Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Janusz Dziedzic | 5423 | 99.93% | 1 | 50.00% |
Colin Ian King | 4 | 0.07% | 1 | 50.00% |
Total | 5427 | 2 |
/* SPDX-License-Identifier: BSD-3-Clause-Clear */ /* * Copyright (c) 2018-2021 The Linux Foundation. All rights reserved. * Copyright (c) 2021-2022 Qualcomm Innovation Center, Inc. All rights reserved. */ #include "core.h" #ifndef ATH12K_HAL_DESC_H #define ATH12K_HAL_DESC_H #define BUFFER_ADDR_INFO0_ADDR GENMASK(31, 0) #define BUFFER_ADDR_INFO1_ADDR GENMASK(7, 0) #define BUFFER_ADDR_INFO1_RET_BUF_MGR GENMASK(11, 8) #define BUFFER_ADDR_INFO1_SW_COOKIE GENMASK(31, 12) struct ath12k_buffer_addr { __le32 info0; __le32 info1; } __packed; /* ath12k_buffer_addr * * buffer_addr_31_0 * Address (lower 32 bits) of the MSDU buffer or MSDU_EXTENSION * descriptor or Link descriptor * * buffer_addr_39_32 * Address (upper 8 bits) of the MSDU buffer or MSDU_EXTENSION * descriptor or Link descriptor * * return_buffer_manager (RBM) * Consumer: WBM * Producer: SW/FW * Indicates to which buffer manager the buffer or MSDU_EXTENSION * descriptor or link descriptor that is being pointed to shall be * returned after the frame has been processed. It is used by WBM * for routing purposes. * * Values are defined in enum %HAL_RX_BUF_RBM_ * * sw_buffer_cookie * Cookie field exclusively used by SW. HW ignores the contents, * accept that it passes the programmed value on to other * descriptors together with the physical address. * * Field can be used by SW to for example associate the buffers * physical address with the virtual address. * * NOTE1: * The three most significant bits can have a special meaning * in case this struct is embedded in a TX_MPDU_DETAILS STRUCT, * and field transmit_bw_restriction is set * * In case of NON punctured transmission: * Sw_buffer_cookie[19:17] = 3'b000: 20 MHz TX only * Sw_buffer_cookie[19:17] = 3'b001: 40 MHz TX only * Sw_buffer_cookie[19:17] = 3'b010: 80 MHz TX only * Sw_buffer_cookie[19:17] = 3'b011: 160 MHz TX only * Sw_buffer_cookie[19:17] = 3'b101: 240 MHz TX only * Sw_buffer_cookie[19:17] = 3'b100: 320 MHz TX only * Sw_buffer_cookie[19:18] = 2'b11: reserved * * In case of punctured transmission: * Sw_buffer_cookie[19:16] = 4'b0000: pattern 0 only * Sw_buffer_cookie[19:16] = 4'b0001: pattern 1 only * Sw_buffer_cookie[19:16] = 4'b0010: pattern 2 only * Sw_buffer_cookie[19:16] = 4'b0011: pattern 3 only * Sw_buffer_cookie[19:16] = 4'b0100: pattern 4 only * Sw_buffer_cookie[19:16] = 4'b0101: pattern 5 only * Sw_buffer_cookie[19:16] = 4'b0110: pattern 6 only * Sw_buffer_cookie[19:16] = 4'b0111: pattern 7 only * Sw_buffer_cookie[19:16] = 4'b1000: pattern 8 only * Sw_buffer_cookie[19:16] = 4'b1001: pattern 9 only * Sw_buffer_cookie[19:16] = 4'b1010: pattern 10 only * Sw_buffer_cookie[19:16] = 4'b1011: pattern 11 only * Sw_buffer_cookie[19:18] = 2'b11: reserved * * Note: a punctured transmission is indicated by the presence * of TLV TX_PUNCTURE_SETUP embedded in the scheduler TLV * * Sw_buffer_cookie[20:17]: Tid: The TID field in the QoS control * field * * Sw_buffer_cookie[16]: Mpdu_qos_control_valid: This field * indicates MPDUs with a QoS control field. * */ enum hal_tlv_tag { HAL_MACTX_CBF_START = 0 /* 0x0 */, HAL_PHYRX_DATA = 1 /* 0x1 */, HAL_PHYRX_CBF_DATA_RESP = 2 /* 0x2 */, HAL_PHYRX_ABORT_REQUEST = 3 /* 0x3 */, HAL_PHYRX_USER_ABORT_NOTIFICATION = 4 /* 0x4 */, HAL_MACTX_DATA_RESP = 5 /* 0x5 */, HAL_MACTX_CBF_DATA = 6 /* 0x6 */, HAL_MACTX_CBF_DONE = 7 /* 0x7 */, HAL_PHYRX_LMR_DATA_RESP = 8 /* 0x8 */, HAL_RXPCU_TO_UCODE_START = 9 /* 0x9 */, HAL_RXPCU_TO_UCODE_DELIMITER_FOR_FULL_MPDU = 10 /* 0xa */, HAL_RXPCU_TO_UCODE_FULL_MPDU_DATA = 11 /* 0xb */, HAL_RXPCU_TO_UCODE_FCS_STATUS = 12 /* 0xc */, HAL_RXPCU_TO_UCODE_MPDU_DELIMITER = 13 /* 0xd */, HAL_RXPCU_TO_UCODE_DELIMITER_FOR_MPDU_HEADER = 14 /* 0xe */, HAL_RXPCU_TO_UCODE_MPDU_HEADER_DATA = 15 /* 0xf */, HAL_RXPCU_TO_UCODE_END = 16 /* 0x10 */, HAL_MACRX_CBF_READ_REQUEST = 32 /* 0x20 */, HAL_MACRX_CBF_DATA_REQUEST = 33 /* 0x21 */, HAL_MACRXXPECT_NDP_RECEPTION = 34 /* 0x22 */, HAL_MACRX_FREEZE_CAPTURE_CHANNEL = 35 /* 0x23 */, HAL_MACRX_NDP_TIMEOUT = 36 /* 0x24 */, HAL_MACRX_ABORT_ACK = 37 /* 0x25 */, HAL_MACRX_REQ_IMPLICIT_FB = 38 /* 0x26 */, HAL_MACRX_CHAIN_MASK = 39 /* 0x27 */, HAL_MACRX_NAP_USER = 40 /* 0x28 */, HAL_MACRX_ABORT_REQUEST = 41 /* 0x29 */, HAL_PHYTX_OTHER_TRANSMIT_INFO16 = 42 /* 0x2a */, HAL_PHYTX_ABORT_ACK = 43 /* 0x2b */, HAL_PHYTX_ABORT_REQUEST = 44 /* 0x2c */, HAL_PHYTX_PKT_END = 45 /* 0x2d */, HAL_PHYTX_PPDU_HEADER_INFO_REQUEST = 46 /* 0x2e */, HAL_PHYTX_REQUEST_CTRL_INFO = 47 /* 0x2f */, HAL_PHYTX_DATA_REQUEST = 48 /* 0x30 */, HAL_PHYTX_BF_CV_LOADING_DONE = 49 /* 0x31 */, HAL_PHYTX_NAP_ACK = 50 /* 0x32 */, HAL_PHYTX_NAP_DONE = 51 /* 0x33 */, HAL_PHYTX_OFF_ACK = 52 /* 0x34 */, HAL_PHYTX_ON_ACK = 53 /* 0x35 */, HAL_PHYTX_SYNTH_OFF_ACK = 54 /* 0x36 */, HAL_PHYTX_DEBUG16 = 55 /* 0x37 */, HAL_MACTX_ABORT_REQUEST = 56 /* 0x38 */, HAL_MACTX_ABORT_ACK = 57 /* 0x39 */, HAL_MACTX_PKT_END = 58 /* 0x3a */, HAL_MACTX_PRE_PHY_DESC = 59 /* 0x3b */, HAL_MACTX_BF_PARAMS_COMMON = 60 /* 0x3c */, HAL_MACTX_BF_PARAMS_PER_USER = 61 /* 0x3d */, HAL_MACTX_PREFETCH_CV = 62 /* 0x3e */, HAL_MACTX_USER_DESC_COMMON = 63 /* 0x3f */, HAL_MACTX_USER_DESC_PER_USER = 64 /* 0x40 */, HAL_XAMPLE_USER_TLV_16 = 65 /* 0x41 */, HAL_XAMPLE_TLV_16 = 66 /* 0x42 */, HAL_MACTX_PHY_OFF = 67 /* 0x43 */, HAL_MACTX_PHY_ON = 68 /* 0x44 */, HAL_MACTX_SYNTH_OFF = 69 /* 0x45 */, HAL_MACTXXPECT_CBF_COMMON = 70 /* 0x46 */, HAL_MACTXXPECT_CBF_PER_USER = 71 /* 0x47 */, HAL_MACTX_PHY_DESC = 72 /* 0x48 */, HAL_MACTX_L_SIG_A = 73 /* 0x49 */, HAL_MACTX_L_SIG_B = 74 /* 0x4a */, HAL_MACTX_HT_SIG = 75 /* 0x4b */, HAL_MACTX_VHT_SIG_A = 76 /* 0x4c */, HAL_MACTX_VHT_SIG_B_SU20 = 77 /* 0x4d */, HAL_MACTX_VHT_SIG_B_SU40 = 78 /* 0x4e */, HAL_MACTX_VHT_SIG_B_SU80 = 79 /* 0x4f */, HAL_MACTX_VHT_SIG_B_SU160 = 80 /* 0x50 */, HAL_MACTX_VHT_SIG_B_MU20 = 81 /* 0x51 */, HAL_MACTX_VHT_SIG_B_MU40 = 82 /* 0x52 */, HAL_MACTX_VHT_SIG_B_MU80 = 83 /* 0x53 */, HAL_MACTX_VHT_SIG_B_MU160 = 84 /* 0x54 */, HAL_MACTX_SERVICE = 85 /* 0x55 */, HAL_MACTX_HE_SIG_A_SU = 86 /* 0x56 */, HAL_MACTX_HE_SIG_A_MU_DL = 87 /* 0x57 */, HAL_MACTX_HE_SIG_A_MU_UL = 88 /* 0x58 */, HAL_MACTX_HE_SIG_B1_MU = 89 /* 0x59 */, HAL_MACTX_HE_SIG_B2_MU = 90 /* 0x5a */, HAL_MACTX_HE_SIG_B2_OFDMA = 91 /* 0x5b */, HAL_MACTX_DELETE_CV = 92 /* 0x5c */, HAL_MACTX_MU_UPLINK_COMMON = 93 /* 0x5d */, HAL_MACTX_MU_UPLINK_USER_SETUP = 94 /* 0x5e */, HAL_MACTX_OTHER_TRANSMIT_INFO = 95 /* 0x5f */, HAL_MACTX_PHY_NAP = 96 /* 0x60 */, HAL_MACTX_DEBUG = 97 /* 0x61 */, HAL_PHYRX_ABORT_ACK = 98 /* 0x62 */, HAL_PHYRX_GENERATED_CBF_DETAILS = 99 /* 0x63 */, HAL_PHYRX_RSSI_LEGACY = 100 /* 0x64 */, HAL_PHYRX_RSSI_HT = 101 /* 0x65 */, HAL_PHYRX_USER_INFO = 102 /* 0x66 */, HAL_PHYRX_PKT_END = 103 /* 0x67 */, HAL_PHYRX_DEBUG = 104 /* 0x68 */, HAL_PHYRX_CBF_TRANSFER_DONE = 105 /* 0x69 */, HAL_PHYRX_CBF_TRANSFER_ABORT = 106 /* 0x6a */, HAL_PHYRX_L_SIG_A = 107 /* 0x6b */, HAL_PHYRX_L_SIG_B = 108 /* 0x6c */, HAL_PHYRX_HT_SIG = 109 /* 0x6d */, HAL_PHYRX_VHT_SIG_A = 110 /* 0x6e */, HAL_PHYRX_VHT_SIG_B_SU20 = 111 /* 0x6f */, HAL_PHYRX_VHT_SIG_B_SU40 = 112 /* 0x70 */, HAL_PHYRX_VHT_SIG_B_SU80 = 113 /* 0x71 */, HAL_PHYRX_VHT_SIG_B_SU160 = 114 /* 0x72 */, HAL_PHYRX_VHT_SIG_B_MU20 = 115 /* 0x73 */, HAL_PHYRX_VHT_SIG_B_MU40 = 116 /* 0x74 */, HAL_PHYRX_VHT_SIG_B_MU80 = 117 /* 0x75 */, HAL_PHYRX_VHT_SIG_B_MU160 = 118 /* 0x76 */, HAL_PHYRX_HE_SIG_A_SU = 119 /* 0x77 */, HAL_PHYRX_HE_SIG_A_MU_DL = 120 /* 0x78 */, HAL_PHYRX_HE_SIG_A_MU_UL = 121 /* 0x79 */, HAL_PHYRX_HE_SIG_B1_MU = 122 /* 0x7a */, HAL_PHYRX_HE_SIG_B2_MU = 123 /* 0x7b */, HAL_PHYRX_HE_SIG_B2_OFDMA = 124 /* 0x7c */, HAL_PHYRX_OTHER_RECEIVE_INFO = 125 /* 0x7d */, HAL_PHYRX_COMMON_USER_INFO = 126 /* 0x7e */, HAL_PHYRX_DATA_DONE = 127 /* 0x7f */, HAL_COEX_TX_REQ = 128 /* 0x80 */, HAL_DUMMY = 129 /* 0x81 */, HALXAMPLE_TLV_32_NAME = 130 /* 0x82 */, HAL_MPDU_LIMIT = 131 /* 0x83 */, HAL_NA_LENGTH_END = 132 /* 0x84 */, HAL_OLE_BUF_STATUS = 133 /* 0x85 */, HAL_PCU_PPDU_SETUP_DONE = 134 /* 0x86 */, HAL_PCU_PPDU_SETUP_END = 135 /* 0x87 */, HAL_PCU_PPDU_SETUP_INIT = 136 /* 0x88 */, HAL_PCU_PPDU_SETUP_START = 137 /* 0x89 */, HAL_PDG_FES_SETUP = 138 /* 0x8a */, HAL_PDG_RESPONSE = 139 /* 0x8b */, HAL_PDG_TX_REQ = 140 /* 0x8c */, HAL_SCH_WAIT_INSTR = 141 /* 0x8d */, HAL_TQM_FLOWMPTY_STATUS = 143 /* 0x8f */, HAL_TQM_FLOW_NOTMPTY_STATUS = 144 /* 0x90 */, HAL_TQM_GEN_MPDU_LENGTH_LIST = 145 /* 0x91 */, HAL_TQM_GEN_MPDU_LENGTH_LIST_STATUS = 146 /* 0x92 */, HAL_TQM_GEN_MPDUS = 147 /* 0x93 */, HAL_TQM_GEN_MPDUS_STATUS = 148 /* 0x94 */, HAL_TQM_REMOVE_MPDU = 149 /* 0x95 */, HAL_TQM_REMOVE_MPDU_STATUS = 150 /* 0x96 */, HAL_TQM_REMOVE_MSDU = 151 /* 0x97 */, HAL_TQM_REMOVE_MSDU_STATUS = 152 /* 0x98 */, HAL_TQM_UPDATE_TX_MPDU_COUNT = 153 /* 0x99 */, HAL_TQM_WRITE_CMD = 154 /* 0x9a */, HAL_OFDMA_TRIGGER_DETAILS = 155 /* 0x9b */, HAL_TX_DATA = 156 /* 0x9c */, HAL_TX_FES_SETUP = 157 /* 0x9d */, HAL_RX_PACKET = 158 /* 0x9e */, HALXPECTED_RESPONSE = 159 /* 0x9f */, HAL_TX_MPDU_END = 160 /* 0xa0 */, HAL_TX_MPDU_START = 161 /* 0xa1 */, HAL_TX_MSDU_END = 162 /* 0xa2 */, HAL_TX_MSDU_START = 163 /* 0xa3 */, HAL_TX_SW_MODE_SETUP = 164 /* 0xa4 */, HAL_TXPCU_BUFFER_STATUS = 165 /* 0xa5 */, HAL_TXPCU_USER_BUFFER_STATUS = 166 /* 0xa6 */, HAL_DATA_TO_TIME_CONFIG = 167 /* 0xa7 */, HALXAMPLE_USER_TLV_32 = 168 /* 0xa8 */, HAL_MPDU_INFO = 169 /* 0xa9 */, HAL_PDG_USER_SETUP = 170 /* 0xaa */, HAL_TX_11AH_SETUP = 171 /* 0xab */, HAL_REO_UPDATE_RX_REO_QUEUE_STATUS = 172 /* 0xac */, HAL_TX_PEER_ENTRY = 173 /* 0xad */, HAL_TX_RAW_OR_NATIVE_FRAME_SETUP = 174 /* 0xae */, HALXAMPLE_USER_TLV_44 = 175 /* 0xaf */, HAL_TX_FLUSH = 176 /* 0xb0 */, HAL_TX_FLUSH_REQ = 177 /* 0xb1 */, HAL_TQM_WRITE_CMD_STATUS = 178 /* 0xb2 */, HAL_TQM_GET_MPDU_QUEUE_STATS = 179 /* 0xb3 */, HAL_TQM_GET_MSDU_FLOW_STATS = 180 /* 0xb4 */, HALXAMPLE_USER_CTLV_44 = 181 /* 0xb5 */, HAL_TX_FES_STATUS_START = 182 /* 0xb6 */, HAL_TX_FES_STATUS_USER_PPDU = 183 /* 0xb7 */, HAL_TX_FES_STATUS_USER_RESPONSE = 184 /* 0xb8 */, HAL_TX_FES_STATUS_END = 185 /* 0xb9 */, HAL_RX_TRIG_INFO = 186 /* 0xba */, HAL_RXPCU_TX_SETUP_CLEAR = 187 /* 0xbb */, HAL_RX_FRAME_BITMAP_REQ = 188 /* 0xbc */, HAL_RX_FRAME_BITMAP_ACK = 189 /* 0xbd */, HAL_COEX_RX_STATUS = 190 /* 0xbe */, HAL_RX_START_PARAM = 191 /* 0xbf */, HAL_RX_PPDU_START = 192 /* 0xc0 */, HAL_RX_PPDU_END = 193 /* 0xc1 */, HAL_RX_MPDU_START = 194 /* 0xc2 */, HAL_RX_MPDU_END = 195 /* 0xc3 */, HAL_RX_MSDU_START = 196 /* 0xc4 */, HAL_RX_MSDU_END = 197 /* 0xc5 */, HAL_RX_ATTENTION = 198 /* 0xc6 */, HAL_RECEIVED_RESPONSE_INFO = 199 /* 0xc7 */, HAL_RX_PHY_SLEEP = 200 /* 0xc8 */, HAL_RX_HEADER = 201 /* 0xc9 */, HAL_RX_PEER_ENTRY = 202 /* 0xca */, HAL_RX_FLUSH = 203 /* 0xcb */, HAL_RX_RESPONSE_REQUIRED_INFO = 204 /* 0xcc */, HAL_RX_FRAMELESS_BAR_DETAILS = 205 /* 0xcd */, HAL_TQM_GET_MPDU_QUEUE_STATS_STATUS = 206 /* 0xce */, HAL_TQM_GET_MSDU_FLOW_STATS_STATUS = 207 /* 0xcf */, HAL_TX_CBF_INFO = 208 /* 0xd0 */, HAL_PCU_PPDU_SETUP_USER = 209 /* 0xd1 */, HAL_RX_MPDU_PCU_START = 210 /* 0xd2 */, HAL_RX_PM_INFO = 211 /* 0xd3 */, HAL_RX_USER_PPDU_END = 212 /* 0xd4 */, HAL_RX_PRE_PPDU_START = 213 /* 0xd5 */, HAL_RX_PREAMBLE = 214 /* 0xd6 */, HAL_TX_FES_SETUP_COMPLETE = 215 /* 0xd7 */, HAL_TX_LAST_MPDU_FETCHED = 216 /* 0xd8 */, HAL_TXDMA_STOP_REQUEST = 217 /* 0xd9 */, HAL_RXPCU_SETUP = 218 /* 0xda */, HAL_RXPCU_USER_SETUP = 219 /* 0xdb */, HAL_TX_FES_STATUS_ACK_OR_BA = 220 /* 0xdc */, HAL_TQM_ACKED_MPDU = 221 /* 0xdd */, HAL_COEX_TX_RESP = 222 /* 0xde */, HAL_COEX_TX_STATUS = 223 /* 0xdf */, HAL_MACTX_COEX_PHY_CTRL = 224 /* 0xe0 */, HAL_COEX_STATUS_BROADCAST = 225 /* 0xe1 */, HAL_RESPONSE_START_STATUS = 226 /* 0xe2 */, HAL_RESPONSEND_STATUS = 227 /* 0xe3 */, HAL_CRYPTO_STATUS = 228 /* 0xe4 */, HAL_RECEIVED_TRIGGER_INFO = 229 /* 0xe5 */, HAL_COEX_TX_STOP_CTRL = 230 /* 0xe6 */, HAL_RX_PPDU_ACK_REPORT = 231 /* 0xe7 */, HAL_RX_PPDU_NO_ACK_REPORT = 232 /* 0xe8 */, HAL_SCH_COEX_STATUS = 233 /* 0xe9 */, HAL_SCHEDULER_COMMAND_STATUS = 234 /* 0xea */, HAL_SCHEDULER_RX_PPDU_NO_RESPONSE_STATUS = 235 /* 0xeb */, HAL_TX_FES_STATUS_PROT = 236 /* 0xec */, HAL_TX_FES_STATUS_START_PPDU = 237 /* 0xed */, HAL_TX_FES_STATUS_START_PROT = 238 /* 0xee */, HAL_TXPCU_PHYTX_DEBUG32 = 239 /* 0xef */, HAL_TXPCU_PHYTX_OTHER_TRANSMIT_INFO32 = 240 /* 0xf0 */, HAL_TX_MPDU_COUNT_TRANSFERND = 241 /* 0xf1 */, HAL_WHO_ANCHOR_OFFSET = 242 /* 0xf2 */, HAL_WHO_ANCHOR_VALUE = 243 /* 0xf3 */, HAL_WHO_CCE_INFO = 244 /* 0xf4 */, HAL_WHO_COMMIT = 245 /* 0xf5 */, HAL_WHO_COMMIT_DONE = 246 /* 0xf6 */, HAL_WHO_FLUSH = 247 /* 0xf7 */, HAL_WHO_L2_LLC = 248 /* 0xf8 */, HAL_WHO_L2_PAYLOAD = 249 /* 0xf9 */, HAL_WHO_L3_CHECKSUM = 250 /* 0xfa */, HAL_WHO_L3_INFO = 251 /* 0xfb */, HAL_WHO_L4_CHECKSUM = 252 /* 0xfc */, HAL_WHO_L4_INFO = 253 /* 0xfd */, HAL_WHO_MSDU = 254 /* 0xfe */, HAL_WHO_MSDU_MISC = 255 /* 0xff */, HAL_WHO_PACKET_DATA = 256 /* 0x100 */, HAL_WHO_PACKET_HDR = 257 /* 0x101 */, HAL_WHO_PPDU_END = 258 /* 0x102 */, HAL_WHO_PPDU_START = 259 /* 0x103 */, HAL_WHO_TSO = 260 /* 0x104 */, HAL_WHO_WMAC_HEADER_PV0 = 261 /* 0x105 */, HAL_WHO_WMAC_HEADER_PV1 = 262 /* 0x106 */, HAL_WHO_WMAC_IV = 263 /* 0x107 */, HAL_MPDU_INFO_END = 264 /* 0x108 */, HAL_MPDU_INFO_BITMAP = 265 /* 0x109 */, HAL_TX_QUEUE_EXTENSION = 266 /* 0x10a */, HAL_SCHEDULER_SELFGEN_RESPONSE_STATUS = 267 /* 0x10b */, HAL_TQM_UPDATE_TX_MPDU_COUNT_STATUS = 268 /* 0x10c */, HAL_TQM_ACKED_MPDU_STATUS = 269 /* 0x10d */, HAL_TQM_ADD_MSDU_STATUS = 270 /* 0x10e */, HAL_TQM_LIST_GEN_DONE = 271 /* 0x10f */, HAL_WHO_TERMINATE = 272 /* 0x110 */, HAL_TX_LAST_MPDU_END = 273 /* 0x111 */, HAL_TX_CV_DATA = 274 /* 0x112 */, HAL_PPDU_TX_END = 275 /* 0x113 */, HAL_PROT_TX_END = 276 /* 0x114 */, HAL_MPDU_INFO_GLOBAL_END = 277 /* 0x115 */, HAL_TQM_SCH_INSTR_GLOBAL_END = 278 /* 0x116 */, HAL_RX_PPDU_END_USER_STATS = 279 /* 0x117 */, HAL_RX_PPDU_END_USER_STATS_EXT = 280 /* 0x118 */, HAL_REO_GET_QUEUE_STATS = 281 /* 0x119 */, HAL_REO_FLUSH_QUEUE = 282 /* 0x11a */, HAL_REO_FLUSH_CACHE = 283 /* 0x11b */, HAL_REO_UNBLOCK_CACHE = 284 /* 0x11c */, HAL_REO_GET_QUEUE_STATS_STATUS = 285 /* 0x11d */, HAL_REO_FLUSH_QUEUE_STATUS = 286 /* 0x11e */, HAL_REO_FLUSH_CACHE_STATUS = 287 /* 0x11f */, HAL_REO_UNBLOCK_CACHE_STATUS = 288 /* 0x120 */, HAL_TQM_FLUSH_CACHE = 289 /* 0x121 */, HAL_TQM_UNBLOCK_CACHE = 290 /* 0x122 */, HAL_TQM_FLUSH_CACHE_STATUS = 291 /* 0x123 */, HAL_TQM_UNBLOCK_CACHE_STATUS = 292 /* 0x124 */, HAL_RX_PPDU_END_STATUS_DONE = 293 /* 0x125 */, HAL_RX_STATUS_BUFFER_DONE = 294 /* 0x126 */, HAL_TX_DATA_SYNC = 297 /* 0x129 */, HAL_PHYRX_CBF_READ_REQUEST_ACK = 298 /* 0x12a */, HAL_TQM_GET_MPDU_HEAD_INFO = 299 /* 0x12b */, HAL_TQM_SYNC_CMD = 300 /* 0x12c */, HAL_TQM_GET_MPDU_HEAD_INFO_STATUS = 301 /* 0x12d */, HAL_TQM_SYNC_CMD_STATUS = 302 /* 0x12e */, HAL_TQM_THRESHOLD_DROP_NOTIFICATION_STATUS = 303 /* 0x12f */, HAL_TQM_DESCRIPTOR_THRESHOLD_REACHED_STATUS = 304 /* 0x130 */, HAL_REO_FLUSH_TIMEOUT_LIST = 305 /* 0x131 */, HAL_REO_FLUSH_TIMEOUT_LIST_STATUS = 306 /* 0x132 */, HAL_REO_DESCRIPTOR_THRESHOLD_REACHED_STATUS = 307 /* 0x133 */, HAL_SCHEDULER_RX_SIFS_RESPONSE_TRIGGER_STATUS = 308 /* 0x134 */, HALXAMPLE_USER_TLV_32_NAME = 309 /* 0x135 */, HAL_RX_PPDU_START_USER_INFO = 310 /* 0x136 */, HAL_RX_RING_MASK = 311 /* 0x137 */, HAL_COEX_MAC_NAP = 312 /* 0x138 */, HAL_RXPCU_PPDU_END_INFO = 313 /* 0x139 */, HAL_WHO_MESH_CONTROL = 314 /* 0x13a */, HAL_PDG_SW_MODE_BW_START = 315 /* 0x13b */, HAL_PDG_SW_MODE_BW_END = 316 /* 0x13c */, HAL_PDG_WAIT_FOR_MAC_REQUEST = 317 /* 0x13d */, HAL_PDG_WAIT_FOR_PHY_REQUEST = 318 /* 0x13e */, HAL_SCHEDULER_END = 319 /* 0x13f */, HAL_RX_PPDU_START_DROPPED = 320 /* 0x140 */, HAL_RX_PPDU_END_DROPPED = 321 /* 0x141 */, HAL_RX_PPDU_END_STATUS_DONE_DROPPED = 322 /* 0x142 */, HAL_RX_MPDU_START_DROPPED = 323 /* 0x143 */, HAL_RX_MSDU_START_DROPPED = 324 /* 0x144 */, HAL_RX_MSDU_END_DROPPED = 325 /* 0x145 */, HAL_RX_MPDU_END_DROPPED = 326 /* 0x146 */, HAL_RX_ATTENTION_DROPPED = 327 /* 0x147 */, HAL_TXPCU_USER_SETUP = 328 /* 0x148 */, HAL_RXPCU_USER_SETUP_EXT = 329 /* 0x149 */, HAL_CMD_PART_0_END = 330 /* 0x14a */, HAL_MACTX_SYNTH_ON = 331 /* 0x14b */, HAL_SCH_CRITICAL_TLV_REFERENCE = 332 /* 0x14c */, HAL_TQM_MPDU_GLOBAL_START = 333 /* 0x14d */, HALXAMPLE_TLV_32 = 334 /* 0x14e */, HAL_TQM_UPDATE_TX_MSDU_FLOW = 335 /* 0x14f */, HAL_TQM_UPDATE_TX_MPDU_QUEUE_HEAD = 336 /* 0x150 */, HAL_TQM_UPDATE_TX_MSDU_FLOW_STATUS = 337 /* 0x151 */, HAL_TQM_UPDATE_TX_MPDU_QUEUE_HEAD_STATUS = 338 /* 0x152 */, HAL_REO_UPDATE_RX_REO_QUEUE = 339 /* 0x153 */, HAL_TQM_MPDU_QUEUEMPTY_STATUS = 340 /* 0x154 */, HAL_TQM_2_SCH_MPDU_AVAILABLE = 341 /* 0x155 */, HAL_PDG_TRIG_RESPONSE = 342 /* 0x156 */, HAL_TRIGGER_RESPONSE_TX_DONE = 343 /* 0x157 */, HAL_ABORT_FROM_PHYRX_DETAILS = 344 /* 0x158 */, HAL_SCH_TQM_CMD_WRAPPER = 345 /* 0x159 */, HAL_MPDUS_AVAILABLE = 346 /* 0x15a */, HAL_RECEIVED_RESPONSE_INFO_PART2 = 347 /* 0x15b */, HAL_PHYRX_TX_START_TIMING = 348 /* 0x15c */, HAL_TXPCU_PREAMBLE_DONE = 349 /* 0x15d */, HAL_NDP_PREAMBLE_DONE = 350 /* 0x15e */, HAL_SCH_TQM_CMD_WRAPPER_RBO_DROP = 351 /* 0x15f */, HAL_SCH_TQM_CMD_WRAPPER_CONT_DROP = 352 /* 0x160 */, HAL_MACTX_CLEAR_PREV_TX_INFO = 353 /* 0x161 */, HAL_TX_PUNCTURE_SETUP = 354 /* 0x162 */, HAL_R2R_STATUS_END = 355 /* 0x163 */, HAL_MACTX_PREFETCH_CV_COMMON = 356 /* 0x164 */, HAL_END_OF_FLUSH_MARKER = 357 /* 0x165 */, HAL_MACTX_MU_UPLINK_COMMON_PUNC = 358 /* 0x166 */, HAL_MACTX_MU_UPLINK_USER_SETUP_PUNC = 359 /* 0x167 */, HAL_RECEIVED_RESPONSE_USER_7_0 = 360 /* 0x168 */, HAL_RECEIVED_RESPONSE_USER_15_8 = 361 /* 0x169 */, HAL_RECEIVED_RESPONSE_USER_23_16 = 362 /* 0x16a */, HAL_RECEIVED_RESPONSE_USER_31_24 = 363 /* 0x16b */, HAL_RECEIVED_RESPONSE_USER_36_32 = 364 /* 0x16c */, HAL_TX_LOOPBACK_SETUP = 365 /* 0x16d */, HAL_PHYRX_OTHER_RECEIVE_INFO_RU_DETAILS = 366 /* 0x16e */, HAL_SCH_WAIT_INSTR_TX_PATH = 367 /* 0x16f */, HAL_MACTX_OTHER_TRANSMIT_INFO_TX2TX = 368 /* 0x170 */, HAL_MACTX_OTHER_TRANSMIT_INFOMUPHY_SETUP = 369 /* 0x171 */, HAL_PHYRX_OTHER_RECEIVE_INFOVM_DETAILS = 370 /* 0x172 */, HAL_TX_WUR_DATA = 371 /* 0x173 */, HAL_RX_PPDU_END_START = 372 /* 0x174 */, HAL_RX_PPDU_END_MIDDLE = 373 /* 0x175 */, HAL_RX_PPDU_END_LAST = 374 /* 0x176 */, HAL_MACTX_BACKOFF_BASED_TRANSMISSION = 375 /* 0x177 */, HAL_MACTX_OTHER_TRANSMIT_INFO_DL_OFDMA_TX = 376 /* 0x178 */, HAL_SRP_INFO = 377 /* 0x179 */, HAL_OBSS_SR_INFO = 378 /* 0x17a */, HAL_SCHEDULER_SW_MSG_STATUS = 379 /* 0x17b */, HAL_HWSCH_RXPCU_MAC_INFO_ANNOUNCEMENT = 380 /* 0x17c */, HAL_RXPCU_SETUP_COMPLETE = 381 /* 0x17d */, HAL_SNOOP_PPDU_START = 382 /* 0x17e */, HAL_SNOOP_MPDU_USR_DBG_INFO = 383 /* 0x17f */, HAL_SNOOP_MSDU_USR_DBG_INFO = 384 /* 0x180 */, HAL_SNOOP_MSDU_USR_DATA = 385 /* 0x181 */, HAL_SNOOP_MPDU_USR_STAT_INFO = 386 /* 0x182 */, HAL_SNOOP_PPDU_END = 387 /* 0x183 */, HAL_SNOOP_SPARE = 388 /* 0x184 */, HAL_PHYRX_OTHER_RECEIVE_INFO_MU_RSSI_COMMON = 390 /* 0x186 */, HAL_PHYRX_OTHER_RECEIVE_INFO_MU_RSSI_USER = 391 /* 0x187 */, HAL_MACTX_OTHER_TRANSMIT_INFO_SCH_DETAILS = 392 /* 0x188 */, HAL_PHYRX_OTHER_RECEIVE_INFO_108PVM_DETAILS = 393 /* 0x189 */, HAL_SCH_TLV_WRAPPER = 394 /* 0x18a */, HAL_SCHEDULER_STATUS_WRAPPER = 395 /* 0x18b */, HAL_MPDU_INFO_6X = 396 /* 0x18c */, HAL_MACTX_11AZ_USER_DESC_PER_USER = 397 /* 0x18d */, HAL_MACTX_U_SIGHT_SU_MU = 398 /* 0x18e */, HAL_MACTX_U_SIGHT_TB = 399 /* 0x18f */, HAL_PHYRX_U_SIGHT_SU_MU = 403 /* 0x193 */, HAL_PHYRX_U_SIGHT_TB = 404 /* 0x194 */, HAL_MACRX_LMR_READ_REQUEST = 408 /* 0x198 */, HAL_MACRX_LMR_DATA_REQUEST = 409 /* 0x199 */, HAL_PHYRX_LMR_TRANSFER_DONE = 410 /* 0x19a */, HAL_PHYRX_LMR_TRANSFER_ABORT = 411 /* 0x19b */, HAL_PHYRX_LMR_READ_REQUEST_ACK = 412 /* 0x19c */, HAL_MACRX_SECURE_LTF_SEQ_PTR = 413 /* 0x19d */, HAL_PHYRX_USER_INFO_MU_UL = 414 /* 0x19e */, HAL_MPDU_QUEUE_OVERVIEW = 415 /* 0x19f */, HAL_SCHEDULER_NAV_INFO = 416 /* 0x1a0 */, HAL_LMR_PEER_ENTRY = 418 /* 0x1a2 */, HAL_LMR_MPDU_START = 419 /* 0x1a3 */, HAL_LMR_DATA = 420 /* 0x1a4 */, HAL_LMR_MPDU_END = 421 /* 0x1a5 */, HAL_REO_GET_QUEUE_1K_STATS_STATUS = 422 /* 0x1a6 */, HAL_RX_FRAME_1K_BITMAP_ACK = 423 /* 0x1a7 */, HAL_TX_FES_STATUS_1K_BA = 424 /* 0x1a8 */, HAL_TQM_ACKED_1K_MPDU = 425 /* 0x1a9 */, HAL_MACRX_INBSS_OBSS_IND = 426 /* 0x1aa */, HAL_PHYRX_LOCATION = 427 /* 0x1ab */, HAL_MLO_TX_NOTIFICATION_SU = 428 /* 0x1ac */, HAL_MLO_TX_NOTIFICATION_MU = 429 /* 0x1ad */, HAL_MLO_TX_REQ_SU = 430 /* 0x1ae */, HAL_MLO_TX_REQ_MU = 431 /* 0x1af */, HAL_MLO_TX_RESP = 432 /* 0x1b0 */, HAL_MLO_RX_NOTIFICATION = 433 /* 0x1b1 */, HAL_MLO_BKOFF_TRUNC_REQ = 434 /* 0x1b2 */, HAL_MLO_TBTT_NOTIFICATION = 435 /* 0x1b3 */, HAL_MLO_MESSAGE = 436 /* 0x1b4 */, HAL_MLO_TS_SYNC_MSG = 437 /* 0x1b5 */, HAL_MLO_FES_SETUP = 438 /* 0x1b6 */, HAL_MLO_PDG_FES_SETUP_SU = 439 /* 0x1b7 */, HAL_MLO_PDG_FES_SETUP_MU = 440 /* 0x1b8 */, HAL_MPDU_INFO_1K_BITMAP = 441 /* 0x1b9 */, HAL_MON_BUF_ADDR = 442 /* 0x1ba */, HAL_TX_FRAG_STATE = 443 /* 0x1bb */, HAL_MACTXHT_SIG_USR_OFDMA = 446 /* 0x1be */, HAL_PHYRXHT_SIG_CMN_PUNC = 448 /* 0x1c0 */, HAL_PHYRXHT_SIG_CMN_OFDMA = 450 /* 0x1c2 */, HAL_PHYRXHT_SIG_USR_OFDMA = 454 /* 0x1c6 */, HAL_PHYRX_PKT_END_PART1 = 456 /* 0x1c8 */, HAL_MACTXXPECT_NDP_RECEPTION = 457 /* 0x1c9 */, HAL_MACTX_SECURE_LTF_SEQ_PTR = 458 /* 0x1ca */, HAL_MLO_PDG_BKOFF_TRUNC_NOTIFY = 460 /* 0x1cc */, HAL_PHYRX_11AZ_INTEGRITY_DATA = 461 /* 0x1cd */, HAL_PHYTX_LOCATION = 462 /* 0x1ce */, HAL_PHYTX_11AZ_INTEGRITY_DATA = 463 /* 0x1cf */, HAL_MACTXHT_SIG_USR_SU = 466 /* 0x1d2 */, HAL_MACTXHT_SIG_USR_MU_MIMO = 467 /* 0x1d3 */, HAL_PHYRXHT_SIG_USR_SU = 468 /* 0x1d4 */, HAL_PHYRXHT_SIG_USR_MU_MIMO = 469 /* 0x1d5 */, HAL_PHYRX_GENERIC_U_SIG = 470 /* 0x1d6 */, HAL_PHYRX_GENERICHT_SIG = 471 /* 0x1d7 */, HAL_OVERWRITE_RESP_START = 472 /* 0x1d8 */, HAL_OVERWRITE_RESP_PREAMBLE_INFO = 473 /* 0x1d9 */, HAL_OVERWRITE_RESP_FRAME_INFO = 474 /* 0x1da */, HAL_OVERWRITE_RESP_END = 475 /* 0x1db */, HAL_RXPCUARLY_RX_INDICATION = 476 /* 0x1dc */, HAL_MON_DROP = 477 /* 0x1dd */, HAL_MACRX_MU_UPLINK_COMMON_SNIFF = 478 /* 0x1de */, HAL_MACRX_MU_UPLINK_USER_SETUP_SNIFF = 479 /* 0x1df */, HAL_MACRX_MU_UPLINK_USER_SEL_SNIFF = 480 /* 0x1e0 */, HAL_MACRX_MU_UPLINK_FCS_STATUS_SNIFF = 481 /* 0x1e1 */, HAL_MACTX_PREFETCH_CV_DMA = 482 /* 0x1e2 */, HAL_MACTX_PREFETCH_CV_PER_USER = 483 /* 0x1e3 */, HAL_PHYRX_OTHER_RECEIVE_INFO_ALL_SIGB_DETAILS = 484 /* 0x1e4 */, HAL_MACTX_BF_PARAMS_UPDATE_COMMON = 485 /* 0x1e5 */, HAL_MACTX_BF_PARAMS_UPDATE_PER_USER = 486 /* 0x1e6 */, HAL_RANGING_USER_DETAILS = 487 /* 0x1e7 */, HAL_PHYTX_CV_CORR_STATUS = 488 /* 0x1e8 */, HAL_PHYTX_CV_CORR_COMMON = 489 /* 0x1e9 */, HAL_PHYTX_CV_CORR_USER = 490 /* 0x1ea */, HAL_MACTX_CV_CORR_COMMON = 491 /* 0x1eb */, HAL_MACTX_CV_CORR_MAC_INFO_GROUP = 492 /* 0x1ec */, HAL_BW_PUNCTUREVAL_WRAPPER = 493 /* 0x1ed */, HAL_MACTX_RX_NOTIFICATION_FOR_PHY = 494 /* 0x1ee */, HAL_MACTX_TX_NOTIFICATION_FOR_PHY = 495 /* 0x1ef */, HAL_MACTX_MU_UPLINK_COMMON_PER_BW = 496 /* 0x1f0 */, HAL_MACTX_MU_UPLINK_USER_SETUP_PER_BW = 497 /* 0x1f1 */, HAL_RX_PPDU_END_USER_STATS_EXT2 = 498 /* 0x1f2 */, HAL_FW2SW_MON = 499 /* 0x1f3 */, HAL_WSI_DIRECT_MESSAGE = 500 /* 0x1f4 */, HAL_MACTXMLSR_PRE_SWITCH = 501 /* 0x1f5 */, HAL_MACTXMLSR_SWITCH = 502 /* 0x1f6 */, HAL_MACTXMLSR_SWITCH_BACK = 503 /* 0x1f7 */, HAL_PHYTXMLSR_SWITCH_ACK = 504 /* 0x1f8 */, HAL_PHYTXMLSR_SWITCH_BACK_ACK = 505 /* 0x1f9 */, HAL_SPARE_REUSE_TAG_0 = 506 /* 0x1fa */, HAL_SPARE_REUSE_TAG_1 = 507 /* 0x1fb */, HAL_SPARE_REUSE_TAG_2 = 508 /* 0x1fc */, HAL_SPARE_REUSE_TAG_3 = 509 /* 0x1fd */, /* FIXME: Assign correct value for HAL_TCL_DATA_CMD */ HAL_TCL_DATA_CMD = 510, HAL_TLV_BASE = 511 /* 0x1ff */, }; #define HAL_TLV_HDR_TAG GENMASK(9, 1) #define HAL_TLV_HDR_LEN GENMASK(25, 10) #define HAL_TLV_USR_ID GENMASK(31, 26) #define HAL_TLV_ALIGN 4 struct hal_tlv_hdr { __le32 tl; u8 value[]; } __packed; #define HAL_TLV_64_HDR_TAG GENMASK(9, 1) #define HAL_TLV_64_HDR_LEN GENMASK(21, 10) struct hal_tlv_64_hdr { u64 tl; u8 value[]; } __packed; #define RX_MPDU_DESC_INFO0_MSDU_COUNT GENMASK(7, 0) #define RX_MPDU_DESC_INFO0_FRAG_FLAG BIT(8) #define RX_MPDU_DESC_INFO0_MPDU_RETRY BIT(9) #define RX_MPDU_DESC_INFO0_AMPDU_FLAG BIT(10) #define RX_MPDU_DESC_INFO0_BAR_FRAME BIT(11) #define RX_MPDU_DESC_INFO0_VALID_PN BIT(12) #define RX_MPDU_DESC_INFO0_RAW_MPDU BIT(13) #define RX_MPDU_DESC_INFO0_MORE_FRAG_FLAG BIT(14) #define RX_MPDU_DESC_INFO0_SRC_INFO GENMASK(26, 15) #define RX_MPDU_DESC_INFO0_MPDU_QOS_CTRL_VALID BIT(27) #define RX_MPDU_DESC_INFO0_TID GENMASK(31, 28) /* TODO revisit after meta data is concluded */ #define RX_MPDU_DESC_META_DATA_PEER_ID GENMASK(15, 0) struct rx_mpdu_desc { __le32 info0; /* %RX_MPDU_DESC_INFO */ __le32 peer_meta_data; } __packed; /* rx_mpdu_desc * Producer: RXDMA * Consumer: REO/SW/FW * * msdu_count * The number of MSDUs within the MPDU * * fragment_flag * When set, this MPDU is a fragment and REO should forward this * fragment MPDU to the REO destination ring without any reorder * checks, pn checks or bitmap update. This implies that REO is * forwarding the pointer to the MSDU link descriptor. * * mpdu_retry_bit * The retry bit setting from the MPDU header of the received frame * * ampdu_flag * Indicates the MPDU was received as part of an A-MPDU. * * bar_frame * Indicates the received frame is a BAR frame. After processing, * this frame shall be pushed to SW or deleted. * * valid_pn * When not set, REO will not perform a PN sequence number check. * * raw_mpdu * Field only valid when first_msdu_in_mpdu_flag is set. Indicates * the contents in the MSDU buffer contains a 'RAW' MPDU. This * 'RAW' MPDU might be spread out over multiple MSDU buffers. * * more_fragment_flag * The More Fragment bit setting from the MPDU header of the * received frame * * src_info * Source (Virtual) device/interface info associated with this peer. * This field gets passed on by REO to PPE in the EDMA descriptor. * * mpdu_qos_control_valid * When set, the MPDU has a QoS control field * * tid * Field only valid when mpdu_qos_control_valid is set */ enum hal_rx_msdu_desc_reo_dest_ind { HAL_RX_MSDU_DESC_REO_DEST_IND_TCL, HAL_RX_MSDU_DESC_REO_DEST_IND_SW1, HAL_RX_MSDU_DESC_REO_DEST_IND_SW2, HAL_RX_MSDU_DESC_REO_DEST_IND_SW3, HAL_RX_MSDU_DESC_REO_DEST_IND_SW4, HAL_RX_MSDU_DESC_REO_DEST_IND_RELEASE, HAL_RX_MSDU_DESC_REO_DEST_IND_FW, HAL_RX_MSDU_DESC_REO_DEST_IND_SW5, HAL_RX_MSDU_DESC_REO_DEST_IND_SW6, HAL_RX_MSDU_DESC_REO_DEST_IND_SW7, HAL_RX_MSDU_DESC_REO_DEST_IND_SW8, }; #define RX_MSDU_DESC_INFO0_FIRST_MSDU_IN_MPDU BIT(0) #define RX_MSDU_DESC_INFO0_LAST_MSDU_IN_MPDU BIT(1) #define RX_MSDU_DESC_INFO0_MSDU_CONTINUATION BIT(2) #define RX_MSDU_DESC_INFO0_MSDU_LENGTH GENMASK(16, 3) #define RX_MSDU_DESC_INFO0_MSDU_DROP BIT(17) #define RX_MSDU_DESC_INFO0_VALID_SA BIT(18) #define RX_MSDU_DESC_INFO0_VALID_DA BIT(19) #define RX_MSDU_DESC_INFO0_DA_MCBC BIT(20) #define RX_MSDU_DESC_INFO0_L3_HDR_PAD_MSB BIT(21) #define RX_MSDU_DESC_INFO0_TCP_UDP_CHKSUM_FAIL BIT(22) #define RX_MSDU_DESC_INFO0_IP_CHKSUM_FAIL BIT(23) #define RX_MSDU_DESC_INFO0_FROM_DS BIT(24) #define RX_MSDU_DESC_INFO0_TO_DS BIT(25) #define RX_MSDU_DESC_INFO0_INTRA_BSS BIT(26) #define RX_MSDU_DESC_INFO0_DST_CHIP_ID GENMASK(28, 27) #define RX_MSDU_DESC_INFO0_DECAP_FORMAT GENMASK(30, 29) #define HAL_RX_MSDU_PKT_LENGTH_GET(val) \ (u32_get_bits((val), RX_MSDU_DESC_INFO0_MSDU_LENGTH)) struct rx_msdu_desc { __le32 info0; } __packed; /* rx_msdu_desc * * first_msdu_in_mpdu * Indicates first msdu in mpdu. * * last_msdu_in_mpdu * Indicates last msdu in mpdu. This flag can be true only when * 'Msdu_continuation' set to 0. This implies that when an msdu * is spread out over multiple buffers and thus msdu_continuation * is set, only for the very last buffer of the msdu, can the * 'last_msdu_in_mpdu' be set. * * When both first_msdu_in_mpdu and last_msdu_in_mpdu are set, * the MPDU that this MSDU belongs to only contains a single MSDU. * * msdu_continuation * When set, this MSDU buffer was not able to hold the entire MSDU. * The next buffer will therefore contain additional information * related to this MSDU. * * msdu_length * Field is only valid in combination with the 'first_msdu_in_mpdu' * being set. Full MSDU length in bytes after decapsulation. This * field is still valid for MPDU frames without A-MSDU. It still * represents MSDU length after decapsulation Or in case of RAW * MPDUs, it indicates the length of the entire MPDU (without FCS * field). * * msdu_drop * Indicates that REO shall drop this MSDU and not forward it to * any other ring. * * valid_sa * Indicates OLE found a valid SA entry for this MSDU. * * valid_da * When set, OLE found a valid DA entry for this MSDU. * * da_mcbc * Field Only valid if valid_da is set. Indicates the DA address * is a Multicast or Broadcast address for this MSDU. * * l3_header_padding_msb * Passed on from 'RX_MSDU_END' TLV (only the MSB is reported as * the LSB is always zero). Number of bytes padded to make sure * that the L3 header will always start of a Dword boundary * * tcp_udp_checksum_fail * Passed on from 'RX_ATTENTION' TLV * Indicates that the computed checksum did not match the checksum * in the TCP/UDP header. * * ip_checksum_fail * Passed on from 'RX_ATTENTION' TLV * Indicates that the computed checksum did not match the checksum * in the IP header. * * from_DS * Set if the 'from DS' bit is set in the frame control. * * to_DS * Set if the 'to DS' bit is set in the frame control. * * intra_bss * This packet needs intra-BSS routing by SW as the 'vdev_id' * for the destination is the same as the 'vdev_id' that this * MSDU was got in. * * dest_chip_id * If intra_bss is set, copied by RXOLE/RXDMA from 'ADDR_SEARCH_ENTRY' * to support intra-BSS routing with multi-chip multi-link operation. * This indicates into which chip's TCL the packet should be queued. * * decap_format * Indicates the format after decapsulation: */ #define RX_MSDU_EXT_DESC_INFO0_REO_DEST_IND GENMASK(4, 0) #define RX_MSDU_EXT_DESC_INFO0_SERVICE_CODE GENMASK(13, 5) #define RX_MSDU_EXT_DESC_INFO0_PRIORITY_VALID BIT(14) #define RX_MSDU_EXT_DESC_INFO0_DATA_OFFSET GENMASK(26, 15) #define RX_MSDU_EXT_DESC_INFO0_SRC_LINK_ID GENMASK(29, 27) struct rx_msdu_ext_desc { __le32 info0; } __packed; /* rx_msdu_ext_desc * * reo_destination_indication * The ID of the REO exit ring where the MSDU frame shall push * after (MPDU level) reordering has finished. * * service_code * Opaque service code between PPE and Wi-Fi * * priority_valid * * data_offset * The offset to Rx packet data within the buffer (including * Rx DMA offset programming and L3 header padding inserted * by Rx OLE). * * src_link_id * Set to the link ID of the PMAC that received the frame */ enum hal_reo_dest_ring_buffer_type { HAL_REO_DEST_RING_BUFFER_TYPE_MSDU, HAL_REO_DEST_RING_BUFFER_TYPE_LINK_DESC, }; enum hal_reo_dest_ring_push_reason { HAL_REO_DEST_RING_PUSH_REASON_ERR_DETECTED, HAL_REO_DEST_RING_PUSH_REASON_ROUTING_INSTRUCTION, }; enum hal_reo_dest_ring_error_code { HAL_REO_DEST_RING_ERROR_CODE_DESC_ADDR_ZERO, HAL_REO_DEST_RING_ERROR_CODE_DESC_INVALID, HAL_REO_DEST_RING_ERROR_CODE_AMPDU_IN_NON_BA, HAL_REO_DEST_RING_ERROR_CODE_NON_BA_DUPLICATE, HAL_REO_DEST_RING_ERROR_CODE_BA_DUPLICATE, HAL_REO_DEST_RING_ERROR_CODE_FRAME_2K_JUMP, HAL_REO_DEST_RING_ERROR_CODE_BAR_2K_JUMP, HAL_REO_DEST_RING_ERROR_CODE_FRAME_OOR, HAL_REO_DEST_RING_ERROR_CODE_BAR_OOR, HAL_REO_DEST_RING_ERROR_CODE_NO_BA_SESSION, HAL_REO_DEST_RING_ERROR_CODE_FRAME_SN_EQUALS_SSN, HAL_REO_DEST_RING_ERROR_CODE_PN_CHECK_FAILED, HAL_REO_DEST_RING_ERROR_CODE_2K_ERR_FLAG_SET, HAL_REO_DEST_RING_ERROR_CODE_PN_ERR_FLAG_SET, HAL_REO_DEST_RING_ERROR_CODE_DESC_BLOCKED, HAL_REO_DEST_RING_ERROR_CODE_MAX, }; #define HAL_REO_DEST_RING_INFO0_BUFFER_TYPE BIT(0) #define HAL_REO_DEST_RING_INFO0_PUSH_REASON GENMASK(2, 1) #define HAL_REO_DEST_RING_INFO0_ERROR_CODE GENMASK(7, 3) #define HAL_REO_DEST_RING_INFO0_MSDU_DATA_SIZE GENMASK(11, 8) #define HAL_REO_DEST_RING_INFO0_SW_EXCEPTION BIT(12) #define HAL_REO_DEST_RING_INFO0_SRC_LINK_ID GENMASK(15, 13) #define HAL_REO_DEST_RING_INFO0_SIGNATURE GENMASK(19, 16) #define HAL_REO_DEST_RING_INFO0_RING_ID GENMASK(27, 20) #define HAL_REO_DEST_RING_INFO0_LOOPING_COUNT GENMASK(31, 28) struct hal_reo_dest_ring { struct ath12k_buffer_addr buf_addr_info; struct rx_mpdu_desc rx_mpdu_info; struct rx_msdu_desc rx_msdu_info; __le32 buf_va_lo; __le32 buf_va_hi; __le32 info0; /* %HAL_REO_DEST_RING_INFO0_ */ } __packed; /* hal_reo_dest_ring * * Producer: RXDMA * Consumer: REO/SW/FW * * buf_addr_info * Details of the physical address of a buffer or MSDU * link descriptor. * * rx_mpdu_info * General information related to the MPDU that is passed * on from REO entrance ring to the REO destination ring. * * rx_msdu_info * General information related to the MSDU that is passed * on from RXDMA all the way to the REO destination ring. * * buf_va_lo * Field only valid if Reo_dest_buffer_type is set to MSDU_buf_address * Lower 32 bits of the 64-bit virtual address corresponding * to Buf_or_link_desc_addr_info * * buf_va_hi * Address (upper 32 bits) of the REO queue descriptor. * Upper 32 bits of the 64-bit virtual address corresponding * to Buf_or_link_desc_addr_info * * buffer_type * Indicates the type of address provided in the buf_addr_info. * Values are defined in enum %HAL_REO_DEST_RING_BUFFER_TYPE_. * * push_reason * Reason for pushing this frame to this exit ring. Values are * defined in enum %HAL_REO_DEST_RING_PUSH_REASON_. * * error_code * Valid only when 'push_reason' is set. All error codes are * defined in enum %HAL_REO_DEST_RING_ERROR_CODE_. * * captured_msdu_data_size * The number of following REO_DESTINATION STRUCTs that have * been replaced with msdu_data extracted from the msdu_buffer * and copied into the ring for easy FW/SW access. * * sw_exception * This field has the same setting as the SW_exception field * in the corresponding REO_entrance_ring descriptor. * When set, the REO entrance descriptor is generated by FW, * and the MPDU was processed in the following way: * - NO re-order function is needed. * - MPDU delinking is determined by the setting of Entrance * ring field: SW_excection_mpdu_delink * - Destination ring selection is based on the setting of * the Entrance ring field SW_exception_destination _ring_valid * * src_link_id * Set to the link ID of the PMAC that received the frame * * signature * Set to value 0x8 when msdu capture mode is enabled for this ring * * ring_id * The buffer pointer ring id. * 0 - Idle ring * 1 - N refers to other rings. * * looping_count * Indicates the number of times the producer of entries into * this ring has looped around the ring. */ #define HAL_REO_TO_PPE_RING_INFO0_DATA_LENGTH GENMASK(15, 0) #define HAL_REO_TO_PPE_RING_INFO0_DATA_OFFSET GENMASK(23, 16) #define HAL_REO_TO_PPE_RING_INFO0_POOL_ID GENMASK(28, 24) #define HAL_REO_TO_PPE_RING_INFO0_PREHEADER BIT(29) #define HAL_REO_TO_PPE_RING_INFO0_TSO_EN BIT(30) #define HAL_REO_TO_PPE_RING_INFO0_MORE BIT(31) struct hal_reo_to_ppe_ring { __le32 buffer_addr; __le32 info0; /* %HAL_REO_TO_PPE_RING_INFO0_ */ } __packed; /* hal_reo_to_ppe_ring * * Producer: REO * Consumer: PPE * * buf_addr_info * Details of the physical address of a buffer or MSDU * link descriptor. * * data_length * Length of valid data in bytes * * data_offset * Offset to the data from buffer pointer. Can be used to * strip header in the data for tunnel termination etc. * * pool_id * REO has global configuration register for this field. * It may have several free buffer pools, each * RX-Descriptor ring can fetch free buffer from specific * buffer pool; pool id will indicate which pool the buffer * will be released to; POOL_ID Zero returned to SW * * preheader * Disabled: 0 (Default) * Enabled: 1 * * tso_en * Disabled: 0 (Default) * Enabled: 1 * * more * More Segments followed */ enum hal_reo_entr_rxdma_push_reason { HAL_REO_ENTR_RING_RXDMA_PUSH_REASON_ERR_DETECTED, HAL_REO_ENTR_RING_RXDMA_PUSH_REASON_ROUTING_INSTRUCTION, HAL_REO_ENTR_RING_RXDMA_PUSH_REASON_RX_FLUSH, }; enum hal_reo_entr_rxdma_ecode { HAL_REO_ENTR_RING_RXDMA_ECODE_OVERFLOW_ERR, HAL_REO_ENTR_RING_RXDMA_ECODE_MPDU_LEN_ERR, HAL_REO_ENTR_RING_RXDMA_ECODE_FCS_ERR, HAL_REO_ENTR_RING_RXDMA_ECODE_DECRYPT_ERR, HAL_REO_ENTR_RING_RXDMA_ECODE_TKIP_MIC_ERR, HAL_REO_ENTR_RING_RXDMA_ECODE_UNECRYPTED_ERR, HAL_REO_ENTR_RING_RXDMA_ECODE_MSDU_LEN_ERR, HAL_REO_ENTR_RING_RXDMA_ECODE_MSDU_LIMIT_ERR, HAL_REO_ENTR_RING_RXDMA_ECODE_WIFI_PARSE_ERR, HAL_REO_ENTR_RING_RXDMA_ECODE_AMSDU_PARSE_ERR, HAL_REO_ENTR_RING_RXDMA_ECODE_SA_TIMEOUT_ERR, HAL_REO_ENTR_RING_RXDMA_ECODE_DA_TIMEOUT_ERR, HAL_REO_ENTR_RING_RXDMA_ECODE_FLOW_TIMEOUT_ERR, HAL_REO_ENTR_RING_RXDMA_ECODE_FLUSH_REQUEST_ERR, HAL_REO_ENTR_RING_RXDMA_ECODE_AMSDU_FRAG_ERR, HAL_REO_ENTR_RING_RXDMA_ECODE_MAX, }; enum hal_rx_reo_dest_ring { HAL_RX_REO_DEST_RING_TCL, HAL_RX_REO_DEST_RING_SW1, HAL_RX_REO_DEST_RING_SW2, HAL_RX_REO_DEST_RING_SW3, HAL_RX_REO_DEST_RING_SW4, HAL_RX_REO_DEST_RING_RELEASE, HAL_RX_REO_DEST_RING_FW, HAL_RX_REO_DEST_RING_SW5, HAL_RX_REO_DEST_RING_SW6, HAL_RX_REO_DEST_RING_SW7, HAL_RX_REO_DEST_RING_SW8, }; #define HAL_REO_ENTR_RING_INFO0_QUEUE_ADDR_HI GENMASK(7, 0) #define HAL_REO_ENTR_RING_INFO0_MPDU_BYTE_COUNT GENMASK(21, 8) #define HAL_REO_ENTR_RING_INFO0_DEST_IND GENMASK(26, 22) #define HAL_REO_ENTR_RING_INFO0_FRAMELESS_BAR BIT(27) #define HAL_REO_ENTR_RING_INFO1_RXDMA_PUSH_REASON GENMASK(1, 0) #define HAL_REO_ENTR_RING_INFO1_RXDMA_ERROR_CODE GENMASK(6, 2) #define HAL_REO_ENTR_RING_INFO1_MPDU_FRAG_NUM GENMASK(10, 7) #define HAL_REO_ENTR_RING_INFO1_SW_EXCEPTION BIT(11) #define HAL_REO_ENTR_RING_INFO1_SW_EXCEPT_MPDU_DELINK BIT(12) #define HAL_REO_ENTR_RING_INFO1_SW_EXCEPTION_RING_VLD BIT(13) #define HAL_REO_ENTR_RING_INFO1_SW_EXCEPTION_RING GENMASK(18, 14) #define HAL_REO_ENTR_RING_INFO1_MPDU_SEQ_NUM GENMASK(30, 19) #define HAL_REO_ENTR_RING_INFO2_PHY_PPDU_ID GENMASK(15, 0) #define HAL_REO_ENTR_RING_INFO2_SRC_LINK_ID GENMASK(18, 16) #define HAL_REO_ENTR_RING_INFO2_RING_ID GENMASK(27, 20) #define HAL_REO_ENTR_RING_INFO2_LOOPING_COUNT GENMASK(31, 28) struct hal_reo_entrance_ring { struct ath12k_buffer_addr buf_addr_info; struct rx_mpdu_desc rx_mpdu_info; __le32 queue_addr_lo; __le32 info0; /* %HAL_REO_ENTR_RING_INFO0_ */ __le32 info1; /* %HAL_REO_ENTR_RING_INFO1_ */ __le32 info2; /* %HAL_REO_DEST_RING_INFO2_ */ } __packed; /* hal_reo_entrance_ring * * Producer: RXDMA * Consumer: REO * * buf_addr_info * Details of the physical address of a buffer or MSDU * link descriptor. * * rx_mpdu_info * General information related to the MPDU that is passed * on from REO entrance ring to the REO destination ring. * * queue_addr_lo * Address (lower 32 bits) of the REO queue descriptor. * * queue_addr_hi * Address (upper 8 bits) of the REO queue descriptor. * * mpdu_byte_count * An approximation of the number of bytes received in this MPDU. * Used to keeps stats on the amount of data flowing * through a queue. * * reo_destination_indication * The id of the reo exit ring where the msdu frame shall push * after (MPDU level) reordering has finished. Values are defined * in enum %HAL_RX_MSDU_DESC_REO_DEST_IND_. * * frameless_bar * Indicates that this REO entrance ring struct contains BAR info * from a multi TID BAR frame. The original multi TID BAR frame * itself contained all the REO info for the first TID, but all * the subsequent TID info and their linkage to the REO descriptors * is passed down as 'frameless' BAR info. * * The only fields valid in this descriptor when this bit is set * are queue_addr_lo, queue_addr_hi, mpdu_sequence_number, * bar_frame and peer_meta_data. * * rxdma_push_reason * Reason for pushing this frame to this exit ring. Values are * defined in enum %HAL_REO_ENTR_RING_RXDMA_PUSH_REASON_. * * rxdma_error_code * Valid only when 'push_reason' is set. All error codes are * defined in enum %HAL_REO_ENTR_RING_RXDMA_ECODE_. * * mpdu_fragment_number * Field only valid when Reo_level_mpdu_frame_info. * Rx_mpdu_desc_info_details.Fragment_flag is set. * * sw_exception * When not set, REO is performing all its default MPDU processing * operations, * When set, this REO entrance descriptor is generated by FW, and * should be processed as an exception. This implies: * NO re-order function is needed. * MPDU delinking is determined by the setting of field * SW_excection_mpdu_delink * * sw_exception_mpdu_delink * Field only valid when SW_exception is set. * 1'b0: REO should NOT delink the MPDU, and thus pass this * MPDU on to the destination ring as is. This implies that * in the REO_DESTINATION_RING struct field * Buf_or_link_desc_addr_info should point to an MSDU link * descriptor * 1'b1: REO should perform the normal MPDU delink into MSDU operations. * * sw_exception_dest_ring * Field only valid when fields SW_exception and SW * exception_destination_ring_valid are set. values are defined * in %HAL_RX_REO_DEST_RING_. * * mpdu_seq_number * The field can have two different meanings based on the setting * of sub-field Reo level mpdu frame info. * Rx_mpdu_desc_info_details. BAR_frame * 'BAR_frame' is NOT set: * The MPDU sequence number of the received frame. * 'BAR_frame' is set. * The MPDU Start sequence number from the BAR frame * * phy_ppdu_id * A PPDU counter value that PHY increments for every PPDU received * * src_link_id * Set to the link ID of the PMAC that received the frame * * ring_id * The buffer pointer ring id. * 0 - Idle ring * 1 - N refers to other rings. * * looping_count * Indicates the number of times the producer of entries into * this ring has looped around the ring. */ #define HAL_REO_CMD_HDR_INFO0_CMD_NUMBER GENMASK(15, 0) #define HAL_REO_CMD_HDR_INFO0_STATUS_REQUIRED BIT(16) struct hal_reo_cmd_hdr { __le32 info0; } __packed; #define HAL_REO_GET_QUEUE_STATS_INFO0_QUEUE_ADDR_HI GENMASK(7, 0) #define HAL_REO_GET_QUEUE_STATS_INFO0_CLEAR_STATS BIT(8) struct hal_reo_get_queue_stats { struct hal_reo_cmd_hdr cmd; __le32 queue_addr_lo; __le32 info0; __le32 rsvd0[6]; __le32 tlv64_pad; } __packed; /* hal_reo_get_queue_stats * Producer: SW * Consumer: REO * * cmd * Details for command execution tracking purposes. * * queue_addr_lo * Address (lower 32 bits) of the REO queue descriptor. * * queue_addr_hi * Address (upper 8 bits) of the REO queue descriptor. * * clear_stats * Clear stats settings. When set, Clear the stats after * generating the status. * * Following stats will be cleared. * Timeout_count * Forward_due_to_bar_count * Duplicate_count * Frames_in_order_count * BAR_received_count * MPDU_Frames_processed_count * MSDU_Frames_processed_count * Total_processed_byte_count * Late_receive_MPDU_count * window_jump_2k * Hole_count */ #define HAL_REO_FLUSH_QUEUE_INFO0_DESC_ADDR_HI GENMASK(7, 0) #define HAL_REO_FLUSH_QUEUE_INFO0_BLOCK_DESC_ADDR BIT(8) #define HAL_REO_FLUSH_QUEUE_INFO0_BLOCK_RESRC_IDX GENMASK(10, 9) struct hal_reo_flush_queue { struct hal_reo_cmd_hdr cmd; __le32 desc_addr_lo; __le32 info0; __le32 rsvd0[6]; } __packed; #define HAL_REO_FLUSH_CACHE_INFO0_CACHE_ADDR_HI GENMASK(7, 0) #define HAL_REO_FLUSH_CACHE_INFO0_FWD_ALL_MPDUS BIT(8) #define HAL_REO_FLUSH_CACHE_INFO0_RELEASE_BLOCK_IDX BIT(9) #define HAL_REO_FLUSH_CACHE_INFO0_BLOCK_RESRC_IDX GENMASK(11, 10) #define HAL_REO_FLUSH_CACHE_INFO0_FLUSH_WO_INVALIDATE BIT(12) #define HAL_REO_FLUSH_CACHE_INFO0_BLOCK_CACHE_USAGE BIT(13) #define HAL_REO_FLUSH_CACHE_INFO0_FLUSH_ALL BIT(14) struct hal_reo_flush_cache { struct hal_reo_cmd_hdr cmd; __le32 cache_addr_lo; __le32 info0; __le32 rsvd0[6]; } __packed; #define HAL_TCL_DATA_CMD_INFO0_CMD_TYPE BIT(0) #define HAL_TCL_DATA_CMD_INFO0_DESC_TYPE BIT(1) #define HAL_TCL_DATA_CMD_INFO0_BANK_ID GENMASK(7, 2) #define HAL_TCL_DATA_CMD_INFO0_TX_NOTIFY_FRAME GENMASK(10, 8) #define HAL_TCL_DATA_CMD_INFO0_HDR_LEN_READ_SEL BIT(11) #define HAL_TCL_DATA_CMD_INFO0_BUF_TIMESTAMP GENMASK(30, 12) #define HAL_TCL_DATA_CMD_INFO0_BUF_TIMESTAMP_VLD BIT(31) #define HAL_TCL_DATA_CMD_INFO1_CMD_NUM GENMASK(31, 16) #define HAL_TCL_DATA_CMD_INFO2_DATA_LEN GENMASK(15, 0) #define HAL_TCL_DATA_CMD_INFO2_IP4_CKSUM_EN BIT(16) #define HAL_TCL_DATA_CMD_INFO2_UDP4_CKSUM_EN BIT(17) #define HAL_TCL_DATA_CMD_INFO2_UDP6_CKSUM_EN BIT(18) #define HAL_TCL_DATA_CMD_INFO2_TCP4_CKSUM_EN BIT(19) #define HAL_TCL_DATA_CMD_INFO2_TCP6_CKSUM_EN BIT(20) #define HAL_TCL_DATA_CMD_INFO2_TO_FW BIT(21) #define HAL_TCL_DATA_CMD_INFO2_PKT_OFFSET GENMASK(31, 23) #define HAL_TCL_DATA_CMD_INFO3_TID_OVERWRITE BIT(0) #define HAL_TCL_DATA_CMD_INFO3_FLOW_OVERRIDE_EN BIT(1) #define HAL_TCL_DATA_CMD_INFO3_CLASSIFY_INFO_SEL GENMASK(3, 2) #define HAL_TCL_DATA_CMD_INFO3_TID GENMASK(7, 4) #define HAL_TCL_DATA_CMD_INFO3_FLOW_OVERRIDE BIT(8) #define HAL_TCL_DATA_CMD_INFO3_PMAC_ID GENMASK(10, 9) #define HAL_TCL_DATA_CMD_INFO3_MSDU_COLOR GENMASK(12, 11) #define HAL_TCL_DATA_CMD_INFO3_VDEV_ID GENMASK(31, 24) #define HAL_TCL_DATA_CMD_INFO4_SEARCH_INDEX GENMASK(19, 0) #define HAL_TCL_DATA_CMD_INFO4_CACHE_SET_NUM GENMASK(23, 20) #define HAL_TCL_DATA_CMD_INFO4_IDX_LOOKUP_OVERRIDE BIT(24) #define HAL_TCL_DATA_CMD_INFO5_RING_ID GENMASK(27, 20) #define HAL_TCL_DATA_CMD_INFO5_LOOPING_COUNT GENMASK(31, 28) enum hal_encrypt_type { HAL_ENCRYPT_TYPE_WEP_40, HAL_ENCRYPT_TYPE_WEP_104, HAL_ENCRYPT_TYPE_TKIP_NO_MIC, HAL_ENCRYPT_TYPE_WEP_128, HAL_ENCRYPT_TYPE_TKIP_MIC, HAL_ENCRYPT_TYPE_WAPI, HAL_ENCRYPT_TYPE_CCMP_128, HAL_ENCRYPT_TYPE_OPEN, HAL_ENCRYPT_TYPE_CCMP_256, HAL_ENCRYPT_TYPE_GCMP_128, HAL_ENCRYPT_TYPE_AES_GCMP_256, HAL_ENCRYPT_TYPE_WAPI_GCM_SM4, }; enum hal_tcl_encap_type { HAL_TCL_ENCAP_TYPE_RAW, HAL_TCL_ENCAP_TYPE_NATIVE_WIFI, HAL_TCL_ENCAP_TYPE_ETHERNET, HAL_TCL_ENCAP_TYPE_802_3 = 3, }; enum hal_tcl_desc_type { HAL_TCL_DESC_TYPE_BUFFER, HAL_TCL_DESC_TYPE_EXT_DESC, }; enum hal_wbm_htt_tx_comp_status { HAL_WBM_REL_HTT_TX_COMP_STATUS_OK, HAL_WBM_REL_HTT_TX_COMP_STATUS_DROP, HAL_WBM_REL_HTT_TX_COMP_STATUS_TTL, HAL_WBM_REL_HTT_TX_COMP_STATUS_REINJ, HAL_WBM_REL_HTT_TX_COMP_STATUS_INSPECT, HAL_WBM_REL_HTT_TX_COMP_STATUS_MEC_NOTIFY, HAL_WBM_REL_HTT_TX_COMP_STATUS_MAX, }; struct hal_tcl_data_cmd { struct ath12k_buffer_addr buf_addr_info; __le32 info0; __le32 info1; __le32 info2; __le32 info3; __le32 info4; __le32 info5; } __packed; /* hal_tcl_data_cmd * * buf_addr_info * Details of the physical address of a buffer or MSDU * link descriptor. * * tcl_cmd_type * used to select the type of TCL Command descriptor * * desc_type * Indicates the type of address provided in the buf_addr_info. * Values are defined in enum %HAL_REO_DEST_RING_BUFFER_TYPE_. * * bank_id * used to select one of the TCL register banks for fields removed * from 'TCL_DATA_CMD' that do not change often within one virtual * device or a set of virtual devices: * * tx_notify_frame * TCL copies this value to 'TQM_ENTRANCE_RING' field FW_tx_notify_frame. * * hdr_length_read_sel * used to select the per 'encap_type' register set for MSDU header * read length * * buffer_timestamp * buffer_timestamp_valid * Frame system entrance timestamp. It shall be filled by first * module (SW, TCL or TQM) that sees the frames first. * * cmd_num * This number can be used to match against status. * * data_length * MSDU length in case of direct descriptor. Length of link * extension descriptor in case of Link extension descriptor. * * *_checksum_en * Enable checksum replacement for ipv4, udp_over_ipv4, ipv6, * udp_over_ipv6, tcp_over_ipv4 and tcp_over_ipv6. * * to_fw * Forward packet to FW along with classification result. The * packet will not be forward to TQM when this bit is set. * 1'b0: Use classification result to forward the packet. * 1'b1: Override classification result & forward packet only to fw * * packet_offset * Packet offset from Metadata in case of direct buffer descriptor. * * hlos_tid_overwrite * * When set, TCL shall ignore the IP DSCP and VLAN PCP * fields and use HLOS_TID as the final TID. Otherwise TCL * shall consider the DSCP and PCP fields as well as HLOS_TID * and choose a final TID based on the configured priority * * flow_override_enable * TCL uses this to select the flow pointer from the peer table, * which can be overridden by SW for pre-encrypted raw WiFi packets * that cannot be parsed for UDP or for other MLO * 0 - FP_PARSE_IP: Use the flow-pointer based on parsing the IPv4 * or IPv6 header. * 1 - FP_USE_OVERRIDE: Use the who_classify_info_sel and * flow_override fields to select the flow-pointer * * who_classify_info_sel * Field only valid when flow_override_enable is set to FP_USE_OVERRIDE. * This field is used to select one of the 'WHO_CLASSIFY_INFO's in the * peer table in case more than 2 flows are mapped to a single TID. * 0: To choose Flow 0 and 1 of any TID use this value. * 1: To choose Flow 2 and 3 of any TID use this value. * 2: To choose Flow 4 and 5 of any TID use this value. * 3: To choose Flow 6 and 7 of any TID use this value. * * If who_classify_info sel is not in sync with the num_tx_classify_info * field from address search, then TCL will set 'who_classify_info_sel' * to 0 use flows 0 and 1. * * hlos_tid * HLOS MSDU priority * Field is used when HLOS_TID_overwrite is set. * * flow_override * Field only valid when flow_override_enable is set to FP_USE_OVERRIDE * TCL uses this to select the flow pointer from the peer table, * which can be overridden by SW for pre-encrypted raw WiFi packets * that cannot be parsed for UDP or for other MLO * 0 - FP_USE_NON_UDP: Use the non-UDP flow pointer (flow 0) * 1 - FP_USE_UDP: Use the UDP flow pointer (flow 1) * * pmac_id * TCL uses this PMAC_ID in address search, i.e, while * finding matching entry for the packet in AST corresponding * to given PMAC_ID * * If PMAC ID is all 1s (=> value 3), it indicates wildcard * match for any PMAC * * vdev_id * Virtual device ID to check against the address search entry to * avoid security issues from transmitting packets from an incorrect * virtual device * * search_index * The index that will be used for index based address or * flow search. The field is valid when 'search_type' is 1 or 2. * * cache_set_num * * Cache set number that should be used to cache the index * based search results, for address and flow search. This * value should be equal to LSB four bits of the hash value of * match data, in case of search index points to an entry which * may be used in content based search also. The value can be * anything when the entry pointed by search index will not be * used for content based search. * * index_loop_override * When set, address search and packet routing is forced to use * 'search_index' instead of following the register configuration * selected by Bank_id. * * ring_id * The buffer pointer ring ID. * 0 refers to the IDLE ring * 1 - N refers to other rings * * looping_count * * A count value that indicates the number of times the * producer of entries into the Ring has looped around the * ring. * * At initialization time, this value is set to 0. On the * first loop, this value is set to 1. After the max value is * reached allowed by the number of bits for this field, the * count value continues with 0 again. * * In case SW is the consumer of the ring entries, it can * use this field to figure out up to where the producer of * entries has created new entries. This eliminates the need to * check where the head pointer' of the ring is located once * the SW starts processing an interrupt indicating that new * entries have been put into this ring... * * Also note that SW if it wants only needs to look at the * LSB bit of this count value. */ #define HAL_TCL_DESC_LEN sizeof(struct hal_tcl_data_cmd) #define HAL_TX_MSDU_EXT_INFO0_BUF_PTR_LO GENMASK(31, 0) #define HAL_TX_MSDU_EXT_INFO1_BUF_PTR_HI GENMASK(7, 0) #define HAL_TX_MSDU_EXT_INFO1_EXTN_OVERRIDE BIT(8) #define HAL_TX_MSDU_EXT_INFO1_ENCAP_TYPE GENMASK(10, 9) #define HAL_TX_MSDU_EXT_INFO1_ENCRYPT_TYPE GENMASK(14, 11) #define HAL_TX_MSDU_EXT_INFO1_BUF_LEN GENMASK(31, 16) struct hal_tx_msdu_ext_desc { __le32 rsvd0[6]; __le32 info0; __le32 info1; __le32 rsvd1[10]; }; struct hal_tcl_gse_cmd { __le32 ctrl_buf_addr_lo; __le32 info0; __le32 meta_data[2]; __le32 rsvd0[2]; __le32 info1; } __packed; /* hal_tcl_gse_cmd * * ctrl_buf_addr_lo, ctrl_buf_addr_hi * Address of a control buffer containing additional info needed * for this command execution. * * meta_data * Meta data to be returned in the status descriptor */ enum hal_tcl_cache_op_res { HAL_TCL_CACHE_OP_RES_DONE, HAL_TCL_CACHE_OP_RES_NOT_FOUND, HAL_TCL_CACHE_OP_RES_TIMEOUT, }; struct hal_tcl_status_ring { __le32 info0; __le32 msdu_byte_count; __le32 msdu_timestamp; __le32 meta_data[2]; __le32 info1; __le32 rsvd0; __le32 info2; } __packed; /* hal_tcl_status_ring * * msdu_cnt * msdu_byte_count * MSDU count of Entry and MSDU byte count for entry 1. * */ #define HAL_CE_SRC_DESC_ADDR_INFO_ADDR_HI GENMASK(7, 0) #define HAL_CE_SRC_DESC_ADDR_INFO_HASH_EN BIT(8) #define HAL_CE_SRC_DESC_ADDR_INFO_BYTE_SWAP BIT(9) #define HAL_CE_SRC_DESC_ADDR_INFO_DEST_SWAP BIT(10) #define HAL_CE_SRC_DESC_ADDR_INFO_GATHER BIT(11) #define HAL_CE_SRC_DESC_ADDR_INFO_LEN GENMASK(31, 16) #define HAL_CE_SRC_DESC_META_INFO_DATA GENMASK(15, 0) #define HAL_CE_SRC_DESC_FLAGS_RING_ID GENMASK(27, 20) #define HAL_CE_SRC_DESC_FLAGS_LOOP_CNT HAL_SRNG_DESC_LOOP_CNT struct hal_ce_srng_src_desc { __le32 buffer_addr_low; __le32 buffer_addr_info; /* %HAL_CE_SRC_DESC_ADDR_INFO_ */ __le32 meta_info; /* %HAL_CE_SRC_DESC_META_INFO_ */ __le32 flags; /* %HAL_CE_SRC_DESC_FLAGS_ */ } __packed; /* hal_ce_srng_src_desc * * buffer_addr_lo * LSB 32 bits of the 40 Bit Pointer to the source buffer * * buffer_addr_hi * MSB 8 bits of the 40 Bit Pointer to the source buffer * * toeplitz_en * Enable generation of 32-bit Toeplitz-LFSR hash for * data transfer. In case of gather field in first source * ring entry of the gather copy cycle in taken into account. * * src_swap * Treats source memory organization as big-endian. For * each dword read (4 bytes), the byte 0 is swapped with byte 3 * and byte 1 is swapped with byte 2. * In case of gather field in first source ring entry of * the gather copy cycle in taken into account. * * dest_swap * Treats destination memory organization as big-endian. * For each dword write (4 bytes), the byte 0 is swapped with * byte 3 and byte 1 is swapped with byte 2. * In case of gather field in first source ring entry of * the gather copy cycle in taken into account. * * gather * Enables gather of multiple copy engine source * descriptors to one destination. * * ce_res_0 * Reserved * * * length * Length of the buffer in units of octets of the current * descriptor * * fw_metadata * Meta data used by FW. * In case of gather field in first source ring entry of * the gather copy cycle in taken into account. * * ce_res_1 * Reserved * * ce_res_2 * Reserved * * ring_id * The buffer pointer ring ID. * 0 refers to the IDLE ring * 1 - N refers to other rings * Helps with debugging when dumping ring contents. * * looping_count * A count value that indicates the number of times the * producer of entries into the Ring has looped around the * ring. * * At initialization time, this value is set to 0. On the * first loop, this value is set to 1. After the max value is * reached allowed by the number of bits for this field, the * count value continues with 0 again. * * In case SW is the consumer of the ring entries, it can * use this field to figure out up to where the producer of * entries has created new entries. This eliminates the need to * check where the head pointer' of the ring is located once * the SW starts processing an interrupt indicating that new * entries have been put into this ring... * * Also note that SW if it wants only needs to look at the * LSB bit of this count value. */ #define HAL_CE_DEST_DESC_ADDR_INFO_ADDR_HI GENMASK(7, 0) #define HAL_CE_DEST_DESC_ADDR_INFO_RING_ID GENMASK(27, 20) #define HAL_CE_DEST_DESC_ADDR_INFO_LOOP_CNT HAL_SRNG_DESC_LOOP_CNT struct hal_ce_srng_dest_desc { __le32 buffer_addr_low; __le32 buffer_addr_info; /* %HAL_CE_DEST_DESC_ADDR_INFO_ */ } __packed; /* hal_ce_srng_dest_desc * * dst_buffer_low * LSB 32 bits of the 40 Bit Pointer to the Destination * buffer * * dst_buffer_high * MSB 8 bits of the 40 Bit Pointer to the Destination * buffer * * ce_res_4 * Reserved * * ring_id * The buffer pointer ring ID. * 0 refers to the IDLE ring * 1 - N refers to other rings * Helps with debugging when dumping ring contents. * * looping_count * A count value that indicates the number of times the * producer of entries into the Ring has looped around the * ring. * * At initialization time, this value is set to 0. On the * first loop, this value is set to 1. After the max value is * reached allowed by the number of bits for this field, the * count value continues with 0 again. * * In case SW is the consumer of the ring entries, it can * use this field to figure out up to where the producer of * entries has created new entries. This eliminates the need to * check where the head pointer' of the ring is located once * the SW starts processing an interrupt indicating that new * entries have been put into this ring... * * Also note that SW if it wants only needs to look at the * LSB bit of this count value. */ #define HAL_CE_DST_STATUS_DESC_FLAGS_HASH_EN BIT(8) #define HAL_CE_DST_STATUS_DESC_FLAGS_BYTE_SWAP BIT(9) #define HAL_CE_DST_STATUS_DESC_FLAGS_DEST_SWAP BIT(10) #define HAL_CE_DST_STATUS_DESC_FLAGS_GATHER BIT(11) #define HAL_CE_DST_STATUS_DESC_FLAGS_LEN GENMASK(31, 16) #define HAL_CE_DST_STATUS_DESC_META_INFO_DATA GENMASK(15, 0) #define HAL_CE_DST_STATUS_DESC_META_INFO_RING_ID GENMASK(27, 20) #define HAL_CE_DST_STATUS_DESC_META_INFO_LOOP_CNT HAL_SRNG_DESC_LOOP_CNT struct hal_ce_srng_dst_status_desc { __le32 flags; /* %HAL_CE_DST_STATUS_DESC_FLAGS_ */ __le32 toeplitz_hash0; __le32 toeplitz_hash1; __le32 meta_info; /* HAL_CE_DST_STATUS_DESC_META_INFO_ */ } __packed; /* hal_ce_srng_dst_status_desc * * ce_res_5 * Reserved * * toeplitz_en * * src_swap * Source memory buffer swapped * * dest_swap * Destination memory buffer swapped * * gather * Gather of multiple copy engine source descriptors to one * destination enabled * * ce_res_6 * Reserved * * length * Sum of all the Lengths of the source descriptor in the * gather chain * * toeplitz_hash_0 * 32 LS bits of 64 bit Toeplitz LFSR hash result * * toeplitz_hash_1 * 32 MS bits of 64 bit Toeplitz LFSR hash result * * fw_metadata * Meta data used by FW * In case of gather field in first source ring entry of * the gather copy cycle in taken into account. * * ce_res_7 * Reserved * * ring_id * The buffer pointer ring ID. * 0 refers to the IDLE ring * 1 - N refers to other rings * Helps with debugging when dumping ring contents. * * looping_count * A count value that indicates the number of times the * producer of entries into the Ring has looped around the * ring. * * At initialization time, this value is set to 0. On the * first loop, this value is set to 1. After the max value is * reached allowed by the number of bits for this field, the * count value continues with 0 again. * * In case SW is the consumer of the ring entries, it can * use this field to figure out up to where the producer of * entries has created new entries. This eliminates the need to * check where the head pointer' of the ring is located once * the SW starts processing an interrupt indicating that new * entries have been put into this ring... * * Also note that SW if it wants only needs to look at the * LSB bit of this count value. */ #define HAL_TX_RATE_STATS_INFO0_VALID BIT(0) #define HAL_TX_RATE_STATS_INFO0_BW GENMASK(3, 1) #define HAL_TX_RATE_STATS_INFO0_PKT_TYPE GENMASK(7, 4) #define HAL_TX_RATE_STATS_INFO0_STBC BIT(8) #define HAL_TX_RATE_STATS_INFO0_LDPC BIT(9) #define HAL_TX_RATE_STATS_INFO0_SGI GENMASK(11, 10) #define HAL_TX_RATE_STATS_INFO0_MCS GENMASK(15, 12) #define HAL_TX_RATE_STATS_INFO0_OFDMA_TX BIT(16) #define HAL_TX_RATE_STATS_INFO0_TONES_IN_RU GENMASK(28, 17) enum hal_tx_rate_stats_bw { HAL_TX_RATE_STATS_BW_20, HAL_TX_RATE_STATS_BW_40, HAL_TX_RATE_STATS_BW_80, HAL_TX_RATE_STATS_BW_160, }; enum hal_tx_rate_stats_pkt_type { HAL_TX_RATE_STATS_PKT_TYPE_11A, HAL_TX_RATE_STATS_PKT_TYPE_11B, HAL_TX_RATE_STATS_PKT_TYPE_11N, HAL_TX_RATE_STATS_PKT_TYPE_11AC, HAL_TX_RATE_STATS_PKT_TYPE_11AX, HAL_TX_RATE_STATS_PKT_TYPE_11BA, HAL_TX_RATE_STATS_PKT_TYPE_11BE, }; enum hal_tx_rate_stats_sgi { HAL_TX_RATE_STATS_SGI_08US, HAL_TX_RATE_STATS_SGI_04US, HAL_TX_RATE_STATS_SGI_16US, HAL_TX_RATE_STATS_SGI_32US, }; struct hal_tx_rate_stats { __le32 info0; __le32 tsf; } __packed; struct hal_wbm_link_desc { struct ath12k_buffer_addr buf_addr_info; } __packed; /* hal_wbm_link_desc * * Producer: WBM * Consumer: WBM * * buf_addr_info * Details of the physical address of a buffer or MSDU * link descriptor. */ enum hal_wbm_rel_src_module { HAL_WBM_REL_SRC_MODULE_TQM, HAL_WBM_REL_SRC_MODULE_RXDMA, HAL_WBM_REL_SRC_MODULE_REO, HAL_WBM_REL_SRC_MODULE_FW, HAL_WBM_REL_SRC_MODULE_SW, }; enum hal_wbm_rel_desc_type { HAL_WBM_REL_DESC_TYPE_REL_MSDU, HAL_WBM_REL_DESC_TYPE_MSDU_LINK, HAL_WBM_REL_DESC_TYPE_MPDU_LINK, HAL_WBM_REL_DESC_TYPE_MSDU_EXT, HAL_WBM_REL_DESC_TYPE_QUEUE_EXT, }; /* hal_wbm_rel_desc_type * * msdu_buffer * The address points to an MSDU buffer * * msdu_link_descriptor * The address points to an Tx MSDU link descriptor * * mpdu_link_descriptor * The address points to an MPDU link descriptor * * msdu_ext_descriptor * The address points to an MSDU extension descriptor * * queue_ext_descriptor * The address points to an TQM queue extension descriptor. WBM should * treat this is the same way as a link descriptor. */ enum hal_wbm_rel_bm_act { HAL_WBM_REL_BM_ACT_PUT_IN_IDLE, HAL_WBM_REL_BM_ACT_REL_MSDU, }; /* hal_wbm_rel_bm_act * * put_in_idle_list * Put the buffer or descriptor back in the idle list. In case of MSDU or * MDPU link descriptor, BM does not need to check to release any * individual MSDU buffers. * * release_msdu_list * This BM action can only be used in combination with desc_type being * msdu_link_descriptor. Field first_msdu_index points out which MSDU * pointer in the MSDU link descriptor is the first of an MPDU that is * released. BM shall release all the MSDU buffers linked to this first * MSDU buffer pointer. All related MSDU buffer pointer entries shall be * set to value 0, which represents the 'NULL' pointer. When all MSDU * buffer pointers in the MSDU link descriptor are 'NULL', the MSDU link * descriptor itself shall also be released. */ #define HAL_WBM_COMPL_RX_INFO0_REL_SRC_MODULE GENMASK(2, 0) #define HAL_WBM_COMPL_RX_INFO0_BM_ACTION GENMASK(5, 3) #define HAL_WBM_COMPL_RX_INFO0_DESC_TYPE GENMASK(8, 6) #define HAL_WBM_COMPL_RX_INFO0_RBM GENMASK(12, 9) #define HAL_WBM_COMPL_RX_INFO0_RXDMA_PUSH_REASON GENMASK(18, 17) #define HAL_WBM_COMPL_RX_INFO0_RXDMA_ERROR_CODE GENMASK(23, 19) #define HAL_WBM_COMPL_RX_INFO0_REO_PUSH_REASON GENMASK(25, 24) #define HAL_WBM_COMPL_RX_INFO0_REO_ERROR_CODE GENMASK(30, 26) #define HAL_WBM_COMPL_RX_INFO0_WBM_INTERNAL_ERROR BIT(31) #define HAL_WBM_COMPL_RX_INFO1_PHY_ADDR_HI GENMASK(7, 0) #define HAL_WBM_COMPL_RX_INFO1_SW_COOKIE GENMASK(27, 8) #define HAL_WBM_COMPL_RX_INFO1_LOOPING_COUNT GENMASK(31, 28) struct hal_wbm_completion_ring_rx { __le32 addr_lo; __le32 addr_hi; __le32 info0; struct rx_mpdu_desc rx_mpdu_info; struct rx_msdu_desc rx_msdu_info; __le32 phy_addr_lo; __le32 info1; } __packed; #define HAL_WBM_COMPL_TX_INFO0_REL_SRC_MODULE GENMASK(2, 0) #define HAL_WBM_COMPL_TX_INFO0_DESC_TYPE GENMASK(8, 6) #define HAL_WBM_COMPL_TX_INFO0_RBM GENMASK(12, 9) #define HAL_WBM_COMPL_TX_INFO0_TQM_RELEASE_REASON GENMASK(16, 13) #define HAL_WBM_COMPL_TX_INFO0_RBM_OVERRIDE_VLD BIT(17) #define HAL_WBM_COMPL_TX_INFO0_SW_COOKIE_LO GENMASK(29, 18) #define HAL_WBM_COMPL_TX_INFO0_CC_DONE BIT(30) #define HAL_WBM_COMPL_TX_INFO0_WBM_INTERNAL_ERROR BIT(31) #define HAL_WBM_COMPL_TX_INFO1_TQM_STATUS_NUMBER GENMASK(23, 0) #define HAL_WBM_COMPL_TX_INFO1_TRANSMIT_COUNT GENMASK(30, 24) #define HAL_WBM_COMPL_TX_INFO1_SW_REL_DETAILS_VALID BIT(31) #define HAL_WBM_COMPL_TX_INFO2_ACK_FRAME_RSSI GENMASK(7, 0) #define HAL_WBM_COMPL_TX_INFO2_FIRST_MSDU BIT(8) #define HAL_WBM_COMPL_TX_INFO2_LAST_MSDU BIT(9) #define HAL_WBM_COMPL_TX_INFO2_FW_TX_NOTIF_FRAME GENMASK(12, 10) #define HAL_WBM_COMPL_TX_INFO2_BUFFER_TIMESTAMP GENMASK(31, 13) #define HAL_WBM_COMPL_TX_INFO3_PEER_ID GENMASK(15, 0) #define HAL_WBM_COMPL_TX_INFO3_TID GENMASK(19, 16) #define HAL_WBM_COMPL_TX_INFO3_SW_COOKIE_HI GENMASK(27, 20) #define HAL_WBM_COMPL_TX_INFO3_LOOPING_COUNT GENMASK(31, 28) struct hal_wbm_completion_ring_tx { __le32 buf_va_lo; __le32 buf_va_hi; __le32 info0; __le32 info1; __le32 info2; struct hal_tx_rate_stats rate_stats; __le32 info3; } __packed; #define HAL_WBM_RELEASE_TX_INFO0_REL_SRC_MODULE GENMASK(2, 0) #define HAL_WBM_RELEASE_TX_INFO0_BM_ACTION GENMASK(5, 3) #define HAL_WBM_RELEASE_TX_INFO0_DESC_TYPE GENMASK(8, 6) #define HAL_WBM_RELEASE_TX_INFO0_FIRST_MSDU_IDX GENMASK(12, 9) #define HAL_WBM_RELEASE_TX_INFO0_TQM_RELEASE_REASON GENMASK(18, 13) #define HAL_WBM_RELEASE_TX_INFO0_RBM_OVERRIDE_VLD BIT(17) #define HAL_WBM_RELEASE_TX_INFO0_SW_BUFFER_COOKIE_11_0 GENMASK(29, 18) #define HAL_WBM_RELEASE_TX_INFO0_WBM_INTERNAL_ERROR BIT(31) #define HAL_WBM_RELEASE_TX_INFO1_TQM_STATUS_NUMBER GENMASK(23, 0) #define HAL_WBM_RELEASE_TX_INFO1_TRANSMIT_COUNT GENMASK(30, 24) #define HAL_WBM_RELEASE_TX_INFO1_SW_REL_DETAILS_VALID BIT(31) #define HAL_WBM_RELEASE_TX_INFO2_ACK_FRAME_RSSI GENMASK(7, 0) #define HAL_WBM_RELEASE_TX_INFO2_FIRST_MSDU BIT(8) #define HAL_WBM_RELEASE_TX_INFO2_LAST_MSDU BIT(9) #define HAL_WBM_RELEASE_TX_INFO2_FW_TX_NOTIF_FRAME GENMASK(12, 10) #define HAL_WBM_RELEASE_TX_INFO2_BUFFER_TIMESTAMP GENMASK(31, 13) #define HAL_WBM_RELEASE_TX_INFO3_PEER_ID GENMASK(15, 0) #define HAL_WBM_RELEASE_TX_INFO3_TID GENMASK(19, 16) #define HAL_WBM_RELEASE_TX_INFO3_SW_BUFFER_COOKIE_19_12 GENMASK(27, 20) #define HAL_WBM_RELEASE_TX_INFO3_LOOPING_COUNT GENMASK(31, 28) struct hal_wbm_release_ring_tx { struct ath12k_buffer_addr buf_addr_info; __le32 info0; __le32 info1; __le32 info2; struct hal_tx_rate_stats rate_stats; __le32 info3; } __packed; #define HAL_WBM_RELEASE_RX_INFO0_REL_SRC_MODULE GENMASK(2, 0) #define HAL_WBM_RELEASE_RX_INFO0_BM_ACTION GENMASK(5, 3) #define HAL_WBM_RELEASE_RX_INFO0_DESC_TYPE GENMASK(8, 6) #define HAL_WBM_RELEASE_RX_INFO0_FIRST_MSDU_IDX GENMASK(12, 9) #define HAL_WBM_RELEASE_RX_INFO0_CC_STATUS BIT(16) #define HAL_WBM_RELEASE_RX_INFO0_RXDMA_PUSH_REASON GENMASK(18, 17) #define HAL_WBM_RELEASE_RX_INFO0_RXDMA_ERROR_CODE GENMASK(23, 19) #define HAL_WBM_RELEASE_RX_INFO0_REO_PUSH_REASON GENMASK(25, 24) #define HAL_WBM_RELEASE_RX_INFO0_REO_ERROR_CODE GENMASK(30, 26) #define HAL_WBM_RELEASE_RX_INFO0_WBM_INTERNAL_ERROR BIT(31) #define HAL_WBM_RELEASE_RX_INFO2_RING_ID GENMASK(27, 20) #define HAL_WBM_RELEASE_RX_INFO2_LOOPING_COUNT GENMASK(31, 28) struct hal_wbm_release_ring_rx { struct ath12k_buffer_addr buf_addr_info; __le32 info0; struct rx_mpdu_desc rx_mpdu_info; struct rx_msdu_desc rx_msdu_info; __le32 info1; __le32 info2; } __packed; #define HAL_WBM_RELEASE_RX_CC_INFO0_RBM GENMASK(12, 9) #define HAL_WBM_RELEASE_RX_CC_INFO1_COOKIE GENMASK(27, 8) /* Used when hw cc is success */ struct hal_wbm_release_ring_cc_rx { __le32 buf_va_lo; __le32 buf_va_hi; __le32 info0; struct rx_mpdu_desc rx_mpdu_info; struct rx_msdu_desc rx_msdu_info; __le32 buf_pa_lo; __le32 info1; } __packed; #define HAL_WBM_RELEASE_INFO0_REL_SRC_MODULE GENMASK(2, 0) #define HAL_WBM_RELEASE_INFO0_BM_ACTION GENMASK(5, 3) #define HAL_WBM_RELEASE_INFO0_DESC_TYPE GENMASK(8, 6) #define HAL_WBM_RELEASE_INFO0_RXDMA_PUSH_REASON GENMASK(18, 17) #define HAL_WBM_RELEASE_INFO0_RXDMA_ERROR_CODE GENMASK(23, 19) #define HAL_WBM_RELEASE_INFO0_REO_PUSH_REASON GENMASK(25, 24) #define HAL_WBM_RELEASE_INFO0_REO_ERROR_CODE GENMASK(30, 26) #define HAL_WBM_RELEASE_INFO0_WBM_INTERNAL_ERROR BIT(31) #define HAL_WBM_RELEASE_INFO3_FIRST_MSDU BIT(0) #define HAL_WBM_RELEASE_INFO3_LAST_MSDU BIT(1) #define HAL_WBM_RELEASE_INFO3_CONTINUATION BIT(2) #define HAL_WBM_RELEASE_INFO5_LOOPING_COUNT GENMASK(31, 28) struct hal_wbm_release_ring { struct ath12k_buffer_addr buf_addr_info; __le32 info0; __le32 info1; __le32 info2; __le32 info3; __le32 info4; __le32 info5; } __packed; /* hal_wbm_release_ring * * Producer: SW/TQM/RXDMA/REO/SWITCH * Consumer: WBM/SW/FW * * HTT tx status is overlaid on wbm_release ring on 4-byte words 2, 3, 4 and 5 * for software based completions. * * buf_addr_info * Details of the physical address of the buffer or link descriptor. * * release_source_module * Indicates which module initiated the release of this buffer/descriptor. * Values are defined in enum %HAL_WBM_REL_SRC_MODULE_. * * buffer_or_desc_type * Field only valid when WBM is marked as the return_buffer_manager in * the Released_Buffer_address_info. Indicates that type of buffer or * descriptor is being released. Values are in enum %HAL_WBM_REL_DESC_TYPE. * * wbm_internal_error * Is set when WBM got a buffer pointer but the action was to push it to * the idle link descriptor ring or do link related activity OR * Is set when WBM got a link buffer pointer but the action was to push it * to the buffer descriptor ring. * * looping_count * A count value that indicates the number of times the * producer of entries into the Buffer Manager Ring has looped * around the ring. * * At initialization time, this value is set to 0. On the * first loop, this value is set to 1. After the max value is * reached allowed by the number of bits for this field, the * count value continues with 0 again. * * In case SW is the consumer of the ring entries, it can * use this field to figure out up to where the producer of * entries has created new entries. This eliminates the need to * check where the head pointer' of the ring is located once * the SW starts processing an interrupt indicating that new * entries have been put into this ring... * * Also note that SW if it wants only needs to look at the * LSB bit of this count value. */ /** * enum hal_wbm_tqm_rel_reason - TQM release reason code * @HAL_WBM_TQM_REL_REASON_FRAME_ACKED: ACK or BACK received for the frame * @HAL_WBM_TQM_REL_REASON_CMD_REMOVE_MPDU: Command remove_mpdus initiated by SW * @HAL_WBM_TQM_REL_REASON_CMD_REMOVE_TX: Command remove transmitted_mpdus * initiated by sw. * @HAL_WBM_TQM_REL_REASON_CMD_REMOVE_NOTX: Command remove untransmitted_mpdus * initiated by sw. * @HAL_WBM_TQM_REL_REASON_CMD_REMOVE_AGED_FRAMES: Command remove aged msdus or * mpdus. * @HAL_WBM_TQM_REL_REASON_CMD_REMOVE_RESEAON1: Remove command initiated by * fw with fw_reason1. * @HAL_WBM_TQM_REL_REASON_CMD_REMOVE_RESEAON2: Remove command initiated by * fw with fw_reason2. * @HAL_WBM_TQM_REL_REASON_CMD_REMOVE_RESEAON3: Remove command initiated by * fw with fw_reason3. */ enum hal_wbm_tqm_rel_reason { HAL_WBM_TQM_REL_REASON_FRAME_ACKED, HAL_WBM_TQM_REL_REASON_CMD_REMOVE_MPDU, HAL_WBM_TQM_REL_REASON_CMD_REMOVE_TX, HAL_WBM_TQM_REL_REASON_CMD_REMOVE_NOTX, HAL_WBM_TQM_REL_REASON_CMD_REMOVE_AGED_FRAMES, HAL_WBM_TQM_REL_REASON_CMD_REMOVE_RESEAON1, HAL_WBM_TQM_REL_REASON_CMD_REMOVE_RESEAON2, HAL_WBM_TQM_REL_REASON_CMD_REMOVE_RESEAON3, }; struct hal_wbm_buffer_ring { struct ath12k_buffer_addr buf_addr_info; }; enum hal_mon_end_reason { HAL_MON_STATUS_BUFFER_FULL, HAL_MON_FLUSH_DETECTED, HAL_MON_END_OF_PPDU, HAL_MON_PPDU_TRUNCATED, }; #define HAL_SW_MONITOR_RING_INFO0_RXDMA_PUSH_REASON GENMASK(1, 0) #define HAL_SW_MONITOR_RING_INFO0_RXDMA_ERROR_CODE GENMASK(6, 2) #define HAL_SW_MONITOR_RING_INFO0_MPDU_FRAGMENT_NUMBER GENMASK(10, 7) #define HAL_SW_MONITOR_RING_INFO0_FRAMELESS_BAR BIT(11) #define HAL_SW_MONITOR_RING_INFO0_STATUS_BUF_COUNT GENMASK(15, 12) #define HAL_SW_MONITOR_RING_INFO0_END_OF_PPDU BIT(16) #define HAL_SW_MONITOR_RING_INFO1_PHY_PPDU_ID GENMASK(15, 0) #define HAL_SW_MONITOR_RING_INFO1_RING_ID GENMASK(27, 20) #define HAL_SW_MONITOR_RING_INFO1_LOOPING_COUNT GENMASK(31, 28) struct hal_sw_monitor_ring { struct ath12k_buffer_addr buf_addr_info; struct rx_mpdu_desc rx_mpdu_info; struct ath12k_buffer_addr status_buff_addr_info; __le32 info0; /* %HAL_SW_MONITOR_RING_INFO0 */ __le32 info1; /* %HAL_SW_MONITOR_RING_INFO1 */ } __packed; /* hal_sw_monitor_ring * * Producer: RXDMA * Consumer: REO/SW/FW * buf_addr_info * Details of the physical address of a buffer or MSDU * link descriptor. * * rx_mpdu_info * Details related to the MPDU being pushed to SW, valid * only if end_of_ppdu is set to 0. * * status_buff_addr_info * Details of the physical address of the first status * buffer used for the PPDU (either the PPDU that included the * MPDU being pushed to SW if end_of_ppdu = 0, or the PPDU * whose end is indicated through end_of_ppdu = 1) * * rxdma_push_reason * Indicates why RXDMA pushed the frame to this ring * * <enum 0 rxdma_error_detected> RXDMA detected an error an * pushed this frame to this queue * * <enum 1 rxdma_routing_instruction> RXDMA pushed the * frame to this queue per received routing instructions. No * error within RXDMA was detected * * <enum 2 rxdma_rx_flush> RXDMA received an RX_FLUSH. As a * result the MSDU link descriptor might not have the * last_msdu_in_mpdu_flag set, but instead WBM might just see a * NULL pointer in the MSDU link descriptor. This is to be * considered a normal condition for this scenario. * * rxdma_error_code * Field only valid when rxdma_push_reason is set to * 'rxdma_error_detected.' * * <enum 0 rxdma_overflow_err>MPDU frame is not complete * due to a FIFO overflow error in RXPCU. * * <enum 1 rxdma_mpdu_length_err>MPDU frame is not complete * due to receiving incomplete MPDU from the PHY * * <enum 3 rxdma_decrypt_err>CRYPTO reported a decryption * error or CRYPTO received an encrypted frame, but did not get * a valid corresponding key id in the peer entry. * * <enum 4 rxdma_tkip_mic_err>CRYPTO reported a TKIP MIC * error * * <enum 5 rxdma_unecrypted_err>CRYPTO reported an * unencrypted frame error when encrypted was expected * * <enum 6 rxdma_msdu_len_err>RX OLE reported an MSDU * length error * * <enum 7 rxdma_msdu_limit_err>RX OLE reported that max * number of MSDUs allowed in an MPDU got exceeded * * <enum 8 rxdma_wifi_parse_err>RX OLE reported a parsing * error * * <enum 9 rxdma_amsdu_parse_err>RX OLE reported an A-MSDU * parsing error * * <enum 10 rxdma_sa_timeout_err>RX OLE reported a timeout * during SA search * * <enum 11 rxdma_da_timeout_err>RX OLE reported a timeout * during DA search * * <enum 12 rxdma_flow_timeout_err>RX OLE reported a * timeout during flow search * * <enum 13 rxdma_flush_request>RXDMA received a flush * request * * <enum 14 rxdma_amsdu_fragment_err>Rx PCU reported A-MSDU * present as well as a fragmented MPDU. * * mpdu_fragment_number * Field only valid when Reo_level_mpdu_frame_info. * Rx_mpdu_desc_info_details.Fragment_flag is set and * end_of_ppdu is set to 0. * * The fragment number from the 802.11 header. * * Note that the sequence number is embedded in the field: * Reo_level_mpdu_frame_info. Rx_mpdu_desc_info_details. * Mpdu_sequence_number * * frameless_bar * When set, this SW monitor ring struct contains BAR info * from a multi TID BAR frame. The original multi TID BAR frame * itself contained all the REO info for the first TID, but all * the subsequent TID info and their linkage to the REO * descriptors is passed down as 'frameless' BAR info. * * The only fields valid in this descriptor when this bit * is within the * * Reo_level_mpdu_frame_info: * Within Rx_mpdu_desc_info_details: * Mpdu_Sequence_number * BAR_frame * Peer_meta_data * All other fields shall be set to 0. * * status_buf_count * A count of status buffers used so far for the PPDU * (either the PPDU that included the MPDU being pushed to SW * if end_of_ppdu = 0, or the PPDU whose end is indicated * through end_of_ppdu = 1) * * end_of_ppdu * Some hw RXDMA can be configured to generate a separate * 'SW_MONITOR_RING' descriptor at the end of a PPDU (either * through an 'RX_PPDU_END' TLV or through an 'RX_FLUSH') to * demarcate PPDUs. * * For such a descriptor, this bit is set to 1 and fields * Reo_level_mpdu_frame_info, mpdu_fragment_number and * Frameless_bar are all set to 0. * * Otherwise this bit is set to 0. * * phy_ppdu_id * A PPDU counter value that PHY increments for every PPDU * received * * The counter value wraps around. Some hw RXDMA can be * configured to copy this from the RX_PPDU_START TLV for every * output descriptor. * * ring_id * For debugging. * This field is filled in by the SRNG module. * It help to identify the ring that is being looked * * looping_count * For debugging. * This field is filled in by the SRNG module. * * A count value that indicates the number of times the * producer of entries into this Ring has looped around the * ring. * At initialization time, this value is set to 0. On the * first loop, this value is set to 1. After the max value is * reached allowed by the number of bits for this field, the * count value continues with 0 again. * * In case SW is the consumer of the ring entries, it can * use this field to figure out up to where the producer of * entries has created new entries. This eliminates the need to * check where the head pointer' of the ring is located once * the SW starts processing an interrupt indicating that new * entries have been put into this ring... */ enum hal_desc_owner { HAL_DESC_OWNER_WBM, HAL_DESC_OWNER_SW, HAL_DESC_OWNER_TQM, HAL_DESC_OWNER_RXDMA, HAL_DESC_OWNER_REO, HAL_DESC_OWNER_SWITCH, }; enum hal_desc_buf_type { HAL_DESC_BUF_TYPE_TX_MSDU_LINK, HAL_DESC_BUF_TYPE_TX_MPDU_LINK, HAL_DESC_BUF_TYPE_TX_MPDU_QUEUE_HEAD, HAL_DESC_BUF_TYPE_TX_MPDU_QUEUE_EXT, HAL_DESC_BUF_TYPE_TX_FLOW, HAL_DESC_BUF_TYPE_TX_BUFFER, HAL_DESC_BUF_TYPE_RX_MSDU_LINK, HAL_DESC_BUF_TYPE_RX_MPDU_LINK, HAL_DESC_BUF_TYPE_RX_REO_QUEUE, HAL_DESC_BUF_TYPE_RX_REO_QUEUE_EXT, HAL_DESC_BUF_TYPE_RX_BUFFER, HAL_DESC_BUF_TYPE_IDLE_LINK, }; #define HAL_DESC_REO_OWNED 4 #define HAL_DESC_REO_QUEUE_DESC 8 #define HAL_DESC_REO_QUEUE_EXT_DESC 9 #define HAL_DESC_REO_NON_QOS_TID 16 #define HAL_DESC_HDR_INFO0_OWNER GENMASK(3, 0) #define HAL_DESC_HDR_INFO0_BUF_TYPE GENMASK(7, 4) #define HAL_DESC_HDR_INFO0_DBG_RESERVED GENMASK(31, 8) struct hal_desc_header { __le32 info0; } __packed; struct hal_rx_mpdu_link_ptr { struct ath12k_buffer_addr addr_info; } __packed; struct hal_rx_msdu_details { struct ath12k_buffer_addr buf_addr_info; struct rx_msdu_desc rx_msdu_info; struct rx_msdu_ext_desc rx_msdu_ext_info; } __packed; #define HAL_RX_MSDU_LNK_INFO0_RX_QUEUE_NUMBER GENMASK(15, 0) #define HAL_RX_MSDU_LNK_INFO0_FIRST_MSDU_LNK BIT(16) struct hal_rx_msdu_link { struct hal_desc_header desc_hdr; struct ath12k_buffer_addr buf_addr_info; __le32 info0; __le32 pn[4]; struct hal_rx_msdu_details msdu_link[6]; } __packed; struct hal_rx_reo_queue_ext { struct hal_desc_header desc_hdr; __le32 rsvd; struct hal_rx_mpdu_link_ptr mpdu_link[15]; } __packed; /* hal_rx_reo_queue_ext * Consumer: REO * Producer: REO * * descriptor_header * Details about which module owns this struct. * * mpdu_link * Pointer to the next MPDU_link descriptor in the MPDU queue. */ enum hal_rx_reo_queue_pn_size { HAL_RX_REO_QUEUE_PN_SIZE_24, HAL_RX_REO_QUEUE_PN_SIZE_48, HAL_RX_REO_QUEUE_PN_SIZE_128, }; #define HAL_RX_REO_QUEUE_RX_QUEUE_NUMBER GENMASK(15, 0) #define HAL_RX_REO_QUEUE_INFO0_VLD BIT(0) #define HAL_RX_REO_QUEUE_INFO0_ASSOC_LNK_DESC_COUNTER GENMASK(2, 1) #define HAL_RX_REO_QUEUE_INFO0_DIS_DUP_DETECTION BIT(3) #define HAL_RX_REO_QUEUE_INFO0_SOFT_REORDER_EN BIT(4) #define HAL_RX_REO_QUEUE_INFO0_AC GENMASK(6, 5) #define HAL_RX_REO_QUEUE_INFO0_BAR BIT(7) #define HAL_RX_REO_QUEUE_INFO0_RETRY BIT(8) #define HAL_RX_REO_QUEUE_INFO0_CHECK_2K_MODE BIT(9) #define HAL_RX_REO_QUEUE_INFO0_OOR_MODE BIT(10) #define HAL_RX_REO_QUEUE_INFO0_BA_WINDOW_SIZE GENMASK(20, 11) #define HAL_RX_REO_QUEUE_INFO0_PN_CHECK BIT(21) #define HAL_RX_REO_QUEUE_INFO0_EVEN_PN BIT(22) #define HAL_RX_REO_QUEUE_INFO0_UNEVEN_PN BIT(23) #define HAL_RX_REO_QUEUE_INFO0_PN_HANDLE_ENABLE BIT(24) #define HAL_RX_REO_QUEUE_INFO0_PN_SIZE GENMASK(26, 25) #define HAL_RX_REO_QUEUE_INFO0_IGNORE_AMPDU_FLG BIT(27) #define HAL_RX_REO_QUEUE_INFO1_SVLD BIT(0) #define HAL_RX_REO_QUEUE_INFO1_SSN GENMASK(12, 1) #define HAL_RX_REO_QUEUE_INFO1_CURRENT_IDX GENMASK(22, 13) #define HAL_RX_REO_QUEUE_INFO1_SEQ_2K_ERR BIT(23) #define HAL_RX_REO_QUEUE_INFO1_PN_ERR BIT(24) #define HAL_RX_REO_QUEUE_INFO1_PN_VALID BIT(31) #define HAL_RX_REO_QUEUE_INFO2_MPDU_COUNT GENMASK(6, 0) #define HAL_RX_REO_QUEUE_INFO2_MSDU_COUNT (31, 7) #define HAL_RX_REO_QUEUE_INFO3_TIMEOUT_COUNT GENMASK(9, 4) #define HAL_RX_REO_QUEUE_INFO3_FWD_DUE_TO_BAR_CNT GENMASK(15, 10) #define HAL_RX_REO_QUEUE_INFO3_DUPLICATE_COUNT GENMASK(31, 16) #define HAL_RX_REO_QUEUE_INFO4_FRAME_IN_ORD_COUNT GENMASK(23, 0) #define HAL_RX_REO_QUEUE_INFO4_BAR_RECVD_COUNT GENMASK(31, 24) #define HAL_RX_REO_QUEUE_INFO5_LATE_RX_MPDU_COUNT GENMASK(11, 0) #define HAL_RX_REO_QUEUE_INFO5_WINDOW_JUMP_2K GENMASK(15, 12) #define HAL_RX_REO_QUEUE_INFO5_HOLE_COUNT GENMASK(31, 16) struct hal_rx_reo_queue { struct hal_desc_header desc_hdr; __le32 rx_queue_num; __le32 info0; __le32 info1; __le32 pn[4]; __le32 last_rx_enqueue_timestamp; __le32 last_rx_dequeue_timestamp; __le32 next_aging_queue[2]; __le32 prev_aging_queue[2]; __le32 rx_bitmap[9]; __le32 info2; __le32 info3; __le32 info4; __le32 processed_mpdus; __le32 processed_msdus; __le32 processed_total_bytes; __le32 info5; __le32 rsvd[2]; struct hal_rx_reo_queue_ext ext_desc[]; } __packed; /* hal_rx_reo_queue * * descriptor_header * Details about which module owns this struct. Note that sub field * Buffer_type shall be set to receive_reo_queue_descriptor. * * receive_queue_number * Indicates the MPDU queue ID to which this MPDU link descriptor belongs. * * vld * Valid bit indicating a session is established and the queue descriptor * is valid. * associated_link_descriptor_counter * Indicates which of the 3 link descriptor counters shall be incremented * or decremented when link descriptors are added or removed from this * flow queue. * disable_duplicate_detection * When set, do not perform any duplicate detection. * soft_reorder_enable * When set, REO has been instructed to not perform the actual re-ordering * of frames for this queue, but just to insert the reorder opcodes. * ac * Indicates the access category of the queue descriptor. * bar * Indicates if BAR has been received. * retry * Retry bit is checked if this bit is set. * chk_2k_mode * Indicates what type of operation is expected from Reo when the received * frame SN falls within the 2K window. * oor_mode * Indicates what type of operation is expected when the received frame * falls within the OOR window. * ba_window_size * Indicates the negotiated (window size + 1). Max of 256 bits. * * A value 255 means 256 bitmap, 63 means 64 bitmap, 0 (means non-BA * session, with window size of 0). The 3 values here are the main values * validated, but other values should work as well. * * A BA window size of 0 (=> one frame entry bitmat), means that there is * no additional rx_reo_queue_ext desc. following rx_reo_queue in memory. * A BA window size of 1 - 105, means that there is 1 rx_reo_queue_ext. * A BA window size of 106 - 210, means that there are 2 rx_reo_queue_ext. * A BA window size of 211 - 256, means that there are 3 rx_reo_queue_ext. * pn_check_needed, pn_shall_be_even, pn_shall_be_uneven, pn_handling_enable, * pn_size * REO shall perform the PN increment check, even number check, uneven * number check, PN error check and size of the PN field check. * ignore_ampdu_flag * REO shall ignore the ampdu_flag on entrance descriptor for this queue. * * svld * Sequence number in next field is valid one. * ssn * Starting Sequence number of the session. * current_index * Points to last forwarded packet * seq_2k_error_detected_flag * REO has detected a 2k error jump in the sequence number and from that * moment forward, all new frames are forwarded directly to FW, without * duplicate detect, reordering, etc. * pn_error_detected_flag * REO has detected a PN error. */ #define HAL_REO_UPD_RX_QUEUE_INFO0_QUEUE_ADDR_HI GENMASK(7, 0) #define HAL_REO_UPD_RX_QUEUE_INFO0_UPD_RX_QUEUE_NUM BIT(8) #define HAL_REO_UPD_RX_QUEUE_INFO0_UPD_VLD BIT(9) #define HAL_REO_UPD_RX_QUEUE_INFO0_UPD_ASSOC_LNK_DESC_CNT BIT(10) #define HAL_REO_UPD_RX_QUEUE_INFO0_UPD_DIS_DUP_DETECTION BIT(11) #define HAL_REO_UPD_RX_QUEUE_INFO0_UPD_SOFT_REORDER_EN BIT(12) #define HAL_REO_UPD_RX_QUEUE_INFO0_UPD_AC BIT(13) #define HAL_REO_UPD_RX_QUEUE_INFO0_UPD_BAR BIT(14) #define HAL_REO_UPD_RX_QUEUE_INFO0_UPD_RETRY BIT(15) #define HAL_REO_UPD_RX_QUEUE_INFO0_UPD_CHECK_2K_MODE BIT(16) #define HAL_REO_UPD_RX_QUEUE_INFO0_UPD_OOR_MODE BIT(17) #define HAL_REO_UPD_RX_QUEUE_INFO0_UPD_BA_WINDOW_SIZE BIT(18) #define HAL_REO_UPD_RX_QUEUE_INFO0_UPD_PN_CHECK BIT(19) #define HAL_REO_UPD_RX_QUEUE_INFO0_UPD_EVEN_PN BIT(20) #define HAL_REO_UPD_RX_QUEUE_INFO0_UPD_UNEVEN_PN BIT(21) #define HAL_REO_UPD_RX_QUEUE_INFO0_UPD_PN_HANDLE_ENABLE BIT(22) #define HAL_REO_UPD_RX_QUEUE_INFO0_UPD_PN_SIZE BIT(23) #define HAL_REO_UPD_RX_QUEUE_INFO0_UPD_IGNORE_AMPDU_FLG BIT(24) #define HAL_REO_UPD_RX_QUEUE_INFO0_UPD_SVLD BIT(25) #define HAL_REO_UPD_RX_QUEUE_INFO0_UPD_SSN BIT(26) #define HAL_REO_UPD_RX_QUEUE_INFO0_UPD_SEQ_2K_ERR BIT(27) #define HAL_REO_UPD_RX_QUEUE_INFO0_UPD_PN_ERR BIT(28) #define HAL_REO_UPD_RX_QUEUE_INFO0_UPD_PN_VALID BIT(29) #define HAL_REO_UPD_RX_QUEUE_INFO0_UPD_PN BIT(30) #define HAL_REO_UPD_RX_QUEUE_INFO1_RX_QUEUE_NUMBER GENMASK(15, 0) #define HAL_REO_UPD_RX_QUEUE_INFO1_VLD BIT(16) #define HAL_REO_UPD_RX_QUEUE_INFO1_ASSOC_LNK_DESC_COUNTER GENMASK(18, 17) #define HAL_REO_UPD_RX_QUEUE_INFO1_DIS_DUP_DETECTION BIT(19) #define HAL_REO_UPD_RX_QUEUE_INFO1_SOFT_REORDER_EN BIT(20) #define HAL_REO_UPD_RX_QUEUE_INFO1_AC GENMASK(22, 21) #define HAL_REO_UPD_RX_QUEUE_INFO1_BAR BIT(23) #define HAL_REO_UPD_RX_QUEUE_INFO1_RETRY BIT(24) #define HAL_REO_UPD_RX_QUEUE_INFO1_CHECK_2K_MODE BIT(25) #define HAL_REO_UPD_RX_QUEUE_INFO1_OOR_MODE BIT(26) #define HAL_REO_UPD_RX_QUEUE_INFO1_PN_CHECK BIT(27) #define HAL_REO_UPD_RX_QUEUE_INFO1_EVEN_PN BIT(28) #define HAL_REO_UPD_RX_QUEUE_INFO1_UNEVEN_PN BIT(29) #define HAL_REO_UPD_RX_QUEUE_INFO1_PN_HANDLE_ENABLE BIT(30) #define HAL_REO_UPD_RX_QUEUE_INFO1_IGNORE_AMPDU_FLG BIT(31) #define HAL_REO_UPD_RX_QUEUE_INFO2_BA_WINDOW_SIZE GENMASK(7, 0) #define HAL_REO_UPD_RX_QUEUE_INFO2_PN_SIZE GENMASK(9, 8) #define HAL_REO_UPD_RX_QUEUE_INFO2_SVLD BIT(10) #define HAL_REO_UPD_RX_QUEUE_INFO2_SSN GENMASK(22, 11) #define HAL_REO_UPD_RX_QUEUE_INFO2_SEQ_2K_ERR BIT(23) #define HAL_REO_UPD_RX_QUEUE_INFO2_PN_ERR BIT(24) #define HAL_REO_UPD_RX_QUEUE_INFO2_PN_VALID BIT(25) struct hal_reo_update_rx_queue { struct hal_reo_cmd_hdr cmd; __le32 queue_addr_lo; __le32 info0; __le32 info1; __le32 info2; __le32 pn[4]; } __packed; #define HAL_REO_UNBLOCK_CACHE_INFO0_UNBLK_CACHE BIT(0) #define HAL_REO_UNBLOCK_CACHE_INFO0_RESOURCE_IDX GENMASK(2, 1) struct hal_reo_unblock_cache { struct hal_reo_cmd_hdr cmd; __le32 info0; __le32 rsvd[7]; } __packed; enum hal_reo_exec_status { HAL_REO_EXEC_STATUS_SUCCESS, HAL_REO_EXEC_STATUS_BLOCKED, HAL_REO_EXEC_STATUS_FAILED, HAL_REO_EXEC_STATUS_RESOURCE_BLOCKED, }; #define HAL_REO_STATUS_HDR_INFO0_STATUS_NUM GENMASK(15, 0) #define HAL_REO_STATUS_HDR_INFO0_EXEC_TIME GENMASK(25, 16) #define HAL_REO_STATUS_HDR_INFO0_EXEC_STATUS GENMASK(27, 26) struct hal_reo_status_hdr { __le32 info0; __le32 timestamp; } __packed; /* hal_reo_status_hdr * Producer: REO * Consumer: SW * * status_num * The value in this field is equal to value of the reo command * number. This field helps to correlate the statuses with the REO * commands. * * execution_time (in us) * The amount of time REO took to execute the command. Note that * this time does not include the duration of the command waiting * in the command ring, before the execution started. * * execution_status * Execution status of the command. Values are defined in * enum %HAL_REO_EXEC_STATUS_. */ #define HAL_REO_GET_QUEUE_STATS_STATUS_INFO0_SSN GENMASK(11, 0) #define HAL_REO_GET_QUEUE_STATS_STATUS_INFO0_CUR_IDX GENMASK(21, 12) #define HAL_REO_GET_QUEUE_STATS_STATUS_INFO1_MPDU_COUNT GENMASK(6, 0) #define HAL_REO_GET_QUEUE_STATS_STATUS_INFO1_MSDU_COUNT GENMASK(31, 7) #define HAL_REO_GET_QUEUE_STATS_STATUS_INFO2_WINDOW_JMP2K GENMASK(3, 0) #define HAL_REO_GET_QUEUE_STATS_STATUS_INFO2_TIMEOUT_COUNT GENMASK(9, 4) #define HAL_REO_GET_QUEUE_STATS_STATUS_INFO2_FDTB_COUNT GENMASK(15, 10) #define HAL_REO_GET_QUEUE_STATS_STATUS_INFO2_DUPLICATE_COUNT GENMASK(31, 16) #define HAL_REO_GET_QUEUE_STATS_STATUS_INFO3_FIO_COUNT GENMASK(23, 0) #define HAL_REO_GET_QUEUE_STATS_STATUS_INFO3_BAR_RCVD_CNT GENMASK(31, 24) #define HAL_REO_GET_QUEUE_STATS_STATUS_INFO4_LATE_RX_MPDU GENMASK(11, 0) #define HAL_REO_GET_QUEUE_STATS_STATUS_INFO4_HOLE_COUNT GENMASK(27, 12) #define HAL_REO_GET_QUEUE_STATS_STATUS_INFO5_LOOPING_CNT GENMASK(31, 28) struct hal_reo_get_queue_stats_status { struct hal_reo_status_hdr hdr; __le32 info0; __le32 pn[4]; __le32 last_rx_enqueue_timestamp; __le32 last_rx_dequeue_timestamp; __le32 rx_bitmap[9]; __le32 info1; __le32 info2; __le32 info3; __le32 num_mpdu_frames; __le32 num_msdu_frames; __le32 total_bytes; __le32 info4; __le32 info5; } __packed; /* hal_reo_get_queue_stats_status * Producer: REO * Consumer: SW * * status_hdr * Details that can link this status with the original command. It * also contains info on how long REO took to execute this command. * * ssn * Starting Sequence number of the session, this changes whenever * window moves (can be filled by SW then maintained by REO). * * current_index * Points to last forwarded packet. * * pn * Bits of the PN number. * * last_rx_enqueue_timestamp * last_rx_dequeue_timestamp * Timestamp of arrival of the last MPDU for this queue and * Timestamp of forwarding an MPDU accordingly. * * rx_bitmap * When a bit is set, the corresponding frame is currently held * in the re-order queue. The bitmap is Fully managed by HW. * * current_mpdu_count * current_msdu_count * The number of MPDUs and MSDUs in the queue. * * timeout_count * The number of times REO started forwarding frames even though * there is a hole in the bitmap. Forwarding reason is timeout. * * forward_due_to_bar_count * The number of times REO started forwarding frames even though * there is a hole in the bitmap. Fwd reason is reception of BAR. * * duplicate_count * The number of duplicate frames that have been detected. * * frames_in_order_count * The number of frames that have been received in order (without * a hole that prevented them from being forwarded immediately). * * bar_received_count * The number of times a BAR frame is received. * * mpdu_frames_processed_count * msdu_frames_processed_count * The total number of MPDU/MSDU frames that have been processed. * * total_bytes * An approximation of the number of bytes received for this queue. * * late_receive_mpdu_count * The number of MPDUs received after the window had already moved * on. The 'late' sequence window is defined as * (Window SSN - 256) - (Window SSN - 1). * * window_jump_2k * The number of times the window moved more than 2K * * hole_count * The number of times a hole was created in the receive bitmap. * * looping_count * A count value that indicates the number of times the producer of * entries into this Ring has looped around the ring. */ #define HAL_REO_STATUS_LOOP_CNT GENMASK(31, 28) #define HAL_REO_FLUSH_QUEUE_INFO0_ERR_DETECTED BIT(0) #define HAL_REO_FLUSH_QUEUE_INFO0_RSVD GENMASK(31, 1) #define HAL_REO_FLUSH_QUEUE_INFO1_RSVD GENMASK(27, 0) struct hal_reo_flush_queue_status { struct hal_reo_status_hdr hdr; __le32 info0; __le32 rsvd0[21]; __le32 info1; } __packed; /* hal_reo_flush_queue_status * Producer: REO * Consumer: SW * * status_hdr * Details that can link this status with the original command. It * also contains info on how long REO took to execute this command. * * error_detected * Status of blocking resource * * 0 - No error has been detected while executing this command * 1 - Error detected. The resource to be used for blocking was * already in use. * * looping_count * A count value that indicates the number of times the producer of * entries into this Ring has looped around the ring. */ #define HAL_REO_FLUSH_CACHE_STATUS_INFO0_IS_ERR BIT(0) #define HAL_REO_FLUSH_CACHE_STATUS_INFO0_BLOCK_ERR_CODE GENMASK(2, 1) #define HAL_REO_FLUSH_CACHE_STATUS_INFO0_FLUSH_STATUS_HIT BIT(8) #define HAL_REO_FLUSH_CACHE_STATUS_INFO0_FLUSH_DESC_TYPE GENMASK(11, 9) #define HAL_REO_FLUSH_CACHE_STATUS_INFO0_FLUSH_CLIENT_ID GENMASK(15, 12) #define HAL_REO_FLUSH_CACHE_STATUS_INFO0_FLUSH_ERR GENMASK(17, 16) #define HAL_REO_FLUSH_CACHE_STATUS_INFO0_FLUSH_COUNT GENMASK(25, 18) struct hal_reo_flush_cache_status { struct hal_reo_status_hdr hdr; __le32 info0; __le32 rsvd0[21]; __le32 info1; } __packed; /* hal_reo_flush_cache_status * Producer: REO * Consumer: SW * * status_hdr * Details that can link this status with the original command. It * also contains info on how long REO took to execute this command. * * error_detected * Status for blocking resource handling * * 0 - No error has been detected while executing this command * 1 - An error in the blocking resource management was detected * * block_error_details * only valid when error_detected is set * * 0 - No blocking related errors found * 1 - Blocking resource is already in use * 2 - Resource requested to be unblocked, was not blocked * * cache_controller_flush_status_hit * The status that the cache controller returned on executing the * flush command. * * 0 - miss; 1 - hit * * cache_controller_flush_status_desc_type * Flush descriptor type * * cache_controller_flush_status_client_id * Module who made the flush request * * In REO, this is always 0 * * cache_controller_flush_status_error * Error condition * * 0 - No error found * 1 - HW interface is still busy * 2 - Line currently locked. Used for one line flush command * 3 - At least one line is still locked. * Used for cache flush command. * * cache_controller_flush_count * The number of lines that were actually flushed out * * looping_count * A count value that indicates the number of times the producer of * entries into this Ring has looped around the ring. */ #define HAL_REO_UNBLOCK_CACHE_STATUS_INFO0_IS_ERR BIT(0) #define HAL_REO_UNBLOCK_CACHE_STATUS_INFO0_TYPE BIT(1) struct hal_reo_unblock_cache_status { struct hal_reo_status_hdr hdr; __le32 info0; __le32 rsvd0[21]; __le32 info1; } __packed; /* hal_reo_unblock_cache_status * Producer: REO * Consumer: SW * * status_hdr * Details that can link this status with the original command. It * also contains info on how long REO took to execute this command. * * error_detected * 0 - No error has been detected while executing this command * 1 - The blocking resource was not in use, and therefore it could * not be unblocked. * * unblock_type * Reference to the type of unblock command * 0 - Unblock a blocking resource * 1 - The entire cache usage is unblock * * looping_count * A count value that indicates the number of times the producer of * entries into this Ring has looped around the ring. */ #define HAL_REO_FLUSH_TIMEOUT_STATUS_INFO0_IS_ERR BIT(0) #define HAL_REO_FLUSH_TIMEOUT_STATUS_INFO0_LIST_EMPTY BIT(1) #define HAL_REO_FLUSH_TIMEOUT_STATUS_INFO1_REL_DESC_COUNT GENMASK(15, 0) #define HAL_REO_FLUSH_TIMEOUT_STATUS_INFO1_FWD_BUF_COUNT GENMASK(31, 16) struct hal_reo_flush_timeout_list_status { struct hal_reo_status_hdr hdr; __le32 info0; __le32 info1; __le32 rsvd0[20]; __le32 info2; } __packed; /* hal_reo_flush_timeout_list_status * Producer: REO * Consumer: SW * * status_hdr * Details that can link this status with the original command. It * also contains info on how long REO took to execute this command. * * error_detected * 0 - No error has been detected while executing this command * 1 - Command not properly executed and returned with error * * timeout_list_empty * When set, REO has depleted the timeout list and all entries are * gone. * * release_desc_count * Producer: SW; Consumer: REO * The number of link descriptor released * * forward_buf_count * Producer: SW; Consumer: REO * The number of buffers forwarded to the REO destination rings * * looping_count * A count value that indicates the number of times the producer of * entries into this Ring has looped around the ring. */ #define HAL_REO_DESC_THRESH_STATUS_INFO0_THRESH_INDEX GENMASK(1, 0) #define HAL_REO_DESC_THRESH_STATUS_INFO1_LINK_DESC_COUNTER0 GENMASK(23, 0) #define HAL_REO_DESC_THRESH_STATUS_INFO2_LINK_DESC_COUNTER1 GENMASK(23, 0) #define HAL_REO_DESC_THRESH_STATUS_INFO3_LINK_DESC_COUNTER2 GENMASK(23, 0) #define HAL_REO_DESC_THRESH_STATUS_INFO4_LINK_DESC_COUNTER_SUM GENMASK(25, 0) struct hal_reo_desc_thresh_reached_status { struct hal_reo_status_hdr hdr; __le32 info0; __le32 info1; __le32 info2; __le32 info3; __le32 info4; __le32 rsvd0[17]; __le32 info5; } __packed; /* hal_reo_desc_thresh_reached_status * Producer: REO * Consumer: SW * * status_hdr * Details that can link this status with the original command. It * also contains info on how long REO took to execute this command. * * threshold_index * The index of the threshold register whose value got reached * * link_descriptor_counter0 * link_descriptor_counter1 * link_descriptor_counter2 * link_descriptor_counter_sum * Value of the respective counters at generation of this message * * looping_count * A count value that indicates the number of times the producer of * entries into this Ring has looped around the ring. */ #define HAL_TCL_ENTRANCE_FROM_PPE_RING_INFO0_DATA_LENGTH GENMASK(13, 0) #define HAL_TCL_ENTRANCE_FROM_PPE_RING_INFO0_L4_CSUM_STATUS BIT(14) #define HAL_TCL_ENTRANCE_FROM_PPE_RING_INFO0_L3_CSUM_STATUS BIT(15) #define HAL_TCL_ENTRANCE_FROM_PPE_RING_INFO0_PID GENMASK(27, 24) #define HAL_TCL_ENTRANCE_FROM_PPE_RING_INFO0_QDISC BIT(28) #define HAL_TCL_ENTRANCE_FROM_PPE_RING_INFO0_MULTICAST BIT(29) #define HAL_TCL_ENTRANCE_FROM_PPE_RING_INFO0_MORE BIT(30) #define HAL_TCL_ENTRANCE_FROM_PPE_RING_INFO0_VALID_TOGGLE BIT(31) struct hal_tcl_entrance_from_ppe_ring { __le32 buffer_addr; __le32 info0; } __packed; struct hal_mon_buf_ring { __le32 paddr_lo; __le32 paddr_hi; __le64 cookie; }; /* hal_mon_buf_ring * Producer : SW * Consumer : Monitor * * paddr_lo * Lower 32-bit physical address of the buffer pointer from the source ring. * paddr_hi * bit range 7-0 : upper 8 bit of the physical address. * bit range 31-8 : reserved. * cookie * Consumer: RxMon/TxMon 64 bit cookie of the buffers. */ #define HAL_MON_DEST_COOKIE_BUF_ID GENMASK(17, 0) #define HAL_MON_DEST_INFO0_END_OFFSET GENMASK(15, 0) #define HAL_MON_DEST_INFO0_FLUSH_DETECTED BIT(16) #define HAL_MON_DEST_INFO0_END_OF_PPDU BIT(17) #define HAL_MON_DEST_INFO0_INITIATOR BIT(18) #define HAL_MON_DEST_INFO0_EMPTY_DESC BIT(19) #define HAL_MON_DEST_INFO0_RING_ID GENMASK(27, 20) #define HAL_MON_DEST_INFO0_LOOPING_COUNT GENMASK(31, 28) struct hal_mon_dest_desc { __le32 cookie; __le32 reserved; __le32 ppdu_id; __le32 info0; }; /* hal_mon_dest_ring * Producer : TxMon/RxMon * Consumer : SW * cookie * bit 0 -17 buf_id to track the skb's vaddr. * ppdu_id * Phy ppdu_id * end_offset * The offset into status buffer where DMA ended, ie., offset to the last * TLV + last TLV size. * flush_detected * Indicates whether 'tx_flush' or 'rx_flush' occurred. * end_of_ppdu * Indicates end of ppdu. * pmac_id * Indicates PMAC that received from frame. * empty_descriptor * This descriptor is written on flush or end of ppdu or end of status * buffer. * ring_id * updated by SRNG. * looping_count * updated by SRNG. */ #endif /* ATH12K_HAL_DESC_H */
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