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/******************************************************************************
*
* This file is provided under a dual BSD/GPLv2 license. When using or
* redistributing this file, you may do so under either license.
*
* GPL LICENSE SUMMARY
*
* Copyright(c) 2007 - 2014 Intel Corporation. All rights reserved.
* Copyright(c) 2013 - 2015 Intel Mobile Communications GmbH
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of version 2 of the GNU General Public License as
* published by the Free Software Foundation.
*
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* General Public License for more details.
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* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110,
* USA
*
* The full GNU General Public License is included in this distribution
* in the file called COPYING.
*
* Contact Information:
* Intel Linux Wireless <linuxwifi@intel.com>
* Intel Corporation, 5200 N.E. Elam Young Parkway, Hillsboro, OR 97124-6497
*
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*
* Copyright(c) 2005 - 2014 Intel Corporation. All rights reserved.
* Copyright(c) 2013 - 2015 Intel Mobile Communications GmbH
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* modification, are permitted provided that the following conditions
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*****************************************************************************/
#ifndef __iwl_trans_h__
#define __iwl_trans_h__
#include <linux/ieee80211.h>
#include <linux/mm.h> /* for page_address */
#include <linux/lockdep.h>
#include <linux/kernel.h>
#include "iwl-debug.h"
#include "iwl-config.h"
#include "iwl-fw.h"
#include "iwl-op-mode.h"
/**
* DOC: Transport layer - what is it ?
*
* The transport layer is the layer that deals with the HW directly. It provides
* an abstraction of the underlying HW to the upper layer. The transport layer
* doesn't provide any policy, algorithm or anything of this kind, but only
* mechanisms to make the HW do something. It is not completely stateless but
* close to it.
* We will have an implementation for each different supported bus.
*/
/**
* DOC: Life cycle of the transport layer
*
* The transport layer has a very precise life cycle.
*
* 1) A helper function is called during the module initialization and
* registers the bus driver's ops with the transport's alloc function.
* 2) Bus's probe calls to the transport layer's allocation functions.
* Of course this function is bus specific.
* 3) This allocation functions will spawn the upper layer which will
* register mac80211.
*
* 4) At some point (i.e. mac80211's start call), the op_mode will call
* the following sequence:
* start_hw
* start_fw
*
* 5) Then when finished (or reset):
* stop_device
*
* 6) Eventually, the free function will be called.
*/
/**
* DOC: Host command section
*
* A host command is a command issued by the upper layer to the fw. There are
* several versions of fw that have several APIs. The transport layer is
* completely agnostic to these differences.
* The transport does provide helper functionality (i.e. SYNC / ASYNC mode),
*/
#define SEQ_TO_QUEUE(s) (((s) >> 8) & 0x1f)
#define QUEUE_TO_SEQ(q) (((q) & 0x1f) << 8)
#define SEQ_TO_INDEX(s) ((s) & 0xff)
#define INDEX_TO_SEQ(i) ((i) & 0xff)
#define SEQ_RX_FRAME cpu_to_le16(0x8000)
/*
* those functions retrieve specific information from
* the id field in the iwl_host_cmd struct which contains
* the command id, the group id and the version of the command
* and vice versa
*/
static inline u8 iwl_cmd_opcode(u32 cmdid)
{
return cmdid & 0xFF;
}
static inline u8 iwl_cmd_groupid(u32 cmdid)
{
return ((cmdid & 0xFF00) >> 8);
}
static inline u8 iwl_cmd_version(u32 cmdid)
{
return ((cmdid & 0xFF0000) >> 16);
}
static inline u32 iwl_cmd_id(u8 opcode, u8 groupid, u8 version)
{
return opcode + (groupid << 8) + (version << 16);
}
/* make u16 wide id out of u8 group and opcode */
#define WIDE_ID(grp, opcode) ((grp << 8) | opcode)
/* due to the conversion, this group is special; new groups
* should be defined in the appropriate fw-api header files
*/
#define IWL_ALWAYS_LONG_GROUP 1
/**
* struct iwl_cmd_header
*
* This header format appears in the beginning of each command sent from the
* driver, and each response/notification received from uCode.
*/
struct iwl_cmd_header {
u8 cmd; /* Command ID: REPLY_RXON, etc. */
u8 group_id;
/*
* The driver sets up the sequence number to values of its choosing.
* uCode does not use this value, but passes it back to the driver
* when sending the response to each driver-originated command, so
* the driver can match the response to the command. Since the values
* don't get used by uCode, the driver may set up an arbitrary format.
*
* There is one exception: uCode sets bit 15 when it originates
* the response/notification, i.e. when the response/notification
* is not a direct response to a command sent by the driver. For
* example, uCode issues REPLY_RX when it sends a received frame
* to the driver; it is not a direct response to any driver command.
*
* The Linux driver uses the following format:
*
* 0:7 tfd index - position within TX queue
* 8:12 TX queue id
* 13:14 reserved
* 15 unsolicited RX or uCode-originated notification
*/
__le16 sequence;
} __packed;
/**
* struct iwl_cmd_header_wide
*
* This header format appears in the beginning of each command sent from the
* driver, and each response/notification received from uCode.
* this is the wide version that contains more information about the command
* like length, version and command type
*/
struct iwl_cmd_header_wide {
u8 cmd;
u8 group_id;
__le16 sequence;
__le16 length;
u8 reserved;
u8 version;
} __packed;
#define FH_RSCSR_FRAME_SIZE_MSK 0x00003FFF /* bits 0-13 */
#define FH_RSCSR_FRAME_INVALID 0x55550000
#define FH_RSCSR_FRAME_ALIGN 0x40
struct iwl_rx_packet {
/*
* The first 4 bytes of the RX frame header contain both the RX frame
* size and some flags.
* Bit fields:
* 31: flag flush RB request
* 30: flag ignore TC (terminal counter) request
* 29: flag fast IRQ request
* 28-14: Reserved
* 13-00: RX frame size
*/
__le32 len_n_flags;
struct iwl_cmd_header hdr;
u8 data[];
} __packed;
static inline u32 iwl_rx_packet_len(const struct iwl_rx_packet *pkt)
{
return le32_to_cpu(pkt->len_n_flags) & FH_RSCSR_FRAME_SIZE_MSK;
}
static inline u32 iwl_rx_packet_payload_len(const struct iwl_rx_packet *pkt)
{
return iwl_rx_packet_len(pkt) - sizeof(pkt->hdr);
}
/**
* enum CMD_MODE - how to send the host commands ?
*
* @CMD_ASYNC: Return right away and don't wait for the response
* @CMD_WANT_SKB: Not valid with CMD_ASYNC. The caller needs the buffer of
* the response. The caller needs to call iwl_free_resp when done.
* @CMD_HIGH_PRIO: The command is high priority - it goes to the front of the
* command queue, but after other high priority commands. Valid only
* with CMD_ASYNC.
* @CMD_SEND_IN_IDLE: The command should be sent even when the trans is idle.
* @CMD_MAKE_TRANS_IDLE: The command response should mark the trans as idle.
* @CMD_WAKE_UP_TRANS: The command response should wake up the trans
* (i.e. mark it as non-idle).
* @CMD_WANT_ASYNC_CALLBACK: the op_mode's async callback function must be
* called after this command completes. Valid only with CMD_ASYNC.
* @CMD_TB_BITMAP_POS: Position of the first bit for the TB bitmap. We need to
* check that we leave enough room for the TBs bitmap which needs 20 bits.
*/
enum CMD_MODE {
CMD_ASYNC = BIT(0),
CMD_WANT_SKB = BIT(1),
CMD_SEND_IN_RFKILL = BIT(2),
CMD_HIGH_PRIO = BIT(3),
CMD_SEND_IN_IDLE = BIT(4),
CMD_MAKE_TRANS_IDLE = BIT(5),
CMD_WAKE_UP_TRANS = BIT(6),
CMD_WANT_ASYNC_CALLBACK = BIT(7),
CMD_TB_BITMAP_POS = 11,
};
#define DEF_CMD_PAYLOAD_SIZE 320
/**
* struct iwl_device_cmd
*
* For allocation of the command and tx queues, this establishes the overall
* size of the largest command we send to uCode, except for commands that
* aren't fully copied and use other TFD space.
*/
struct iwl_device_cmd {
union {
struct {
struct iwl_cmd_header hdr; /* uCode API */
u8 payload[DEF_CMD_PAYLOAD_SIZE];
};
struct {
struct iwl_cmd_header_wide hdr_wide;
u8 payload_wide[DEF_CMD_PAYLOAD_SIZE -
sizeof(struct iwl_cmd_header_wide) +
sizeof(struct iwl_cmd_header)];
};
};
} __packed;
#define TFD_MAX_PAYLOAD_SIZE (sizeof(struct iwl_device_cmd))
/*
* number of transfer buffers (fragments) per transmit frame descriptor;
* this is just the driver's idea, the hardware supports 20
*/
#define IWL_MAX_CMD_TBS_PER_TFD 2
/**
* struct iwl_hcmd_dataflag - flag for each one of the chunks of the command
*
* @IWL_HCMD_DFL_NOCOPY: By default, the command is copied to the host command's
* ring. The transport layer doesn't map the command's buffer to DMA, but
* rather copies it to a previously allocated DMA buffer. This flag tells
* the transport layer not to copy the command, but to map the existing
* buffer (that is passed in) instead. This saves the memcpy and allows
* commands that are bigger than the fixed buffer to be submitted.
* Note that a TFD entry after a NOCOPY one cannot be a normal copied one.
* @IWL_HCMD_DFL_DUP: Only valid without NOCOPY, duplicate the memory for this
* chunk internally and free it again after the command completes. This
* can (currently) be used only once per command.
* Note that a TFD entry after a DUP one cannot be a normal copied one.
*/
enum iwl_hcmd_dataflag {
IWL_HCMD_DFL_NOCOPY = BIT(0),
IWL_HCMD_DFL_DUP = BIT(1),
};
/**
* struct iwl_host_cmd - Host command to the uCode
*
* @data: array of chunks that composes the data of the host command
* @resp_pkt: response packet, if %CMD_WANT_SKB was set
* @_rx_page_order: (internally used to free response packet)
* @_rx_page_addr: (internally used to free response packet)
* @flags: can be CMD_*
* @len: array of the lengths of the chunks in data
* @dataflags: IWL_HCMD_DFL_*
* @id: command id of the host command, for wide commands encoding the
* version and group as well
*/
struct iwl_host_cmd {
const void *data[IWL_MAX_CMD_TBS_PER_TFD];
struct iwl_rx_packet *resp_pkt;
unsigned long _rx_page_addr;
u32 _rx_page_order;
u32 flags;
u32 id;
u16 len[IWL_MAX_CMD_TBS_PER_TFD];
u8 dataflags[IWL_MAX_CMD_TBS_PER_TFD];
};
static inline void iwl_free_resp(struct iwl_host_cmd *cmd)
{
free_pages(cmd->_rx_page_addr, cmd->_rx_page_order);
}
struct iwl_rx_cmd_buffer {
struct page *_page;
int _offset;
bool _page_stolen;
u32 _rx_page_order;
unsigned int truesize;
};
static inline void *rxb_addr(struct iwl_rx_cmd_buffer *r)
{
return (void *)((unsigned long)page_address(r->_page) + r->_offset);
}
static inline int rxb_offset(struct iwl_rx_cmd_buffer *r)
{
return r->_offset;
}
static inline struct page *rxb_steal_page(struct iwl_rx_cmd_buffer *r)
{
r->_page_stolen = true;
get_page(r->_page);
return r->_page;
}
static inline void iwl_free_rxb(struct iwl_rx_cmd_buffer *r)
{
__free_pages(r->_page, r->_rx_page_order);
}
#define MAX_NO_RECLAIM_CMDS 6
/*
* The first entry in driver_data array in ieee80211_tx_info
* that can be used by the transport.
*/
#define IWL_TRANS_FIRST_DRIVER_DATA 2
#define IWL_MASK(lo, hi) ((1 << (hi)) | ((1 << (hi)) - (1 << (lo))))
/*
* Maximum number of HW queues the transport layer
* currently supports
*/
#define IWL_MAX_HW_QUEUES 32
#define IWL_MAX_TID_COUNT 8
#define IWL_FRAME_LIMIT 64
#define IWL_MAX_RX_HW_QUEUES 16
/**
* enum iwl_wowlan_status - WoWLAN image/device status
* @IWL_D3_STATUS_ALIVE: firmware is still running after resume
* @IWL_D3_STATUS_RESET: device was reset while suspended
*/
enum iwl_d3_status {
IWL_D3_STATUS_ALIVE,
IWL_D3_STATUS_RESET,
};
/**
* enum iwl_trans_status: transport status flags
* @STATUS_SYNC_HCMD_ACTIVE: a SYNC command is being processed
* @STATUS_DEVICE_ENABLED: APM is enabled
* @STATUS_TPOWER_PMI: the device might be asleep (need to wake it up)
* @STATUS_INT_ENABLED: interrupts are enabled
* @STATUS_RFKILL: the HW RFkill switch is in KILL position
* @STATUS_FW_ERROR: the fw is in error state
* @STATUS_TRANS_GOING_IDLE: shutting down the trans, only special commands
* are sent
* @STATUS_TRANS_IDLE: the trans is idle - general commands are not to be sent
* @STATUS_TRANS_DEAD: trans is dead - avoid any read/write operation
*/
enum iwl_trans_status {
STATUS_SYNC_HCMD_ACTIVE,
STATUS_DEVICE_ENABLED,
STATUS_TPOWER_PMI,
STATUS_INT_ENABLED,
STATUS_RFKILL,
STATUS_FW_ERROR,
STATUS_TRANS_GOING_IDLE,
STATUS_TRANS_IDLE,
STATUS_TRANS_DEAD,
};
static inline int
iwl_trans_get_rb_size_order(enum iwl_amsdu_size rb_size)
{
switch (rb_size) {
case IWL_AMSDU_4K:
return get_order(4 * 1024);
case IWL_AMSDU_8K:
return get_order(8 * 1024);
case IWL_AMSDU_12K:
return get_order(12 * 1024);
default:
WARN_ON(1);
return -1;
}
}
struct iwl_hcmd_names {
u8 cmd_id;
const char *const cmd_name;
};
#define HCMD_NAME(x) \
{ .cmd_id = x, .cmd_name = #x }
struct iwl_hcmd_arr {
const struct iwl_hcmd_names *arr;
int size;
};
#define HCMD_ARR(x) \
{ .arr = x, .size = ARRAY_SIZE(x) }
/**
* struct iwl_trans_config - transport configuration
*
* @op_mode: pointer to the upper layer.
* @cmd_queue: the index of the command queue.
* Must be set before start_fw.
* @cmd_fifo: the fifo for host commands
* @cmd_q_wdg_timeout: the timeout of the watchdog timer for the command queue.
* @no_reclaim_cmds: Some devices erroneously don't set the
* SEQ_RX_FRAME bit on some notifications, this is the
* list of such notifications to filter. Max length is
* %MAX_NO_RECLAIM_CMDS.
* @n_no_reclaim_cmds: # of commands in list
* @rx_buf_size: RX buffer size needed for A-MSDUs
* if unset 4k will be the RX buffer size
* @bc_table_dword: set to true if the BC table expects the byte count to be
* in DWORD (as opposed to bytes)
* @scd_set_active: should the transport configure the SCD for HCMD queue
* @wide_cmd_header: firmware supports wide host command header
* @sw_csum_tx: transport should compute the TCP checksum
* @command_groups: array of command groups, each member is an array of the
* commands in the group; for debugging only
* @command_groups_size: number of command groups, to avoid illegal access
* @sdio_adma_addr: the default address to set for the ADMA in SDIO mode until
* we get the ALIVE from the uCode
*/
struct iwl_trans_config {
struct iwl_op_mode *op_mode;
u8 cmd_queue;
u8 cmd_fifo;
unsigned int cmd_q_wdg_timeout;
const u8 *no_reclaim_cmds;
unsigned int n_no_reclaim_cmds;
enum iwl_amsdu_size rx_buf_size;
bool bc_table_dword;
bool scd_set_active;
bool wide_cmd_header;
bool sw_csum_tx;
const struct iwl_hcmd_arr *command_groups;
int command_groups_size;
u32 sdio_adma_addr;
};
struct iwl_trans_dump_data {
u32 len;
u8 data[];
};
struct iwl_trans;
struct iwl_trans_txq_scd_cfg {
u8 fifo;
s8 sta_id;
u8 tid;
bool aggregate;
int frame_limit;
};
/**
* struct iwl_trans_ops - transport specific operations
*
* All the handlers MUST be implemented
*
* @start_hw: starts the HW. If low_power is true, the NIC needs to be taken
* out of a low power state. From that point on, the HW can send
* interrupts. May sleep.
* @op_mode_leave: Turn off the HW RF kill indication if on
* May sleep
* @start_fw: allocates and inits all the resources for the transport
* layer. Also kick a fw image.
* May sleep
* @fw_alive: called when the fw sends alive notification. If the fw provides
* the SCD base address in SRAM, then provide it here, or 0 otherwise.
* May sleep
* @stop_device: stops the whole device (embedded CPU put to reset) and stops
* the HW. If low_power is true, the NIC will be put in low power state.
* From that point on, the HW will be stopped but will still issue an
* interrupt if the HW RF kill switch is triggered.
* This callback must do the right thing and not crash even if %start_hw()
* was called but not &start_fw(). May sleep.
* @d3_suspend: put the device into the correct mode for WoWLAN during
* suspend. This is optional, if not implemented WoWLAN will not be
* supported. This callback may sleep.
* @d3_resume: resume the device after WoWLAN, enabling the opmode to
* talk to the WoWLAN image to get its status. This is optional, if not
* implemented WoWLAN will not be supported. This callback may sleep.
* @send_cmd:send a host command. Must return -ERFKILL if RFkill is asserted.
* If RFkill is asserted in the middle of a SYNC host command, it must
* return -ERFKILL straight away.
* May sleep only if CMD_ASYNC is not set
* @tx: send an skb. The transport relies on the op_mode to zero the
* the ieee80211_tx_info->driver_data. If the MPDU is an A-MSDU, all
* the CSUM will be taken care of (TCP CSUM and IP header in case of
* IPv4). If the MPDU is a single MSDU, the op_mode must compute the IP
* header if it is IPv4.
* Must be atomic
* @reclaim: free packet until ssn. Returns a list of freed packets.
* Must be atomic
* @txq_enable: setup a queue. To setup an AC queue, use the
* iwl_trans_ac_txq_enable wrapper. fw_alive must have been called before
* this one. The op_mode must not configure the HCMD queue. The scheduler
* configuration may be %NULL, in which case the hardware will not be
* configured. May sleep.
* @txq_disable: de-configure a Tx queue to send AMPDUs
* Must be atomic
* @wait_tx_queue_empty: wait until tx queues are empty. May sleep.
* @freeze_txq_timer: prevents the timer of the queue from firing until the
* queue is set to awake. Must be atomic.
* @block_txq_ptrs: stop updating the write pointers of the Tx queues. Note
* that the transport needs to refcount the calls since this function
* will be called several times with block = true, and then the queues
* need to be unblocked only after the same number of calls with
* block = false.
* @write8: write a u8 to a register at offset ofs from the BAR
* @write32: write a u32 to a register at offset ofs from the BAR
* @read32: read a u32 register at offset ofs from the BAR
* @read_prph: read a DWORD from a periphery register
* @write_prph: write a DWORD to a periphery register
* @read_mem: read device's SRAM in DWORD
* @write_mem: write device's SRAM in DWORD. If %buf is %NULL, then the memory
* will be zeroed.
* @configure: configure parameters required by the transport layer from
* the op_mode. May be called several times before start_fw, can't be
* called after that.
* @set_pmi: set the power pmi state
* @grab_nic_access: wake the NIC to be able to access non-HBUS regs.
* Sleeping is not allowed between grab_nic_access and
* release_nic_access.
* @release_nic_access: let the NIC go to sleep. The "flags" parameter
* must be the same one that was sent before to the grab_nic_access.
* @set_bits_mask - set SRAM register according to value and mask.
* @ref: grab a reference to the transport/FW layers, disallowing
* certain low power states
* @unref: release a reference previously taken with @ref. Note that
* initially the reference count is 1, making an initial @unref
* necessary to allow low power states.
* @dump_data: return a vmalloc'ed buffer with debug data, maybe containing last
* TX'ed commands and similar. The buffer will be vfree'd by the caller.
* Note that the transport must fill in the proper file headers.
*/
struct iwl_trans_ops {
int (*start_hw)(struct iwl_trans *iwl_trans, bool low_power);
void (*op_mode_leave)(struct iwl_trans *iwl_trans);
int (*start_fw)(struct iwl_trans *trans, const struct fw_img *fw,
bool run_in_rfkill);
int (*update_sf)(struct iwl_trans *trans,
struct iwl_sf_region *st_fwrd_space);
void (*fw_alive)(struct iwl_trans *trans, u32 scd_addr);
void (*stop_device)(struct iwl_trans *trans, bool low_power);
void (*d3_suspend)(struct iwl_trans *trans, bool test, bool reset);
int (*d3_resume)(struct iwl_trans *trans, enum iwl_d3_status *status,
bool test, bool reset);
int (*send_cmd)(struct iwl_trans *trans, struct iwl_host_cmd *cmd);
int (*tx)(struct iwl_trans *trans, struct sk_buff *skb,
struct iwl_device_cmd *dev_cmd, int queue);
void (*reclaim)(struct iwl_trans *trans, int queue, int ssn,
struct sk_buff_head *skbs);
void (*txq_enable)(struct iwl_trans *trans, int queue, u16 ssn,
const struct iwl_trans_txq_scd_cfg *cfg,
unsigned int queue_wdg_timeout);
void (*txq_disable)(struct iwl_trans *trans, int queue,
bool configure_scd);
int (*wait_tx_queue_empty)(struct iwl_trans *trans, u32 txq_bm);
void (*freeze_txq_timer)(struct iwl_trans *trans, unsigned long txqs,
bool freeze);
void (*block_txq_ptrs)(struct iwl_trans *trans, bool block);
void (*write8)(struct iwl_trans *trans, u32 ofs, u8 val);
void (*write32)(struct iwl_trans *trans, u32 ofs, u32 val);
u32 (*read32)(struct iwl_trans *trans, u32 ofs);
u32 (*read_prph)(struct iwl_trans *trans, u32 ofs);
void (*write_prph)(struct iwl_trans *trans, u32 ofs, u32 val);
int (*read_mem)(struct iwl_trans *trans, u32 addr,
void *buf, int dwords);
int (*write_mem)(struct iwl_trans *trans, u32 addr,
const void *buf, int dwords);
void (*configure)(struct iwl_trans *trans,
const struct iwl_trans_config *trans_cfg);
void (*set_pmi)(struct iwl_trans *trans, bool state);
bool (*grab_nic_access)(struct iwl_trans *trans, unsigned long *flags);
void (*release_nic_access)(struct iwl_trans *trans,
unsigned long *flags);
void (*set_bits_mask)(struct iwl_trans *trans, u32 reg, u32 mask,
u32 value);
void (*ref)(struct iwl_trans *trans);
void (*unref)(struct iwl_trans *trans);
int (*suspend)(struct iwl_trans *trans);
void (*resume)(struct iwl_trans *trans);
struct iwl_trans_dump_data *(*dump_data)(struct iwl_trans *trans,
const struct iwl_fw_dbg_trigger_tlv
*trigger);
};
/**
* enum iwl_trans_state - state of the transport layer
*
* @IWL_TRANS_NO_FW: no fw has sent an alive response
* @IWL_TRANS_FW_ALIVE: a fw has sent an alive response
*/
enum iwl_trans_state {
IWL_TRANS_NO_FW = 0,
IWL_TRANS_FW_ALIVE = 1,
};
/**
* DOC: Platform power management
*
* There are two types of platform power management: system-wide
* (WoWLAN) and runtime.
*
* In system-wide power management the entire platform goes into a low
* power state (e.g. idle or suspend to RAM) at the same time and the
* device is configured as a wakeup source for the entire platform.
* This is usually triggered by userspace activity (e.g. the user
* presses the suspend button or a power management daemon decides to
* put the platform in low power mode). The device's behavior in this
* mode is dictated by the wake-on-WLAN configuration.
*
* In runtime power management, only the devices which are themselves
* idle enter a low power state. This is done at runtime, which means
* that the entire system is still running normally. This mode is
* usually triggered automatically by the device driver and requires
* the ability to enter and exit the low power modes in a very short
* time, so there is not much impact in usability.
*
* The terms used for the device's behavior are as follows:
*
* - D0: the device is fully powered and the host is awake;
* - D3: the device is in low power mode and only reacts to
* specific events (e.g. magic-packet received or scan
* results found);
* - D0I3: the device is in low power mode and reacts to any
* activity (e.g. RX);
*
* These terms reflect the power modes in the firmware and are not to
* be confused with the physical device power state. The NIC can be
* in D0I3 mode even if, for instance, the PCI device is in D3 state.
*/
/**
* enum iwl_plat_pm_mode - platform power management mode
*
* This enumeration describes the device's platform power management
* behavior when in idle mode (i.e. runtime power management) or when
* in system-wide suspend (i.e WoWLAN).
*
* @IWL_PLAT_PM_MODE_DISABLED: power management is disabled for this
* device. At runtime, this means that nothing happens and the
* device always remains in active. In system-wide suspend mode,
* it means that the all connections will be closed automatically
* by mac80211 before the platform is suspended.
* @IWL_PLAT_PM_MODE_D3: the device goes into D3 mode (i.e. WoWLAN).
* For runtime power management, this mode is not officially
* supported.
* @IWL_PLAT_PM_MODE_D0I3: the device goes into D0I3 mode.
*/
enum iwl_plat_pm_mode {
IWL_PLAT_PM_MODE_DISABLED,
IWL_PLAT_PM_MODE_D3,
IWL_PLAT_PM_MODE_D0I3,
};
/* Max time to wait for trans to become idle/non-idle on d0i3
* enter/exit (in msecs).
*/
#define IWL_TRANS_IDLE_TIMEOUT 2000
/**
* struct iwl_trans - transport common data
*
* @ops - pointer to iwl_trans_ops
* @op_mode - pointer to the op_mode
* @cfg - pointer to the configuration
* @status: a bit-mask of transport status flags
* @dev - pointer to struct device * that represents the device
* @max_skb_frags: maximum number of fragments an SKB can have when transmitted.
* 0 indicates that frag SKBs (NETIF_F_SG) aren't supported.
* @hw_id: a u32 with the ID of the device / sub-device.
* Set during transport allocation.
* @hw_id_str: a string with info about HW ID. Set during transport allocation.
* @pm_support: set to true in start_hw if link pm is supported
* @ltr_enabled: set to true if the LTR is enabled
* @num_rx_queues: number of RX queues allocated by the transport;
* the transport must set this before calling iwl_drv_start()
* @dev_cmd_pool: pool for Tx cmd allocation - for internal use only.
* The user should use iwl_trans_{alloc,free}_tx_cmd.
* @dev_cmd_headroom: room needed for the transport's private use before the
* device_cmd for Tx - for internal use only
* The user should use iwl_trans_{alloc,free}_tx_cmd.
* @rx_mpdu_cmd: MPDU RX command ID, must be assigned by opmode before
* starting the firmware, used for tracing
* @rx_mpdu_cmd_hdr_size: used for tracing, amount of data before the
* start of the 802.11 header in the @rx_mpdu_cmd
* @dflt_pwr_limit: default power limit fetched from the platform (ACPI)
* @dbg_dest_tlv: points to the destination TLV for debug
* @dbg_conf_tlv: array of pointers to configuration TLVs for debug
* @dbg_trigger_tlv: array of pointers to triggers TLVs for debug
* @dbg_dest_reg_num: num of reg_ops in %dbg_dest_tlv
* @paging_req_addr: The location were the FW will upload / download the pages
* from. The address is set by the opmode
* @paging_db: Pointer to the opmode paging data base, the pointer is set by
* the opmode.
* @paging_download_buf: Buffer used for copying all of the pages before
* downloading them to the FW. The buffer is allocated in the opmode
* @system_pm_mode: the system-wide power management mode in use.
* This mode is set dynamically, depending on the WoWLAN values
* configured from the userspace at runtime.
* @runtime_pm_mode: the runtime power management mode in use. This
* mode is set during the initialization phase and is not
* supposed to change during runtime.
*/
struct iwl_trans {
const struct iwl_trans_ops *ops;
struct iwl_op_mode *op_mode;
const struct iwl_cfg *cfg;
enum iwl_trans_state state;
unsigned long status;
struct device *dev;
u32 max_skb_frags;
u32 hw_rev;
u32 hw_id;
char hw_id_str[52];
u8 rx_mpdu_cmd, rx_mpdu_cmd_hdr_size;
bool pm_support;
bool ltr_enabled;
const struct iwl_hcmd_arr *command_groups;
int command_groups_size;
u8 num_rx_queues;
/* The following fields are internal only */
struct kmem_cache *dev_cmd_pool;
size_t dev_cmd_headroom;
char dev_cmd_pool_name[50];
struct dentry *dbgfs_dir;
#ifdef CONFIG_LOCKDEP
struct lockdep_map sync_cmd_lockdep_map;
#endif
u64 dflt_pwr_limit;
const struct iwl_fw_dbg_dest_tlv *dbg_dest_tlv;
const struct iwl_fw_dbg_conf_tlv *dbg_conf_tlv[FW_DBG_CONF_MAX];
struct iwl_fw_dbg_trigger_tlv * const *dbg_trigger_tlv;
u8 dbg_dest_reg_num;
/*
* Paging parameters - All of the parameters should be set by the
* opmode when paging is enabled
*/
u32 paging_req_addr;
struct iwl_fw_paging *paging_db;
void *paging_download_buf;
enum iwl_plat_pm_mode system_pm_mode;
enum iwl_plat_pm_mode runtime_pm_mode;
bool suspending;
/* pointer to trans specific struct */
/*Ensure that this pointer will always be aligned to sizeof pointer */
char trans_specific[0] __aligned(sizeof(void *));
};
const char *iwl_get_cmd_string(struct iwl_trans *trans, u32 id);
int iwl_cmd_groups_verify_sorted(const struct iwl_trans_config *trans);
static inline void iwl_trans_configure(struct iwl_trans *trans,
const struct iwl_trans_config *trans_cfg)
{
trans->op_mode = trans_cfg->op_mode;
trans->ops->configure(trans, trans_cfg);
WARN_ON(iwl_cmd_groups_verify_sorted(trans_cfg));
}
static inline int _iwl_trans_start_hw(struct iwl_trans *trans, bool low_power)
{
might_sleep();
return trans->ops->start_hw(trans, low_power);
}
static inline int iwl_trans_start_hw(struct iwl_trans *trans)
{
return trans->ops->start_hw(trans, true);
}
static inline void iwl_trans_op_mode_leave(struct iwl_trans *trans)
{
might_sleep();
if (trans->ops->op_mode_leave)
trans->ops->op_mode_leave(trans);
trans->op_mode = NULL;
trans->state = IWL_TRANS_NO_FW;
}
static inline void iwl_trans_fw_alive(struct iwl_trans *trans, u32 scd_addr)
{
might_sleep();
trans->state = IWL_TRANS_FW_ALIVE;
trans->ops->fw_alive(trans, scd_addr);
}
static inline int iwl_trans_start_fw(struct iwl_trans *trans,
const struct fw_img *fw,
bool run_in_rfkill)
{
might_sleep();
WARN_ON_ONCE(!trans->rx_mpdu_cmd);
clear_bit(STATUS_FW_ERROR, &trans->status);
return trans->ops->start_fw(trans, fw, run_in_rfkill);
}
static inline int iwl_trans_update_sf(struct iwl_trans *trans,
struct iwl_sf_region *st_fwrd_space)
{
might_sleep();
if (trans->ops->update_sf)
return trans->ops->update_sf(trans, st_fwrd_space);
return 0;
}
static inline void _iwl_trans_stop_device(struct iwl_trans *trans,
bool low_power)
{
might_sleep();
trans->ops->stop_device(trans, low_power);
trans->state = IWL_TRANS_NO_FW;
}
static inline void iwl_trans_stop_device(struct iwl_trans *trans)
{
_iwl_trans_stop_device(trans, true);
}
static inline void iwl_trans_d3_suspend(struct iwl_trans *trans, bool test,
bool reset)
{
might_sleep();
if (trans->ops->d3_suspend)
trans->ops->d3_suspend(trans, test, reset);
}
static inline int iwl_trans_d3_resume(struct iwl_trans *trans,
enum iwl_d3_status *status,
bool test, bool reset)
{
might_sleep();
if (!trans->ops->d3_resume)
return 0;
return trans->ops->d3_resume(trans, status, test, reset);
}
static inline void iwl_trans_ref(struct iwl_trans *trans)
{
if (trans->ops->ref)
trans->ops->ref(trans);
}
static inline void iwl_trans_unref(struct iwl_trans *trans)
{
if (trans->ops->unref)
trans->ops->unref(trans);
}
static inline int iwl_trans_suspend(struct iwl_trans *trans)
{
if (!trans->ops->suspend)
return 0;
return trans->ops->suspend(trans);
}
static inline void iwl_trans_resume(struct iwl_trans *trans)
{
if (trans->ops->resume)
trans->ops->resume(trans);
}
static inline struct iwl_trans_dump_data *
iwl_trans_dump_data(struct iwl_trans *trans,
const struct iwl_fw_dbg_trigger_tlv *trigger)
{
if (!trans->ops->dump_data)
return NULL;
return trans->ops->dump_data(trans, trigger);
}
static inline struct iwl_device_cmd *
iwl_trans_alloc_tx_cmd(struct iwl_trans *trans)
{
u8 *dev_cmd_ptr = kmem_cache_alloc(trans->dev_cmd_pool, GFP_ATOMIC);
if (unlikely(dev_cmd_ptr == NULL))
return NULL;
return (struct iwl_device_cmd *)
(dev_cmd_ptr + trans->dev_cmd_headroom);
}
int iwl_trans_send_cmd(struct iwl_trans *trans, struct iwl_host_cmd *cmd);
static inline void iwl_trans_free_tx_cmd(struct iwl_trans *trans,
struct iwl_device_cmd *dev_cmd)
{
u8 *dev_cmd_ptr = (u8 *)dev_cmd - trans->dev_cmd_headroom;
kmem_cache_free(trans->dev_cmd_pool, dev_cmd_ptr);
}
static inline int iwl_trans_tx(struct iwl_trans *trans, struct sk_buff *skb,
struct iwl_device_cmd *dev_cmd, int queue)
{
if (unlikely(test_bit(STATUS_FW_ERROR, &trans->status)))
return -EIO;
if (WARN_ON_ONCE(trans->state != IWL_TRANS_FW_ALIVE)) {
IWL_ERR(trans, "%s bad state = %d\n", __func__, trans->state);
return -EIO;
}
return trans->ops->tx(trans, skb, dev_cmd, queue);
}
static inline void iwl_trans_reclaim(struct iwl_trans *trans, int queue,
int ssn, struct sk_buff_head *skbs)
{
if (WARN_ON_ONCE(trans->state != IWL_TRANS_FW_ALIVE)) {
IWL_ERR(trans, "%s bad state = %d\n", __func__, trans->state);
return;
}
trans->ops->reclaim(trans, queue, ssn, skbs);
}
static inline void iwl_trans_txq_disable(struct iwl_trans *trans, int queue,
bool configure_scd)
{
trans->ops->txq_disable(trans, queue, configure_scd);
}
static inline void
iwl_trans_txq_enable_cfg(struct iwl_trans *trans, int queue, u16 ssn,
const struct iwl_trans_txq_scd_cfg *cfg,
unsigned int queue_wdg_timeout)
{
might_sleep();
if (WARN_ON_ONCE(trans->state != IWL_TRANS_FW_ALIVE)) {
IWL_ERR(trans, "%s bad state = %d\n", __func__, trans->state);
return;
}
trans->ops->txq_enable(trans, queue, ssn, cfg, queue_wdg_timeout);
}
static inline void iwl_trans_txq_enable(struct iwl_trans *trans, int queue,
int fifo, int sta_id, int tid,
int frame_limit, u16 ssn,
unsigned int queue_wdg_timeout)
{
struct iwl_trans_txq_scd_cfg cfg = {
.fifo = fifo,
.sta_id = sta_id,
.tid = tid,
.frame_limit = frame_limit,
.aggregate = sta_id >= 0,
};
iwl_trans_txq_enable_cfg(trans, queue, ssn, &cfg, queue_wdg_timeout);
}
static inline
void iwl_trans_ac_txq_enable(struct iwl_trans *trans, int queue, int fifo,
unsigned int queue_wdg_timeout)
{
struct iwl_trans_txq_scd_cfg cfg = {
.fifo = fifo,
.sta_id = -1,
.tid = IWL_MAX_TID_COUNT,
.frame_limit = IWL_FRAME_LIMIT,
.aggregate = false,
};
iwl_trans_txq_enable_cfg(trans, queue, 0, &cfg, queue_wdg_timeout);
}
static inline void iwl_trans_freeze_txq_timer(struct iwl_trans *trans,
unsigned long txqs,
bool freeze)
{
if (WARN_ON_ONCE(trans->state != IWL_TRANS_FW_ALIVE)) {
IWL_ERR(trans, "%s bad state = %d\n", __func__, trans->state);
return;
}
if (trans->ops->freeze_txq_timer)
trans->ops->freeze_txq_timer(trans, txqs, freeze);
}
static inline void iwl_trans_block_txq_ptrs(struct iwl_trans *trans,
bool block)
{
if (WARN_ON_ONCE(trans->state != IWL_TRANS_FW_ALIVE)) {
IWL_ERR(trans, "%s bad state = %d\n", __func__, trans->state);
return;
}
if (trans->ops->block_txq_ptrs)
trans->ops->block_txq_ptrs(trans, block);
}
static inline int iwl_trans_wait_tx_queue_empty(struct iwl_trans *trans,
u32 txqs)
{
if (WARN_ON_ONCE(trans->state != IWL_TRANS_FW_ALIVE)) {
IWL_ERR(trans, "%s bad state = %d\n", __func__, trans->state);
return -EIO;
}
return trans->ops->wait_tx_queue_empty(trans, txqs);
}
static inline void iwl_trans_write8(struct iwl_trans *trans, u32 ofs, u8 val)
{
trans->ops->write8(trans, ofs, val);
}
static inline void iwl_trans_write32(struct iwl_trans *trans, u32 ofs, u32 val)
{
trans->ops->write32(trans, ofs, val);
}
static inline u32 iwl_trans_read32(struct iwl_trans *trans, u32 ofs)
{
return trans->ops->read32(trans, ofs);
}
static inline u32 iwl_trans_read_prph(struct iwl_trans *trans, u32 ofs)
{
return trans->ops->read_prph(trans, ofs);
}
static inline void iwl_trans_write_prph(struct iwl_trans *trans, u32 ofs,
u32 val)
{
return trans->ops->write_prph(trans, ofs, val);
}
static inline int iwl_trans_read_mem(struct iwl_trans *trans, u32 addr,
void *buf, int dwords)
{
return trans->ops->read_mem(trans, addr, buf, dwords);
}
#define iwl_trans_read_mem_bytes(trans, addr, buf, bufsize) \
do { \
if (__builtin_constant_p(bufsize)) \
BUILD_BUG_ON((bufsize) % sizeof(u32)); \
iwl_trans_read_mem(trans, addr, buf, (bufsize) / sizeof(u32));\
} while (0)
static inline u32 iwl_trans_read_mem32(struct iwl_trans *trans, u32 addr)
{
u32 value;
if (WARN_ON(iwl_trans_read_mem(trans, addr, &value, 1)))
return 0xa5a5a5a5;
return value;
}
static inline int iwl_trans_write_mem(struct iwl_trans *trans, u32 addr,
const void *buf, int dwords)
{
return trans->ops->write_mem(trans, addr, buf, dwords);
}
static inline u32 iwl_trans_write_mem32(struct iwl_trans *trans, u32 addr,
u32 val)
{
return iwl_trans_write_mem(trans, addr, &val, 1);
}
static inline void iwl_trans_set_pmi(struct iwl_trans *trans, bool state)
{
if (trans->ops->set_pmi)
trans->ops->set_pmi(trans, state);
}
static inline void
iwl_trans_set_bits_mask(struct iwl_trans *trans, u32 reg, u32 mask, u32 value)
{
trans->ops->set_bits_mask(trans, reg, mask, value);
}
#define iwl_trans_grab_nic_access(trans, flags) \
__cond_lock(nic_access, \
likely((trans)->ops->grab_nic_access(trans, flags)))
static inline void __releases(nic_access)
iwl_trans_release_nic_access(struct iwl_trans *trans, unsigned long *flags)
{
trans->ops->release_nic_access(trans, flags);
__release(nic_access);
}
static inline void iwl_trans_fw_error(struct iwl_trans *trans)
{
if (WARN_ON_ONCE(!trans->op_mode))
return;
/* prevent double restarts due to the same erroneous FW */
if (!test_and_set_bit(STATUS_FW_ERROR, &trans->status))
iwl_op_mode_nic_error(trans->op_mode);
}
/*****************************************************
* transport helper functions
*****************************************************/
struct iwl_trans *iwl_trans_alloc(unsigned int priv_size,
struct device *dev,
const struct iwl_cfg *cfg,
const struct iwl_trans_ops *ops,
size_t dev_cmd_headroom);
void iwl_trans_free(struct iwl_trans *trans);
/*****************************************************
* driver (transport) register/unregister functions
******************************************************/
int __must_check iwl_pci_register_driver(void);
void iwl_pci_unregister_driver(void);
#endif /* __iwl_trans_h__ */