ + struct tegra_vi_channel *chan = vb2_get_drv_priv(vq); + + if (chan->kthread_start_capture) { + kthread_stop(chan->kthread_start_capture); + chan->kthread_start_capture = NULL; + } + + if (chan->kthread_finish_capture) { + kthread_stop(chan->kthread_finish_capture); + chan->kthread_finish_capture = NULL; + } + + tegra_channel_release_buffers(chan, VB2_BUF_STATE_ERROR); + tegra_channel_set_stream(chan, false); + video_device_pipeline_stop(&chan->video); +} + +/* + * Tegra210 VI Pixel memory format enum. + * These format enum value gets programmed into corresponding Tegra VI + * channel register bits. + */ +enum tegra210_image_format { + TEGRA210_IMAGE_FORMAT_T_L8 = 16, + + TEGRA210_IMAGE_FORMAT_T_R16_I = 32, + TEGRA210_IMAGE_FORMAT_T_B5G6R5, + TEGRA210_IMAGE_FORMAT_T_R5G6B5, + TEGRA210_IMAGE_FORMAT_T_A1B5G5R5, + TEGRA210_IMAGE_FORMAT_T_A1R5G5B5, + TEGRA210_IMAGE_FORMAT_T_B5G5R5A1, + TEGRA210_IMAGE_FORMAT_T_R5G5B5A1, + TEGRA210_IMAGE_FORMAT_T_A4B4G4R4, + TEGRA210_IMAGE_FORMAT_T_A4R4G4B4, + TEGRA210_IMAGE_FORMAT_T_B4G4R4A4, + TEGRA210_IMAGE_FORMAT_T_R4G4B4A4, + + TEGRA210_IMAGE_FORMAT_T_A8B8G8R8 = 64, + TEGRA210_IMAGE_FORMAT_T_A8R8G8B8, + TEGRA210_IMAGE_FORMAT_T_B8G8R8A8, + TEGRA210_IMAGE_FORMAT_T_R8G8B8A8, + TEGRA210_IMAGE_FORMAT_T_A2B10G10R10, + TEGRA210_IMAGE_FORMAT_T_A2R10G10B10, + TEGRA210_IMAGE_FORMAT_T_B10G10R10A2, + TEGRA210_IMAGE_FORMAT_T_R10G10B10A2, + + TEGRA210_IMAGE_FORMAT_T_A8Y8U8V8 = 193, + TEGRA210_IMAGE_FORMAT_T_V8U8Y8A8, + + TEGRA210_IMAGE_FORMAT_T_A2Y10U10V10 = 197, + TEGRA210_IMAGE_FORMAT_T_V10U10Y10A2, + TEGRA210_IMAGE_FORMAT_T_Y8_U8__Y8_V8, + TEGRA210_IMAGE_FORMAT_T_Y8_V8__Y8_U8, + TEGRA210_IMAGE_FORMAT_T_U8_Y8__V8_Y8, + TEGRA210_IMAGE_FORMAT_T_V8_Y8__U8_Y8, + + TEGRA210_IMAGE_FORMAT_T_Y8__U8__V8_N444 = 224, + TEGRA210_IMAGE_FORMAT_T_Y8__U8V8_N444, + TEGRA210_IMAGE_FORMAT_T_Y8__V8U8_N444, + TEGRA210_IMAGE_FORMAT_T_Y8__U8__V8_N422, + TEGRA210_IMAGE_FORMAT_T_Y8__U8V8_N422, + TEGRA210_IMAGE_FORMAT_T_Y8__V8U8_N422, + TEGRA210_IMAGE_FORMAT_T_Y8__U8__V8_N420, + TEGRA210_IMAGE_FORMAT_T_Y8__U8V8_N420, + TEGRA210_IMAGE_FORMAT_T_Y8__V8U8_N420, + TEGRA210_IMAGE_FORMAT_T_X2LC10LB10LA10, + TEGRA210_IMAGE_FORMAT_T_A2R6R6R6R6R6, +}; + +#define TEGRA210_VIDEO_FMT(DATA_TYPE, BIT_WIDTH, MBUS_CODE, BPP, \ + FORMAT, FOURCC) \ +{ \ + TEGRA_IMAGE_DT_##DATA_TYPE, \ + BIT_WIDTH, \ + MEDIA_BUS_FMT_##MBUS_CODE, \ + BPP, \ + TEGRA210_IMAGE_FORMAT_##FORMAT, \ + V4L2_PIX_FMT_##FOURCC, \ +} + +/* Tegra210 supported video formats */ +static const struct tegra_video_format tegra210_video_formats[] = { + /* RAW 8 */ + TEGRA210_VIDEO_FMT(RAW8, 8, SRGGB8_1X8, 1, T_L8, SRGGB8), + TEGRA210_VIDEO_FMT(RAW8, 8, SGRBG8_1X8, 1, T_L8, SGRBG8), + TEGRA210_VIDEO_FMT(RAW8, 8, SGBRG8_1X8, 1, T_L8, SGBRG8), + TEGRA210_VIDEO_FMT(RAW8, 8, SBGGR8_1X8, 1, T_L8, SBGGR8), + /* RAW 10 */ + TEGRA210_VIDEO_FMT(RAW10, 10, SRGGB10_1X10, 2, T_R16_I, SRGGB10), + TEGRA210_VIDEO_FMT(RAW10, 10, SGRBG10_1X10, 2, T_R16_I, SGRBG10), + TEGRA210_VIDEO_FMT(RAW10, 10, SGBRG10_1X10, 2, T_R16_I, SGBRG10), + TEGRA210_VIDEO_FMT(RAW10, 10, SBGGR10_1X10, 2, T_R16_I, SBGGR10), + /* RAW 12 */ + TEGRA210_VIDEO_FMT(RAW12, 12, SRGGB12_1X12, 2, T_R16_I, SRGGB12), + TEGRA210_VIDEO_FMT(RAW12, 12, SGRBG12_1X12, 2, T_R16_I, SGRBG12), + TEGRA210_VIDEO_FMT(RAW12, 12, SGBRG12_1X12, 2, T_R16_I, SGBRG12), + TEGRA210_VIDEO_FMT(RAW12, 12, SBGGR12_1X12, 2, T_R16_I, SBGGR12), + /* RGB888 */ + TEGRA210_VIDEO_FMT(RGB888, 24, RGB888_1X24, 4, T_A8R8G8B8, XBGR32), + TEGRA210_VIDEO_FMT(RGB888, 24, RGB888_1X32_PADHI, 4, T_A8B8G8R8, + RGBX32), + /* YUV422 */ + TEGRA210_VIDEO_FMT(YUV422_8, 16, UYVY8_1X16, 2, T_U8_Y8__V8_Y8, YVYU), + TEGRA210_VIDEO_FMT(YUV422_8, 16, VYUY8_1X16, 2, T_V8_Y8__U8_Y8, YUYV), + TEGRA210_VIDEO_FMT(YUV422_8, 16, YUYV8_1X16, 2, T_Y8_U8__Y8_V8, VYUY), + TEGRA210_VIDEO_FMT(YUV422_8, 16, YVYU8_1X16, 2, T_Y8_V8__Y8_U8, UYVY), + TEGRA210_VIDEO_FMT(YUV422_8, 16, UYVY8_1X16, 1, T_Y8__V8U8_N422, NV16), + TEGRA210_VIDEO_FMT(YUV422_8, 16, UYVY8_2X8, 2, T_U8_Y8__V8_Y8, YVYU), + TEGRA210_VIDEO_FMT(YUV422_8, 16, VYUY8_2X8, 2, T_V8_Y8__U8_Y8, YUYV), + TEGRA210_VIDEO_FMT(YUV422_8, 16, YUYV8_2X8, 2, T_Y8_U8__Y8_V8, VYUY), + TEGRA210_VIDEO_FMT(YUV422_8, 16, YVYU8_2X8, 2, T_Y8_V8__Y8_U8, UYVY), +}; + +/* Tegra210 VI operations */ +static const struct tegra_vi_ops tegra210_vi_ops = { + .vi_start_streaming = tegra210_vi_start_streaming, + .vi_stop_streaming = tegra210_vi_stop_streaming, +}; + +/* Tegra210 VI SoC data */ +const struct tegra_vi_soc tegra210_vi_soc = { + .video_formats = tegra210_video_formats, + .nformats = ARRAY_SIZE(tegra210_video_formats), + .ops = &tegra210_vi_ops, + .hw_revision = 3, + .vi_max_channels = 6, +#if IS_ENABLED(CONFIG_VIDEO_TEGRA_TPG) + .vi_max_clk_hz = 499200000, +#else + .vi_max_clk_hz = 998400000, +#endif +}; + +/* Tegra210 CSI PHY registers accessors */ +static void csi_write(struct tegra_csi *csi, u8 portno, unsigned int addr, + u32 val) +{ + void __iomem *csi_pp_base; + + csi_pp_base = csi->iomem + CSI_PP_OFFSET(portno >> 1); + + writel_relaxed(val, csi_pp_base + addr); +} + +/* Tegra210 CSI Pixel parser registers accessors */ +static void pp_write(struct tegra_csi *csi, u8 portno, u32 addr, u32 val) +{ + void __iomem *csi_pp_base; + unsigned int offset; + + csi_pp_base = csi->iomem + CSI_PP_OFFSET(portno >> 1); + offset = (portno % CSI_PORTS_PER_BRICK) * TEGRA210_CSI_PORT_OFFSET; + + writel_relaxed(val, csi_pp_base + offset + addr); +} + +static u32 pp_read(struct tegra_csi *csi, u8 portno, u32 addr) +{ + void __iomem *csi_pp_base; + unsigned int offset; + + csi_pp_base = csi->iomem + CSI_PP_OFFSET(portno >> 1); + offset = (portno % CSI_PORTS_PER_BRICK) * TEGRA210_CSI_PORT_OFFSET; + + return readl_relaxed(csi_pp_base + offset + addr); +} + +/* Tegra210 CSI CIL A/B port registers accessors */ +static void cil_write(struct tegra_csi *csi, u8 portno, u32 addr, u32 val) +{ + void __iomem *csi_cil_base; + unsigned int offset; + + csi_cil_base = csi->iomem + CSI_PP_OFFSET(portno >> 1) + + TEGRA210_CSI_CIL_OFFSET; + offset = (portno % CSI_PORTS_PER_BRICK) * TEGRA210_CSI_PORT_OFFSET; + + writel_relaxed(val, csi_cil_base + offset + addr); +} + +static u32 cil_read(struct tegra_csi *csi, u8 portno, u32 addr) +{ + void __iomem *csi_cil_base; + unsigned int offset; + + csi_cil_base = csi->iomem + CSI_PP_OFFSET(portno >> 1) + + TEGRA210_CSI_CIL_OFFSET; + offset = (portno % CSI_PORTS_PER_BRICK) * TEGRA210_CSI_PORT_OFFSET; + + return readl_relaxed(csi_cil_base + offset + addr); +} + +/* Tegra210 CSI Test pattern generator registers accessor */ +static void tpg_write(struct tegra_csi *csi, u8 portno, unsigned int addr, + u32 val) +{ + void __iomem *csi_pp_base; + unsigned int offset; + + csi_pp_base = csi->iomem + CSI_PP_OFFSET(portno >> 1); + offset = (portno % CSI_PORTS_PER_BRICK) * TEGRA210_CSI_PORT_OFFSET + + TEGRA210_CSI_TPG_OFFSET; + + writel_relaxed(val, csi_pp_base + offset + addr); +} + +/* + * Tegra210 CSI operations + */ +static void tegra210_csi_port_recover(struct tegra_csi_channel *csi_chan, + u8 portno) +{ + struct tegra_csi *csi = csi_chan->csi; + u32 val; + + /* + * Recover CSI hardware in case of capture errors by issuing + * software reset to CSICIL sensor, pixel parser, and clear errors + * to have clean capture on next streaming. + */ + val = pp_read(csi, portno, TEGRA_CSI_PIXEL_PARSER_STATUS); + dev_dbg(csi->dev, "TEGRA_CSI_PIXEL_PARSER_STATUS 0x%08x\n", val); + + val = cil_read(csi, portno, TEGRA_CSI_CIL_STATUS); + dev_dbg(csi->dev, "TEGRA_CSI_CIL_STATUS 0x%08x\n", val); + + val = cil_read(csi, portno, TEGRA_CSI_CILX_STATUS); + dev_dbg(csi->dev, "TEGRA_CSI_CILX_STATUS 0x%08x\n", val); + + if (csi_chan->numlanes == 4) { + /* reset CSI CIL sensor */ + cil_write(csi, portno, TEGRA_CSI_CIL_SW_SENSOR_RESET, 0x1); + cil_write(csi, portno + 1, TEGRA_CSI_CIL_SW_SENSOR_RESET, 0x1); + /* + * SW_STATUS_RESET resets all status bits of PPA, PPB, CILA, + * CILB status registers and debug counters. + * So, SW_STATUS_RESET can be used only when CSI brick is in + * x4 mode. + */ + csi_write(csi, portno, TEGRA_CSI_CSI_SW_STATUS_RESET, 0x1); + + /* sleep for 20 clock cycles to drain the FIFO */ + usleep_range(10, 20); + + cil_write(csi, portno + 1, TEGRA_CSI_CIL_SW_SENSOR_RESET, 0x0); + cil_write(csi, portno, TEGRA_CSI_CIL_SW_SENSOR_RESET, 0x0); + csi_write(csi, portno, TEGRA_CSI_CSI_SW_STATUS_RESET, 0x0); + } else { + /* reset CSICIL sensor */ + cil_write(csi, portno, TEGRA_CSI_CIL_SW_SENSOR_RESET, 0x1); + usleep_range(10, 20); + cil_write(csi, portno, TEGRA_CSI_CIL_SW_SENSOR_RESET, 0x0); + + /* clear the errors */ + pp_write(csi, portno, TEGRA_CSI_PIXEL_PARSER_STATUS, + 0xffffffff); + cil_write(csi, portno, TEGRA_CSI_CIL_STATUS, 0xffffffff); + cil_write(csi, portno, TEGRA_CSI_CILX_STATUS, 0xffffffff); + } +} + +static void tegra210_csi_error_recover(struct tegra_csi_channel *csi_chan) +{ + u8 *portnos = csi_chan->csi_port_nums; + int i; + + for (i = 0; i < csi_chan->numgangports; i++) + tegra210_csi_port_recover(csi_chan, portnos[i]); +} + +static int +tegra210_csi_port_start_streaming(struct tegra_csi_channel *csi_chan, + u8 portno) +{ + struct tegra_csi *csi = csi_chan->csi; + u8 clk_settle_time = 0; + u8 ths_settle_time = 10; + u32 val; + + if (!csi_chan->pg_mode) + tegra_csi_calc_settle_time(csi_chan, portno, &clk_settle_time, + &ths_settle_time); + + csi_write(csi, portno, TEGRA_CSI_CLKEN_OVERRIDE, 0); + + /* clean up status */ + pp_write(csi, portno, TEGRA_CSI_PIXEL_PARSER_STATUS, 0xffffffff); + cil_write(csi, portno, TEGRA_CSI_CIL_STATUS, 0xffffffff); + cil_write(csi, portno, TEGRA_CSI_CILX_STATUS, 0xffffffff); + cil_write(csi, portno, TEGRA_CSI_CIL_INTERRUPT_MASK, 0x0); + + /* CIL PHY registers setup */ + cil_write(csi, portno, TEGRA_CSI_CIL_PAD_CONFIG0, 0x0); + cil_write(csi, portno, TEGRA_CSI_CIL_PHY_CONTROL, + FIELD_PREP(CLK_SETTLE_MASK, clk_settle_time) | + FIELD_PREP(THS_SETTLE_MASK, ths_settle_time)); + + /* + * The CSI unit provides for connection of up to six cameras in + * the system and is organized as three identical instances of + * two MIPI support blocks, each with a separate 4-lane + * interface that can be configured as a single camera with 4 + * lanes or as a dual camera with 2 lanes available for each + * camera. + */ + if (csi_chan->numlanes == 4) { + cil_write(csi, portno + 1, TEGRA_CSI_CIL_STATUS, 0xffffffff); + cil_write(csi, portno + 1, TEGRA_CSI_CILX_STATUS, 0xffffffff); + cil_write(csi, portno + 1, TEGRA_CSI_CIL_INTERRUPT_MASK, 0x0); + + cil_write(csi, portno, TEGRA_CSI_CIL_PAD_CONFIG0, + BRICK_CLOCK_A_4X); + cil_write(csi, portno + 1, TEGRA_CSI_CIL_PAD_CONFIG0, 0x0); + cil_write(csi, portno + 1, TEGRA_CSI_CIL_INTERRUPT_MASK, 0x0); + cil_write(csi, portno + 1, TEGRA_CSI_CIL_PHY_CONTROL, + FIELD_PREP(CLK_SETTLE_MASK, clk_settle_time) | + FIELD_PREP(THS_SETTLE_MASK, ths_settle_time)); + csi_write(csi, portno, TEGRA_CSI_PHY_CIL_COMMAND, + CSI_A_PHY_CIL_ENABLE | CSI_B_PHY_CIL_ENABLE); + } else { + val = ((portno & 1) == PORT_A) ? + CSI_A_PHY_CIL_ENABLE | CSI_B_PHY_CIL_NOP : + CSI_B_PHY_CIL_ENABLE | CSI_A_PHY_CIL_NOP; + csi_write(csi, portno, TEGRA_CSI_PHY_CIL_COMMAND, val); + } + + /* CSI pixel parser registers setup */ + pp_write(csi, portno, TEGRA_CSI_PIXEL_STREAM_PP_COMMAND, + (0xf << CSI_PP_START_MARKER_FRAME_MAX_OFFSET) | + CSI_PP_SINGLE_SHOT_ENABLE | CSI_PP_RST); + pp_write(csi, portno, TEGRA_CSI_PIXEL_PARSER_INTERRUPT_MASK, 0x0); + pp_write(csi, portno, TEGRA_CSI_PIXEL_STREAM_CONTROL0, + CSI_PP_PACKET_HEADER_SENT | + CSI_PP_DATA_IDENTIFIER_ENABLE | + CSI_PP_WORD_COUNT_SELECT_HEADER | + CSI_PP_CRC_CHECK_ENABLE | CSI_PP_WC_CHECK | + CSI_PP_OUTPUT_FORMAT_STORE | CSI_PPA_PAD_LINE_NOPAD | + CSI_PP_HEADER_EC_DISABLE | CSI_PPA_PAD_FRAME_NOPAD | + (portno & 1)); + pp_write(csi, portno, TEGRA_CSI_PIXEL_STREAM_CONTROL1, + (0x1 << CSI_PP_TOP_FIELD_FRAME_OFFSET) | + (0x1 << CSI_PP_TOP_FIELD_FRAME_MASK_OFFSET)); + pp_write(csi, portno, TEGRA_CSI_PIXEL_STREAM_GAP, + 0x14 << PP_FRAME_MIN_GAP_OFFSET); + pp_write(csi, portno, TEGRA_CSI_PIXEL_STREAM_EXPECTED_FRAME, 0x0); + pp_write(csi, portno, TEGRA_CSI_INPUT_STREAM_CONTROL, + (0x3f << CSI_SKIP_PACKET_THRESHOLD_OFFSET) | + (csi_chan->numlanes - 1)); + + /* TPG setup */ + if (csi_chan->pg_mode) { + tpg_write(csi, portno, TEGRA_CSI_PATTERN_GENERATOR_CTRL, + ((csi_chan->pg_mode - 1) << PG_MODE_OFFSET) | + PG_ENABLE); + tpg_write(csi, portno, TEGRA_CSI_PG_BLANK, + csi_chan->v_blank << PG_VBLANK_OFFSET | + csi_chan->h_blank); + tpg_write(csi, portno, TEGRA_CSI_PG_PHASE, 0x0); + tpg_write(csi, portno, TEGRA_CSI_PG_RED_FREQ, + (0x10 << PG_RED_VERT_INIT_FREQ_OFFSET) | + (0x10 << PG_RED_HOR_INIT_FREQ_OFFSET)); + tpg_write(csi, portno, TEGRA_CSI_PG_RED_FREQ_RATE, 0x0); + tpg_write(csi, portno, TEGRA_CSI_PG_GREEN_FREQ, + (0x10 << PG_GREEN_VERT_INIT_FREQ_OFFSET) | + (0x10 << PG_GREEN_HOR_INIT_FREQ_OFFSET)); + tpg_write(csi, portno, TEGRA_CSI_PG_GREEN_FREQ_RATE, 0x0); + tpg_write(csi, portno, TEGRA_CSI_PG_BLUE_FREQ, + (0x10 << PG_BLUE_VERT_INIT_FREQ_OFFSET) | + (0x10 << PG_BLUE_HOR_INIT_FREQ_OFFSET)); + tpg_write(csi, portno, TEGRA_CSI_PG_BLUE_FREQ_RATE, 0x0); + } + + pp_write(csi, portno, TEGRA_CSI_PIXEL_STREAM_PP_COMMAND, + (0xf << CSI_PP_START_MARKER_FRAME_MAX_OFFSET) | + CSI_PP_SINGLE_SHOT_ENABLE | CSI_PP_ENABLE); + + return 0; +} + +static void +tegra210_csi_port_stop_streaming(struct tegra_csi_channel *csi_chan, u8 portno) +{ + struct tegra_csi *csi = csi_chan->csi; + u32 val; + + val = pp_read(csi, portno, TEGRA_CSI_PIXEL_PARSER_STATUS); + + dev_dbg(csi->dev, "TEGRA_CSI_PIXEL_PARSER_STATUS 0x%08x\n", val); + pp_write(csi, portno, TEGRA_CSI_PIXEL_PARSER_STATUS, val); + + val = cil_read(csi, portno, TEGRA_CSI_CIL_STATUS); + dev_dbg(csi->dev, "TEGRA_CSI_CIL_STATUS 0x%08x\n", val); + cil_write(csi, portno, TEGRA_CSI_CIL_STATUS, val); + + val = cil_read(csi, portno, TEGRA_CSI_CILX_STATUS); + dev_dbg(csi->dev, "TEGRA_CSI_CILX_STATUS 0x%08x\n", val); + cil_write(csi, portno, TEGRA_CSI_CILX_STATUS, val); + + pp_write(csi, portno, TEGRA_CSI_PIXEL_STREAM_PP_COMMAND, + (0xf << CSI_PP_START_MARKER_FRAME_MAX_OFFSET) | + CSI_PP_DISABLE); + + if (csi_chan->pg_mode) { + tpg_write(csi, portno, TEGRA_CSI_PATTERN_GENERATOR_CTRL, + PG_DISABLE); + return; + } + + if (csi_chan->numlanes == 4) { + csi_write(csi, portno, TEGRA_CSI_PHY_CIL_COMMAND, + CSI_A_PHY_CIL_DISABLE | + CSI_B_PHY_CIL_DISABLE); + } else { + val = ((portno & 1) == PORT_A) ? + CSI_A_PHY_CIL_DISABLE | CSI_B_PHY_CIL_NOP : + CSI_B_PHY_CIL_DISABLE | CSI_A_PHY_CIL_NOP; + csi_write(csi, portno, TEGRA_CSI_PHY_CIL_COMMAND, val); + } +} + +static int tegra210_csi_start_streaming(struct tegra_csi_channel *csi_chan) +{ + u8 *portnos = csi_chan->csi_port_nums; + int ret, i; + + for (i = 0; i < csi_chan->numgangports; i++) { + ret = tegra210_csi_port_start_streaming(csi_chan, portnos[i]); + if (ret) + goto stream_start_fail; + } + + return 0; + +stream_start_fail: + for (i = i - 1; i >= 0; i--) + tegra210_csi_port_stop_streaming(csi_chan, portnos[i]); + + return ret; +} + +static void tegra210_csi_stop_streaming(struct tegra_csi_channel *csi_chan) +{ + u8 *portnos = csi_chan->csi_port_nums; + int i; + + for (i = 0; i < csi_chan->numgangports; i++) + tegra210_csi_port_stop_streaming(csi_chan, portnos[i]); +} + +/* + * Tegra210 CSI TPG frame rate table with horizontal and vertical + * blanking intervals for corresponding format and resolution. + * Blanking intervals are tuned values from design team for max TPG + * clock rate. + */ +static const struct tpg_framerate tegra210_tpg_frmrate_table[] = { + { + .frmsize = { 1280, 720 }, + .code = MEDIA_BUS_FMT_SRGGB10_1X10, + .framerate = 120, + .h_blank = 512, + .v_blank = 8, + }, + { + .frmsize = { 1920, 1080 }, + .code = MEDIA_BUS_FMT_SRGGB10_1X10, + .framerate = 60, + .h_blank = 512, + .v_blank = 8, + }, + { + .frmsize = { 3840, 2160 }, + .code = MEDIA_BUS_FMT_SRGGB10_1X10, + .framerate = 20, + .h_blank = 8, + .v_blank = 8, + }, + { + .frmsize = { 1280, 720 }, + .code = MEDIA_BUS_FMT_RGB888_1X32_PADHI, + .framerate = 60, + .h_blank = 512, + .v_blank = 8, + }, + { + .frmsize = { 1920, 1080 }, + .code = MEDIA_BUS_FMT_RGB888_1X32_PADHI, + .framerate = 30, + .h_blank = 512, + .v_blank = 8, + }, + { + .frmsize = { 3840, 2160 }, + .code = MEDIA_BUS_FMT_RGB888_1X32_PADHI, + .framerate = 8, + .h_blank = 8, + .v_blank = 8, + }, +}; + +static const char * const tegra210_csi_cil_clks[] = { + "csi", + "cilab", + "cilcd", + "cile", +#if IS_ENABLED(CONFIG_VIDEO_TEGRA_TPG) + "csi_tpg", +#endif +}; + +/* Tegra210 CSI operations */ +static const struct tegra_csi_ops tegra210_csi_ops = { + .csi_start_streaming = tegra210_csi_start_streaming, + .csi_stop_streaming = tegra210_csi_stop_streaming, + .csi_err_recover = tegra210_csi_error_recover, +}; + +/* Tegra210 CSI SoC data */ +const struct tegra_csi_soc tegra210_csi_soc = { + .ops = &tegra210_csi_ops, + .csi_max_channels = 6, + .clk_names = tegra210_csi_cil_clks, + .num_clks = ARRAY_SIZE(tegra210_csi_cil_clks), + .tpg_frmrate_table = tegra210_tpg_frmrate_table, + .tpg_frmrate_table_size = ARRAY_SIZE(tegra210_tpg_frmrate_table), +}; |