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gerrit-public.fairphone.software / platform / vendor / qcom-opensource / wlan / qcacld-3.0 / 2e839e540c929c944e9f777c13f74dbeea65bf68 / . / core / dp / htt / htt_internal.h
blob: 8a14792771597e67c62c701e7a06162e0c247aeb [file] [log] [blame]
/*
* Copyright (c) 2011, 2014-2019 The Linux Foundation. All rights reserved.
*
* Permission to use, copy, modify, and/or distribute this software for
* any purpose with or without fee is hereby granted, provided that the
* above copyright notice and this permission notice appear in all
* copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL
* WARRANTIES WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE
* AUTHOR BE LIABLE FOR ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL
* DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR
* PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER
* TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR
* PERFORMANCE OF THIS SOFTWARE.
*/
#ifndef _HTT_INTERNAL__H_
#define _HTT_INTERNAL__H_
#include <athdefs.h> /* A_STATUS */
#include <qdf_nbuf.h> /* qdf_nbuf_t */
#include <qdf_util.h> /* qdf_assert */
#include <htc_api.h> /* HTC_PACKET */
#include <htt_types.h>
/* htt_rx.c */
#define RX_MSDU_END_4_FIRST_MSDU_MASK \
(pdev->targetdef->d_RX_MSDU_END_4_FIRST_MSDU_MASK)
#define RX_MSDU_END_4_FIRST_MSDU_LSB \
(pdev->targetdef->d_RX_MSDU_END_4_FIRST_MSDU_LSB)
#define RX_MPDU_START_0_RETRY_LSB \
(pdev->targetdef->d_RX_MPDU_START_0_RETRY_LSB)
#define RX_MPDU_START_0_RETRY_MASK \
(pdev->targetdef->d_RX_MPDU_START_0_RETRY_MASK)
#define RX_MPDU_START_0_SEQ_NUM_MASK \
(pdev->targetdef->d_RX_MPDU_START_0_SEQ_NUM_MASK)
#define RX_MPDU_START_0_SEQ_NUM_LSB \
(pdev->targetdef->d_RX_MPDU_START_0_SEQ_NUM_LSB)
#define RX_MPDU_START_2_PN_47_32_LSB \
(pdev->targetdef->d_RX_MPDU_START_2_PN_47_32_LSB)
#define RX_MPDU_START_2_PN_47_32_MASK \
(pdev->targetdef->d_RX_MPDU_START_2_PN_47_32_MASK)
#define RX_MPDU_START_2_TID_LSB \
(pdev->targetdef->d_RX_MPDU_START_2_TID_LSB)
#define RX_MPDU_START_2_TID_MASK \
(pdev->targetdef->d_RX_MPDU_START_2_TID_MASK)
#define RX_MSDU_END_1_KEY_ID_OCT_MASK \
(pdev->targetdef->d_RX_MSDU_END_1_KEY_ID_OCT_MASK)
#define RX_MSDU_END_1_KEY_ID_OCT_LSB \
(pdev->targetdef->d_RX_MSDU_END_1_KEY_ID_OCT_LSB)
#define RX_MSDU_END_1_EXT_WAPI_PN_63_48_MASK \
(pdev->targetdef->d_RX_MSDU_END_1_EXT_WAPI_PN_63_48_MASK)
#define RX_MSDU_END_1_EXT_WAPI_PN_63_48_LSB \
(pdev->targetdef->d_RX_MSDU_END_1_EXT_WAPI_PN_63_48_LSB)
#define RX_MSDU_END_4_LAST_MSDU_MASK \
(pdev->targetdef->d_RX_MSDU_END_4_LAST_MSDU_MASK)
#define RX_MSDU_END_4_LAST_MSDU_LSB \
(pdev->targetdef->d_RX_MSDU_END_4_LAST_MSDU_LSB)
#define RX_ATTENTION_0_MCAST_BCAST_MASK \
(pdev->targetdef->d_RX_ATTENTION_0_MCAST_BCAST_MASK)
#define RX_ATTENTION_0_MCAST_BCAST_LSB \
(pdev->targetdef->d_RX_ATTENTION_0_MCAST_BCAST_LSB)
#define RX_ATTENTION_0_FRAGMENT_MASK \
(pdev->targetdef->d_RX_ATTENTION_0_FRAGMENT_MASK)
#define RX_ATTENTION_0_FRAGMENT_LSB \
(pdev->targetdef->d_RX_ATTENTION_0_FRAGMENT_LSB)
#define RX_ATTENTION_0_MPDU_LENGTH_ERR_MASK \
(pdev->targetdef->d_RX_ATTENTION_0_MPDU_LENGTH_ERR_MASK)
#define RX_FRAG_INFO_0_RING2_MORE_COUNT_MASK \
(pdev->targetdef->d_RX_FRAG_INFO_0_RING2_MORE_COUNT_MASK)
#define RX_FRAG_INFO_0_RING2_MORE_COUNT_LSB \
(pdev->targetdef->d_RX_FRAG_INFO_0_RING2_MORE_COUNT_LSB)
#define RX_MSDU_START_0_MSDU_LENGTH_MASK \
(pdev->targetdef->d_RX_MSDU_START_0_MSDU_LENGTH_MASK)
#define RX_MSDU_START_0_MSDU_LENGTH_LSB \
(pdev->targetdef->d_RX_MSDU_START_0_MSDU_LENGTH_LSB)
#define RX_MPDU_START_0_ENCRYPTED_MASK \
(pdev->targetdef->d_RX_MPDU_START_0_ENCRYPTED_MASK)
#define RX_MPDU_START_0_ENCRYPTED_LSB \
(pdev->targetdef->d_RX_MPDU_START_0_ENCRYPTED_LSB)
#define RX_ATTENTION_0_MORE_DATA_MASK \
(pdev->targetdef->d_RX_ATTENTION_0_MORE_DATA_MASK)
#define RX_ATTENTION_0_MSDU_DONE_MASK \
(pdev->targetdef->d_RX_ATTENTION_0_MSDU_DONE_MASK)
#define RX_ATTENTION_0_TCP_UDP_CHKSUM_FAIL_MASK \
(pdev->targetdef->d_RX_ATTENTION_0_TCP_UDP_CHKSUM_FAIL_MASK)
#define RX_MSDU_START_2_DECAP_FORMAT_OFFSET \
(pdev->targetdef->d_RX_MSDU_START_2_DECAP_FORMAT_OFFSET)
#define RX_MSDU_START_2_DECAP_FORMAT_LSB \
(pdev->targetdef->d_RX_MSDU_START_2_DECAP_FORMAT_LSB)
#define RX_MSDU_START_2_DECAP_FORMAT_MASK \
(pdev->targetdef->d_RX_MSDU_START_2_DECAP_FORMAT_MASK)
/* end */
#ifndef offsetof
#define offsetof(type, field) ((size_t)(&((type *)0)->field))
#endif
#undef MS
#define MS(_v, _f) (((_v) & _f ## _MASK) >> _f ## _LSB)
#undef SM
#define SM(_v, _f) (((_v) << _f ## _LSB) & _f ## _MASK)
#undef WO
#define WO(_f) ((_f ## _OFFSET) >> 2)
#define GET_FIELD(_addr, _f) MS(*((A_UINT32 *)(_addr) + WO(_f)), _f)
#include <rx_desc.h>
#include <wal_rx_desc.h> /* struct rx_attention, etc */
struct htt_host_fw_desc_base {
union {
struct fw_rx_desc_base val;
A_UINT32 dummy_pad; /* make sure it is DOWRD aligned */
} u;
};
/*
* This struct defines the basic descriptor information used by host,
* which is written either by the 11ac HW MAC into the host Rx data
* buffer ring directly or generated by FW and copied from Rx indication
*/
struct htt_host_rx_desc_base {
struct htt_host_fw_desc_base fw_desc;
struct rx_attention attention;
struct rx_frag_info frag_info;
struct rx_mpdu_start mpdu_start;
struct rx_msdu_start msdu_start;
struct rx_msdu_end msdu_end;
struct rx_mpdu_end mpdu_end;
struct rx_ppdu_start ppdu_start;
struct rx_ppdu_end ppdu_end;
#ifdef QCA_WIFI_3_0_ADRASTEA
/* Increased to support some of offload features */
#define RX_HTT_HDR_STATUS_LEN 256
#else
#define RX_HTT_HDR_STATUS_LEN 64
#endif
char rx_hdr_status[RX_HTT_HDR_STATUS_LEN];
};
#define RX_DESC_ATTN_MPDU_LEN_ERR_BIT 0x08000000
#define RX_STD_DESC_ATTN_OFFSET \
(offsetof(struct htt_host_rx_desc_base, attention))
#define RX_STD_DESC_FRAG_INFO_OFFSET \
(offsetof(struct htt_host_rx_desc_base, frag_info))
#define RX_STD_DESC_MPDU_START_OFFSET \
(offsetof(struct htt_host_rx_desc_base, mpdu_start))
#define RX_STD_DESC_MSDU_START_OFFSET \
(offsetof(struct htt_host_rx_desc_base, msdu_start))
#define RX_STD_DESC_MSDU_END_OFFSET \
(offsetof(struct htt_host_rx_desc_base, msdu_end))
#define RX_STD_DESC_MPDU_END_OFFSET \
(offsetof(struct htt_host_rx_desc_base, mpdu_end))
#define RX_STD_DESC_PPDU_START_OFFSET \
(offsetof(struct htt_host_rx_desc_base, ppdu_start))
#define RX_STD_DESC_PPDU_END_OFFSET \
(offsetof(struct htt_host_rx_desc_base, ppdu_end))
#define RX_STD_DESC_HDR_STATUS_OFFSET \
(offsetof(struct htt_host_rx_desc_base, rx_hdr_status))
#define RX_STD_DESC_FW_MSDU_OFFSET \
(offsetof(struct htt_host_rx_desc_base, fw_desc))
#define RX_STD_DESC_SIZE (sizeof(struct htt_host_rx_desc_base))
#define RX_DESC_ATTN_OFFSET32 (RX_STD_DESC_ATTN_OFFSET >> 2)
#define RX_DESC_FRAG_INFO_OFFSET32 (RX_STD_DESC_FRAG_INFO_OFFSET >> 2)
#define RX_DESC_MPDU_START_OFFSET32 (RX_STD_DESC_MPDU_START_OFFSET >> 2)
#define RX_DESC_MSDU_START_OFFSET32 (RX_STD_DESC_MSDU_START_OFFSET >> 2)
#define RX_DESC_MSDU_END_OFFSET32 (RX_STD_DESC_MSDU_END_OFFSET >> 2)
#define RX_DESC_MPDU_END_OFFSET32 (RX_STD_DESC_MPDU_END_OFFSET >> 2)
#define RX_DESC_PPDU_START_OFFSET32 (RX_STD_DESC_PPDU_START_OFFSET >> 2)
#define RX_DESC_PPDU_END_OFFSET32 (RX_STD_DESC_PPDU_END_OFFSET >> 2)
#define RX_DESC_HDR_STATUS_OFFSET32 (RX_STD_DESC_HDR_STATUS_OFFSET >> 2)
#define RX_STD_DESC_SIZE_DWORD (RX_STD_DESC_SIZE >> 2)
/*
* Make sure there is a minimum headroom provided in the rx netbufs
* for use by the OS shim and OS and rx data consumers.
*/
#define HTT_RX_BUF_OS_MIN_HEADROOM 32
#define HTT_RX_STD_DESC_RESERVATION \
((HTT_RX_BUF_OS_MIN_HEADROOM > RX_STD_DESC_SIZE) ? \
HTT_RX_BUF_OS_MIN_HEADROOM : RX_STD_DESC_SIZE)
#define HTT_RX_DESC_RESERVATION32 \
(HTT_RX_STD_DESC_RESERVATION >> 2)
#define HTT_RX_DESC_ALIGN_MASK 7 /* 8-byte alignment */
#ifdef DEBUG_RX_RING_BUFFER
#ifdef MSM_PLATFORM
#define HTT_ADDRESS_MASK 0xfffffffffffffffe
#else
#define HTT_ADDRESS_MASK 0xfffffffe
#endif /* MSM_PLATFORM */
/**
* rx_buf_debug: rx_ring history
*
* There are three types of entries in history:
* 1) rx-descriptors posted (and received)
* Both of these events are stored on the same entry
* @paddr : physical address posted on the ring
* @nbuf : virtual address of nbuf containing data
* @ndata : virual address of data (corresponds to physical address)
* @posted: time-stamp when the buffer is posted to the ring
* @recved: time-stamp when the buffer is received (rx_in_order_ind)
* : or 0, if the buffer has not been received yet
* 2) ring alloc-index (fill-index) updates
* @paddr : = 0
* @nbuf : = 0
* @ndata : = 0
* posted : time-stamp when alloc index was updated
* recved : value of alloc index
* 3) htt_rx_in_order_indication reception
* @paddr : = 0
* @nbuf : = 0
* @ndata : msdu_cnt
* @posted: time-stamp when HTT message is recived
* @recvd : 0x48545452584D5367 ('HTTRXMSG')
*/
#define HTT_RX_RING_BUFF_DBG_LIST (2 * 1024)
struct rx_buf_debug {
qdf_dma_addr_t paddr;
qdf_nbuf_t nbuf;
void *nbuf_data;
uint64_t posted; /* timetamp */
uint64_t recved; /* timestamp */
int cpu;
};
#endif
static inline struct htt_host_rx_desc_base *htt_rx_desc(qdf_nbuf_t msdu)
{
return (struct htt_host_rx_desc_base *)
(((size_t) (qdf_nbuf_head(msdu) + HTT_RX_DESC_ALIGN_MASK)) &
~HTT_RX_DESC_ALIGN_MASK);
}
#if defined(HELIUMPLUS)
/**
* htt_print_rx_desc_lro() - print LRO information in the rx
* descriptor
* @rx_desc: HTT rx descriptor
*
* Prints the LRO related fields in the HTT rx descriptor
*
* Return: none
*/
static inline void htt_print_rx_desc_lro(struct htt_host_rx_desc_base *rx_desc)
{
qdf_nofl_info
("----------------------RX DESC LRO----------------------\n");
qdf_nofl_info("msdu_end.lro_eligible:0x%x\n",
rx_desc->msdu_end.lro_eligible);
qdf_nofl_info("msdu_start.tcp_only_ack:0x%x\n",
rx_desc->msdu_start.tcp_only_ack);
qdf_nofl_info("msdu_end.tcp_udp_chksum:0x%x\n",
rx_desc->msdu_end.tcp_udp_chksum);
qdf_nofl_info("msdu_end.tcp_seq_number:0x%x\n",
rx_desc->msdu_end.tcp_seq_number);
qdf_nofl_info("msdu_end.tcp_ack_number:0x%x\n",
rx_desc->msdu_end.tcp_ack_number);
qdf_nofl_info("msdu_start.tcp_proto:0x%x\n",
rx_desc->msdu_start.tcp_proto);
qdf_nofl_info("msdu_start.ipv6_proto:0x%x\n",
rx_desc->msdu_start.ipv6_proto);
qdf_nofl_info("msdu_start.ipv4_proto:0x%x\n",
rx_desc->msdu_start.ipv4_proto);
qdf_nofl_info("msdu_start.l3_offset:0x%x\n",
rx_desc->msdu_start.l3_offset);
qdf_nofl_info("msdu_start.l4_offset:0x%x\n",
rx_desc->msdu_start.l4_offset);
qdf_nofl_info("msdu_start.flow_id_toeplitz:0x%x\n",
rx_desc->msdu_start.flow_id_toeplitz);
qdf_nofl_info
("---------------------------------------------------------\n");
}
/**
* htt_print_rx_desc_lro() - extract LRO information from the rx
* descriptor
* @msdu: network buffer
* @rx_desc: HTT rx descriptor
*
* Extracts the LRO related fields from the HTT rx descriptor
* and stores them in the network buffer's control block
*
* Return: none
*/
static inline void htt_rx_extract_lro_info(qdf_nbuf_t msdu,
struct htt_host_rx_desc_base *rx_desc)
{
if (rx_desc->attention.tcp_udp_chksum_fail)
QDF_NBUF_CB_RX_LRO_ELIGIBLE(msdu) = 0;
else
QDF_NBUF_CB_RX_LRO_ELIGIBLE(msdu) =
rx_desc->msdu_end.lro_eligible;
if (QDF_NBUF_CB_RX_LRO_ELIGIBLE(msdu)) {
QDF_NBUF_CB_RX_TCP_PURE_ACK(msdu) =
rx_desc->msdu_start.tcp_only_ack;
QDF_NBUF_CB_RX_TCP_CHKSUM(msdu) =
rx_desc->msdu_end.tcp_udp_chksum;
QDF_NBUF_CB_RX_TCP_SEQ_NUM(msdu) =
rx_desc->msdu_end.tcp_seq_number;
QDF_NBUF_CB_RX_TCP_ACK_NUM(msdu) =
rx_desc->msdu_end.tcp_ack_number;
QDF_NBUF_CB_RX_TCP_WIN(msdu) =
rx_desc->msdu_end.window_size;
QDF_NBUF_CB_RX_TCP_PROTO(msdu) =
rx_desc->msdu_start.tcp_proto;
QDF_NBUF_CB_RX_IPV6_PROTO(msdu) =
rx_desc->msdu_start.ipv6_proto;
QDF_NBUF_CB_RX_TCP_OFFSET(msdu) =
rx_desc->msdu_start.l4_offset;
QDF_NBUF_CB_RX_FLOW_ID(msdu) =
rx_desc->msdu_start.flow_id_toeplitz;
}
}
#else
static inline void htt_print_rx_desc_lro(struct htt_host_rx_desc_base *rx_desc)
{}
static inline void htt_rx_extract_lro_info(qdf_nbuf_t msdu,
struct htt_host_rx_desc_base *rx_desc) {}
#endif /* HELIUMPLUS */
static inline void htt_print_rx_desc(struct htt_host_rx_desc_base *rx_desc)
{
qdf_nofl_info
("----------------------RX DESC----------------------------\n");
qdf_nofl_info("attention: %#010x\n",
(unsigned int)(*(uint32_t *)&rx_desc->attention));
qdf_nofl_info("frag_info: %#010x\n",
(unsigned int)(*(uint32_t *)&rx_desc->frag_info));
qdf_nofl_info("mpdu_start: %#010x %#010x %#010x\n",
(unsigned int)(((uint32_t *)&rx_desc->mpdu_start)[0]),
(unsigned int)(((uint32_t *)&rx_desc->mpdu_start)[1]),
(unsigned int)(((uint32_t *)&rx_desc->mpdu_start)[2]));
qdf_nofl_info("msdu_start: %#010x %#010x %#010x\n",
(unsigned int)(((uint32_t *)&rx_desc->msdu_start)[0]),
(unsigned int)(((uint32_t *)&rx_desc->msdu_start)[1]),
(unsigned int)(((uint32_t *)&rx_desc->msdu_start)[2]));
qdf_nofl_info("msdu_end: %#010x %#010x %#010x %#010x %#010x\n",
(unsigned int)(((uint32_t *)&rx_desc->msdu_end)[0]),
(unsigned int)(((uint32_t *)&rx_desc->msdu_end)[1]),
(unsigned int)(((uint32_t *)&rx_desc->msdu_end)[2]),
(unsigned int)(((uint32_t *)&rx_desc->msdu_end)[3]),
(unsigned int)(((uint32_t *)&rx_desc->msdu_end)[4]));
qdf_nofl_info("mpdu_end: %#010x\n",
(unsigned int)(*(uint32_t *)&rx_desc->mpdu_end));
qdf_nofl_info("ppdu_start: %#010x %#010x %#010x %#010x %#010x\n"
"%#010x %#010x %#010x %#010x %#010x\n",
(unsigned int)(((uint32_t *)&rx_desc->ppdu_start)[0]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_start)[1]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_start)[2]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_start)[3]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_start)[4]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_start)[5]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_start)[6]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_start)[7]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_start)[8]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_start)[9]));
qdf_nofl_info("ppdu_end: %#010x %#010x %#010x %#010x %#010x\n"
"%#010x %#010x %#010x %#010x %#010x\n"
"%#010x,%#010x %#010x %#010x %#010x\n"
"%#010x %#010x %#010x %#010x %#010x\n" "%#010x %#010x\n",
(unsigned int)(((uint32_t *)&rx_desc->ppdu_end)[0]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_end)[1]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_end)[2]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_end)[3]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_end)[4]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_end)[5]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_end)[6]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_end)[7]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_end)[8]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_end)[9]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_end)[10]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_end)[11]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_end)[12]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_end)[13]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_end)[14]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_end)[15]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_end)[16]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_end)[17]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_end)[18]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_end)[19]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_end)[20]),
(unsigned int)(((uint32_t *)&rx_desc->ppdu_end)[21]));
qdf_nofl_info
("---------------------------------------------------------\n");
}
#ifndef HTT_ASSERT_LEVEL
#define HTT_ASSERT_LEVEL 3
#endif
#define HTT_ASSERT_ALWAYS(condition) qdf_assert_always((condition))
#define HTT_ASSERT0(condition) qdf_assert((condition))
#if HTT_ASSERT_LEVEL > 0
#define HTT_ASSERT1(condition) qdf_assert((condition))
#else
#define HTT_ASSERT1(condition)
#endif
#if HTT_ASSERT_LEVEL > 1
#define HTT_ASSERT2(condition) qdf_assert((condition))
#else
#define HTT_ASSERT2(condition)
#endif
#if HTT_ASSERT_LEVEL > 2
#define HTT_ASSERT3(condition) qdf_assert((condition))
#else
#define HTT_ASSERT3(condition)
#endif
/*
* HTT_MAX_SEND_QUEUE_DEPTH -
* How many packets HTC should allow to accumulate in a send queue
* before calling the EpSendFull callback to see whether to retain
* or drop packets.
* This is not relevant for LL, where tx descriptors should be immediately
* downloaded to the target.
* This is not very relevant for HL either, since it is anticipated that
* the HL tx download scheduler will not work this far in advance - rather,
* it will make its decisions just-in-time, so it can be responsive to
* changing conditions.
* Hence, this queue depth threshold spec is mostly just a formality.
*/
#define HTT_MAX_SEND_QUEUE_DEPTH 64
#define IS_PWR2(value) (((value) ^ ((value)-1)) == ((value) << 1) - 1)
/*
* HTT_RX_PRE_ALLOC_POOL_SIZE -
* How many Rx Buffer should be there in pre-allocated pool of buffers.
* This is mainly for low memory condition where kernel fails to alloc
* SKB buffer to the Rx ring.
*/
#define HTT_RX_PRE_ALLOC_POOL_SIZE 64
/* Max rx MSDU size including L2 headers */
#define MSDU_SIZE 1560
/* Rounding up to a cache line size. */
#define HTT_RX_BUF_SIZE roundup(MSDU_SIZE + \
sizeof(struct htt_host_rx_desc_base), \
QDF_CACHE_LINE_SZ)
#define MAX_RX_PAYLOAD_SZ (HTT_RX_BUF_SIZE - RX_STD_DESC_SIZE)
/*
* DMA_MAP expects the buffer to be an integral number of cache lines.
* Rather than checking the actual cache line size, this code makes a
* conservative estimate of what the cache line size could be.
*/
#define HTT_LOG2_MAX_CACHE_LINE_SIZE 7 /* 2^7 = 128 */
#define HTT_MAX_CACHE_LINE_SIZE_MASK ((1 << HTT_LOG2_MAX_CACHE_LINE_SIZE) - 1)
#ifdef BIG_ENDIAN_HOST
/*
* big-endian: bytes within a 4-byte "word" are swapped:
* pre-swap post-swap
* index index
* 0 3
* 1 2
* 2 1
* 3 0
* 4 7
* 5 6
* etc.
* To compute the post-swap index from the pre-swap index, compute
* the byte offset for the start of the word (index & ~0x3) and add
* the swapped byte offset within the word (3 - (index & 0x3)).
*/
#define HTT_ENDIAN_BYTE_IDX_SWAP(idx) (((idx) & ~0x3) + (3 - ((idx) & 0x3)))
#else
/* little-endian: no adjustment needed */
#define HTT_ENDIAN_BYTE_IDX_SWAP(idx) idx
#endif
#define HTT_TX_MUTEX_INIT(_mutex) \
qdf_spinlock_create(_mutex)
#define HTT_TX_MUTEX_ACQUIRE(_mutex) \
qdf_spin_lock_bh(_mutex)
#define HTT_TX_MUTEX_RELEASE(_mutex) \
qdf_spin_unlock_bh(_mutex)
#define HTT_TX_MUTEX_DESTROY(_mutex) \
qdf_spinlock_destroy(_mutex)
#ifdef ATH_11AC_TXCOMPACT
#define HTT_TX_NBUF_QUEUE_MUTEX_INIT(_pdev) \
qdf_spinlock_create(&_pdev->txnbufq_mutex)
#define HTT_TX_NBUF_QUEUE_MUTEX_DESTROY(_pdev) \
HTT_TX_MUTEX_DESTROY(&_pdev->txnbufq_mutex)
#define HTT_TX_NBUF_QUEUE_REMOVE(_pdev, _msdu) do { \
HTT_TX_MUTEX_ACQUIRE(&_pdev->txnbufq_mutex); \
_msdu = qdf_nbuf_queue_remove(&_pdev->txnbufq);\
HTT_TX_MUTEX_RELEASE(&_pdev->txnbufq_mutex); \
} while (0)
#define HTT_TX_NBUF_QUEUE_ADD(_pdev, _msdu) do { \
HTT_TX_MUTEX_ACQUIRE(&_pdev->txnbufq_mutex); \
qdf_nbuf_queue_add(&_pdev->txnbufq, _msdu); \
HTT_TX_MUTEX_RELEASE(&_pdev->txnbufq_mutex); \
} while (0)
#define HTT_TX_NBUF_QUEUE_INSERT_HEAD(_pdev, _msdu) do { \
HTT_TX_MUTEX_ACQUIRE(&_pdev->txnbufq_mutex); \
qdf_nbuf_queue_insert_head(&_pdev->txnbufq, _msdu);\
HTT_TX_MUTEX_RELEASE(&_pdev->txnbufq_mutex); \
} while (0)
#else
#define HTT_TX_NBUF_QUEUE_MUTEX_INIT(_pdev)
#define HTT_TX_NBUF_QUEUE_REMOVE(_pdev, _msdu)
#define HTT_TX_NBUF_QUEUE_ADD(_pdev, _msdu)
#define HTT_TX_NBUF_QUEUE_INSERT_HEAD(_pdev, _msdu)
#define HTT_TX_NBUF_QUEUE_MUTEX_DESTROY(_pdev)
#endif
#ifdef CONFIG_HL_SUPPORT
static inline void htt_tx_resume_handler(void *context)
{
}
#else
void htt_tx_resume_handler(void *context);
#endif
#ifdef ATH_11AC_TXCOMPACT
#define HTT_TX_SCHED htt_tx_sched
#else
#define HTT_TX_SCHED(pdev) /* no-op */
#endif
int htt_tx_attach(struct htt_pdev_t *pdev, int desc_pool_elems);
void htt_tx_detach(struct htt_pdev_t *pdev);
int htt_rx_attach(struct htt_pdev_t *pdev);
#if defined(CONFIG_HL_SUPPORT)
static inline void htt_rx_detach(struct htt_pdev_t *pdev)
{
}
#else
void htt_rx_detach(struct htt_pdev_t *pdev);
#endif
int htt_htc_attach(struct htt_pdev_t *pdev, uint16_t service_id);
void htt_t2h_msg_handler(void *context, HTC_PACKET *pkt);
#ifdef WLAN_FEATURE_FASTPATH
void htt_t2h_msg_handler_fast(void *htt_pdev, qdf_nbuf_t *cmpl_msdus,
uint32_t num_cmpls);
#else
static inline void htt_t2h_msg_handler_fast(void *htt_pdev,
qdf_nbuf_t *cmpl_msdus,
uint32_t num_cmpls)
{
}
#endif
void htt_h2t_send_complete(void *context, HTC_PACKET *pkt);
QDF_STATUS htt_h2t_ver_req_msg(struct htt_pdev_t *pdev);
int htt_tx_padding_credit_update_handler(void *context, int pad_credit);
#if defined(HELIUMPLUS)
QDF_STATUS
htt_h2t_frag_desc_bank_cfg_msg(struct htt_pdev_t *pdev);
#endif /* defined(HELIUMPLUS) */
QDF_STATUS htt_h2t_rx_ring_cfg_msg_ll(struct htt_pdev_t *pdev);
QDF_STATUS htt_h2t_rx_ring_rfs_cfg_msg_ll(struct htt_pdev_t *pdev);
QDF_STATUS htt_h2t_rx_ring_rfs_cfg_msg_hl(struct htt_pdev_t *pdev);
QDF_STATUS htt_h2t_rx_ring_cfg_msg_hl(struct htt_pdev_t *pdev);
extern QDF_STATUS (*htt_h2t_rx_ring_cfg_msg)(struct htt_pdev_t *pdev);
enum htc_send_full_action htt_h2t_full(void *context, HTC_PACKET *pkt);
struct htt_htc_pkt *htt_htc_pkt_alloc(struct htt_pdev_t *pdev);
void htt_htc_pkt_free(struct htt_pdev_t *pdev, struct htt_htc_pkt *pkt);
void htt_htc_pkt_pool_free(struct htt_pdev_t *pdev);
#ifdef ATH_11AC_TXCOMPACT
void htt_htc_misc_pkt_list_trim(struct htt_pdev_t *pdev, int level);
void
htt_htc_misc_pkt_list_add(struct htt_pdev_t *pdev, struct htt_htc_pkt *pkt);
void htt_htc_misc_pkt_pool_free(struct htt_pdev_t *pdev);
#endif
#ifdef WLAN_FULL_REORDER_OFFLOAD
int
htt_rx_hash_list_insert(struct htt_pdev_t *pdev,
qdf_dma_addr_t paddr,
qdf_nbuf_t netbuf);
#else
static inline int
htt_rx_hash_list_insert(struct htt_pdev_t *pdev,
qdf_dma_addr_t paddr,
qdf_nbuf_t netbuf)
{
return 0;
}
#endif
qdf_nbuf_t
htt_rx_hash_list_lookup(struct htt_pdev_t *pdev, qdf_dma_addr_t paddr);
#ifdef IPA_OFFLOAD
int
htt_tx_ipa_uc_attach(struct htt_pdev_t *pdev,
unsigned int uc_tx_buf_sz,
unsigned int uc_tx_buf_cnt,
unsigned int uc_tx_partition_base);
int
htt_rx_ipa_uc_attach(struct htt_pdev_t *pdev, unsigned int rx_ind_ring_size);
int htt_tx_ipa_uc_detach(struct htt_pdev_t *pdev);
int htt_rx_ipa_uc_detach(struct htt_pdev_t *pdev);
#else
/**
* htt_tx_ipa_uc_attach() - attach htt ipa uc tx resource
* @pdev: htt context
* @uc_tx_buf_sz: single tx buffer size
* @uc_tx_buf_cnt: total tx buffer count
* @uc_tx_partition_base: tx buffer partition start
*
* Return: 0 success
*/
static inline int
htt_tx_ipa_uc_attach(struct htt_pdev_t *pdev,
unsigned int uc_tx_buf_sz,
unsigned int uc_tx_buf_cnt,
unsigned int uc_tx_partition_base)
{
return 0;
}
/**
* htt_rx_ipa_uc_attach() - attach htt ipa uc rx resource
* @pdev: htt context
* @rx_ind_ring_size: rx ring size
*
* Return: 0 success
*/
static inline int
htt_rx_ipa_uc_attach(struct htt_pdev_t *pdev, unsigned int rx_ind_ring_size)
{
return 0;
}
static inline int htt_tx_ipa_uc_detach(struct htt_pdev_t *pdev)
{
return 0;
}
static inline int htt_rx_ipa_uc_detach(struct htt_pdev_t *pdev)
{
return 0;
}
#endif /* IPA_OFFLOAD */
/* Maximum Outstanding Bus Download */
#define HTT_MAX_BUS_CREDIT 33
#ifdef CONFIG_HL_SUPPORT
/**
* htt_tx_credit_update() - check for diff in bus delta and target delta
* @pdev: pointer to htt device.
*
* Return: min of bus delta and target delta
*/
int
htt_tx_credit_update(struct htt_pdev_t *pdev);
#else
static inline int
htt_tx_credit_update(struct htt_pdev_t *pdev)
{
return 0;
}
#endif
#ifdef FEATURE_HL_GROUP_CREDIT_FLOW_CONTROL
#define HTT_TX_GROUP_INDEX_OFFSET \
(sizeof(struct htt_txq_group) / sizeof(u_int32_t))
void htt_tx_group_credit_process(struct htt_pdev_t *pdev, u_int32_t *msg_word);
#else
static inline
void htt_tx_group_credit_process(struct htt_pdev_t *pdev, u_int32_t *msg_word)
{
}
#endif
#ifdef DEBUG_RX_RING_BUFFER
/**
* htt_rx_dbg_rxbuf_init() - init debug rx buff list
* @pdev: pdev handle
*
* Allocation is done from bss segment. This uses vmalloc and has a bit
* of an overhead compared to kmalloc (which qdf_mem_alloc wraps). The impact
* of the overhead to performance will need to be quantified.
*
* Return: none
*/
static struct rx_buf_debug rx_buff_list_bss[HTT_RX_RING_BUFF_DBG_LIST];
static inline
void htt_rx_dbg_rxbuf_init(struct htt_pdev_t *pdev)
{
pdev->rx_buff_list = rx_buff_list_bss;
qdf_spinlock_create(&(pdev->rx_buff_list_lock));
pdev->rx_buff_index = 0;
pdev->rx_buff_posted_cum = 0;
pdev->rx_buff_recvd_cum = 0;
pdev->rx_buff_recvd_err = 0;
pdev->refill_retry_timer_starts = 0;
pdev->refill_retry_timer_calls = 0;
pdev->refill_retry_timer_doubles = 0;
}
/**
* htt_display_rx_buf_debug() - display debug rx buff list and some counters
* @pdev: pdev handle
*
* Return: Success
*/
static inline int htt_display_rx_buf_debug(struct htt_pdev_t *pdev)
{
int i;
struct rx_buf_debug *buf;
if ((pdev) &&
(pdev->rx_buff_list)) {
buf = pdev->rx_buff_list;
for (i = 0; i < HTT_RX_RING_BUFF_DBG_LIST; i++) {
if (buf[i].posted != 0)
qdf_nofl_info("[%d][0x%x] %pK %lu %pK %llu %llu",
i, buf[i].cpu,
buf[i].nbuf_data,
(unsigned long)buf[i].paddr,
buf[i].nbuf,
buf[i].posted,
buf[i].recved);
}
qdf_nofl_info("rxbuf_idx %d all_posted: %d all_recvd: %d recv_err: %d",
pdev->rx_buff_index,
pdev->rx_buff_posted_cum,
pdev->rx_buff_recvd_cum,
pdev->rx_buff_recvd_err);
qdf_nofl_info("timer kicks :%d actual :%d restarts:%d debtors: %d fill_n: %d",
pdev->refill_retry_timer_starts,
pdev->refill_retry_timer_calls,
pdev->refill_retry_timer_doubles,
pdev->rx_buff_debt_invoked,
pdev->rx_buff_fill_n_invoked);
} else
return -EINVAL;
return 0;
}
/**
* htt_rx_dbg_rxbuf_set() - set element of rx buff list
* @pdev: pdev handle
* @paddr: physical address of netbuf
* @rx_netbuf: received netbuf
*
* Return: none
*/
static inline
void htt_rx_dbg_rxbuf_set(struct htt_pdev_t *pdev, qdf_dma_addr_t paddr,
qdf_nbuf_t rx_netbuf)
{
if (pdev->rx_buff_list) {
qdf_spin_lock_bh(&(pdev->rx_buff_list_lock));
pdev->rx_buff_list[pdev->rx_buff_index].paddr = paddr;
pdev->rx_buff_list[pdev->rx_buff_index].nbuf = rx_netbuf;
pdev->rx_buff_list[pdev->rx_buff_index].nbuf_data =
rx_netbuf->data;
pdev->rx_buff_list[pdev->rx_buff_index].posted =
qdf_get_log_timestamp();
pdev->rx_buff_posted_cum++;
pdev->rx_buff_list[pdev->rx_buff_index].recved = 0;
pdev->rx_buff_list[pdev->rx_buff_index].cpu =
(1 << qdf_get_cpu());
QDF_NBUF_CB_RX_MAP_IDX(rx_netbuf) = pdev->rx_buff_index;
if (++pdev->rx_buff_index >=
HTT_RX_RING_BUFF_DBG_LIST)
pdev->rx_buff_index = 0;
qdf_spin_unlock_bh(&(pdev->rx_buff_list_lock));
}
}
/**
* htt_rx_dbg_rxbuf_set() - reset element of rx buff list
* @pdev: pdev handle
* @netbuf: rx sk_buff
* Return: none
*/
static inline
void htt_rx_dbg_rxbuf_reset(struct htt_pdev_t *pdev,
qdf_nbuf_t netbuf)
{
uint32_t index;
if (pdev->rx_buff_list) {
qdf_spin_lock_bh(&(pdev->rx_buff_list_lock));
index = QDF_NBUF_CB_RX_MAP_IDX(netbuf);
if (index < HTT_RX_RING_BUFF_DBG_LIST) {
pdev->rx_buff_list[index].recved =
qdf_get_log_timestamp();
pdev->rx_buff_recvd_cum++;
} else {
pdev->rx_buff_recvd_err++;
}
pdev->rx_buff_list[pdev->rx_buff_index].cpu |=
(1 << qdf_get_cpu());
qdf_spin_unlock_bh(&(pdev->rx_buff_list_lock));
}
}
/**
* htt_rx_dbg_rxbuf_indupd() - add a record for alloc index update
* @pdev: pdev handle
* @idx : value of the index
*
* Return: none
*/
static inline
void htt_rx_dbg_rxbuf_indupd(struct htt_pdev_t *pdev, int alloc_index)
{
if (pdev->rx_buff_list) {
qdf_spin_lock_bh(&(pdev->rx_buff_list_lock));
pdev->rx_buff_list[pdev->rx_buff_index].paddr = 0;
pdev->rx_buff_list[pdev->rx_buff_index].nbuf = 0;
pdev->rx_buff_list[pdev->rx_buff_index].nbuf_data = 0;
pdev->rx_buff_list[pdev->rx_buff_index].posted =
qdf_get_log_timestamp();
pdev->rx_buff_list[pdev->rx_buff_index].recved =
(uint64_t)alloc_index;
pdev->rx_buff_list[pdev->rx_buff_index].cpu =
(1 << qdf_get_cpu());
if (++pdev->rx_buff_index >=
HTT_RX_RING_BUFF_DBG_LIST)
pdev->rx_buff_index = 0;
qdf_spin_unlock_bh(&(pdev->rx_buff_list_lock));
}
}
/**
* htt_rx_dbg_rxbuf_httrxind() - add a record for recipt of htt rx_ind msg
* @pdev: pdev handle
*
* Return: none
*/
static inline
void htt_rx_dbg_rxbuf_httrxind(struct htt_pdev_t *pdev, unsigned int msdu_cnt)
{
if (pdev->rx_buff_list) {
qdf_spin_lock_bh(&(pdev->rx_buff_list_lock));
pdev->rx_buff_list[pdev->rx_buff_index].paddr = msdu_cnt;
pdev->rx_buff_list[pdev->rx_buff_index].nbuf = 0;
pdev->rx_buff_list[pdev->rx_buff_index].nbuf_data = 0;
pdev->rx_buff_list[pdev->rx_buff_index].posted =
qdf_get_log_timestamp();
pdev->rx_buff_list[pdev->rx_buff_index].recved =
(uint64_t)0x48545452584D5347; /* 'HTTRXMSG' */
pdev->rx_buff_list[pdev->rx_buff_index].cpu =
(1 << qdf_get_cpu());
if (++pdev->rx_buff_index >=
HTT_RX_RING_BUFF_DBG_LIST)
pdev->rx_buff_index = 0;
qdf_spin_unlock_bh(&(pdev->rx_buff_list_lock));
}
}
/**
* htt_rx_dbg_rxbuf_deinit() - deinit debug rx buff list
* @pdev: pdev handle
*
* Return: none
*/
static inline
void htt_rx_dbg_rxbuf_deinit(struct htt_pdev_t *pdev)
{
if (pdev->rx_buff_list)
pdev->rx_buff_list = NULL;
qdf_spinlock_destroy(&(pdev->rx_buff_list_lock));
}
#else
static inline
void htt_rx_dbg_rxbuf_init(struct htt_pdev_t *pdev)
{
}
static inline int htt_display_rx_buf_debug(struct htt_pdev_t *pdev)
{
return 0;
}
static inline
void htt_rx_dbg_rxbuf_set(struct htt_pdev_t *pdev,
uint32_t paddr,
qdf_nbuf_t rx_netbuf)
{
}
static inline
void htt_rx_dbg_rxbuf_reset(struct htt_pdev_t *pdev,
qdf_nbuf_t netbuf)
{
}
static inline
void htt_rx_dbg_rxbuf_indupd(struct htt_pdev_t *pdev,
int alloc_index)
{
}
static inline
void htt_rx_dbg_rxbuf_httrxind(struct htt_pdev_t *pdev,
unsigned int msdu_cnt)
{
}
static inline
void htt_rx_dbg_rxbuf_deinit(struct htt_pdev_t *pdev)
{
return;
}
#endif
#ifndef HTT_RX_RING_SIZE_MIN
#define HTT_RX_RING_SIZE_MIN 128 /* slightly > than one large A-MPDU */
#endif
#ifndef HTT_RX_RING_SIZE_MAX
#define HTT_RX_RING_SIZE_MAX 2048 /* ~20 ms @ 1 Gbps of 1500B MSDUs */
#endif
#ifndef HTT_RX_AVG_FRM_BYTES
#define HTT_RX_AVG_FRM_BYTES 1000
#endif
#define HTT_FCS_LEN (4)
#ifdef HTT_DEBUG_DATA
#define HTT_PKT_DUMP(x) x
#else
#define HTT_PKT_DUMP(x) /* no-op */
#endif
#ifdef RX_HASH_DEBUG
#define HTT_RX_CHECK_MSDU_COUNT(msdu_count) HTT_ASSERT_ALWAYS(msdu_count)
#else
#define HTT_RX_CHECK_MSDU_COUNT(msdu_count) /* no-op */
#endif
#if HTT_PADDR64
#define NEXT_FIELD_OFFSET_IN32 2
#else /* ! HTT_PADDR64 */
#define NEXT_FIELD_OFFSET_IN32 1
#endif /* HTT_PADDR64 */
#define RX_PADDR_MAGIC_PATTERN 0xDEAD0000
#if HTT_PADDR64
static inline qdf_dma_addr_t htt_paddr_trim_to_37(qdf_dma_addr_t paddr)
{
qdf_dma_addr_t ret = paddr;
if (sizeof(paddr) > 4)
ret &= 0x1fffffffff;
return ret;
}
#else /* not 64 bits */
static inline qdf_dma_addr_t htt_paddr_trim_to_37(qdf_dma_addr_t paddr)
{
return paddr;
}
#endif /* HTT_PADDR64 */
#ifdef WLAN_FULL_REORDER_OFFLOAD
#ifdef ENABLE_DEBUG_ADDRESS_MARKING
static inline qdf_dma_addr_t
htt_rx_paddr_unmark_high_bits(qdf_dma_addr_t paddr)
{
uint32_t markings;
if (sizeof(qdf_dma_addr_t) > 4) {
markings = (uint32_t)((paddr >> 16) >> 16);
/*
* check if it is marked correctly:
* See the mark_high_bits function above for the expected
* pattern.
* the LS 5 bits are the high bits of physical address
* padded (with 0b0) to 8 bits
*/
if ((markings & 0xFFFF0000) != RX_PADDR_MAGIC_PATTERN) {
qdf_print("paddr not marked correctly: 0x%pK!\n",
(void *)paddr);
HTT_ASSERT_ALWAYS(0);
}
/* clear markings for further use */
paddr = htt_paddr_trim_to_37(paddr);
}
return paddr;
}
static inline
qdf_dma_addr_t htt_rx_in_ord_paddr_get(uint32_t *u32p)
{
qdf_dma_addr_t paddr = 0;
paddr = (qdf_dma_addr_t)HTT_RX_IN_ORD_PADDR_IND_PADDR_GET(*u32p);
if (sizeof(qdf_dma_addr_t) > 4) {
u32p++;
/* 32 bit architectures dont like <<32 */
paddr |= (((qdf_dma_addr_t)
HTT_RX_IN_ORD_PADDR_IND_PADDR_GET(*u32p))
<< 16 << 16);
}
paddr = htt_rx_paddr_unmark_high_bits(paddr);
return paddr;
}
#else
#if HTT_PADDR64
static inline
qdf_dma_addr_t htt_rx_in_ord_paddr_get(uint32_t *u32p)
{
qdf_dma_addr_t paddr = 0;
paddr = (qdf_dma_addr_t)HTT_RX_IN_ORD_PADDR_IND_PADDR_GET(*u32p);
if (sizeof(qdf_dma_addr_t) > 4) {
u32p++;
/* 32 bit architectures dont like <<32 */
paddr |= (((qdf_dma_addr_t)
HTT_RX_IN_ORD_PADDR_IND_PADDR_GET(*u32p))
<< 16 << 16);
}
return paddr;
}
#else
static inline
qdf_dma_addr_t htt_rx_in_ord_paddr_get(uint32_t *u32p)
{
return HTT_RX_IN_ORD_PADDR_IND_PADDR_GET(*u32p);
}
#endif
#endif /* ENABLE_DEBUG_ADDRESS_MARKING */
static inline
unsigned int htt_rx_in_order_ring_elems(struct htt_pdev_t *pdev)
{
return (*pdev->rx_ring.alloc_idx.vaddr -
*pdev->rx_ring.target_idx.vaddr) &
pdev->rx_ring.size_mask;
}
static inline qdf_nbuf_t
htt_rx_in_order_netbuf_pop(htt_pdev_handle pdev, qdf_dma_addr_t paddr)
{
HTT_ASSERT1(htt_rx_in_order_ring_elems(pdev) != 0);
pdev->rx_ring.fill_cnt--;
paddr = htt_paddr_trim_to_37(paddr);
return htt_rx_hash_list_lookup(pdev, paddr);
}
#else
static inline
qdf_dma_addr_t htt_rx_in_ord_paddr_get(uint32_t *u32p)
{
return 0;
}
static inline qdf_nbuf_t
htt_rx_in_order_netbuf_pop(htt_pdev_handle pdev, qdf_dma_addr_t paddr)
{
return NULL;
}
#endif
#if defined(FEATURE_MONITOR_MODE_SUPPORT) && defined(WLAN_FULL_REORDER_OFFLOAD)
int htt_rx_mon_amsdu_rx_in_order_pop_ll(htt_pdev_handle pdev,
qdf_nbuf_t rx_ind_msg,
qdf_nbuf_t *head_msdu,
qdf_nbuf_t *tail_msdu,
uint32_t *replenish_cnt);
#else
static inline
int htt_rx_mon_amsdu_rx_in_order_pop_ll(htt_pdev_handle pdev,
qdf_nbuf_t rx_ind_msg,
qdf_nbuf_t *head_msdu,
qdf_nbuf_t *tail_msdu,
uint32_t *replenish_cnt)
{
return 0;
}
#endif
#endif /* _HTT_INTERNAL__H_ */