/* SPDX-License-Identifier: (GPL-2.0 OR BSD-3-Clause) */ /* Copyright(c) 2015-17 Intel Corporation. */ #ifndef __SOUNDWIRE_H #define __SOUNDWIRE_H #include #include struct sdw_bus; struct sdw_slave; /* SDW spec defines and enums, as defined by MIPI 1.1. Spec */ /* SDW Broadcast Device Number */ #define SDW_BROADCAST_DEV_NUM 15 /* SDW Enumeration Device Number */ #define SDW_ENUM_DEV_NUM 0 /* SDW Group Device Numbers */ #define SDW_GROUP12_DEV_NUM 12 #define SDW_GROUP13_DEV_NUM 13 /* SDW Master Device Number, not supported yet */ #define SDW_MASTER_DEV_NUM 14 #define SDW_NUM_DEV_ID_REGISTERS 6 /* frame shape defines */ /* * Note: The maximum row define in SoundWire spec 1.1 is 23. In order to * fill hole with 0, one more dummy entry is added */ #define SDW_FRAME_ROWS 24 #define SDW_FRAME_COLS 8 #define SDW_FRAME_ROW_COLS (SDW_FRAME_ROWS * SDW_FRAME_COLS) #define SDW_FRAME_CTRL_BITS 48 #define SDW_MAX_DEVICES 11 #define SDW_MAX_PORTS 15 #define SDW_VALID_PORT_RANGE(n) ((n) < SDW_MAX_PORTS && (n) >= 1) enum { SDW_PORT_DIRN_SINK = 0, SDW_PORT_DIRN_SOURCE, SDW_PORT_DIRN_MAX, }; /* * constants for flow control, ports and transport * * these are bit masks as devices can have multiple capabilities */ /* * flow modes for SDW port. These can be isochronous, tx controlled, * rx controlled or async */ #define SDW_PORT_FLOW_MODE_ISOCH 0 #define SDW_PORT_FLOW_MODE_TX_CNTRL BIT(0) #define SDW_PORT_FLOW_MODE_RX_CNTRL BIT(1) #define SDW_PORT_FLOW_MODE_ASYNC GENMASK(1, 0) /* sample packaging for block. It can be per port or per channel */ #define SDW_BLOCK_PACKG_PER_PORT BIT(0) #define SDW_BLOCK_PACKG_PER_CH BIT(1) /** * enum sdw_slave_status - Slave status * @SDW_SLAVE_UNATTACHED: Slave is not attached with the bus. * @SDW_SLAVE_ATTACHED: Slave is attached with bus. * @SDW_SLAVE_ALERT: Some alert condition on the Slave * @SDW_SLAVE_RESERVED: Reserved for future use */ enum sdw_slave_status { SDW_SLAVE_UNATTACHED = 0, SDW_SLAVE_ATTACHED = 1, SDW_SLAVE_ALERT = 2, SDW_SLAVE_RESERVED = 3, }; /** * enum sdw_clk_stop_type: clock stop operations * * @SDW_CLK_PRE_PREPARE: pre clock stop prepare * @SDW_CLK_POST_PREPARE: post clock stop prepare * @SDW_CLK_PRE_DEPREPARE: pre clock stop de-prepare * @SDW_CLK_POST_DEPREPARE: post clock stop de-prepare */ enum sdw_clk_stop_type { SDW_CLK_PRE_PREPARE = 0, SDW_CLK_POST_PREPARE, SDW_CLK_PRE_DEPREPARE, SDW_CLK_POST_DEPREPARE, }; /** * enum sdw_command_response - Command response as defined by SDW spec * @SDW_CMD_OK: cmd was successful * @SDW_CMD_IGNORED: cmd was ignored * @SDW_CMD_FAIL: cmd was NACKed * @SDW_CMD_TIMEOUT: cmd timedout * @SDW_CMD_FAIL_OTHER: cmd failed due to other reason than above * * NOTE: The enum is different than actual Spec as response in the Spec is * combination of ACK/NAK bits * * SDW_CMD_TIMEOUT/FAIL_OTHER is defined for SW use, not in spec */ enum sdw_command_response { SDW_CMD_OK = 0, SDW_CMD_IGNORED = 1, SDW_CMD_FAIL = 2, SDW_CMD_TIMEOUT = 3, SDW_CMD_FAIL_OTHER = 4, }; /* block group count enum */ enum sdw_dpn_grouping { SDW_BLK_GRP_CNT_1 = 0, SDW_BLK_GRP_CNT_2 = 1, SDW_BLK_GRP_CNT_3 = 2, SDW_BLK_GRP_CNT_4 = 3, }; /* block packing mode enum */ enum sdw_dpn_pkg_mode { SDW_BLK_PKG_PER_PORT = 0, SDW_BLK_PKG_PER_CHANNEL = 1 }; /** * enum sdw_stream_type: data stream type * * @SDW_STREAM_PCM: PCM data stream * @SDW_STREAM_PDM: PDM data stream * * spec doesn't define this, but is used in implementation */ enum sdw_stream_type { SDW_STREAM_PCM = 0, SDW_STREAM_PDM = 1, }; /** * enum sdw_data_direction: Data direction * * @SDW_DATA_DIR_RX: Data into Port * @SDW_DATA_DIR_TX: Data out of Port */ enum sdw_data_direction { SDW_DATA_DIR_RX = 0, SDW_DATA_DIR_TX = 1, }; /** * enum sdw_port_data_mode: Data Port mode * * @SDW_PORT_DATA_MODE_NORMAL: Normal data mode where audio data is received * and transmitted. * @SDW_PORT_DATA_MODE_PRBS: Test mode which uses a PRBS generator to produce * a pseudo random data pattern that is transferred * @SDW_PORT_DATA_MODE_STATIC_0: Simple test mode which uses static value of * logic 0. The encoding will result in no signal transitions * @SDW_PORT_DATA_MODE_STATIC_1: Simple test mode which uses static value of * logic 1. The encoding will result in signal transitions at every bitslot * owned by this Port */ enum sdw_port_data_mode { SDW_PORT_DATA_MODE_NORMAL = 0, SDW_PORT_DATA_MODE_PRBS = 1, SDW_PORT_DATA_MODE_STATIC_0 = 2, SDW_PORT_DATA_MODE_STATIC_1 = 3, }; /* * SDW properties, defined in MIPI DisCo spec v1.0 */ enum sdw_clk_stop_reset_behave { SDW_CLK_STOP_KEEP_STATUS = 1, }; /** * enum sdw_p15_behave - Slave Port 15 behaviour when the Master attempts a * read * @SDW_P15_READ_IGNORED: Read is ignored * @SDW_P15_CMD_OK: Command is ok */ enum sdw_p15_behave { SDW_P15_READ_IGNORED = 0, SDW_P15_CMD_OK = 1, }; /** * enum sdw_dpn_type - Data port types * @SDW_DPN_FULL: Full Data Port is supported * @SDW_DPN_SIMPLE: Simplified Data Port as defined in spec. * DPN_SampleCtrl2, DPN_OffsetCtrl2, DPN_HCtrl and DPN_BlockCtrl3 * are not implemented. * @SDW_DPN_REDUCED: Reduced Data Port as defined in spec. * DPN_SampleCtrl2, DPN_HCtrl are not implemented. */ enum sdw_dpn_type { SDW_DPN_FULL = 0, SDW_DPN_SIMPLE = 1, SDW_DPN_REDUCED = 2, }; /** * enum sdw_clk_stop_mode - Clock Stop modes * @SDW_CLK_STOP_MODE0: Slave can continue operation seamlessly on clock * restart * @SDW_CLK_STOP_MODE1: Slave may have entered a deeper power-saving mode, * not capable of continuing operation seamlessly when the clock restarts */ enum sdw_clk_stop_mode { SDW_CLK_STOP_MODE0 = 0, SDW_CLK_STOP_MODE1 = 1, }; /** * struct sdw_dp0_prop - DP0 properties * @max_word: Maximum number of bits in a Payload Channel Sample, 1 to 64 * (inclusive) * @min_word: Minimum number of bits in a Payload Channel Sample, 1 to 64 * (inclusive) * @num_words: number of wordlengths supported * @words: wordlengths supported * @BRA_flow_controlled: Slave implementation results in an OK_NotReady * response * @simple_ch_prep_sm: If channel prepare sequence is required * @imp_def_interrupts: If set, each bit corresponds to support for * implementation-defined interrupts * * The wordlengths are specified by Spec as max, min AND number of * discrete values, implementation can define based on the wordlengths they * support */ struct sdw_dp0_prop { u32 max_word; u32 min_word; u32 num_words; u32 *words; bool BRA_flow_controlled; bool simple_ch_prep_sm; bool imp_def_interrupts; }; /** * struct sdw_dpn_audio_mode - Audio mode properties for DPn * @bus_min_freq: Minimum bus frequency, in Hz * @bus_max_freq: Maximum bus frequency, in Hz * @bus_num_freq: Number of discrete frequencies supported * @bus_freq: Discrete bus frequencies, in Hz * @min_freq: Minimum sampling frequency, in Hz * @max_freq: Maximum sampling bus frequency, in Hz * @num_freq: Number of discrete sampling frequency supported * @freq: Discrete sampling frequencies, in Hz * @prep_ch_behave: Specifies the dependencies between Channel Prepare * sequence and bus clock configuration * If 0, Channel Prepare can happen at any Bus clock rate * If 1, Channel Prepare sequence shall happen only after Bus clock is * changed to a frequency supported by this mode or compatible modes * described by the next field * @glitchless: Bitmap describing possible glitchless transitions from this * Audio Mode to other Audio Modes */ struct sdw_dpn_audio_mode { u32 bus_min_freq; u32 bus_max_freq; u32 bus_num_freq; u32 *bus_freq; u32 max_freq; u32 min_freq; u32 num_freq; u32 *freq; u32 prep_ch_behave; u32 glitchless; }; /** * struct sdw_dpn_prop - Data Port DPn properties * @num: port number * @max_word: Maximum number of bits in a Payload Channel Sample, 1 to 64 * (inclusive) * @min_word: Minimum number of bits in a Payload Channel Sample, 1 to 64 * (inclusive) * @num_words: Number of discrete supported wordlengths * @words: Discrete supported wordlength * @type: Data port type. Full, Simplified or Reduced * @max_grouping: Maximum number of samples that can be grouped together for * a full data port * @simple_ch_prep_sm: If the port supports simplified channel prepare state * machine * @ch_prep_timeout: Port-specific timeout value, in milliseconds * @imp_def_interrupts: If set, each bit corresponds to support for * implementation-defined interrupts * @max_ch: Maximum channels supported * @min_ch: Minimum channels supported * @num_channels: Number of discrete channels supported * @channels: Discrete channels supported * @num_ch_combinations: Number of channel combinations supported * @ch_combinations: Channel combinations supported * @modes: SDW mode supported * @max_async_buffer: Number of samples that this port can buffer in * asynchronous modes * @block_pack_mode: Type of block port mode supported * @read_only_wordlength: Read Only wordlength field in DPN_BlockCtrl1 register * @port_encoding: Payload Channel Sample encoding schemes supported * @audio_modes: Audio modes supported */ struct sdw_dpn_prop { u32 num; u32 max_word; u32 min_word; u32 num_words; u32 *words; enum sdw_dpn_type type; u32 max_grouping; bool simple_ch_prep_sm; u32 ch_prep_timeout; u32 imp_def_interrupts; u32 max_ch; u32 min_ch; u32 num_channels; u32 *channels; u32 num_ch_combinations; u32 *ch_combinations; u32 modes; u32 max_async_buffer; bool block_pack_mode; bool read_only_wordlength; u32 port_encoding; struct sdw_dpn_audio_mode *audio_modes; }; /** * struct sdw_slave_prop - SoundWire Slave properties * @mipi_revision: Spec version of the implementation * @wake_capable: Wake-up events are supported * @test_mode_capable: If test mode is supported * @clk_stop_mode1: Clock-Stop Mode 1 is supported * @simple_clk_stop_capable: Simple clock mode is supported * @clk_stop_timeout: Worst-case latency of the Clock Stop Prepare State * Machine transitions, in milliseconds * @ch_prep_timeout: Worst-case latency of the Channel Prepare State Machine * transitions, in milliseconds * @reset_behave: Slave keeps the status of the SlaveStopClockPrepare * state machine (P=1 SCSP_SM) after exit from clock-stop mode1 * @high_PHY_capable: Slave is HighPHY capable * @paging_support: Slave implements paging registers SCP_AddrPage1 and * SCP_AddrPage2 * @bank_delay_support: Slave implements bank delay/bridge support registers * SCP_BankDelay and SCP_NextFrame * @p15_behave: Slave behavior when the Master attempts a read to the Port15 * alias * @lane_control_support: Slave supports lane control * @master_count: Number of Masters present on this Slave * @source_ports: Bitmap identifying source ports * @sink_ports: Bitmap identifying sink ports * @dp0_prop: Data Port 0 properties * @src_dpn_prop: Source Data Port N properties * @sink_dpn_prop: Sink Data Port N properties * @scp_int1_mask: SCP_INT1_MASK desired settings * @quirks: bitmask identifying deltas from the MIPI specification * @is_sdca: the Slave supports the SDCA specification */ struct sdw_slave_prop { u32 mipi_revision; bool wake_capable; bool test_mode_capable; bool clk_stop_mode1; bool simple_clk_stop_capable; u32 clk_stop_timeout; u32 ch_prep_timeout; enum sdw_clk_stop_reset_behave reset_behave; bool high_PHY_capable; bool paging_support; bool bank_delay_support; enum sdw_p15_behave p15_behave; bool lane_control_support; u32 master_count; u32 source_ports; u32 sink_ports; struct sdw_dp0_prop *dp0_prop; struct sdw_dpn_prop *src_dpn_prop; struct sdw_dpn_prop *sink_dpn_prop; u8 scp_int1_mask; u32 quirks; bool is_sdca; }; #define SDW_SLAVE_QUIRKS_INVALID_INITIAL_PARITY BIT(0) /** * struct sdw_master_prop - Master properties * @revision: MIPI spec version of the implementation * @clk_stop_modes: Bitmap, bit N set when clock-stop-modeN supported * @max_clk_freq: Maximum Bus clock frequency, in Hz * @num_clk_gears: Number of clock gears supported * @clk_gears: Clock gears supported * @num_clk_freq: Number of clock frequencies supported, in Hz * @clk_freq: Clock frequencies supported, in Hz * @default_frame_rate: Controller default Frame rate, in Hz * @default_row: Number of rows * @default_col: Number of columns * @dynamic_frame: Dynamic frame shape supported * @err_threshold: Number of times that software may retry sending a single * command * @mclk_freq: clock reference passed to SoundWire Master, in Hz. * @hw_disabled: if true, the Master is not functional, typically due to pin-mux * @quirks: bitmask identifying optional behavior beyond the scope of the MIPI specification */ struct sdw_master_prop { u32 revision; u32 clk_stop_modes; u32 max_clk_freq; u32 num_clk_gears; u32 *clk_gears; u32 num_clk_freq; u32 *clk_freq; u32 default_frame_rate; u32 default_row; u32 default_col; bool dynamic_frame; u32 err_threshold; u32 mclk_freq; bool hw_disabled; u64 quirks; }; /* Definitions for Master quirks */ /* * In a number of platforms bus clashes are reported after a hardware * reset but without any explanations or evidence of a real problem. * The following quirk will discard all initial bus clash interrupts * but will leave the detection on should real bus clashes happen */ #define SDW_MASTER_QUIRKS_CLEAR_INITIAL_CLASH BIT(0) /* * Some Slave devices have known issues with incorrect parity errors * reported after a hardware reset. However during integration unexplained * parity errors can be reported by Slave devices, possibly due to electrical * issues at the Master level. * The following quirk will discard all initial parity errors but will leave * the detection on should real parity errors happen. */ #define SDW_MASTER_QUIRKS_CLEAR_INITIAL_PARITY BIT(1) int sdw_master_read_prop(struct sdw_bus *bus); int sdw_slave_read_prop(struct sdw_slave *slave); /* * SDW Slave Structures and APIs */ #define SDW_IGNORED_UNIQUE_ID 0xFF /** * struct sdw_slave_id - Slave ID * @mfg_id: MIPI Manufacturer ID * @part_id: Device Part ID * @class_id: MIPI Class ID (defined starting with SoundWire 1.2 spec) * @unique_id: Device unique ID * @sdw_version: SDW version implemented * * The order of the IDs here does not follow the DisCo spec definitions */ struct sdw_slave_id { __u16 mfg_id; __u16 part_id; __u8 class_id; __u8 unique_id; __u8 sdw_version:4; }; /* * Helper macros to extract the MIPI-defined IDs * * Spec definition * Register Bit Contents * DevId_0 [7:4] 47:44 sdw_version * DevId_0 [3:0] 43:40 unique_id * DevId_1 39:32 mfg_id [15:8] * DevId_2 31:24 mfg_id [7:0] * DevId_3 23:16 part_id [15:8] * DevId_4 15:08 part_id [7:0] * DevId_5 07:00 class_id * * The MIPI DisCo for SoundWire defines in addition the link_id as bits 51:48 */ #define SDW_DISCO_LINK_ID_MASK GENMASK_ULL(51, 48) #define SDW_VERSION_MASK GENMASK_ULL(47, 44) #define SDW_UNIQUE_ID_MASK GENMASK_ULL(43, 40) #define SDW_MFG_ID_MASK GENMASK_ULL(39, 24) #define SDW_PART_ID_MASK GENMASK_ULL(23, 8) #define SDW_CLASS_ID_MASK GENMASK_ULL(7, 0) #define SDW_DISCO_LINK_ID(addr) FIELD_GET(SDW_DISCO_LINK_ID_MASK, addr) #define SDW_VERSION(addr) FIELD_GET(SDW_VERSION_MASK, addr) #define SDW_UNIQUE_ID(addr) FIELD_GET(SDW_UNIQUE_ID_MASK, addr) #define SDW_MFG_ID(addr) FIELD_GET(SDW_MFG_ID_MASK, addr) #define SDW_PART_ID(addr) FIELD_GET(SDW_PART_ID_MASK, addr) #define SDW_CLASS_ID(addr) FIELD_GET(SDW_CLASS_ID_MASK, addr) /** * struct sdw_slave_intr_status - Slave interrupt status * @sdca_cascade: set if the Slave device reports an SDCA interrupt * @control_port: control port status * @port: data port status */ struct sdw_slave_intr_status { bool sdca_cascade; u8 control_port; u8 port[15]; }; /** * sdw_reg_bank - SoundWire register banks * @SDW_BANK0: Soundwire register bank 0 * @SDW_BANK1: Soundwire register bank 1 */ enum sdw_reg_bank { SDW_BANK0, SDW_BANK1, }; /** * struct sdw_bus_conf: Bus configuration * * @clk_freq: Clock frequency, in Hz * @num_rows: Number of rows in frame * @num_cols: Number of columns in frame * @bank: Next register bank */ struct sdw_bus_conf { unsigned int clk_freq; unsigned int num_rows; unsigned int num_cols; unsigned int bank; }; /** * struct sdw_prepare_ch: Prepare/De-prepare Data Port channel * * @num: Port number * @ch_mask: Active channel mask * @prepare: Prepare (true) /de-prepare (false) channel * @bank: Register bank, which bank Slave/Master driver should program for * implementation defined registers. This is always updated to next_bank * value read from bus params. * */ struct sdw_prepare_ch { unsigned int num; unsigned int ch_mask; bool prepare; unsigned int bank; }; /** * enum sdw_port_prep_ops: Prepare operations for Data Port * * @SDW_OPS_PORT_PRE_PREP: Pre prepare operation for the Port * @SDW_OPS_PORT_PREP: Prepare operation for the Port * @SDW_OPS_PORT_POST_PREP: Post prepare operation for the Port */ enum sdw_port_prep_ops { SDW_OPS_PORT_PRE_PREP = 0, SDW_OPS_PORT_PREP = 1, SDW_OPS_PORT_POST_PREP = 2, }; /** * struct sdw_bus_params: Structure holding bus configuration * * @curr_bank: Current bank in use (BANK0/BANK1) * @next_bank: Next bank to use (BANK0/BANK1). next_bank will always be * set to !curr_bank * @max_dr_freq: Maximum double rate clock frequency supported, in Hz * @curr_dr_freq: Current double rate clock frequency, in Hz * @bandwidth: Current bandwidth * @col: Active columns * @row: Active rows * @s_data_mode: NORMAL, STATIC or PRBS mode for all Slave ports * @m_data_mode: NORMAL, STATIC or PRBS mode for all Master ports. The value * should be the same to detect transmission issues, but can be different to * test the interrupt reports */ struct sdw_bus_params { enum sdw_reg_bank curr_bank; enum sdw_reg_bank next_bank; unsigned int max_dr_freq; unsigned int curr_dr_freq; unsigned int bandwidth; unsigned int col; unsigned int row; int s_data_mode; int m_data_mode; }; /** * struct sdw_slave_ops: Slave driver callback ops * * @read_prop: Read Slave properties * @interrupt_callback: Device interrupt notification (invoked in thread * context) * @update_status: Update Slave status * @bus_config: Update the bus config for Slave * @port_prep: Prepare the port with parameters * @clk_stop: handle imp-def sequences before and after prepare and de-prepare */ struct sdw_slave_ops { int (*read_prop)(struct sdw_slave *sdw); int (*interrupt_callback)(struct sdw_slave *slave, struct sdw_slave_intr_status *status); int (*update_status)(struct sdw_slave *slave, enum sdw_slave_status status); int (*bus_config)(struct sdw_slave *slave, struct sdw_bus_params *params); int (*port_prep)(struct sdw_slave *slave, struct sdw_prepare_ch *prepare_ch, enum sdw_port_prep_ops pre_ops); int (*clk_stop)(struct sdw_slave *slave, enum sdw_clk_stop_mode mode, enum sdw_clk_stop_type type); }; /** * struct sdw_slave - SoundWire Slave * @id: MIPI device ID * @dev: Linux device * @status: Status reported by the Slave * @bus: Bus handle * @prop: Slave properties * @debugfs: Slave debugfs * @node: node for bus list * @port_ready: Port ready completion flag for each Slave port * @m_port_map: static Master port map for each Slave port * @dev_num: Current Device Number, values can be 0 or dev_num_sticky * @dev_num_sticky: one-time static Device Number assigned by Bus * @probed: boolean tracking driver state * @enumeration_complete: completion utility to control potential races * on startup between device enumeration and read/write access to the * Slave device * @initialization_complete: completion utility to control potential races * on startup between device enumeration and settings being restored * @unattach_request: mask field to keep track why the Slave re-attached and * was re-initialized. This is useful to deal with potential race conditions * between the Master suspending and the codec resuming, and make sure that * when the Master triggered a reset the Slave is properly enumerated and * initialized * @first_interrupt_done: status flag tracking if the interrupt handling * for a Slave happens for the first time after enumeration * @is_mockup_device: status flag used to squelch errors in the command/control * protocol for SoundWire mockup devices * @sdw_dev_lock: mutex used to protect callbacks/remove races */ struct sdw_slave { struct sdw_slave_id id; struct device dev; enum sdw_slave_status status; struct sdw_bus *bus; struct sdw_slave_prop prop; #ifdef CONFIG_DEBUG_FS struct dentry *debugfs; #endif struct list_head node; struct completion port_ready[SDW_MAX_PORTS]; unsigned int m_port_map[SDW_MAX_PORTS]; u16 dev_num; u16 dev_num_sticky; bool probed; struct completion enumeration_complete; struct completion initialization_complete; u32 unattach_request; bool first_interrupt_done; bool is_mockup_device; struct mutex sdw_dev_lock; /* protect callbacks/remove races */ }; #define dev_to_sdw_dev(_dev) container_of(_dev, struct sdw_slave, dev) /** * struct sdw_master_device - SoundWire 'Master Device' representation * @dev: Linux device for this Master * @bus: Bus handle shortcut */ struct sdw_master_device { struct device dev; struct sdw_bus *bus; }; #define dev_to_sdw_master_device(d) \ container_of(d, struct sdw_master_device, dev) struct sdw_driver { const char *name; int (*probe)(struct sdw_slave *sdw, const struct sdw_device_id *id); int (*remove)(struct sdw_slave *sdw); void (*shutdown)(struct sdw_slave *sdw); const struct sdw_device_id *id_table; const struct sdw_slave_ops *ops; struct device_driver driver; }; #define SDW_SLAVE_ENTRY_EXT(_mfg_id, _part_id, _version, _c_id, _drv_data) \ { .mfg_id = (_mfg_id), .part_id = (_part_id), \ .sdw_version = (_version), .class_id = (_c_id), \ .driver_data = (unsigned long)(_drv_data) } #define SDW_SLAVE_ENTRY(_mfg_id, _part_id, _drv_data) \ SDW_SLAVE_ENTRY_EXT((_mfg_id), (_part_id), 0, 0, (_drv_data)) int sdw_handle_slave_status(struct sdw_bus *bus, enum sdw_slave_status status[]); /* * SDW master structures and APIs */ /** * struct sdw_port_params: Data Port parameters * * @num: Port number * @bps: Word length of the Port * @flow_mode: Port Data flow mode * @data_mode: Test modes or normal mode * * This is used to program the Data Port based on Data Port stream * parameters. */ struct sdw_port_params { unsigned int num; unsigned int bps; unsigned int flow_mode; unsigned int data_mode; }; /** * struct sdw_transport_params: Data Port Transport Parameters * * @blk_grp_ctrl_valid: Port implements block group control * @num: Port number * @blk_grp_ctrl: Block group control value * @sample_interval: Sample interval * @offset1: Blockoffset of the payload data * @offset2: Blockoffset of the payload data * @hstart: Horizontal start of the payload data * @hstop: Horizontal stop of the payload data * @blk_pkg_mode: Block per channel or block per port * @lane_ctrl: Data lane Port uses for Data transfer. Currently only single * data lane is supported in bus * * This is used to program the Data Port based on Data Port transport * parameters. All these parameters are banked and can be modified * during a bank switch without any artifacts in audio stream. */ struct sdw_transport_params { bool blk_grp_ctrl_valid; unsigned int port_num; unsigned int blk_grp_ctrl; unsigned int sample_interval; unsigned int offset1; unsigned int offset2; unsigned int hstart; unsigned int hstop; unsigned int blk_pkg_mode; unsigned int lane_ctrl; }; /** * struct sdw_enable_ch: Enable/disable Data Port channel * * @num: Port number * @ch_mask: Active channel mask * @enable: Enable (true) /disable (false) channel */ struct sdw_enable_ch { unsigned int port_num; unsigned int ch_mask; bool enable; }; /** * struct sdw_master_port_ops: Callback functions from bus to Master * driver to set Master Data ports. * * @dpn_set_port_params: Set the Port parameters for the Master Port. * Mandatory callback * @dpn_set_port_transport_params: Set transport parameters for the Master * Port. Mandatory callback * @dpn_port_prep: Port prepare operations for the Master Data Port. * @dpn_port_enable_ch: Enable the channels of Master Port. */ struct sdw_master_port_ops { int (*dpn_set_port_params)(struct sdw_bus *bus, struct sdw_port_params *port_params, unsigned int bank); int (*dpn_set_port_transport_params)(struct sdw_bus *bus, struct sdw_transport_params *transport_params, enum sdw_reg_bank bank); int (*dpn_port_prep)(struct sdw_bus *bus, struct sdw_prepare_ch *prepare_ch); int (*dpn_port_enable_ch)(struct sdw_bus *bus, struct sdw_enable_ch *enable_ch, unsigned int bank); }; struct sdw_msg; /** * struct sdw_defer - SDW deffered message * @length: message length * @complete: message completion * @msg: SDW message */ struct sdw_defer { int length; struct completion complete; struct sdw_msg *msg; }; /** * struct sdw_master_ops - Master driver ops * @read_prop: Read Master properties * @override_adr: Override value read from firmware (quirk for buggy firmware) * @xfer_msg: Transfer message callback * @xfer_msg_defer: Defer version of transfer message callback * @reset_page_addr: Reset the SCP page address registers * @set_bus_conf: Set the bus configuration * @pre_bank_switch: Callback for pre bank switch * @post_bank_switch: Callback for post bank switch */ struct sdw_master_ops { int (*read_prop)(struct sdw_bus *bus); u64 (*override_adr) (struct sdw_bus *bus, u64 addr); enum sdw_command_response (*xfer_msg) (struct sdw_bus *bus, struct sdw_msg *msg); enum sdw_command_response (*xfer_msg_defer) (struct sdw_bus *bus, struct sdw_msg *msg, struct sdw_defer *defer); enum sdw_command_response (*reset_page_addr) (struct sdw_bus *bus, unsigned int dev_num); int (*set_bus_conf)(struct sdw_bus *bus, struct sdw_bus_params *params); int (*pre_bank_switch)(struct sdw_bus *bus); int (*post_bank_switch)(struct sdw_bus *bus); }; /** * struct sdw_bus - SoundWire bus * @dev: Shortcut to &bus->md->dev to avoid changing the entire code. * @md: Master device * @link_id: Link id number, can be 0 to N, unique for each Master * @id: bus system-wide unique id * @slaves: list of Slaves on this bus * @assigned: Bitmap for Slave device numbers. * Bit set implies used number, bit clear implies unused number. * @bus_lock: bus lock * @msg_lock: message lock * @compute_params: points to Bus resource management implementation * @ops: Master callback ops * @port_ops: Master port callback ops * @params: Current bus parameters * @prop: Master properties * @m_rt_list: List of Master instance of all stream(s) running on Bus. This * is used to compute and program bus bandwidth, clock, frame shape, * transport and port parameters * @debugfs: Bus debugfs * @defer_msg: Defer message * @clk_stop_timeout: Clock stop timeout computed * @bank_switch_timeout: Bank switch timeout computed * @multi_link: Store bus property that indicates if multi links * are supported. This flag is populated by drivers after reading * appropriate firmware (ACPI/DT). * @hw_sync_min_links: Number of links used by a stream above which * hardware-based synchronization is required. This value is only * meaningful if multi_link is set. If set to 1, hardware-based * synchronization will be used even if a stream only uses a single * SoundWire segment. */ struct sdw_bus { struct device *dev; struct sdw_master_device *md; unsigned int link_id; int id; struct list_head slaves; DECLARE_BITMAP(assigned, SDW_MAX_DEVICES); struct mutex bus_lock; struct mutex msg_lock; int (*compute_params)(struct sdw_bus *bus); const struct sdw_master_ops *ops; const struct sdw_master_port_ops *port_ops; struct sdw_bus_params params; struct sdw_master_prop prop; struct list_head m_rt_list; #ifdef CONFIG_DEBUG_FS struct dentry *debugfs; #endif struct sdw_defer defer_msg; unsigned int clk_stop_timeout; u32 bank_switch_timeout; bool multi_link; int hw_sync_min_links; }; int sdw_bus_master_add(struct sdw_bus *bus, struct device *parent, struct fwnode_handle *fwnode); void sdw_bus_master_delete(struct sdw_bus *bus); /** * sdw_port_config: Master or Slave Port configuration * * @num: Port number * @ch_mask: channels mask for port */ struct sdw_port_config { unsigned int num; unsigned int ch_mask; }; /** * sdw_stream_config: Master or Slave stream configuration * * @frame_rate: Audio frame rate of the stream, in Hz * @ch_count: Channel count of the stream * @bps: Number of bits per audio sample * @direction: Data direction * @type: Stream type PCM or PDM */ struct sdw_stream_config { unsigned int frame_rate; unsigned int ch_count; unsigned int bps; enum sdw_data_direction direction; enum sdw_stream_type type; }; /** * sdw_stream_state: Stream states * * @SDW_STREAM_ALLOCATED: New stream allocated. * @SDW_STREAM_CONFIGURED: Stream configured * @SDW_STREAM_PREPARED: Stream prepared * @SDW_STREAM_ENABLED: Stream enabled * @SDW_STREAM_DISABLED: Stream disabled * @SDW_STREAM_DEPREPARED: Stream de-prepared * @SDW_STREAM_RELEASED: Stream released */ enum sdw_stream_state { SDW_STREAM_ALLOCATED = 0, SDW_STREAM_CONFIGURED = 1, SDW_STREAM_PREPARED = 2, SDW_STREAM_ENABLED = 3, SDW_STREAM_DISABLED = 4, SDW_STREAM_DEPREPARED = 5, SDW_STREAM_RELEASED = 6, }; /** * sdw_stream_params: Stream parameters * * @rate: Sampling frequency, in Hz * @ch_count: Number of channels * @bps: bits per channel sample */ struct sdw_stream_params { unsigned int rate; unsigned int ch_count; unsigned int bps; }; /** * sdw_stream_runtime: Runtime stream parameters * * @name: SoundWire stream name * @params: Stream parameters * @state: Current state of the stream * @type: Stream type PCM or PDM * @master_list: List of Master runtime(s) in this stream. * master_list can contain only one m_rt per Master instance * for a stream * @m_rt_count: Count of Master runtime(s) in this stream */ struct sdw_stream_runtime { const char *name; struct sdw_stream_params params; enum sdw_stream_state state; enum sdw_stream_type type; struct list_head master_list; int m_rt_count; }; struct sdw_stream_runtime *sdw_alloc_stream(const char *stream_name); void sdw_release_stream(struct sdw_stream_runtime *stream); int sdw_compute_params(struct sdw_bus *bus); int sdw_stream_add_master(struct sdw_bus *bus, struct sdw_stream_config *stream_config, struct sdw_port_config *port_config, unsigned int num_ports, struct sdw_stream_runtime *stream); int sdw_stream_add_slave(struct sdw_slave *slave, struct sdw_stream_config *stream_config, struct sdw_port_config *port_config, unsigned int num_ports, struct sdw_stream_runtime *stream); int sdw_stream_remove_master(struct sdw_bus *bus, struct sdw_stream_runtime *stream); int sdw_stream_remove_slave(struct sdw_slave *slave, struct sdw_stream_runtime *stream); int sdw_startup_stream(void *sdw_substream); int sdw_prepare_stream(struct sdw_stream_runtime *stream); int sdw_enable_stream(struct sdw_stream_runtime *stream); int sdw_disable_stream(struct sdw_stream_runtime *stream); int sdw_deprepare_stream(struct sdw_stream_runtime *stream); void sdw_shutdown_stream(void *sdw_substream); int sdw_bus_prep_clk_stop(struct sdw_bus *bus); int sdw_bus_clk_stop(struct sdw_bus *bus); int sdw_bus_exit_clk_stop(struct sdw_bus *bus); /* messaging and data APIs */ int sdw_read(struct sdw_slave *slave, u32 addr); int sdw_write(struct sdw_slave *slave, u32 addr, u8 value); int sdw_write_no_pm(struct sdw_slave *slave, u32 addr, u8 value); int sdw_read_no_pm(struct sdw_slave *slave, u32 addr); int sdw_nread(struct sdw_slave *slave, u32 addr, size_t count, u8 *val); int sdw_nwrite(struct sdw_slave *slave, u32 addr, size_t count, const u8 *val); int sdw_update(struct sdw_slave *slave, u32 addr, u8 mask, u8 val); int sdw_update_no_pm(struct sdw_slave *slave, u32 addr, u8 mask, u8 val); int sdw_compare_devid(struct sdw_slave *slave, struct sdw_slave_id id); void sdw_extract_slave_id(struct sdw_bus *bus, u64 addr, struct sdw_slave_id *id); #endif /* __SOUNDWIRE_H */