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linux/drivers/net/wireless/ath/ath11k/qmi.c
Linus Torvalds 3a8a670eee Networking changes for 6.5. 
Core
 ----
 
  - Rework the sendpage & splice implementations. Instead of feeding
    data into sockets page by page extend sendmsg handlers to support
    taking a reference on the data, controlled by a new flag called
    MSG_SPLICE_PAGES. Rework the handling of unexpected-end-of-file
    to invoke an additional callback instead of trying to predict what
    the right combination of MORE/NOTLAST flags is.
    Remove the MSG_SENDPAGE_NOTLAST flag completely.
 
  - Implement SCM_PIDFD, a new type of CMSG type analogous to
    SCM_CREDENTIALS, but it contains pidfd instead of plain pid.
 
  - Enable socket busy polling with CONFIG_RT.
 
  - Improve reliability and efficiency of reporting for ref_tracker.
 
  - Auto-generate a user space C library for various Netlink families.
 
 Protocols
 ---------
 
  - Allow TCP to shrink the advertised window when necessary, prevent
    sk_rcvbuf auto-tuning from growing the window all the way up to
    tcp_rmem[2].
 
  - Use per-VMA locking for "page-flipping" TCP receive zerocopy.
 
  - Prepare TCP for device-to-device data transfers, by making sure
    that payloads are always attached to skbs as page frags.
 
  - Make the backoff time for the first N TCP SYN retransmissions
    linear. Exponential backoff is unnecessarily conservative.
 
  - Create a new MPTCP getsockopt to retrieve all info (MPTCP_FULL_INFO).
 
  - Avoid waking up applications using TLS sockets until we have
    a full record.
 
  - Allow using kernel memory for protocol ioctl callbacks, paving
    the way to issuing ioctls over io_uring.
 
  - Add nolocalbypass option to VxLAN, forcing packets to be fully
    encapsulated even if they are destined for a local IP address.
 
  - Make TCPv4 use consistent hash in TIME_WAIT and SYN_RECV. Ensure
    in-kernel ECMP implementation (e.g. Open vSwitch) select the same
    link for all packets. Support L4 symmetric hashing in Open vSwitch.
 
  - PPPoE: make number of hash bits configurable.
 
  - Allow DNS to be overwritten by DHCPACK in the in-kernel DHCP client
    (ipconfig).
 
  - Add layer 2 miss indication and filtering, allowing higher layers
    (e.g. ACL filters) to make forwarding decisions based on whether
    packet matched forwarding state in lower devices (bridge).
 
  - Support matching on Connectivity Fault Management (CFM) packets.
 
  - Hide the "link becomes ready" IPv6 messages by demoting their
    printk level to debug.
 
  - HSR: don't enable promiscuous mode if device offloads the proto.
 
  - Support active scanning in IEEE 802.15.4.
 
  - Continue work on Multi-Link Operation for WiFi 7.
 
 BPF
 ---
 
  - Add precision propagation for subprogs and callbacks. This allows
    maintaining verification efficiency when subprograms are used,
    or in fact passing the verifier at all for complex programs,
    especially those using open-coded iterators.
 
  - Improve BPF's {g,s}setsockopt() length handling. Previously BPF
    assumed the length is always equal to the amount of written data.
    But some protos allow passing a NULL buffer to discover what
    the output buffer *should* be, without writing anything.
 
  - Accept dynptr memory as memory arguments passed to helpers.
 
  - Add routing table ID to bpf_fib_lookup BPF helper.
 
  - Support O_PATH FDs in BPF_OBJ_PIN and BPF_OBJ_GET commands.
 
  - Drop bpf_capable() check in BPF_MAP_FREEZE command (used to mark
    maps as read-only).
 
  - Show target_{obj,btf}_id in tracing link fdinfo.
 
  - Addition of several new kfuncs (most of the names are self-explanatory):
    - Add a set of new dynptr kfuncs: bpf_dynptr_adjust(),
      bpf_dynptr_is_null(), bpf_dynptr_is_rdonly(), bpf_dynptr_size()
      and bpf_dynptr_clone().
    - bpf_task_under_cgroup()
    - bpf_sock_destroy() - force closing sockets
    - bpf_cpumask_first_and(), rework bpf_cpumask_any*() kfuncs
 
 Netfilter
 ---------
 
  - Relax set/map validation checks in nf_tables. Allow checking
    presence of an entry in a map without using the value.
 
  - Increase ip_vs_conn_tab_bits range for 64BIT builds.
 
  - Allow updating size of a set.
 
  - Improve NAT tuple selection when connection is closing.
 
 Driver API
 ----------
 
  - Integrate netdev with LED subsystem, to allow configuring HW
    "offloaded" blinking of LEDs based on link state and activity
    (i.e. packets coming in and out).
 
  - Support configuring rate selection pins of SFP modules.
 
  - Factor Clause 73 auto-negotiation code out of the drivers, provide
    common helper routines.
 
  - Add more fool-proof helpers for managing lifetime of MDIO devices
    associated with the PCS layer.
 
  - Allow drivers to report advanced statistics related to Time Aware
    scheduler offload (taprio).
 
  - Allow opting out of VF statistics in link dump, to allow more VFs
    to fit into the message.
 
  - Split devlink instance and devlink port operations.
 
 New hardware / drivers
 ----------------------
 
  - Ethernet:
    - Synopsys EMAC4 IP support (stmmac)
    - Marvell 88E6361 8 port (5x1GE + 3x2.5GE) switches
    - Marvell 88E6250 7 port switches
    - Microchip LAN8650/1 Rev.B0 PHYs
    - MediaTek MT7981/MT7988 built-in 1GE PHY driver
 
  - WiFi:
    - Realtek RTL8192FU, 2.4 GHz, b/g/n mode, 2T2R, 300 Mbps
    - Realtek RTL8723DS (SDIO variant)
    - Realtek RTL8851BE
 
  - CAN:
    - Fintek F81604
 
 Drivers
 -------
 
  - Ethernet NICs:
    - Intel (100G, ice):
      - support dynamic interrupt allocation
      - use meta data match instead of VF MAC addr on slow-path
    - nVidia/Mellanox:
      - extend link aggregation to handle 4, rather than just 2 ports
      - spawn sub-functions without any features by default
    - OcteonTX2:
      - support HTB (Tx scheduling/QoS) offload
      - make RSS hash generation configurable
      - support selecting Rx queue using TC filters
    - Wangxun (ngbe/txgbe):
      - add basic Tx/Rx packet offloads
      - add phylink support (SFP/PCS control)
    - Freescale/NXP (enetc):
      - report TAPRIO packet statistics
    - Solarflare/AMD:
      - support matching on IP ToS and UDP source port of outer header
      - VxLAN and GENEVE tunnel encapsulation over IPv4 or IPv6
      - add devlink dev info support for EF10
 
  - Virtual NICs:
    - Microsoft vNIC:
      - size the Rx indirection table based on requested configuration
      - support VLAN tagging
    - Amazon vNIC:
      - try to reuse Rx buffers if not fully consumed, useful for ARM
        servers running with 16kB pages
    - Google vNIC:
      - support TCP segmentation of >64kB frames
 
  - Ethernet embedded switches:
    - Marvell (mv88e6xxx):
      - enable USXGMII (88E6191X)
    - Microchip:
     - lan966x: add support for Egress Stage 0 ACL engine
     - lan966x: support mapping packet priority to internal switch
       priority (based on PCP or DSCP)
 
  - Ethernet PHYs:
    - Broadcom PHYs:
      - support for Wake-on-LAN for BCM54210E/B50212E
      - report LPI counter
    - Microsemi PHYs: support RGMII delay configuration (VSC85xx)
    - Micrel PHYs: receive timestamp in the frame (LAN8841)
    - Realtek PHYs: support optional external PHY clock
    - Altera TSE PCS: merge the driver into Lynx PCS which it is
      a variant of
 
  - CAN: Kvaser PCIEcan:
    - support packet timestamping
 
  - WiFi:
    - Intel (iwlwifi):
      - major update for new firmware and Multi-Link Operation (MLO)
      - configuration rework to drop test devices and split
        the different families
      - support for segmented PNVM images and power tables
      - new vendor entries for PPAG (platform antenna gain) feature
    - Qualcomm 802.11ax (ath11k):
      - Multiple Basic Service Set Identifier (MBSSID) and
        Enhanced MBSSID Advertisement (EMA) support in AP mode
      - support factory test mode
    - RealTek (rtw89):
      - add RSSI based antenna diversity
      - support U-NII-4 channels on 5 GHz band
    - RealTek (rtl8xxxu):
      - AP mode support for 8188f
      - support USB RX aggregation for the newer chips
 
 Signed-off-by: Jakub Kicinski <kuba@kernel.org>
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Merge tag 'net-next-6.5' of git://git.kernel.org/pub/scm/linux/kernel/git/netdev/net-next

Pull networking changes from Jakub Kicinski:
 "WiFi 7 and sendpage changes are the biggest pieces of work for this
  release. The latter will definitely require fixes but I think that we
  got it to a reasonable point.

  Core:

   - Rework the sendpage & splice implementations

     Instead of feeding data into sockets page by page extend sendmsg
     handlers to support taking a reference on the data, controlled by a
     new flag called MSG_SPLICE_PAGES

     Rework the handling of unexpected-end-of-file to invoke an
     additional callback instead of trying to predict what the right
     combination of MORE/NOTLAST flags is

     Remove the MSG_SENDPAGE_NOTLAST flag completely

   - Implement SCM_PIDFD, a new type of CMSG type analogous to
     SCM_CREDENTIALS, but it contains pidfd instead of plain pid

   - Enable socket busy polling with CONFIG_RT

   - Improve reliability and efficiency of reporting for ref_tracker

   - Auto-generate a user space C library for various Netlink families

  Protocols:

   - Allow TCP to shrink the advertised window when necessary, prevent
     sk_rcvbuf auto-tuning from growing the window all the way up to
     tcp_rmem[2]

   - Use per-VMA locking for "page-flipping" TCP receive zerocopy

   - Prepare TCP for device-to-device data transfers, by making sure
     that payloads are always attached to skbs as page frags

   - Make the backoff time for the first N TCP SYN retransmissions
     linear. Exponential backoff is unnecessarily conservative

   - Create a new MPTCP getsockopt to retrieve all info
     (MPTCP_FULL_INFO)

   - Avoid waking up applications using TLS sockets until we have a full
     record

   - Allow using kernel memory for protocol ioctl callbacks, paving the
     way to issuing ioctls over io_uring

   - Add nolocalbypass option to VxLAN, forcing packets to be fully
     encapsulated even if they are destined for a local IP address

   - Make TCPv4 use consistent hash in TIME_WAIT and SYN_RECV. Ensure
     in-kernel ECMP implementation (e.g. Open vSwitch) select the same
     link for all packets. Support L4 symmetric hashing in Open vSwitch

   - PPPoE: make number of hash bits configurable

   - Allow DNS to be overwritten by DHCPACK in the in-kernel DHCP client
     (ipconfig)

   - Add layer 2 miss indication and filtering, allowing higher layers
     (e.g. ACL filters) to make forwarding decisions based on whether
     packet matched forwarding state in lower devices (bridge)

   - Support matching on Connectivity Fault Management (CFM) packets

   - Hide the "link becomes ready" IPv6 messages by demoting their
     printk level to debug

   - HSR: don't enable promiscuous mode if device offloads the proto

   - Support active scanning in IEEE 802.15.4

   - Continue work on Multi-Link Operation for WiFi 7

  BPF:

   - Add precision propagation for subprogs and callbacks. This allows
     maintaining verification efficiency when subprograms are used, or
     in fact passing the verifier at all for complex programs,
     especially those using open-coded iterators

   - Improve BPF's {g,s}setsockopt() length handling. Previously BPF
     assumed the length is always equal to the amount of written data.
     But some protos allow passing a NULL buffer to discover what the
     output buffer *should* be, without writing anything

   - Accept dynptr memory as memory arguments passed to helpers

   - Add routing table ID to bpf_fib_lookup BPF helper

   - Support O_PATH FDs in BPF_OBJ_PIN and BPF_OBJ_GET commands

   - Drop bpf_capable() check in BPF_MAP_FREEZE command (used to mark
     maps as read-only)

   - Show target_{obj,btf}_id in tracing link fdinfo

   - Addition of several new kfuncs (most of the names are
     self-explanatory):
      - Add a set of new dynptr kfuncs: bpf_dynptr_adjust(),
        bpf_dynptr_is_null(), bpf_dynptr_is_rdonly(), bpf_dynptr_size()
        and bpf_dynptr_clone().
      - bpf_task_under_cgroup()
      - bpf_sock_destroy() - force closing sockets
      - bpf_cpumask_first_and(), rework bpf_cpumask_any*() kfuncs

  Netfilter:

   - Relax set/map validation checks in nf_tables. Allow checking
     presence of an entry in a map without using the value

   - Increase ip_vs_conn_tab_bits range for 64BIT builds

   - Allow updating size of a set

   - Improve NAT tuple selection when connection is closing

  Driver API:

   - Integrate netdev with LED subsystem, to allow configuring HW
     "offloaded" blinking of LEDs based on link state and activity
     (i.e. packets coming in and out)

   - Support configuring rate selection pins of SFP modules

   - Factor Clause 73 auto-negotiation code out of the drivers, provide
     common helper routines

   - Add more fool-proof helpers for managing lifetime of MDIO devices
     associated with the PCS layer

   - Allow drivers to report advanced statistics related to Time Aware
     scheduler offload (taprio)

   - Allow opting out of VF statistics in link dump, to allow more VFs
     to fit into the message

   - Split devlink instance and devlink port operations

  New hardware / drivers:

   - Ethernet:
      - Synopsys EMAC4 IP support (stmmac)
      - Marvell 88E6361 8 port (5x1GE + 3x2.5GE) switches
      - Marvell 88E6250 7 port switches
      - Microchip LAN8650/1 Rev.B0 PHYs
      - MediaTek MT7981/MT7988 built-in 1GE PHY driver

   - WiFi:
      - Realtek RTL8192FU, 2.4 GHz, b/g/n mode, 2T2R, 300 Mbps
      - Realtek RTL8723DS (SDIO variant)
      - Realtek RTL8851BE

   - CAN:
      - Fintek F81604

  Drivers:

   - Ethernet NICs:
      - Intel (100G, ice):
         - support dynamic interrupt allocation
         - use meta data match instead of VF MAC addr on slow-path
      - nVidia/Mellanox:
         - extend link aggregation to handle 4, rather than just 2 ports
         - spawn sub-functions without any features by default
      - OcteonTX2:
         - support HTB (Tx scheduling/QoS) offload
         - make RSS hash generation configurable
         - support selecting Rx queue using TC filters
      - Wangxun (ngbe/txgbe):
         - add basic Tx/Rx packet offloads
         - add phylink support (SFP/PCS control)
      - Freescale/NXP (enetc):
         - report TAPRIO packet statistics
      - Solarflare/AMD:
         - support matching on IP ToS and UDP source port of outer
           header
         - VxLAN and GENEVE tunnel encapsulation over IPv4 or IPv6
         - add devlink dev info support for EF10

   - Virtual NICs:
      - Microsoft vNIC:
         - size the Rx indirection table based on requested
           configuration
         - support VLAN tagging
      - Amazon vNIC:
         - try to reuse Rx buffers if not fully consumed, useful for ARM
           servers running with 16kB pages
      - Google vNIC:
         - support TCP segmentation of >64kB frames

   - Ethernet embedded switches:
      - Marvell (mv88e6xxx):
         - enable USXGMII (88E6191X)
      - Microchip:
         - lan966x: add support for Egress Stage 0 ACL engine
         - lan966x: support mapping packet priority to internal switch
           priority (based on PCP or DSCP)

   - Ethernet PHYs:
      - Broadcom PHYs:
         - support for Wake-on-LAN for BCM54210E/B50212E
         - report LPI counter
      - Microsemi PHYs: support RGMII delay configuration (VSC85xx)
      - Micrel PHYs: receive timestamp in the frame (LAN8841)
      - Realtek PHYs: support optional external PHY clock
      - Altera TSE PCS: merge the driver into Lynx PCS which it is a
        variant of

   - CAN: Kvaser PCIEcan:
      - support packet timestamping

   - WiFi:
      - Intel (iwlwifi):
         - major update for new firmware and Multi-Link Operation (MLO)
         - configuration rework to drop test devices and split the
           different families
         - support for segmented PNVM images and power tables
         - new vendor entries for PPAG (platform antenna gain) feature
      - Qualcomm 802.11ax (ath11k):
         - Multiple Basic Service Set Identifier (MBSSID) and Enhanced
           MBSSID Advertisement (EMA) support in AP mode
         - support factory test mode
      - RealTek (rtw89):
         - add RSSI based antenna diversity
         - support U-NII-4 channels on 5 GHz band
      - RealTek (rtl8xxxu):
         - AP mode support for 8188f
         - support USB RX aggregation for the newer chips"

* tag 'net-next-6.5' of git://git.kernel.org/pub/scm/linux/kernel/git/netdev/net-next: (1602 commits)
  net: scm: introduce and use scm_recv_unix helper
  af_unix: Skip SCM_PIDFD if scm->pid is NULL.
  net: lan743x: Simplify comparison
  netlink: Add __sock_i_ino() for __netlink_diag_dump().
  net: dsa: avoid suspicious RCU usage for synced VLAN-aware MAC addresses
  Revert "af_unix: Call scm_recv() only after scm_set_cred()."
  phylink: ReST-ify the phylink_pcs_neg_mode() kdoc
  libceph: Partially revert changes to support MSG_SPLICE_PAGES
  net: phy: mscc: fix packet loss due to RGMII delays
  net: mana: use vmalloc_array and vcalloc
  net: enetc: use vmalloc_array and vcalloc
  ionic: use vmalloc_array and vcalloc
  pds_core: use vmalloc_array and vcalloc
  gve: use vmalloc_array and vcalloc
  octeon_ep: use vmalloc_array and vcalloc
  net: usb: qmi_wwan: add u-blox 0x1312 composition
  perf trace: fix MSG_SPLICE_PAGES build error
  ipvlan: Fix return value of ipvlan_queue_xmit()
  netfilter: nf_tables: fix underflow in chain reference counter
  netfilter: nf_tables: unbind non-anonymous set if rule construction fails
  ...
2023-06-28 16:43:10 -07:00

3308 lines
83 KiB
C
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// SPDX-License-Identifier: BSD-3-Clause-Clear
/*
* Copyright (c) 2018-2019 The Linux Foundation. All rights reserved.
* Copyright (c) 2022-2023 Qualcomm Innovation Center, Inc. All rights reserved.
*/
#include <linux/elf.h>
#include "qmi.h"
#include "core.h"
#include "debug.h"
#include <linux/of.h>
#include <linux/of_address.h>
#include <linux/ioport.h>
#include <linux/firmware.h>
#include <linux/of_device.h>
#include <linux/of_irq.h>
#define SLEEP_CLOCK_SELECT_INTERNAL_BIT 0x02
#define HOST_CSTATE_BIT 0x04
#define PLATFORM_CAP_PCIE_GLOBAL_RESET 0x08
#define PLATFORM_CAP_PCIE_PME_D3COLD 0x10
#define FW_BUILD_ID_MASK "QC_IMAGE_VERSION_STRING="
bool ath11k_cold_boot_cal = 1;
EXPORT_SYMBOL(ath11k_cold_boot_cal);
module_param_named(cold_boot_cal, ath11k_cold_boot_cal, bool, 0644);
MODULE_PARM_DESC(cold_boot_cal,
"Decrease the channel switch time but increase the driver load time (Default: true)");
static const struct qmi_elem_info qmi_wlanfw_host_cap_req_msg_v01_ei[] = {
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x10,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
num_clients_valid),
},
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0x10,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
num_clients),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x11,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
wake_msi_valid),
},
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0x11,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
wake_msi),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x12,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
gpios_valid),
},
{
.data_type = QMI_DATA_LEN,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x12,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
gpios_len),
},
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = QMI_WLFW_MAX_NUM_GPIO_V01,
.elem_size = sizeof(u32),
.array_type = VAR_LEN_ARRAY,
.tlv_type = 0x12,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
gpios),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x13,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
nm_modem_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x13,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
nm_modem),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x14,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
bdf_support_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x14,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
bdf_support),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x15,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
bdf_cache_support_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x15,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
bdf_cache_support),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x16,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
m3_support_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x16,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
m3_support),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x17,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
m3_cache_support_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x17,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
m3_cache_support),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x18,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
cal_filesys_support_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x18,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
cal_filesys_support),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x19,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
cal_cache_support_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x19,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
cal_cache_support),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x1A,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
cal_done_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x1A,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
cal_done),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x1B,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
mem_bucket_valid),
},
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0x1B,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
mem_bucket),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x1C,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
mem_cfg_mode_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x1C,
.offset = offsetof(struct qmi_wlanfw_host_cap_req_msg_v01,
mem_cfg_mode),
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_host_cap_resp_msg_v01_ei[] = {
{
.data_type = QMI_STRUCT,
.elem_len = 1,
.elem_size = sizeof(struct qmi_response_type_v01),
.array_type = NO_ARRAY,
.tlv_type = 0x02,
.offset = offsetof(struct qmi_wlanfw_host_cap_resp_msg_v01, resp),
.ei_array = qmi_response_type_v01_ei,
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_ind_register_req_msg_v01_ei[] = {
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x10,
.offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
fw_ready_enable_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x10,
.offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
fw_ready_enable),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x11,
.offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
initiate_cal_download_enable_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x11,
.offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
initiate_cal_download_enable),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x12,
.offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
initiate_cal_update_enable_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x12,
.offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
initiate_cal_update_enable),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x13,
.offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
msa_ready_enable_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x13,
.offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
msa_ready_enable),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x14,
.offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
pin_connect_result_enable_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x14,
.offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
pin_connect_result_enable),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x15,
.offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
client_id_valid),
},
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0x15,
.offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
client_id),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x16,
.offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
request_mem_enable_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x16,
.offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
request_mem_enable),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x17,
.offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
fw_mem_ready_enable_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x17,
.offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
fw_mem_ready_enable),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x18,
.offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
fw_init_done_enable_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x18,
.offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
fw_init_done_enable),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x19,
.offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
rejuvenate_enable_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x19,
.offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
rejuvenate_enable),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x1A,
.offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
xo_cal_enable_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x1A,
.offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
xo_cal_enable),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x1B,
.offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
cal_done_enable_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x1B,
.offset = offsetof(struct qmi_wlanfw_ind_register_req_msg_v01,
cal_done_enable),
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_ind_register_resp_msg_v01_ei[] = {
{
.data_type = QMI_STRUCT,
.elem_len = 1,
.elem_size = sizeof(struct qmi_response_type_v01),
.array_type = NO_ARRAY,
.tlv_type = 0x02,
.offset = offsetof(struct qmi_wlanfw_ind_register_resp_msg_v01,
resp),
.ei_array = qmi_response_type_v01_ei,
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x10,
.offset = offsetof(struct qmi_wlanfw_ind_register_resp_msg_v01,
fw_status_valid),
},
{
.data_type = QMI_UNSIGNED_8_BYTE,
.elem_len = 1,
.elem_size = sizeof(u64),
.array_type = NO_ARRAY,
.tlv_type = 0x10,
.offset = offsetof(struct qmi_wlanfw_ind_register_resp_msg_v01,
fw_status),
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_mem_cfg_s_v01_ei[] = {
{
.data_type = QMI_UNSIGNED_8_BYTE,
.elem_len = 1,
.elem_size = sizeof(u64),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_mem_cfg_s_v01, offset),
},
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_mem_cfg_s_v01, size),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_mem_cfg_s_v01, secure_flag),
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_mem_seg_s_v01_ei[] = {
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_mem_seg_s_v01,
size),
},
{
.data_type = QMI_SIGNED_4_BYTE_ENUM,
.elem_len = 1,
.elem_size = sizeof(enum qmi_wlanfw_mem_type_enum_v01),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_mem_seg_s_v01, type),
},
{
.data_type = QMI_DATA_LEN,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_mem_seg_s_v01, mem_cfg_len),
},
{
.data_type = QMI_STRUCT,
.elem_len = QMI_WLANFW_MAX_NUM_MEM_CFG_V01,
.elem_size = sizeof(struct qmi_wlanfw_mem_cfg_s_v01),
.array_type = VAR_LEN_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_mem_seg_s_v01, mem_cfg),
.ei_array = qmi_wlanfw_mem_cfg_s_v01_ei,
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_request_mem_ind_msg_v01_ei[] = {
{
.data_type = QMI_DATA_LEN,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x01,
.offset = offsetof(struct qmi_wlanfw_request_mem_ind_msg_v01,
mem_seg_len),
},
{
.data_type = QMI_STRUCT,
.elem_len = ATH11K_QMI_WLANFW_MAX_NUM_MEM_SEG_V01,
.elem_size = sizeof(struct qmi_wlanfw_mem_seg_s_v01),
.array_type = VAR_LEN_ARRAY,
.tlv_type = 0x01,
.offset = offsetof(struct qmi_wlanfw_request_mem_ind_msg_v01,
mem_seg),
.ei_array = qmi_wlanfw_mem_seg_s_v01_ei,
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_mem_seg_resp_s_v01_ei[] = {
{
.data_type = QMI_UNSIGNED_8_BYTE,
.elem_len = 1,
.elem_size = sizeof(u64),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_mem_seg_resp_s_v01, addr),
},
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_mem_seg_resp_s_v01, size),
},
{
.data_type = QMI_SIGNED_4_BYTE_ENUM,
.elem_len = 1,
.elem_size = sizeof(enum qmi_wlanfw_mem_type_enum_v01),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_mem_seg_resp_s_v01, type),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_mem_seg_resp_s_v01, restore),
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_respond_mem_req_msg_v01_ei[] = {
{
.data_type = QMI_DATA_LEN,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x01,
.offset = offsetof(struct qmi_wlanfw_respond_mem_req_msg_v01,
mem_seg_len),
},
{
.data_type = QMI_STRUCT,
.elem_len = ATH11K_QMI_WLANFW_MAX_NUM_MEM_SEG_V01,
.elem_size = sizeof(struct qmi_wlanfw_mem_seg_resp_s_v01),
.array_type = VAR_LEN_ARRAY,
.tlv_type = 0x01,
.offset = offsetof(struct qmi_wlanfw_respond_mem_req_msg_v01,
mem_seg),
.ei_array = qmi_wlanfw_mem_seg_resp_s_v01_ei,
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_respond_mem_resp_msg_v01_ei[] = {
{
.data_type = QMI_STRUCT,
.elem_len = 1,
.elem_size = sizeof(struct qmi_response_type_v01),
.array_type = NO_ARRAY,
.tlv_type = 0x02,
.offset = offsetof(struct qmi_wlanfw_respond_mem_resp_msg_v01,
resp),
.ei_array = qmi_response_type_v01_ei,
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_cap_req_msg_v01_ei[] = {
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_device_info_req_msg_v01_ei[] = {
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlfw_device_info_resp_msg_v01_ei[] = {
{
.data_type = QMI_STRUCT,
.elem_len = 1,
.elem_size = sizeof(struct qmi_response_type_v01),
.array_type = NO_ARRAY,
.tlv_type = 0x02,
.offset = offsetof(struct qmi_wlanfw_device_info_resp_msg_v01,
resp),
.ei_array = qmi_response_type_v01_ei,
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x10,
.offset = offsetof(struct qmi_wlanfw_device_info_resp_msg_v01,
bar_addr_valid),
},
{
.data_type = QMI_UNSIGNED_8_BYTE,
.elem_len = 1,
.elem_size = sizeof(u64),
.array_type = NO_ARRAY,
.tlv_type = 0x10,
.offset = offsetof(struct qmi_wlanfw_device_info_resp_msg_v01,
bar_addr),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x11,
.offset = offsetof(struct qmi_wlanfw_device_info_resp_msg_v01,
bar_size_valid),
},
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0x11,
.offset = offsetof(struct qmi_wlanfw_device_info_resp_msg_v01,
bar_size),
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_rf_chip_info_s_v01_ei[] = {
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_rf_chip_info_s_v01,
chip_id),
},
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_rf_chip_info_s_v01,
chip_family),
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_rf_board_info_s_v01_ei[] = {
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_rf_board_info_s_v01,
board_id),
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_soc_info_s_v01_ei[] = {
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_soc_info_s_v01, soc_id),
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_fw_version_info_s_v01_ei[] = {
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_fw_version_info_s_v01,
fw_version),
},
{
.data_type = QMI_STRING,
.elem_len = ATH11K_QMI_WLANFW_MAX_TIMESTAMP_LEN_V01 + 1,
.elem_size = sizeof(char),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_fw_version_info_s_v01,
fw_build_timestamp),
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_cap_resp_msg_v01_ei[] = {
{
.data_type = QMI_STRUCT,
.elem_len = 1,
.elem_size = sizeof(struct qmi_response_type_v01),
.array_type = NO_ARRAY,
.tlv_type = 0x02,
.offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01, resp),
.ei_array = qmi_response_type_v01_ei,
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x10,
.offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
chip_info_valid),
},
{
.data_type = QMI_STRUCT,
.elem_len = 1,
.elem_size = sizeof(struct qmi_wlanfw_rf_chip_info_s_v01),
.array_type = NO_ARRAY,
.tlv_type = 0x10,
.offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
chip_info),
.ei_array = qmi_wlanfw_rf_chip_info_s_v01_ei,
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x11,
.offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
board_info_valid),
},
{
.data_type = QMI_STRUCT,
.elem_len = 1,
.elem_size = sizeof(struct qmi_wlanfw_rf_board_info_s_v01),
.array_type = NO_ARRAY,
.tlv_type = 0x11,
.offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
board_info),
.ei_array = qmi_wlanfw_rf_board_info_s_v01_ei,
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x12,
.offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
soc_info_valid),
},
{
.data_type = QMI_STRUCT,
.elem_len = 1,
.elem_size = sizeof(struct qmi_wlanfw_soc_info_s_v01),
.array_type = NO_ARRAY,
.tlv_type = 0x12,
.offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
soc_info),
.ei_array = qmi_wlanfw_soc_info_s_v01_ei,
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x13,
.offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
fw_version_info_valid),
},
{
.data_type = QMI_STRUCT,
.elem_len = 1,
.elem_size = sizeof(struct qmi_wlanfw_fw_version_info_s_v01),
.array_type = NO_ARRAY,
.tlv_type = 0x13,
.offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
fw_version_info),
.ei_array = qmi_wlanfw_fw_version_info_s_v01_ei,
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x14,
.offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
fw_build_id_valid),
},
{
.data_type = QMI_STRING,
.elem_len = ATH11K_QMI_WLANFW_MAX_BUILD_ID_LEN_V01 + 1,
.elem_size = sizeof(char),
.array_type = NO_ARRAY,
.tlv_type = 0x14,
.offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
fw_build_id),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x15,
.offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
num_macs_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x15,
.offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
num_macs),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x16,
.offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
voltage_mv_valid),
},
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0x16,
.offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
voltage_mv),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x17,
.offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
time_freq_hz_valid),
},
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0x17,
.offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
time_freq_hz),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x18,
.offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
otp_version_valid),
},
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0x18,
.offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
otp_version),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x19,
.offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
eeprom_read_timeout_valid),
},
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0x19,
.offset = offsetof(struct qmi_wlanfw_cap_resp_msg_v01,
eeprom_read_timeout),
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_bdf_download_req_msg_v01_ei[] = {
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x01,
.offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
valid),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x10,
.offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
file_id_valid),
},
{
.data_type = QMI_SIGNED_4_BYTE_ENUM,
.elem_len = 1,
.elem_size = sizeof(enum qmi_wlanfw_cal_temp_id_enum_v01),
.array_type = NO_ARRAY,
.tlv_type = 0x10,
.offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
file_id),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x11,
.offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
total_size_valid),
},
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0x11,
.offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
total_size),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x12,
.offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
seg_id_valid),
},
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0x12,
.offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
seg_id),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x13,
.offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
data_valid),
},
{
.data_type = QMI_DATA_LEN,
.elem_len = 1,
.elem_size = sizeof(u16),
.array_type = NO_ARRAY,
.tlv_type = 0x13,
.offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
data_len),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = QMI_WLANFW_MAX_DATA_SIZE_V01,
.elem_size = sizeof(u8),
.array_type = VAR_LEN_ARRAY,
.tlv_type = 0x13,
.offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
data),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x14,
.offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
end_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x14,
.offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
end),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x15,
.offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
bdf_type_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x15,
.offset = offsetof(struct qmi_wlanfw_bdf_download_req_msg_v01,
bdf_type),
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_bdf_download_resp_msg_v01_ei[] = {
{
.data_type = QMI_STRUCT,
.elem_len = 1,
.elem_size = sizeof(struct qmi_response_type_v01),
.array_type = NO_ARRAY,
.tlv_type = 0x02,
.offset = offsetof(struct qmi_wlanfw_bdf_download_resp_msg_v01,
resp),
.ei_array = qmi_response_type_v01_ei,
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_m3_info_req_msg_v01_ei[] = {
{
.data_type = QMI_UNSIGNED_8_BYTE,
.elem_len = 1,
.elem_size = sizeof(u64),
.array_type = NO_ARRAY,
.tlv_type = 0x01,
.offset = offsetof(struct qmi_wlanfw_m3_info_req_msg_v01, addr),
},
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0x02,
.offset = offsetof(struct qmi_wlanfw_m3_info_req_msg_v01, size),
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_m3_info_resp_msg_v01_ei[] = {
{
.data_type = QMI_STRUCT,
.elem_len = 1,
.elem_size = sizeof(struct qmi_response_type_v01),
.array_type = NO_ARRAY,
.tlv_type = 0x02,
.offset = offsetof(struct qmi_wlanfw_m3_info_resp_msg_v01, resp),
.ei_array = qmi_response_type_v01_ei,
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_ce_tgt_pipe_cfg_s_v01_ei[] = {
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_ce_tgt_pipe_cfg_s_v01,
pipe_num),
},
{
.data_type = QMI_SIGNED_4_BYTE_ENUM,
.elem_len = 1,
.elem_size = sizeof(enum qmi_wlanfw_pipedir_enum_v01),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_ce_tgt_pipe_cfg_s_v01,
pipe_dir),
},
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_ce_tgt_pipe_cfg_s_v01,
nentries),
},
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_ce_tgt_pipe_cfg_s_v01,
nbytes_max),
},
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_ce_tgt_pipe_cfg_s_v01,
flags),
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_ce_svc_pipe_cfg_s_v01_ei[] = {
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_ce_svc_pipe_cfg_s_v01,
service_id),
},
{
.data_type = QMI_SIGNED_4_BYTE_ENUM,
.elem_len = 1,
.elem_size = sizeof(enum qmi_wlanfw_pipedir_enum_v01),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_ce_svc_pipe_cfg_s_v01,
pipe_dir),
},
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_ce_svc_pipe_cfg_s_v01,
pipe_num),
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_shadow_reg_cfg_s_v01_ei[] = {
{
.data_type = QMI_UNSIGNED_2_BYTE,
.elem_len = 1,
.elem_size = sizeof(u16),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_shadow_reg_cfg_s_v01, id),
},
{
.data_type = QMI_UNSIGNED_2_BYTE,
.elem_len = 1,
.elem_size = sizeof(u16),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_shadow_reg_cfg_s_v01,
offset),
},
{
.data_type = QMI_EOTI,
.array_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_shadow_reg_v2_cfg_s_v01_ei[] = {
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0,
.offset = offsetof(struct qmi_wlanfw_shadow_reg_v2_cfg_s_v01,
addr),
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_wlan_mode_req_msg_v01_ei[] = {
{
.data_type = QMI_UNSIGNED_4_BYTE,
.elem_len = 1,
.elem_size = sizeof(u32),
.array_type = NO_ARRAY,
.tlv_type = 0x01,
.offset = offsetof(struct qmi_wlanfw_wlan_mode_req_msg_v01,
mode),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x10,
.offset = offsetof(struct qmi_wlanfw_wlan_mode_req_msg_v01,
hw_debug_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x10,
.offset = offsetof(struct qmi_wlanfw_wlan_mode_req_msg_v01,
hw_debug),
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_wlan_mode_resp_msg_v01_ei[] = {
{
.data_type = QMI_STRUCT,
.elem_len = 1,
.elem_size = sizeof(struct qmi_response_type_v01),
.array_type = NO_ARRAY,
.tlv_type = 0x02,
.offset = offsetof(struct qmi_wlanfw_wlan_mode_resp_msg_v01,
resp),
.ei_array = qmi_response_type_v01_ei,
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_wlan_cfg_req_msg_v01_ei[] = {
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x10,
.offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
host_version_valid),
},
{
.data_type = QMI_STRING,
.elem_len = QMI_WLANFW_MAX_STR_LEN_V01 + 1,
.elem_size = sizeof(char),
.array_type = NO_ARRAY,
.tlv_type = 0x10,
.offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
host_version),
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x11,
.offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
tgt_cfg_valid),
},
{
.data_type = QMI_DATA_LEN,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x11,
.offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
tgt_cfg_len),
},
{
.data_type = QMI_STRUCT,
.elem_len = QMI_WLANFW_MAX_NUM_CE_V01,
.elem_size = sizeof(
struct qmi_wlanfw_ce_tgt_pipe_cfg_s_v01),
.array_type = VAR_LEN_ARRAY,
.tlv_type = 0x11,
.offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
tgt_cfg),
.ei_array = qmi_wlanfw_ce_tgt_pipe_cfg_s_v01_ei,
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x12,
.offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
svc_cfg_valid),
},
{
.data_type = QMI_DATA_LEN,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x12,
.offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
svc_cfg_len),
},
{
.data_type = QMI_STRUCT,
.elem_len = QMI_WLANFW_MAX_NUM_SVC_V01,
.elem_size = sizeof(struct qmi_wlanfw_ce_svc_pipe_cfg_s_v01),
.array_type = VAR_LEN_ARRAY,
.tlv_type = 0x12,
.offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
svc_cfg),
.ei_array = qmi_wlanfw_ce_svc_pipe_cfg_s_v01_ei,
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x13,
.offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
shadow_reg_valid),
},
{
.data_type = QMI_DATA_LEN,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x13,
.offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
shadow_reg_len),
},
{
.data_type = QMI_STRUCT,
.elem_len = QMI_WLANFW_MAX_NUM_SHADOW_REG_V01,
.elem_size = sizeof(struct qmi_wlanfw_shadow_reg_cfg_s_v01),
.array_type = VAR_LEN_ARRAY,
.tlv_type = 0x13,
.offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
shadow_reg),
.ei_array = qmi_wlanfw_shadow_reg_cfg_s_v01_ei,
},
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x14,
.offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
shadow_reg_v2_valid),
},
{
.data_type = QMI_DATA_LEN,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x14,
.offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
shadow_reg_v2_len),
},
{
.data_type = QMI_STRUCT,
.elem_len = QMI_WLANFW_MAX_NUM_SHADOW_REG_V2_V01,
.elem_size = sizeof(struct qmi_wlanfw_shadow_reg_v2_cfg_s_v01),
.array_type = VAR_LEN_ARRAY,
.tlv_type = 0x14,
.offset = offsetof(struct qmi_wlanfw_wlan_cfg_req_msg_v01,
shadow_reg_v2),
.ei_array = qmi_wlanfw_shadow_reg_v2_cfg_s_v01_ei,
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_wlan_cfg_resp_msg_v01_ei[] = {
{
.data_type = QMI_STRUCT,
.elem_len = 1,
.elem_size = sizeof(struct qmi_response_type_v01),
.array_type = NO_ARRAY,
.tlv_type = 0x02,
.offset = offsetof(struct qmi_wlanfw_wlan_cfg_resp_msg_v01, resp),
.ei_array = qmi_response_type_v01_ei,
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_mem_ready_ind_msg_v01_ei[] = {
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
},
};
static const struct qmi_elem_info qmi_wlanfw_fw_ready_ind_msg_v01_ei[] = {
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
},
};
static const struct qmi_elem_info qmi_wlanfw_cold_boot_cal_done_ind_msg_v01_ei[] = {
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
},
};
static const struct qmi_elem_info qmi_wlanfw_wlan_ini_req_msg_v01_ei[] = {
{
.data_type = QMI_OPT_FLAG,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x10,
.offset = offsetof(struct qmi_wlanfw_wlan_ini_req_msg_v01,
enablefwlog_valid),
},
{
.data_type = QMI_UNSIGNED_1_BYTE,
.elem_len = 1,
.elem_size = sizeof(u8),
.array_type = NO_ARRAY,
.tlv_type = 0x10,
.offset = offsetof(struct qmi_wlanfw_wlan_ini_req_msg_v01,
enablefwlog),
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlanfw_wlan_ini_resp_msg_v01_ei[] = {
{
.data_type = QMI_STRUCT,
.elem_len = 1,
.elem_size = sizeof(struct qmi_response_type_v01),
.array_type = NO_ARRAY,
.tlv_type = 0x02,
.offset = offsetof(struct qmi_wlanfw_wlan_ini_resp_msg_v01,
resp),
.ei_array = qmi_response_type_v01_ei,
},
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
},
};
static const struct qmi_elem_info qmi_wlfw_fw_init_done_ind_msg_v01_ei[] = {
{
.data_type = QMI_EOTI,
.array_type = NO_ARRAY,
},
};
static int ath11k_qmi_host_cap_send(struct ath11k_base *ab)
{
struct qmi_wlanfw_host_cap_req_msg_v01 req;
struct qmi_wlanfw_host_cap_resp_msg_v01 resp;
struct qmi_txn txn;
int ret = 0;
memset(&req, 0, sizeof(req));
memset(&resp, 0, sizeof(resp));
req.num_clients_valid = 1;
req.num_clients = 1;
req.mem_cfg_mode = ab->qmi.target_mem_mode;
req.mem_cfg_mode_valid = 1;
req.bdf_support_valid = 1;
req.bdf_support = 1;
if (ab->hw_params.m3_fw_support) {
req.m3_support_valid = 1;
req.m3_support = 1;
req.m3_cache_support_valid = 1;
req.m3_cache_support = 1;
} else {
req.m3_support_valid = 0;
req.m3_support = 0;
req.m3_cache_support_valid = 0;
req.m3_cache_support = 0;
}
req.cal_done_valid = 1;
req.cal_done = ab->qmi.cal_done;
if (ab->hw_params.internal_sleep_clock) {
req.nm_modem_valid = 1;
/* Notify firmware that this is non-qualcomm platform. */
req.nm_modem |= HOST_CSTATE_BIT;
/* Notify firmware about the sleep clock selection,
* nm_modem_bit[1] is used for this purpose. Host driver on
* non-qualcomm platforms should select internal sleep
* clock.
*/
req.nm_modem |= SLEEP_CLOCK_SELECT_INTERNAL_BIT;
}
if (ab->hw_params.global_reset)
req.nm_modem |= PLATFORM_CAP_PCIE_GLOBAL_RESET;
req.nm_modem |= PLATFORM_CAP_PCIE_PME_D3COLD;
ath11k_dbg(ab, ATH11K_DBG_QMI, "host cap request\n");
ret = qmi_txn_init(&ab->qmi.handle, &txn,
qmi_wlanfw_host_cap_resp_msg_v01_ei, &resp);
if (ret < 0)
goto out;
ret = qmi_send_request(&ab->qmi.handle, NULL, &txn,
QMI_WLANFW_HOST_CAP_REQ_V01,
QMI_WLANFW_HOST_CAP_REQ_MSG_V01_MAX_LEN,
qmi_wlanfw_host_cap_req_msg_v01_ei, &req);
if (ret < 0) {
qmi_txn_cancel(&txn);
ath11k_warn(ab, "failed to send host capability request: %d\n", ret);
goto out;
}
ret = qmi_txn_wait(&txn, msecs_to_jiffies(ATH11K_QMI_WLANFW_TIMEOUT_MS));
if (ret < 0)
goto out;
if (resp.resp.result != QMI_RESULT_SUCCESS_V01) {
ath11k_warn(ab, "host capability request failed: %d %d\n",
resp.resp.result, resp.resp.error);
ret = -EINVAL;
goto out;
}
out:
return ret;
}
static int ath11k_qmi_fw_ind_register_send(struct ath11k_base *ab)
{
struct qmi_wlanfw_ind_register_req_msg_v01 *req;
struct qmi_wlanfw_ind_register_resp_msg_v01 *resp;
struct qmi_handle *handle = &ab->qmi.handle;
struct qmi_txn txn;
int ret;
req = kzalloc(sizeof(*req), GFP_KERNEL);
if (!req)
return -ENOMEM;
resp = kzalloc(sizeof(*resp), GFP_KERNEL);
if (!resp) {
ret = -ENOMEM;
goto resp_out;
}
req->client_id_valid = 1;
req->client_id = QMI_WLANFW_CLIENT_ID;
req->fw_ready_enable_valid = 1;
req->fw_ready_enable = 1;
req->cal_done_enable_valid = 1;
req->cal_done_enable = 1;
req->fw_init_done_enable_valid = 1;
req->fw_init_done_enable = 1;
req->pin_connect_result_enable_valid = 0;
req->pin_connect_result_enable = 0;
/* WCN6750 doesn't request for DDR memory via QMI,
* instead it uses a fixed 12MB reserved memory
* region in DDR.
*/
if (!ab->hw_params.fixed_fw_mem) {
req->request_mem_enable_valid = 1;
req->request_mem_enable = 1;
req->fw_mem_ready_enable_valid = 1;
req->fw_mem_ready_enable = 1;
}
ret = qmi_txn_init(handle, &txn,
qmi_wlanfw_ind_register_resp_msg_v01_ei, resp);
if (ret < 0)
goto out;
ath11k_dbg(ab, ATH11K_DBG_QMI, "indication register request\n");
ret = qmi_send_request(&ab->qmi.handle, NULL, &txn,
QMI_WLANFW_IND_REGISTER_REQ_V01,
QMI_WLANFW_IND_REGISTER_REQ_MSG_V01_MAX_LEN,
qmi_wlanfw_ind_register_req_msg_v01_ei, req);
if (ret < 0) {
qmi_txn_cancel(&txn);
ath11k_warn(ab, "failed to send indication register request: %d\n",
ret);
goto out;
}
ret = qmi_txn_wait(&txn, msecs_to_jiffies(ATH11K_QMI_WLANFW_TIMEOUT_MS));
if (ret < 0) {
ath11k_warn(ab, "failed to register fw indication: %d\n", ret);
goto out;
}
if (resp->resp.result != QMI_RESULT_SUCCESS_V01) {
ath11k_warn(ab, "firmware indication register request failed: %d %d\n",
resp->resp.result, resp->resp.error);
ret = -EINVAL;
goto out;
}
out:
kfree(resp);
resp_out:
kfree(req);
return ret;
}
static int ath11k_qmi_respond_fw_mem_request(struct ath11k_base *ab)
{
struct qmi_wlanfw_respond_mem_req_msg_v01 *req;
struct qmi_wlanfw_respond_mem_resp_msg_v01 resp;
struct qmi_txn txn;
int ret = 0, i;
bool delayed;
req = kzalloc(sizeof(*req), GFP_KERNEL);
if (!req)
return -ENOMEM;
memset(&resp, 0, sizeof(resp));
/* For QCA6390 by default FW requests a block of ~4M contiguous
* DMA memory, it's hard to allocate from OS. So host returns
* failure to FW and FW will then request multiple blocks of small
* chunk size memory.
*/
if (!(ab->hw_params.fixed_mem_region ||
test_bit(ATH11K_FLAG_FIXED_MEM_RGN, &ab->dev_flags)) &&
ab->qmi.target_mem_delayed) {
delayed = true;
ath11k_dbg(ab, ATH11K_DBG_QMI, "delays mem_request %d\n",
ab->qmi.mem_seg_count);
memset(req, 0, sizeof(*req));
} else {
delayed = false;
req->mem_seg_len = ab->qmi.mem_seg_count;
for (i = 0; i < req->mem_seg_len ; i++) {
req->mem_seg[i].addr = ab->qmi.target_mem[i].paddr;
req->mem_seg[i].size = ab->qmi.target_mem[i].size;
req->mem_seg[i].type = ab->qmi.target_mem[i].type;
ath11k_dbg(ab, ATH11K_DBG_QMI,
"req mem_seg[%d] %pad %u %u\n", i,
&ab->qmi.target_mem[i].paddr,
ab->qmi.target_mem[i].size,
ab->qmi.target_mem[i].type);
}
}
ret = qmi_txn_init(&ab->qmi.handle, &txn,
qmi_wlanfw_respond_mem_resp_msg_v01_ei, &resp);
if (ret < 0)
goto out;
ath11k_dbg(ab, ATH11K_DBG_QMI, "respond memory request delayed %i\n",
delayed);
ret = qmi_send_request(&ab->qmi.handle, NULL, &txn,
QMI_WLANFW_RESPOND_MEM_REQ_V01,
QMI_WLANFW_RESPOND_MEM_REQ_MSG_V01_MAX_LEN,
qmi_wlanfw_respond_mem_req_msg_v01_ei, req);
if (ret < 0) {
qmi_txn_cancel(&txn);
ath11k_warn(ab, "failed to respond qmi memory request: %d\n",
ret);
goto out;
}
ret = qmi_txn_wait(&txn, msecs_to_jiffies(ATH11K_QMI_WLANFW_TIMEOUT_MS));
if (ret < 0) {
ath11k_warn(ab, "failed to wait qmi memory request: %d\n", ret);
goto out;
}
if (resp.resp.result != QMI_RESULT_SUCCESS_V01) {
/* the error response is expected when
* target_mem_delayed is true.
*/
if (delayed && resp.resp.error == 0)
goto out;
ath11k_warn(ab, "qmi respond memory request failed: %d %d\n",
resp.resp.result, resp.resp.error);
ret = -EINVAL;
goto out;
}
out:
kfree(req);
return ret;
}
static void ath11k_qmi_free_target_mem_chunk(struct ath11k_base *ab)
{
int i;
for (i = 0; i < ab->qmi.mem_seg_count; i++) {
if ((ab->hw_params.fixed_mem_region ||
test_bit(ATH11K_FLAG_FIXED_MEM_RGN, &ab->dev_flags)) &&
ab->qmi.target_mem[i].iaddr)
iounmap(ab->qmi.target_mem[i].iaddr);
if (!ab->qmi.target_mem[i].vaddr)
continue;
dma_free_coherent(ab->dev,
ab->qmi.target_mem[i].prev_size,
ab->qmi.target_mem[i].vaddr,
ab->qmi.target_mem[i].paddr);
ab->qmi.target_mem[i].vaddr = NULL;
}
}
static int ath11k_qmi_alloc_target_mem_chunk(struct ath11k_base *ab)
{
int i;
struct target_mem_chunk *chunk;
ab->qmi.target_mem_delayed = false;
for (i = 0; i < ab->qmi.mem_seg_count; i++) {
chunk = &ab->qmi.target_mem[i];
/* Firmware reloads in coldboot/firmware recovery.
* in such case, no need to allocate memory for FW again.
*/
if (chunk->vaddr) {
if (chunk->prev_type == chunk->type &&
chunk->prev_size == chunk->size)
continue;
/* cannot reuse the existing chunk */
dma_free_coherent(ab->dev, chunk->prev_size,
chunk->vaddr, chunk->paddr);
chunk->vaddr = NULL;
}
chunk->vaddr = dma_alloc_coherent(ab->dev,
chunk->size,
&chunk->paddr,
GFP_KERNEL | __GFP_NOWARN);
if (!chunk->vaddr) {
if (ab->qmi.mem_seg_count <= ATH11K_QMI_FW_MEM_REQ_SEGMENT_CNT) {
ath11k_dbg(ab, ATH11K_DBG_QMI,
"dma allocation failed (%d B type %u), will try later with small size\n",
chunk->size,
chunk->type);
ath11k_qmi_free_target_mem_chunk(ab);
ab->qmi.target_mem_delayed = true;
return 0;
}
ath11k_err(ab, "failed to allocate dma memory for qmi (%d B type %u)\n",
chunk->size,
chunk->type);
return -EINVAL;
}
chunk->prev_type = chunk->type;
chunk->prev_size = chunk->size;
}
return 0;
}
static int ath11k_qmi_assign_target_mem_chunk(struct ath11k_base *ab)
{
struct device *dev = ab->dev;
struct device_node *hremote_node = NULL;
struct resource res;
u32 host_ddr_sz;
int i, idx, ret;
for (i = 0, idx = 0; i < ab->qmi.mem_seg_count; i++) {
switch (ab->qmi.target_mem[i].type) {
case HOST_DDR_REGION_TYPE:
hremote_node = of_parse_phandle(dev->of_node, "memory-region", 0);
if (!hremote_node) {
ath11k_dbg(ab, ATH11K_DBG_QMI,
"fail to get hremote_node\n");
return -ENODEV;
}
ret = of_address_to_resource(hremote_node, 0, &res);
of_node_put(hremote_node);
if (ret) {
ath11k_dbg(ab, ATH11K_DBG_QMI,
"fail to get reg from hremote\n");
return ret;
}
if (res.end - res.start + 1 < ab->qmi.target_mem[i].size) {
ath11k_dbg(ab, ATH11K_DBG_QMI,
"fail to assign memory of sz\n");
return -EINVAL;
}
ab->qmi.target_mem[idx].paddr = res.start;
ab->qmi.target_mem[idx].iaddr =
ioremap(ab->qmi.target_mem[idx].paddr,
ab->qmi.target_mem[i].size);
if (!ab->qmi.target_mem[idx].iaddr)
return -EIO;
ab->qmi.target_mem[idx].size = ab->qmi.target_mem[i].size;
host_ddr_sz = ab->qmi.target_mem[i].size;
ab->qmi.target_mem[idx].type = ab->qmi.target_mem[i].type;
idx++;
break;
case BDF_MEM_REGION_TYPE:
ab->qmi.target_mem[idx].paddr = ab->hw_params.bdf_addr;
ab->qmi.target_mem[idx].vaddr = NULL;
ab->qmi.target_mem[idx].size = ab->qmi.target_mem[i].size;
ab->qmi.target_mem[idx].type = ab->qmi.target_mem[i].type;
idx++;
break;
case CALDB_MEM_REGION_TYPE:
if (ab->qmi.target_mem[i].size > ATH11K_QMI_CALDB_SIZE) {
ath11k_warn(ab, "qmi mem size is low to load caldata\n");
return -EINVAL;
}
if (ath11k_cold_boot_cal && ab->hw_params.cold_boot_calib) {
if (hremote_node) {
ab->qmi.target_mem[idx].paddr =
res.start + host_ddr_sz;
ab->qmi.target_mem[idx].iaddr =
ioremap(ab->qmi.target_mem[idx].paddr,
ab->qmi.target_mem[i].size);
if (!ab->qmi.target_mem[idx].iaddr)
return -EIO;
} else {
ab->qmi.target_mem[idx].paddr =
ATH11K_QMI_CALDB_ADDRESS;
}
} else {
ab->qmi.target_mem[idx].paddr = 0;
ab->qmi.target_mem[idx].vaddr = NULL;
}
ab->qmi.target_mem[idx].size = ab->qmi.target_mem[i].size;
ab->qmi.target_mem[idx].type = ab->qmi.target_mem[i].type;
idx++;
break;
default:
ath11k_warn(ab, "qmi ignore invalid mem req type %d\n",
ab->qmi.target_mem[i].type);
break;
}
}
ab->qmi.mem_seg_count = idx;
return 0;
}
static int ath11k_qmi_request_device_info(struct ath11k_base *ab)
{
struct qmi_wlanfw_device_info_req_msg_v01 req = {};
struct qmi_wlanfw_device_info_resp_msg_v01 resp = {};
struct qmi_txn txn;
void __iomem *bar_addr_va;
int ret;
/* device info message req is only sent for hybrid bus devices */
if (!ab->hw_params.hybrid_bus_type)
return 0;
ret = qmi_txn_init(&ab->qmi.handle, &txn,
qmi_wlfw_device_info_resp_msg_v01_ei, &resp);
if (ret < 0)
goto out;
ret = qmi_send_request(&ab->qmi.handle, NULL, &txn,
QMI_WLANFW_DEVICE_INFO_REQ_V01,
QMI_WLANFW_DEVICE_INFO_REQ_MSG_V01_MAX_LEN,
qmi_wlanfw_device_info_req_msg_v01_ei, &req);
if (ret < 0) {
qmi_txn_cancel(&txn);
ath11k_warn(ab, "failed to send qmi target device info request: %d\n",
ret);
goto out;
}
ret = qmi_txn_wait(&txn, msecs_to_jiffies(ATH11K_QMI_WLANFW_TIMEOUT_MS));
if (ret < 0) {
ath11k_warn(ab, "failed to wait qmi target device info request: %d\n",
ret);
goto out;
}
if (resp.resp.result != QMI_RESULT_SUCCESS_V01) {
ath11k_warn(ab, "qmi device info request failed: %d %d\n",
resp.resp.result, resp.resp.error);
ret = -EINVAL;
goto out;
}
if (!resp.bar_addr_valid || !resp.bar_size_valid) {
ath11k_warn(ab, "qmi device info response invalid: %d %d\n",
resp.resp.result, resp.resp.error);
ret = -EINVAL;
goto out;
}
if (!resp.bar_addr ||
resp.bar_size != ATH11K_QMI_DEVICE_BAR_SIZE) {
ath11k_warn(ab, "qmi device info invalid address and size: %llu %u\n",
resp.bar_addr, resp.bar_size);
ret = -EINVAL;
goto out;
}
bar_addr_va = devm_ioremap(ab->dev, resp.bar_addr, resp.bar_size);
if (!bar_addr_va) {
ath11k_warn(ab, "qmi device info ioremap failed\n");
ab->mem_len = 0;
ret = -EIO;
goto out;
}
ab->mem = bar_addr_va;
ab->mem_len = resp.bar_size;
return 0;
out:
return ret;
}
static int ath11k_qmi_request_target_cap(struct ath11k_base *ab)
{
struct qmi_wlanfw_cap_req_msg_v01 req;
struct qmi_wlanfw_cap_resp_msg_v01 resp;
struct qmi_txn txn;
int ret = 0;
int r;
char *fw_build_id;
int fw_build_id_mask_len;
memset(&req, 0, sizeof(req));
memset(&resp, 0, sizeof(resp));
ret = qmi_txn_init(&ab->qmi.handle, &txn, qmi_wlanfw_cap_resp_msg_v01_ei,
&resp);
if (ret < 0)
goto out;
ath11k_dbg(ab, ATH11K_DBG_QMI, "target cap request\n");
ret = qmi_send_request(&ab->qmi.handle, NULL, &txn,
QMI_WLANFW_CAP_REQ_V01,
QMI_WLANFW_CAP_REQ_MSG_V01_MAX_LEN,
qmi_wlanfw_cap_req_msg_v01_ei, &req);
if (ret < 0) {
qmi_txn_cancel(&txn);
ath11k_warn(ab, "failed to send qmi cap request: %d\n",
ret);
goto out;
}
ret = qmi_txn_wait(&txn, msecs_to_jiffies(ATH11K_QMI_WLANFW_TIMEOUT_MS));
if (ret < 0) {
ath11k_warn(ab, "failed to wait qmi cap request: %d\n", ret);
goto out;
}
if (resp.resp.result != QMI_RESULT_SUCCESS_V01) {
ath11k_warn(ab, "qmi cap request failed: %d %d\n",
resp.resp.result, resp.resp.error);
ret = -EINVAL;
goto out;
}
if (resp.chip_info_valid) {
ab->qmi.target.chip_id = resp.chip_info.chip_id;
ab->qmi.target.chip_family = resp.chip_info.chip_family;
}
if (resp.board_info_valid)
ab->qmi.target.board_id = resp.board_info.board_id;
else
ab->qmi.target.board_id = 0xFF;
if (resp.soc_info_valid)
ab->qmi.target.soc_id = resp.soc_info.soc_id;
if (resp.fw_version_info_valid) {
ab->qmi.target.fw_version = resp.fw_version_info.fw_version;
strscpy(ab->qmi.target.fw_build_timestamp,
resp.fw_version_info.fw_build_timestamp,
sizeof(ab->qmi.target.fw_build_timestamp));
}
if (resp.fw_build_id_valid)
strscpy(ab->qmi.target.fw_build_id, resp.fw_build_id,
sizeof(ab->qmi.target.fw_build_id));
if (resp.eeprom_read_timeout_valid) {
ab->qmi.target.eeprom_caldata =
resp.eeprom_read_timeout;
ath11k_dbg(ab, ATH11K_DBG_QMI, "cal data supported from eeprom\n");
}
fw_build_id = ab->qmi.target.fw_build_id;
fw_build_id_mask_len = strlen(FW_BUILD_ID_MASK);
if (!strncmp(fw_build_id, FW_BUILD_ID_MASK, fw_build_id_mask_len))
fw_build_id = fw_build_id + fw_build_id_mask_len;
ath11k_info(ab, "chip_id 0x%x chip_family 0x%x board_id 0x%x soc_id 0x%x\n",
ab->qmi.target.chip_id, ab->qmi.target.chip_family,
ab->qmi.target.board_id, ab->qmi.target.soc_id);
ath11k_info(ab, "fw_version 0x%x fw_build_timestamp %s fw_build_id %s",
ab->qmi.target.fw_version,
ab->qmi.target.fw_build_timestamp,
fw_build_id);
r = ath11k_core_check_smbios(ab);
if (r)
ath11k_dbg(ab, ATH11K_DBG_QMI, "SMBIOS bdf variant name not set.\n");
r = ath11k_core_check_dt(ab);
if (r)
ath11k_dbg(ab, ATH11K_DBG_QMI, "DT bdf variant name not set.\n");
out:
return ret;
}
static int ath11k_qmi_load_file_target_mem(struct ath11k_base *ab,
const u8 *data, u32 len, u8 type)
{
struct qmi_wlanfw_bdf_download_req_msg_v01 *req;
struct qmi_wlanfw_bdf_download_resp_msg_v01 resp;
struct qmi_txn txn;
const u8 *temp = data;
void __iomem *bdf_addr = NULL;
int ret;
u32 remaining = len;
req = kzalloc(sizeof(*req), GFP_KERNEL);
if (!req)
return -ENOMEM;
memset(&resp, 0, sizeof(resp));
if (ab->hw_params.fixed_bdf_addr) {
bdf_addr = ioremap(ab->hw_params.bdf_addr, ab->hw_params.fw.board_size);
if (!bdf_addr) {
ath11k_warn(ab, "qmi ioremap error for bdf_addr\n");
ret = -EIO;
goto err_free_req;
}
}
while (remaining) {
req->valid = 1;
req->file_id_valid = 1;
req->file_id = ab->qmi.target.board_id;
req->total_size_valid = 1;
req->total_size = remaining;
req->seg_id_valid = 1;
req->data_valid = 1;
req->bdf_type = type;
req->bdf_type_valid = 1;
req->end_valid = 1;
req->end = 0;
if (remaining > QMI_WLANFW_MAX_DATA_SIZE_V01) {
req->data_len = QMI_WLANFW_MAX_DATA_SIZE_V01;
} else {
req->data_len = remaining;
req->end = 1;
}
if (ab->hw_params.fixed_bdf_addr ||
type == ATH11K_QMI_FILE_TYPE_EEPROM) {
req->data_valid = 0;
req->end = 1;
req->data_len = ATH11K_QMI_MAX_BDF_FILE_NAME_SIZE;
} else {
memcpy(req->data, temp, req->data_len);
}
if (ab->hw_params.fixed_bdf_addr) {
if (type == ATH11K_QMI_FILE_TYPE_CALDATA)
bdf_addr += ab->hw_params.fw.cal_offset;
memcpy_toio(bdf_addr, temp, len);
}
ret = qmi_txn_init(&ab->qmi.handle, &txn,
qmi_wlanfw_bdf_download_resp_msg_v01_ei,
&resp);
if (ret < 0)
goto err_iounmap;
ath11k_dbg(ab, ATH11K_DBG_QMI, "bdf download req fixed addr type %d\n",
type);
ret = qmi_send_request(&ab->qmi.handle, NULL, &txn,
QMI_WLANFW_BDF_DOWNLOAD_REQ_V01,
QMI_WLANFW_BDF_DOWNLOAD_REQ_MSG_V01_MAX_LEN,
qmi_wlanfw_bdf_download_req_msg_v01_ei, req);
if (ret < 0) {
qmi_txn_cancel(&txn);
goto err_iounmap;
}
ret = qmi_txn_wait(&txn, msecs_to_jiffies(ATH11K_QMI_WLANFW_TIMEOUT_MS));
if (ret < 0) {
ath11k_warn(ab, "failed to wait board file download request: %d\n",
ret);
goto err_iounmap;
}
if (resp.resp.result != QMI_RESULT_SUCCESS_V01) {
ath11k_warn(ab, "board file download request failed: %d %d\n",
resp.resp.result, resp.resp.error);
ret = -EINVAL;
goto err_iounmap;
}
if (ab->hw_params.fixed_bdf_addr ||
type == ATH11K_QMI_FILE_TYPE_EEPROM) {
remaining = 0;
} else {
remaining -= req->data_len;
temp += req->data_len;
req->seg_id++;
ath11k_dbg(ab, ATH11K_DBG_QMI, "bdf download request remaining %i\n",
remaining);
}
}
err_iounmap:
if (ab->hw_params.fixed_bdf_addr)
iounmap(bdf_addr);
err_free_req:
kfree(req);
return ret;
}
static int ath11k_qmi_load_bdf_qmi(struct ath11k_base *ab,
bool regdb)
{
struct device *dev = ab->dev;
char filename[ATH11K_QMI_MAX_BDF_FILE_NAME_SIZE];
const struct firmware *fw_entry;
struct ath11k_board_data bd;
u32 fw_size, file_type;
int ret = 0, bdf_type;
const u8 *tmp;
memset(&bd, 0, sizeof(bd));
if (regdb) {
ret = ath11k_core_fetch_regdb(ab, &bd);
} else {
ret = ath11k_core_fetch_bdf(ab, &bd);
if (ret)
ath11k_warn(ab, "qmi failed to fetch board file: %d\n", ret);
}
if (ret)
goto out;
if (regdb)
bdf_type = ATH11K_QMI_BDF_TYPE_REGDB;
else if (bd.len >= SELFMAG && memcmp(bd.data, ELFMAG, SELFMAG) == 0)
bdf_type = ATH11K_QMI_BDF_TYPE_ELF;
else
bdf_type = ATH11K_QMI_BDF_TYPE_BIN;
ath11k_dbg(ab, ATH11K_DBG_QMI, "bdf_type %d\n", bdf_type);
fw_size = min_t(u32, ab->hw_params.fw.board_size, bd.len);
ret = ath11k_qmi_load_file_target_mem(ab, bd.data, fw_size, bdf_type);
if (ret < 0) {
ath11k_warn(ab, "qmi failed to load bdf file\n");
goto out;
}
/* QCA6390/WCN6855 does not support cal data, skip it */
if (bdf_type == ATH11K_QMI_BDF_TYPE_ELF || bdf_type == ATH11K_QMI_BDF_TYPE_REGDB)
goto out;
if (ab->qmi.target.eeprom_caldata) {
file_type = ATH11K_QMI_FILE_TYPE_EEPROM;
tmp = filename;
fw_size = ATH11K_QMI_MAX_BDF_FILE_NAME_SIZE;
} else {
file_type = ATH11K_QMI_FILE_TYPE_CALDATA;
/* cal-<bus>-<id>.bin */
snprintf(filename, sizeof(filename), "cal-%s-%s.bin",
ath11k_bus_str(ab->hif.bus), dev_name(dev));
fw_entry = ath11k_core_firmware_request(ab, filename);
if (!IS_ERR(fw_entry))
goto success;
fw_entry = ath11k_core_firmware_request(ab, ATH11K_DEFAULT_CAL_FILE);
if (IS_ERR(fw_entry)) {
/* Caldata may not be present during first time calibration in
* factory hence allow to boot without loading caldata in ftm mode
*/
if (ath11k_ftm_mode) {
ath11k_info(ab,
"Booting without cal data file in factory test mode\n");
return 0;
}
ret = PTR_ERR(fw_entry);
ath11k_warn(ab,
"qmi failed to load CAL data file:%s\n",
filename);
goto out;
}
success:
fw_size = min_t(u32, ab->hw_params.fw.board_size, fw_entry->size);
tmp = fw_entry->data;
}
ret = ath11k_qmi_load_file_target_mem(ab, tmp, fw_size, file_type);
if (ret < 0) {
ath11k_warn(ab, "qmi failed to load caldata\n");
goto out_qmi_cal;
}
ath11k_dbg(ab, ATH11K_DBG_QMI, "caldata type: %u\n", file_type);
out_qmi_cal:
if (!ab->qmi.target.eeprom_caldata)
release_firmware(fw_entry);
out:
ath11k_core_free_bdf(ab, &bd);
ath11k_dbg(ab, ATH11K_DBG_QMI, "BDF download sequence completed\n");
return ret;
}
static int ath11k_qmi_m3_load(struct ath11k_base *ab)
{
struct m3_mem_region *m3_mem = &ab->qmi.m3_mem;
const struct firmware *fw;
char path[100];
int ret;
fw = ath11k_core_firmware_request(ab, ATH11K_M3_FILE);
if (IS_ERR(fw)) {
ret = PTR_ERR(fw);
ath11k_core_create_firmware_path(ab, ATH11K_M3_FILE,
path, sizeof(path));
ath11k_err(ab, "failed to load %s: %d\n", path, ret);
return ret;
}
if (m3_mem->vaddr || m3_mem->size)
goto skip_m3_alloc;
m3_mem->vaddr = dma_alloc_coherent(ab->dev,
fw->size, &m3_mem->paddr,
GFP_KERNEL);
if (!m3_mem->vaddr) {
ath11k_err(ab, "failed to allocate memory for M3 with size %zu\n",
fw->size);
release_firmware(fw);
return -ENOMEM;
}
skip_m3_alloc:
memcpy(m3_mem->vaddr, fw->data, fw->size);
m3_mem->size = fw->size;
release_firmware(fw);
return 0;
}
static void ath11k_qmi_m3_free(struct ath11k_base *ab)
{
struct m3_mem_region *m3_mem = &ab->qmi.m3_mem;
if (!ab->hw_params.m3_fw_support || !m3_mem->vaddr)
return;
dma_free_coherent(ab->dev, m3_mem->size,
m3_mem->vaddr, m3_mem->paddr);
m3_mem->vaddr = NULL;
m3_mem->size = 0;
}
static int ath11k_qmi_wlanfw_m3_info_send(struct ath11k_base *ab)
{
struct m3_mem_region *m3_mem = &ab->qmi.m3_mem;
struct qmi_wlanfw_m3_info_req_msg_v01 req;
struct qmi_wlanfw_m3_info_resp_msg_v01 resp;
struct qmi_txn txn;
int ret = 0;
memset(&req, 0, sizeof(req));
memset(&resp, 0, sizeof(resp));
if (ab->hw_params.m3_fw_support) {
ret = ath11k_qmi_m3_load(ab);
if (ret) {
ath11k_err(ab, "failed to load m3 firmware: %d", ret);
return ret;
}
req.addr = m3_mem->paddr;
req.size = m3_mem->size;
} else {
req.addr = 0;
req.size = 0;
}
ret = qmi_txn_init(&ab->qmi.handle, &txn,
qmi_wlanfw_m3_info_resp_msg_v01_ei, &resp);
if (ret < 0)
goto out;
ath11k_dbg(ab, ATH11K_DBG_QMI, "m3 info req\n");
ret = qmi_send_request(&ab->qmi.handle, NULL, &txn,
QMI_WLANFW_M3_INFO_REQ_V01,
QMI_WLANFW_M3_INFO_REQ_MSG_V01_MAX_MSG_LEN,
qmi_wlanfw_m3_info_req_msg_v01_ei, &req);
if (ret < 0) {
qmi_txn_cancel(&txn);
ath11k_warn(ab, "failed to send m3 information request: %d\n",
ret);
goto out;
}
ret = qmi_txn_wait(&txn, msecs_to_jiffies(ATH11K_QMI_WLANFW_TIMEOUT_MS));
if (ret < 0) {
ath11k_warn(ab, "failed to wait m3 information request: %d\n", ret);
goto out;
}
if (resp.resp.result != QMI_RESULT_SUCCESS_V01) {
ath11k_warn(ab, "m3 info request failed: %d %d\n",
resp.resp.result, resp.resp.error);
ret = -EINVAL;
goto out;
}
out:
return ret;
}
static int ath11k_qmi_wlanfw_mode_send(struct ath11k_base *ab,
u32 mode)
{
struct qmi_wlanfw_wlan_mode_req_msg_v01 req;
struct qmi_wlanfw_wlan_mode_resp_msg_v01 resp;
struct qmi_txn txn;
int ret = 0;
memset(&req, 0, sizeof(req));
memset(&resp, 0, sizeof(resp));
req.mode = mode;
req.hw_debug_valid = 1;
req.hw_debug = 0;
ret = qmi_txn_init(&ab->qmi.handle, &txn,
qmi_wlanfw_wlan_mode_resp_msg_v01_ei, &resp);
if (ret < 0)
goto out;
ath11k_dbg(ab, ATH11K_DBG_QMI, "wlan mode req mode %d\n", mode);
ret = qmi_send_request(&ab->qmi.handle, NULL, &txn,
QMI_WLANFW_WLAN_MODE_REQ_V01,
QMI_WLANFW_WLAN_MODE_REQ_MSG_V01_MAX_LEN,
qmi_wlanfw_wlan_mode_req_msg_v01_ei, &req);
if (ret < 0) {
qmi_txn_cancel(&txn);
ath11k_warn(ab, "failed to send wlan mode request (mode %d): %d\n",
mode, ret);
goto out;
}
ret = qmi_txn_wait(&txn, msecs_to_jiffies(ATH11K_QMI_WLANFW_TIMEOUT_MS));
if (ret < 0) {
if (mode == ATH11K_FIRMWARE_MODE_OFF && ret == -ENETRESET) {
ath11k_warn(ab, "WLFW service is dis-connected\n");
return 0;
}
ath11k_warn(ab, "failed to wait wlan mode request (mode %d): %d\n",
mode, ret);
goto out;
}
if (resp.resp.result != QMI_RESULT_SUCCESS_V01) {
ath11k_warn(ab, "wlan mode request failed (mode: %d): %d %d\n",
mode, resp.resp.result, resp.resp.error);
ret = -EINVAL;
goto out;
}
out:
return ret;
}
static int ath11k_qmi_wlanfw_wlan_cfg_send(struct ath11k_base *ab)
{
struct qmi_wlanfw_wlan_cfg_req_msg_v01 *req;
struct qmi_wlanfw_wlan_cfg_resp_msg_v01 resp;
struct ce_pipe_config *ce_cfg;
struct service_to_pipe *svc_cfg;
struct qmi_txn txn;
int ret = 0, pipe_num;
ce_cfg = (struct ce_pipe_config *)ab->qmi.ce_cfg.tgt_ce;
svc_cfg = (struct service_to_pipe *)ab->qmi.ce_cfg.svc_to_ce_map;
req = kzalloc(sizeof(*req), GFP_KERNEL);
if (!req)
return -ENOMEM;
memset(&resp, 0, sizeof(resp));
req->host_version_valid = 1;
strscpy(req->host_version, ATH11K_HOST_VERSION_STRING,
sizeof(req->host_version));
req->tgt_cfg_valid = 1;
/* This is number of CE configs */
req->tgt_cfg_len = ab->qmi.ce_cfg.tgt_ce_len;
for (pipe_num = 0; pipe_num < req->tgt_cfg_len ; pipe_num++) {
req->tgt_cfg[pipe_num].pipe_num = ce_cfg[pipe_num].pipenum;
req->tgt_cfg[pipe_num].pipe_dir = ce_cfg[pipe_num].pipedir;
req->tgt_cfg[pipe_num].nentries = ce_cfg[pipe_num].nentries;
req->tgt_cfg[pipe_num].nbytes_max = ce_cfg[pipe_num].nbytes_max;
req->tgt_cfg[pipe_num].flags = ce_cfg[pipe_num].flags;
}
req->svc_cfg_valid = 1;
/* This is number of Service/CE configs */
req->svc_cfg_len = ab->qmi.ce_cfg.svc_to_ce_map_len;
for (pipe_num = 0; pipe_num < req->svc_cfg_len; pipe_num++) {
req->svc_cfg[pipe_num].service_id = svc_cfg[pipe_num].service_id;
req->svc_cfg[pipe_num].pipe_dir = svc_cfg[pipe_num].pipedir;
req->svc_cfg[pipe_num].pipe_num = svc_cfg[pipe_num].pipenum;
}
req->shadow_reg_valid = 0;
/* set shadow v2 configuration */
if (ab->hw_params.supports_shadow_regs) {
req->shadow_reg_v2_valid = 1;
req->shadow_reg_v2_len = min_t(u32,
ab->qmi.ce_cfg.shadow_reg_v2_len,
QMI_WLANFW_MAX_NUM_SHADOW_REG_V2_V01);
memcpy(&req->shadow_reg_v2, ab->qmi.ce_cfg.shadow_reg_v2,
sizeof(u32) * req->shadow_reg_v2_len);
} else {
req->shadow_reg_v2_valid = 0;
}
ret = qmi_txn_init(&ab->qmi.handle, &txn,
qmi_wlanfw_wlan_cfg_resp_msg_v01_ei, &resp);
if (ret < 0)
goto out;
ath11k_dbg(ab, ATH11K_DBG_QMI, "wlan cfg req\n");
ret = qmi_send_request(&ab->qmi.handle, NULL, &txn,
QMI_WLANFW_WLAN_CFG_REQ_V01,
QMI_WLANFW_WLAN_CFG_REQ_MSG_V01_MAX_LEN,
qmi_wlanfw_wlan_cfg_req_msg_v01_ei, req);
if (ret < 0) {
qmi_txn_cancel(&txn);
ath11k_warn(ab, "failed to send wlan config request: %d\n",
ret);
goto out;
}
ret = qmi_txn_wait(&txn, msecs_to_jiffies(ATH11K_QMI_WLANFW_TIMEOUT_MS));
if (ret < 0) {
ath11k_warn(ab, "failed to wait wlan config request: %d\n", ret);
goto out;
}
if (resp.resp.result != QMI_RESULT_SUCCESS_V01) {
ath11k_warn(ab, "wlan config request failed: %d %d\n",
resp.resp.result, resp.resp.error);
ret = -EINVAL;
goto out;
}
out:
kfree(req);
return ret;
}
static int ath11k_qmi_wlanfw_wlan_ini_send(struct ath11k_base *ab, bool enable)
{
int ret;
struct qmi_txn txn;
struct qmi_wlanfw_wlan_ini_req_msg_v01 req = {};
struct qmi_wlanfw_wlan_ini_resp_msg_v01 resp = {};
req.enablefwlog_valid = true;
req.enablefwlog = enable ? 1 : 0;
ret = qmi_txn_init(&ab->qmi.handle, &txn,
qmi_wlanfw_wlan_ini_resp_msg_v01_ei, &resp);
if (ret < 0)
goto out;
ret = qmi_send_request(&ab->qmi.handle, NULL, &txn,
QMI_WLANFW_WLAN_INI_REQ_V01,
QMI_WLANFW_WLAN_INI_REQ_MSG_V01_MAX_LEN,
qmi_wlanfw_wlan_ini_req_msg_v01_ei, &req);
if (ret < 0) {
ath11k_warn(ab, "qmi failed to send wlan ini request, err = %d\n",
ret);
qmi_txn_cancel(&txn);
goto out;
}
ret = qmi_txn_wait(&txn, msecs_to_jiffies(ATH11K_QMI_WLANFW_TIMEOUT_MS));
if (ret < 0) {
ath11k_warn(ab, "qmi failed wlan ini request, err = %d\n", ret);
goto out;
}
if (resp.resp.result != QMI_RESULT_SUCCESS_V01) {
ath11k_warn(ab, "qmi wlan ini request failed, result: %d, err: %d\n",
resp.resp.result, resp.resp.error);
ret = -EINVAL;
}
out:
return ret;
}
void ath11k_qmi_firmware_stop(struct ath11k_base *ab)
{
int ret;
ath11k_dbg(ab, ATH11K_DBG_QMI, "firmware stop\n");
ret = ath11k_qmi_wlanfw_mode_send(ab, ATH11K_FIRMWARE_MODE_OFF);
if (ret < 0) {
ath11k_warn(ab, "qmi failed to send wlan mode off: %d\n", ret);
return;
}
}
int ath11k_qmi_firmware_start(struct ath11k_base *ab,
u32 mode)
{
int ret;
ath11k_dbg(ab, ATH11K_DBG_QMI, "firmware start\n");
if (ab->hw_params.fw_wmi_diag_event) {
ret = ath11k_qmi_wlanfw_wlan_ini_send(ab, true);
if (ret < 0) {
ath11k_warn(ab, "qmi failed to send wlan fw ini:%d\n", ret);
return ret;
}
}
ret = ath11k_qmi_wlanfw_wlan_cfg_send(ab);
if (ret < 0) {
ath11k_warn(ab, "qmi failed to send wlan cfg: %d\n", ret);
return ret;
}
ret = ath11k_qmi_wlanfw_mode_send(ab, mode);
if (ret < 0) {
ath11k_warn(ab, "qmi failed to send wlan fw mode: %d\n", ret);
return ret;
}
return 0;
}
static int ath11k_qmi_process_coldboot_calibration(struct ath11k_base *ab)
{
int timeout;
int ret;
ret = ath11k_qmi_wlanfw_mode_send(ab, ATH11K_FIRMWARE_MODE_COLD_BOOT);
if (ret < 0) {
ath11k_warn(ab, "qmi failed to send wlan fw mode: %d\n", ret);
return ret;
}
ath11k_dbg(ab, ATH11K_DBG_QMI, "Coldboot calibration wait started\n");
timeout = wait_event_timeout(ab->qmi.cold_boot_waitq,
(ab->qmi.cal_done == 1),
ATH11K_COLD_BOOT_FW_RESET_DELAY);
if (timeout <= 0) {
ath11k_warn(ab, "coldboot calibration timed out\n");
return 0;
}
ath11k_dbg(ab, ATH11K_DBG_QMI, "Coldboot calibration done\n");
return 0;
}
static int
ath11k_qmi_driver_event_post(struct ath11k_qmi *qmi,
enum ath11k_qmi_event_type type,
void *data)
{
struct ath11k_qmi_driver_event *event;
event = kzalloc(sizeof(*event), GFP_ATOMIC);
if (!event)
return -ENOMEM;
event->type = type;
event->data = data;
spin_lock(&qmi->event_lock);
list_add_tail(&event->list, &qmi->event_list);
spin_unlock(&qmi->event_lock);
queue_work(qmi->event_wq, &qmi->event_work);
return 0;
}
static int ath11k_qmi_event_mem_request(struct ath11k_qmi *qmi)
{
struct ath11k_base *ab = qmi->ab;
int ret;
ret = ath11k_qmi_respond_fw_mem_request(ab);
if (ret < 0) {
ath11k_warn(ab, "qmi failed to respond fw mem req: %d\n", ret);
return ret;
}
return ret;
}
static int ath11k_qmi_event_load_bdf(struct ath11k_qmi *qmi)
{
struct ath11k_base *ab = qmi->ab;
int ret;
ret = ath11k_qmi_request_target_cap(ab);
if (ret < 0) {
ath11k_warn(ab, "failed to request qmi target capabilities: %d\n",
ret);
return ret;
}
ret = ath11k_qmi_request_device_info(ab);
if (ret < 0) {
ath11k_warn(ab, "failed to request qmi device info: %d\n", ret);
return ret;
}
if (ab->hw_params.supports_regdb)
ath11k_qmi_load_bdf_qmi(ab, true);
ret = ath11k_qmi_load_bdf_qmi(ab, false);
if (ret < 0) {
ath11k_warn(ab, "failed to load board data file: %d\n", ret);
return ret;
}
return 0;
}
static int ath11k_qmi_event_server_arrive(struct ath11k_qmi *qmi)
{
struct ath11k_base *ab = qmi->ab;
int ret;
ret = ath11k_qmi_fw_ind_register_send(ab);
if (ret < 0) {
ath11k_warn(ab, "failed to send qmi firmware indication: %d\n",
ret);
return ret;
}
ret = ath11k_qmi_host_cap_send(ab);
if (ret < 0) {
ath11k_warn(ab, "failed to send qmi host cap: %d\n", ret);
return ret;
}
if (!ab->hw_params.fixed_fw_mem)
return ret;
ret = ath11k_qmi_event_load_bdf(qmi);
if (ret < 0) {
ath11k_warn(ab, "qmi failed to download BDF:%d\n", ret);
return ret;
}
return ret;
}
static void ath11k_qmi_msg_mem_request_cb(struct qmi_handle *qmi_hdl,
struct sockaddr_qrtr *sq,
struct qmi_txn *txn,
const void *data)
{
struct ath11k_qmi *qmi = container_of(qmi_hdl, struct ath11k_qmi, handle);
struct ath11k_base *ab = qmi->ab;
const struct qmi_wlanfw_request_mem_ind_msg_v01 *msg = data;
int i, ret;
ath11k_dbg(ab, ATH11K_DBG_QMI, "firmware request memory request\n");
if (msg->mem_seg_len == 0 ||
msg->mem_seg_len > ATH11K_QMI_WLANFW_MAX_NUM_MEM_SEG_V01)
ath11k_warn(ab, "invalid memory segment length: %u\n",
msg->mem_seg_len);
ab->qmi.mem_seg_count = msg->mem_seg_len;
for (i = 0; i < qmi->mem_seg_count ; i++) {
ab->qmi.target_mem[i].type = msg->mem_seg[i].type;
ab->qmi.target_mem[i].size = msg->mem_seg[i].size;
ath11k_dbg(ab, ATH11K_DBG_QMI, "mem seg type %d size %d\n",
msg->mem_seg[i].type, msg->mem_seg[i].size);
}
if (ab->hw_params.fixed_mem_region ||
test_bit(ATH11K_FLAG_FIXED_MEM_RGN, &ab->dev_flags)) {
ret = ath11k_qmi_assign_target_mem_chunk(ab);
if (ret) {
ath11k_warn(ab, "failed to assign qmi target memory: %d\n",
ret);
return;
}
} else {
ret = ath11k_qmi_alloc_target_mem_chunk(ab);
if (ret) {
ath11k_warn(ab, "failed to allocate qmi target memory: %d\n",
ret);
return;
}
}
ath11k_qmi_driver_event_post(qmi, ATH11K_QMI_EVENT_REQUEST_MEM, NULL);
}
static void ath11k_qmi_msg_mem_ready_cb(struct qmi_handle *qmi_hdl,
struct sockaddr_qrtr *sq,
struct qmi_txn *txn,
const void *decoded)
{
struct ath11k_qmi *qmi = container_of(qmi_hdl, struct ath11k_qmi, handle);
struct ath11k_base *ab = qmi->ab;
ath11k_dbg(ab, ATH11K_DBG_QMI, "firmware memory ready indication\n");
ath11k_qmi_driver_event_post(qmi, ATH11K_QMI_EVENT_FW_MEM_READY, NULL);
}
static void ath11k_qmi_msg_fw_ready_cb(struct qmi_handle *qmi_hdl,
struct sockaddr_qrtr *sq,
struct qmi_txn *txn,
const void *decoded)
{
struct ath11k_qmi *qmi = container_of(qmi_hdl, struct ath11k_qmi, handle);
struct ath11k_base *ab = qmi->ab;
ath11k_dbg(ab, ATH11K_DBG_QMI, "firmware ready\n");
if (!ab->qmi.cal_done) {
ab->qmi.cal_done = 1;
wake_up(&ab->qmi.cold_boot_waitq);
}
ath11k_qmi_driver_event_post(qmi, ATH11K_QMI_EVENT_FW_READY, NULL);
}
static void ath11k_qmi_msg_cold_boot_cal_done_cb(struct qmi_handle *qmi_hdl,
struct sockaddr_qrtr *sq,
struct qmi_txn *txn,
const void *decoded)
{
struct ath11k_qmi *qmi = container_of(qmi_hdl,
struct ath11k_qmi, handle);
struct ath11k_base *ab = qmi->ab;
ab->qmi.cal_done = 1;
wake_up(&ab->qmi.cold_boot_waitq);
ath11k_dbg(ab, ATH11K_DBG_QMI, "cold boot calibration done\n");
}
static void ath11k_qmi_msg_fw_init_done_cb(struct qmi_handle *qmi_hdl,
struct sockaddr_qrtr *sq,
struct qmi_txn *txn,
const void *decoded)
{
struct ath11k_qmi *qmi = container_of(qmi_hdl,
struct ath11k_qmi, handle);
struct ath11k_base *ab = qmi->ab;
ath11k_qmi_driver_event_post(qmi, ATH11K_QMI_EVENT_FW_INIT_DONE, NULL);
ath11k_dbg(ab, ATH11K_DBG_QMI, "firmware init done\n");
}
static const struct qmi_msg_handler ath11k_qmi_msg_handlers[] = {
{
.type = QMI_INDICATION,
.msg_id = QMI_WLFW_REQUEST_MEM_IND_V01,
.ei = qmi_wlanfw_request_mem_ind_msg_v01_ei,
.decoded_size = sizeof(struct qmi_wlanfw_request_mem_ind_msg_v01),
.fn = ath11k_qmi_msg_mem_request_cb,
},
{
.type = QMI_INDICATION,
.msg_id = QMI_WLFW_FW_MEM_READY_IND_V01,
.ei = qmi_wlanfw_mem_ready_ind_msg_v01_ei,
.decoded_size = sizeof(struct qmi_wlanfw_fw_mem_ready_ind_msg_v01),
.fn = ath11k_qmi_msg_mem_ready_cb,
},
{
.type = QMI_INDICATION,
.msg_id = QMI_WLFW_FW_READY_IND_V01,
.ei = qmi_wlanfw_fw_ready_ind_msg_v01_ei,
.decoded_size = sizeof(struct qmi_wlanfw_fw_ready_ind_msg_v01),
.fn = ath11k_qmi_msg_fw_ready_cb,
},
{
.type = QMI_INDICATION,
.msg_id = QMI_WLFW_COLD_BOOT_CAL_DONE_IND_V01,
.ei = qmi_wlanfw_cold_boot_cal_done_ind_msg_v01_ei,
.decoded_size =
sizeof(struct qmi_wlanfw_fw_cold_cal_done_ind_msg_v01),
.fn = ath11k_qmi_msg_cold_boot_cal_done_cb,
},
{
.type = QMI_INDICATION,
.msg_id = QMI_WLFW_FW_INIT_DONE_IND_V01,
.ei = qmi_wlfw_fw_init_done_ind_msg_v01_ei,
.decoded_size =
sizeof(struct qmi_wlfw_fw_init_done_ind_msg_v01),
.fn = ath11k_qmi_msg_fw_init_done_cb,
},
/* end of list */
{},
};
static int ath11k_qmi_ops_new_server(struct qmi_handle *qmi_hdl,
struct qmi_service *service)
{
struct ath11k_qmi *qmi = container_of(qmi_hdl, struct ath11k_qmi, handle);
struct ath11k_base *ab = qmi->ab;
struct sockaddr_qrtr *sq = &qmi->sq;
int ret;
sq->sq_family = AF_QIPCRTR;
sq->sq_node = service->node;
sq->sq_port = service->port;
ret = kernel_connect(qmi_hdl->sock, (struct sockaddr *)sq,
sizeof(*sq), 0);
if (ret) {
ath11k_warn(ab, "failed to connect to qmi remote service: %d\n", ret);
return ret;
}
ath11k_dbg(ab, ATH11K_DBG_QMI, "wifi fw qmi service connected\n");
ath11k_qmi_driver_event_post(qmi, ATH11K_QMI_EVENT_SERVER_ARRIVE, NULL);
return ret;
}
static void ath11k_qmi_ops_del_server(struct qmi_handle *qmi_hdl,
struct qmi_service *service)
{
struct ath11k_qmi *qmi = container_of(qmi_hdl, struct ath11k_qmi, handle);
struct ath11k_base *ab = qmi->ab;
ath11k_dbg(ab, ATH11K_DBG_QMI, "wifi fw del server\n");
ath11k_qmi_driver_event_post(qmi, ATH11K_QMI_EVENT_SERVER_EXIT, NULL);
}
static const struct qmi_ops ath11k_qmi_ops = {
.new_server = ath11k_qmi_ops_new_server,
.del_server = ath11k_qmi_ops_del_server,
};
static void ath11k_qmi_driver_event_work(struct work_struct *work)
{
struct ath11k_qmi *qmi = container_of(work, struct ath11k_qmi,
event_work);
struct ath11k_qmi_driver_event *event;
struct ath11k_base *ab = qmi->ab;
int ret;
spin_lock(&qmi->event_lock);
while (!list_empty(&qmi->event_list)) {
event = list_first_entry(&qmi->event_list,
struct ath11k_qmi_driver_event, list);
list_del(&event->list);
spin_unlock(&qmi->event_lock);
if (test_bit(ATH11K_FLAG_UNREGISTERING, &ab->dev_flags)) {
kfree(event);
return;
}
switch (event->type) {
case ATH11K_QMI_EVENT_SERVER_ARRIVE:
ret = ath11k_qmi_event_server_arrive(qmi);
if (ret < 0)
set_bit(ATH11K_FLAG_QMI_FAIL, &ab->dev_flags);
break;
case ATH11K_QMI_EVENT_SERVER_EXIT:
set_bit(ATH11K_FLAG_CRASH_FLUSH, &ab->dev_flags);
set_bit(ATH11K_FLAG_RECOVERY, &ab->dev_flags);
if (!ab->is_reset)
ath11k_core_pre_reconfigure_recovery(ab);
break;
case ATH11K_QMI_EVENT_REQUEST_MEM:
ret = ath11k_qmi_event_mem_request(qmi);
if (ret < 0)
set_bit(ATH11K_FLAG_QMI_FAIL, &ab->dev_flags);
break;
case ATH11K_QMI_EVENT_FW_MEM_READY:
ret = ath11k_qmi_event_load_bdf(qmi);
if (ret < 0) {
set_bit(ATH11K_FLAG_QMI_FAIL, &ab->dev_flags);
break;
}
ret = ath11k_qmi_wlanfw_m3_info_send(ab);
if (ret < 0) {
ath11k_warn(ab,
"failed to send qmi m3 info req: %d\n", ret);
set_bit(ATH11K_FLAG_QMI_FAIL, &ab->dev_flags);
}
break;
case ATH11K_QMI_EVENT_FW_INIT_DONE:
clear_bit(ATH11K_FLAG_QMI_FAIL, &ab->dev_flags);
if (test_bit(ATH11K_FLAG_REGISTERED, &ab->dev_flags)) {
ath11k_hal_dump_srng_stats(ab);
queue_work(ab->workqueue, &ab->restart_work);
break;
}
if (ath11k_cold_boot_cal && ab->qmi.cal_done == 0 &&
ab->hw_params.cold_boot_calib) {
ath11k_qmi_process_coldboot_calibration(ab);
} else {
clear_bit(ATH11K_FLAG_CRASH_FLUSH,
&ab->dev_flags);
clear_bit(ATH11K_FLAG_RECOVERY, &ab->dev_flags);
ret = ath11k_core_qmi_firmware_ready(ab);
if (ret) {
set_bit(ATH11K_FLAG_QMI_FAIL, &ab->dev_flags);
break;
}
set_bit(ATH11K_FLAG_REGISTERED, &ab->dev_flags);
}
break;
case ATH11K_QMI_EVENT_FW_READY:
/* For targets requiring a FW restart upon cold
* boot completion, there is no need to process
* FW ready; such targets will receive FW init
* done message after FW restart.
*/
if (ab->hw_params.cbcal_restart_fw)
break;
clear_bit(ATH11K_FLAG_CRASH_FLUSH,
&ab->dev_flags);
clear_bit(ATH11K_FLAG_RECOVERY, &ab->dev_flags);
ath11k_core_qmi_firmware_ready(ab);
set_bit(ATH11K_FLAG_REGISTERED, &ab->dev_flags);
break;
case ATH11K_QMI_EVENT_COLD_BOOT_CAL_DONE:
break;
default:
ath11k_warn(ab, "invalid qmi event type: %d", event->type);
break;
}
kfree(event);
spin_lock(&qmi->event_lock);
}
spin_unlock(&qmi->event_lock);
}
int ath11k_qmi_init_service(struct ath11k_base *ab)
{
int ret;
memset(&ab->qmi.target, 0, sizeof(struct target_info));
memset(&ab->qmi.target_mem, 0, sizeof(struct target_mem_chunk));
ab->qmi.ab = ab;
ab->qmi.target_mem_mode = ab->hw_params.fw_mem_mode;
ret = qmi_handle_init(&ab->qmi.handle, ATH11K_QMI_RESP_LEN_MAX,
&ath11k_qmi_ops, ath11k_qmi_msg_handlers);
if (ret < 0) {
ath11k_warn(ab, "failed to initialize qmi handle: %d\n", ret);
return ret;
}
ab->qmi.event_wq = alloc_ordered_workqueue("ath11k_qmi_driver_event", 0);
if (!ab->qmi.event_wq) {
ath11k_err(ab, "failed to allocate workqueue\n");
return -EFAULT;
}
INIT_LIST_HEAD(&ab->qmi.event_list);
spin_lock_init(&ab->qmi.event_lock);
INIT_WORK(&ab->qmi.event_work, ath11k_qmi_driver_event_work);
ret = qmi_add_lookup(&ab->qmi.handle, ATH11K_QMI_WLFW_SERVICE_ID_V01,
ATH11K_QMI_WLFW_SERVICE_VERS_V01,
ab->qmi.service_ins_id);
if (ret < 0) {
ath11k_warn(ab, "failed to add qmi lookup: %d\n", ret);
destroy_workqueue(ab->qmi.event_wq);
return ret;
}
return ret;
}
void ath11k_qmi_deinit_service(struct ath11k_base *ab)
{
qmi_handle_release(&ab->qmi.handle);
cancel_work_sync(&ab->qmi.event_work);
destroy_workqueue(ab->qmi.event_wq);
ath11k_qmi_m3_free(ab);
ath11k_qmi_free_target_mem_chunk(ab);
}
EXPORT_SYMBOL(ath11k_qmi_deinit_service);
void ath11k_qmi_free_resource(struct ath11k_base *ab)
{
ath11k_qmi_free_target_mem_chunk(ab);
ath11k_qmi_m3_free(ab);
}
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