// SPDX-License-Identifier: GPL-2.0 /* * Qualcomm MSM Camera Subsystem - CSID (CSI Decoder) Module * * Copyright (C) 2020-2025 Linaro Ltd. */ #include #include #include #include #include "camss.h" #include "camss-csid.h" #include "camss-csid-gen2.h" #define CSID_TOP_IO_PATH_CFG0(csid) (0x4 * (csid)) #define CSID_TOP_IO_PATH_CFG0_INTERNAL_CSID BIT(0) #define CSID_TOP_IO_PATH_CFG0_SFE_0 BIT(1) #define CSID_TOP_IO_PATH_CFG0_SFE_1 GENMASK(1, 0) #define CSID_TOP_IO_PATH_CFG0_SBI_0 BIT(4) #define CSID_TOP_IO_PATH_CFG0_SBI_1 GENMASK(3, 0) #define CSID_TOP_IO_PATH_CFG0_SBI_2 GENMASK(3, 1) #define CSID_TOP_IO_PATH_CFG0_OUTPUT_IFE_EN BIT(8) #define CSID_TOP_IO_PATH_CFG0_SFE_OFFLINE_EN BIT(12) #define CSID_RESET_CMD 0x10 #define CSID_RESET_CMD_HW_RESET BIT(0) #define CSID_RESET_CMD_SW_RESET BIT(1) #define CSID_RESET_CMD_IRQ_CTRL BIT(2) #define CSID_IRQ_CMD 0x14 #define CSID_IRQ_CMD_CLEAR BIT(0) #define CSID_IRQ_CMD_SET BIT(4) #define CSID_REG_UPDATE_CMD 0x18 #define CSID_CSI2_RDIN_IRQ_STATUS(rdi) (0xec + 0x10 * (rdi)) #define CSID_CSI2_RDIN_CCIF_VIOLATION BIT(29) #define CSID_CSI2_RDIN_SENSOR_SWITCH_OUT_OF_SYNC_FRAME_DROP BIT(28) #define CSID_CSI2_RDIN_ERROR_REC_WIDTH_VIOLATION BIT(27) #define CSID_CSI2_RDIN_ERROR_REC_HEIGHT_VIOLATION BIT(26) #define CSID_CSI2_RDIN_BATCH_END_MISSING_VIOLATION BIT(25) #define CSID_CSI2_RDIN_ILLEGAL_BATCH_ID_IRQ BIT(24) #define CSID_CSI2_RDIN_RUP_DONE BIT(23) #define CSID_CSI2_RDIN_CAMIF_EPOCH_1_IRQ BIT(22) #define CSID_CSI2_RDIN_CAMIF_EPOCH_0_IRQ BIT(21) #define CSID_CSI2_RDIN_ERROR_REC_OVERFLOW_IRQ BIT(19) #define CSID_CSI2_RDIN_ERROR_REC_FRAME_DROP BIT(18) #define CSID_CSI2_RDIN_VCDT_GRP_CHANG BIT(17) #define CSID_CSI2_RDIN_VCDT_GRP_0_SEL BIT(16) #define CSID_CSI2_RDIN_VCDT_GRP_1_SEL BIT(15) #define CSID_CSI2_RDIN_ERROR_LINE_COUNT BIT(14) #define CSID_CSI2_RDIN_ERROR_PIX_COUNT BIT(13) #define CSID_CSI2_RDIN_INFO_INPUT_SOF BIT(12) #define CSID_CSI2_RDIN_INFO_INPUT_SOL BIT(11) #define CSID_CSI2_RDIN_INFO_INPUT_EOL BIT(10) #define CSID_CSI2_RDIN_INFO_INPUT_EOF BIT(9) #define CSID_CSI2_RDIN_INFO_FRAME_DROP_SOF BIT(8) #define CSID_CSI2_RDIN_INFO_FRAME_DROP_SOL BIT(7) #define CSID_CSI2_RDIN_INFO_FRAME_DROP_EOL BIT(6) #define CSID_CSI2_RDIN_INFO_FRAME_DROP_EOF BIT(5) #define CSID_CSI2_RDIN_INFO_CAMIF_SOF BIT(4) #define CSID_CSI2_RDIN_INFO_CAMIF_EOF BIT(3) #define CSID_CSI2_RDIN_INFO_FIFO_OVERFLOW BIT(2) #define CSID_CSI2_RDIN_RES1 BIT(1) #define CSID_CSI2_RDIN_RES0 BIT(0) #define CSID_CSI2_RDIN_IRQ_MASK(rdi) (0xf0 + 0x10 * (rdi)) #define CSID_CSI2_RDIN_IRQ_CLEAR(rdi) (0xf4 + 0x10 * (rdi)) #define CSID_CSI2_RDIN_IRQ_SET(rdi) (0xf8 + 0x10 * (rdi)) #define CSID_TOP_IRQ_STATUS 0x7c #define CSID_TOP_IRQ_MASK 0x80 #define CSID_TOP_IRQ_CLEAR 0x84 #define CSID_TOP_IRQ_RESET BIT(0) #define CSID_TOP_IRQ_RX BIT(2) #define CSID_TOP_IRQ_LONG_PKT(rdi) (BIT(8) << (rdi)) #define CSID_TOP_IRQ_BUF_DONE BIT(13) #define CSID_BUF_DONE_IRQ_STATUS 0x8c #define BUF_DONE_IRQ_STATUS_RDI_OFFSET (csid_is_lite(csid) ? 1 : 14) #define CSID_BUF_DONE_IRQ_MASK 0x90 #define CSID_BUF_DONE_IRQ_CLEAR 0x94 #define CSID_CSI2_RX_IRQ_STATUS 0x9c #define CSID_CSI2_RX_IRQ_MASK 0xa0 #define CSID_CSI2_RX_IRQ_CLEAR 0xa4 #define CSID_RESET_CFG 0xc #define CSID_RESET_CFG_MODE_IMMEDIATE BIT(0) #define CSID_RESET_CFG_LOCATION_COMPLETE BIT(4) #define CSID_CSI2_RDI_IRQ_STATUS(rdi) (0xec + 0x10 * (rdi)) #define CSID_CSI2_RDI_IRQ_MASK(rdi) (0xf0 + 0x10 * (rdi)) #define CSID_CSI2_RDI_IRQ_CLEAR(rdi) (0xf4 + 0x10 * (rdi)) #define CSID_CSI2_RX_CFG0 0x200 #define CSI2_RX_CFG0_NUM_ACTIVE_LANES 0 #define CSI2_RX_CFG0_DL0_INPUT_SEL 4 #define CSI2_RX_CFG0_DL1_INPUT_SEL 8 #define CSI2_RX_CFG0_DL2_INPUT_SEL 12 #define CSI2_RX_CFG0_DL3_INPUT_SEL 16 #define CSI2_RX_CFG0_PHY_NUM_SEL 20 #define CSI2_RX_CFG0_PHY_SEL_BASE_IDX 1 #define CSI2_RX_CFG0_PHY_TYPE_SEL 24 #define CSID_CSI2_RX_CFG1 0x204 #define CSI2_RX_CFG1_PACKET_ECC_CORRECTION_EN BIT(0) #define CSI2_RX_CFG1_DE_SCRAMBLE_EN BIT(1) #define CSI2_RX_CFG1_VC_MODE BIT(2) #define CSI2_RX_CFG1_COMPLETE_STREAM_EN BIT(4) #define CSI2_RX_CFG1_COMPLETE_STREAM_FRAME_TIMING BIT(5) #define CSI2_RX_CFG1_MISR_EN BIT(6) #define CSI2_RX_CFG1_CGC_MODE BIT(7) #define CSID_CSI2_RX_CAPTURE_CTRL 0x208 #define CSI2_RX_CAPTURE_CTRL_LONG_PKT_EN BIT(0) #define CSI2_RX_CAPTURE_CTRL_SHORT_PKT_EN BIT(1) #define CSI2_RX_CAPTURE_CTRL_CPHY_PKT_EN BIT(2) #define CSI2_RX_CAPTURE_CTRL_LONG_PKT_DT GENMASK(9, 4) #define CSI2_RX_CAPTURE_CTRL_LONG_PKT_VC GENMASK(14, 10) #define CSI2_RX_CAPTURE_CTRL_SHORT_PKT_VC GENMASK(19, 15) #define CSI2_RX_CAPTURE_CTRL_CPHY_PKT_DT GENMASK(20, 25) #define CSI2_RX_CAPTURE_CTRL_CPHY_PKT_VC GENMASK(30, 26) #define CSID_CSI2_RX_TOTAL_PKTS_RCVD 0x240 #define CSID_CSI2_RX_STATS_ECC 0x244 #define CSID_CSI2_RX_CRC_ERRORS 0x248 #define CSID_RDI_CFG0(rdi) (0x500 + 0x100 * (rdi)) #define RDI_CFG0_DECODE_FORMAT 12 #define RDI_CFG0_DATA_TYPE 16 #define RDI_CFG0_VIRTUAL_CHANNEL 22 #define RDI_CFG0_DT_ID 27 #define RDI_CFG0_ENABLE BIT(31) #define CSID_RDI_CTRL(rdi) (0x504 + 0x100 * (rdi)) #define CSID_RDI_CTRL_HALT_CMD_HALT_AT_FRAME_BOUNDARY 0 #define CSID_RDI_CTRL_HALT_CMD_RESUME_AT_FRAME_BOUNDARY 1 #define CSID_RDI_CFG1(rdi) (0x510 + 0x100 * (rdi)) #define RDI_CFG1_TIMESTAMP_STB_FRAME BIT(0) #define RDI_CFG1_TIMESTAMP_STB_IRQ BIT(1) #define RDI_CFG1_BYTE_CNTR_EN BIT(2) #define RDI_CFG1_TIMESTAMP_EN BIT(4) #define RDI_CFG1_DROP_H_EN BIT(5) #define RDI_CFG1_DROP_V_EN BIT(6) #define RDI_CFG1_CROP_H_EN BIT(7) #define RDI_CFG1_CROP_V_EN BIT(8) #define RDI_CFG1_MISR_EN BIT(9) #define RDI_CFG1_PLAIN_ALIGN_MSB BIT(11) #define RDI_CFG1_EARLY_EOF_EN BIT(14) #define RDI_CFG1_PACKING_MIPI BIT(15) #define CSID_RDI_ERR_RECOVERY_CFG0(rdi) (0x514 + 0x100 * (rdi)) #define CSID_RDI_EPOCH_IRQ_CFG(rdi) (0x52c + 0x100 * (rdi)) #define CSID_RDI_FRM_DROP_PATTERN(rdi) (0x540 + 0x100 * (rdi)) #define CSID_RDI_FRM_DROP_PERIOD(rdi) (0x544 + 0x100 * (rdi)) #define CSID_RDI_IRQ_SUBSAMPLE_PATTERN(rdi) (0x548 + 0x100 * (rdi)) #define CSID_RDI_IRQ_SUBSAMPLE_PERIOD(rdi) (0x54c + 0x100 * (rdi)) #define CSID_RDI_PIX_DROP_PATTERN(rdi) (0x558 + 0x100 * (rdi)) #define CSID_RDI_PIX_DROP_PERIOD(rdi) (0x55c + 0x100 * (rdi)) #define CSID_RDI_LINE_DROP_PATTERN(rdi) (0x560 + 0x100 * (rdi)) #define CSID_RDI_LINE_DROP_PERIOD(rdi) (0x564 + 0x100 * (rdi)) static inline int reg_update_rdi(struct csid_device *csid, int n) { return BIT(4 + n) + BIT(20 + n); } static void csid_reg_update(struct csid_device *csid, int port_id) { csid->reg_update |= reg_update_rdi(csid, port_id); writel(csid->reg_update, csid->base + CSID_REG_UPDATE_CMD); } static inline void csid_reg_update_clear(struct csid_device *csid, int port_id) { csid->reg_update &= ~reg_update_rdi(csid, port_id); writel(csid->reg_update, csid->base + CSID_REG_UPDATE_CMD); } static void __csid_configure_rx(struct csid_device *csid, struct csid_phy_config *phy, int vc) { u32 val; val = (phy->lane_cnt - 1) << CSI2_RX_CFG0_NUM_ACTIVE_LANES; val |= phy->lane_assign << CSI2_RX_CFG0_DL0_INPUT_SEL; val |= (phy->csiphy_id + CSI2_RX_CFG0_PHY_SEL_BASE_IDX) << CSI2_RX_CFG0_PHY_NUM_SEL; writel(val, csid->base + CSID_CSI2_RX_CFG0); val = CSI2_RX_CFG1_PACKET_ECC_CORRECTION_EN; if (vc > 3) val |= CSI2_RX_CFG1_VC_MODE; writel(val, csid->base + CSID_CSI2_RX_CFG1); } static void __csid_ctrl_rdi(struct csid_device *csid, int enable, u8 rdi) { u32 val; if (enable) val = CSID_RDI_CTRL_HALT_CMD_RESUME_AT_FRAME_BOUNDARY; else val = CSID_RDI_CTRL_HALT_CMD_HALT_AT_FRAME_BOUNDARY; writel(val, csid->base + CSID_RDI_CTRL(rdi)); } static void __csid_configure_top(struct csid_device *csid) { u32 val; val = CSID_TOP_IO_PATH_CFG0_OUTPUT_IFE_EN | CSID_TOP_IO_PATH_CFG0_INTERNAL_CSID; writel(val, csid->camss->csid_wrapper_base + CSID_TOP_IO_PATH_CFG0(csid->id)); } static void __csid_configure_rdi_stream(struct csid_device *csid, u8 enable, u8 vc) { struct v4l2_mbus_framefmt *input_format = &csid->fmt[MSM_CSID_PAD_FIRST_SRC + vc]; const struct csid_format_info *format = csid_get_fmt_entry(csid->res->formats->formats, csid->res->formats->nformats, input_format->code); u8 lane_cnt = csid->phy.lane_cnt; u8 dt_id; u32 val; if (!lane_cnt) lane_cnt = 4; val = 0; writel(val, csid->base + CSID_RDI_FRM_DROP_PERIOD(vc)); /* * DT_ID is a two bit bitfield that is concatenated with * the four least significant bits of the five bit VC * bitfield to generate an internal CID value. * * CSID_RDI_CFG0(vc) * DT_ID : 28:27 * VC : 26:22 * DT : 21:16 * * CID : VC 3:0 << 2 | DT_ID 1:0 */ dt_id = vc & 0x03; /* note: for non-RDI path, this should be format->decode_format */ val |= DECODE_FORMAT_PAYLOAD_ONLY << RDI_CFG0_DECODE_FORMAT; val |= format->data_type << RDI_CFG0_DATA_TYPE; val |= vc << RDI_CFG0_VIRTUAL_CHANNEL; val |= dt_id << RDI_CFG0_DT_ID; writel(val, csid->base + CSID_RDI_CFG0(vc)); val = RDI_CFG1_TIMESTAMP_STB_FRAME; val |= RDI_CFG1_BYTE_CNTR_EN; val |= RDI_CFG1_TIMESTAMP_EN; val |= RDI_CFG1_DROP_H_EN; val |= RDI_CFG1_DROP_V_EN; val |= RDI_CFG1_CROP_H_EN; val |= RDI_CFG1_CROP_V_EN; val |= RDI_CFG1_PACKING_MIPI; writel(val, csid->base + CSID_RDI_CFG1(vc)); val = 0; writel(val, csid->base + CSID_RDI_IRQ_SUBSAMPLE_PERIOD(vc)); val = 1; writel(val, csid->base + CSID_RDI_IRQ_SUBSAMPLE_PATTERN(vc)); val = 0; writel(val, csid->base + CSID_RDI_CTRL(vc)); val = readl(csid->base + CSID_RDI_CFG0(vc)); if (enable) val |= RDI_CFG0_ENABLE; else val &= ~RDI_CFG0_ENABLE; writel(val, csid->base + CSID_RDI_CFG0(vc)); } static void csid_configure_stream(struct csid_device *csid, u8 enable) { int i; __csid_configure_top(csid); /* Loop through all enabled VCs and configure stream for each */ for (i = 0; i < MSM_CSID_MAX_SRC_STREAMS; i++) { if (csid->phy.en_vc & BIT(i)) { __csid_configure_rdi_stream(csid, enable, i); __csid_configure_rx(csid, &csid->phy, i); __csid_ctrl_rdi(csid, enable, i); } } } /* * csid_reset - Trigger reset on CSID module and wait to complete * @csid: CSID device * * Return 0 on success or a negative error code otherwise */ static int csid_reset(struct csid_device *csid) { unsigned long time; u32 val; int i; reinit_completion(&csid->reset_complete); writel(CSID_IRQ_CMD_CLEAR, csid->base + CSID_IRQ_CMD); /* preserve registers */ val = CSID_RESET_CFG_MODE_IMMEDIATE | CSID_RESET_CFG_LOCATION_COMPLETE; writel(val, csid->base + CSID_RESET_CFG); val = CSID_RESET_CMD_HW_RESET | CSID_RESET_CMD_SW_RESET; writel(val, csid->base + CSID_RESET_CMD); time = wait_for_completion_timeout(&csid->reset_complete, msecs_to_jiffies(CSID_RESET_TIMEOUT_MS)); if (!time) { dev_err(csid->camss->dev, "CSID reset timeout\n"); return -EIO; } for (i = 0; i < MSM_CSID_MAX_SRC_STREAMS; i++) { /* Enable RUP done for the client port */ writel(CSID_CSI2_RDIN_RUP_DONE, csid->base + CSID_CSI2_RDIN_IRQ_MASK(i)); } /* Clear RDI status */ writel(~0u, csid->base + CSID_BUF_DONE_IRQ_CLEAR); /* Enable BUF_DONE bit for all write-master client ports */ writel(~0u, csid->base + CSID_BUF_DONE_IRQ_MASK); /* Unmask all TOP interrupts */ writel(~0u, csid->base + CSID_TOP_IRQ_MASK); return 0; } static void csid_rup_complete(struct csid_device *csid, int rdi) { csid_reg_update_clear(csid, rdi); } /* * csid_isr - CSID module interrupt service routine * @irq: Interrupt line * @dev: CSID device * * Return IRQ_HANDLED on success */ static irqreturn_t csid_isr(int irq, void *dev) { struct csid_device *csid = dev; u32 buf_done_val, val, val_top; int i; /* Latch and clear TOP status */ val_top = readl(csid->base + CSID_TOP_IRQ_STATUS); writel(val_top, csid->base + CSID_TOP_IRQ_CLEAR); /* Latch and clear CSID_CSI2 status */ val = readl(csid->base + CSID_CSI2_RX_IRQ_STATUS); writel(val, csid->base + CSID_CSI2_RX_IRQ_CLEAR); /* Latch and clear top level BUF_DONE status */ buf_done_val = readl(csid->base + CSID_BUF_DONE_IRQ_STATUS); writel(buf_done_val, csid->base + CSID_BUF_DONE_IRQ_CLEAR); /* Process state for each RDI channel */ for (i = 0; i < MSM_CSID_MAX_SRC_STREAMS; i++) { val = readl(csid->base + CSID_CSI2_RDIN_IRQ_STATUS(i)); if (val) writel(val, csid->base + CSID_CSI2_RDIN_IRQ_CLEAR(i)); if (val & CSID_CSI2_RDIN_RUP_DONE) csid_rup_complete(csid, i); if (buf_done_val & BIT(BUF_DONE_IRQ_STATUS_RDI_OFFSET + i)) camss_buf_done(csid->camss, csid->id, i); } /* Issue clear command */ writel(CSID_IRQ_CMD_CLEAR, csid->base + CSID_IRQ_CMD); /* Reset complete */ if (val_top & CSID_TOP_IRQ_RESET) complete(&csid->reset_complete); return IRQ_HANDLED; } static void csid_subdev_reg_update(struct csid_device *csid, int port_id, bool is_clear) { if (is_clear) csid_reg_update_clear(csid, port_id); else csid_reg_update(csid, port_id); } static void csid_subdev_init(struct csid_device *csid) {} const struct csid_hw_ops csid_ops_680 = { .configure_testgen_pattern = NULL, .configure_stream = csid_configure_stream, .hw_version = csid_hw_version, .isr = csid_isr, .reset = csid_reset, .src_pad_code = csid_src_pad_code, .subdev_init = csid_subdev_init, .reg_update = csid_subdev_reg_update, };