Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Kalle Valo | 5325 | 92.92% | 1 | 50.00% |
Manikanta Pubbisetty | 406 | 7.08% | 1 | 50.00% |
Total | 5731 | 2 |
// SPDX-License-Identifier: BSD-3-Clause-Clear /* * Copyright (c) 2018-2019 The Linux Foundation. All rights reserved. */ #include <linux/dma-mapping.h> #include "ahb.h" #include "hal_tx.h" #include "debug.h" #include "hal_desc.h" static const struct hal_srng_config hw_srng_config[] = { /* TODO: max_rings can populated by querying HW capabilities */ { /* REO_DST */ .start_ring_id = HAL_SRNG_RING_ID_REO2SW1, .max_rings = 4, .entry_size = sizeof(struct hal_reo_dest_ring) >> 2, .lmac_ring = false, .ring_dir = HAL_SRNG_DIR_DST, .reg_start = { HAL_SEQ_WCSS_UMAC_REO_REG + HAL_REO1_RING_BASE_LSB, HAL_SEQ_WCSS_UMAC_REO_REG + HAL_REO1_RING_HP, }, .reg_size = { HAL_REO2_RING_BASE_LSB - HAL_REO1_RING_BASE_LSB, HAL_REO2_RING_HP - HAL_REO1_RING_HP, }, .max_size = HAL_REO_REO2SW1_RING_BASE_MSB_RING_SIZE, }, { /* REO_EXCEPTION */ /* Designating REO2TCL ring as exception ring. This ring is * similar to other REO2SW rings though it is named as REO2TCL. * Any of theREO2SW rings can be used as exception ring. */ .start_ring_id = HAL_SRNG_RING_ID_REO2TCL, .max_rings = 1, .entry_size = sizeof(struct hal_reo_dest_ring) >> 2, .lmac_ring = false, .ring_dir = HAL_SRNG_DIR_DST, .reg_start = { HAL_SEQ_WCSS_UMAC_REO_REG + HAL_REO_TCL_RING_BASE_LSB, HAL_SEQ_WCSS_UMAC_REO_REG + HAL_REO_TCL_RING_HP, }, .max_size = HAL_REO_REO2TCL_RING_BASE_MSB_RING_SIZE, }, { /* REO_REINJECT */ .start_ring_id = HAL_SRNG_RING_ID_SW2REO, .max_rings = 1, .entry_size = sizeof(struct hal_reo_entrance_ring) >> 2, .lmac_ring = false, .ring_dir = HAL_SRNG_DIR_SRC, .reg_start = { HAL_SEQ_WCSS_UMAC_REO_REG + HAL_SW2REO_RING_BASE_LSB, HAL_SEQ_WCSS_UMAC_REO_REG + HAL_SW2REO_RING_HP, }, .max_size = HAL_REO_SW2REO_RING_BASE_MSB_RING_SIZE, }, { /* REO_CMD */ .start_ring_id = HAL_SRNG_RING_ID_REO_CMD, .max_rings = 1, .entry_size = (sizeof(struct hal_tlv_hdr) + sizeof(struct hal_reo_get_queue_stats)) >> 2, .lmac_ring = false, .ring_dir = HAL_SRNG_DIR_SRC, .reg_start = { HAL_SEQ_WCSS_UMAC_REO_REG + HAL_REO_CMD_RING_BASE_LSB, HAL_SEQ_WCSS_UMAC_REO_REG + HAL_REO_CMD_HP, }, .max_size = HAL_REO_CMD_RING_BASE_MSB_RING_SIZE, }, { /* REO_STATUS */ .start_ring_id = HAL_SRNG_RING_ID_REO_STATUS, .max_rings = 1, .entry_size = (sizeof(struct hal_tlv_hdr) + sizeof(struct hal_reo_get_queue_stats_status)) >> 2, .lmac_ring = false, .ring_dir = HAL_SRNG_DIR_DST, .reg_start = { HAL_SEQ_WCSS_UMAC_REO_REG + HAL_REO_STATUS_RING_BASE_LSB, HAL_SEQ_WCSS_UMAC_REO_REG + HAL_REO_STATUS_HP, }, .max_size = HAL_REO_STATUS_RING_BASE_MSB_RING_SIZE, }, { /* TCL_DATA */ .start_ring_id = HAL_SRNG_RING_ID_SW2TCL1, .max_rings = 3, .entry_size = (sizeof(struct hal_tlv_hdr) + sizeof(struct hal_tcl_data_cmd)) >> 2, .lmac_ring = false, .ring_dir = HAL_SRNG_DIR_SRC, .reg_start = { HAL_SEQ_WCSS_UMAC_TCL_REG + HAL_TCL1_RING_BASE_LSB, HAL_SEQ_WCSS_UMAC_TCL_REG + HAL_TCL1_RING_HP, }, .reg_size = { HAL_TCL2_RING_BASE_LSB - HAL_TCL1_RING_BASE_LSB, HAL_TCL2_RING_HP - HAL_TCL1_RING_HP, }, .max_size = HAL_SW2TCL1_RING_BASE_MSB_RING_SIZE, }, { /* TCL_CMD */ .start_ring_id = HAL_SRNG_RING_ID_SW2TCL_CMD, .max_rings = 1, .entry_size = (sizeof(struct hal_tlv_hdr) + sizeof(struct hal_tcl_gse_cmd)) >> 2, .lmac_ring = false, .ring_dir = HAL_SRNG_DIR_SRC, .reg_start = { HAL_SEQ_WCSS_UMAC_TCL_REG + HAL_TCL_RING_BASE_LSB, HAL_SEQ_WCSS_UMAC_TCL_REG + HAL_TCL_RING_HP, }, .max_size = HAL_SW2TCL1_CMD_RING_BASE_MSB_RING_SIZE, }, { /* TCL_STATUS */ .start_ring_id = HAL_SRNG_RING_ID_TCL_STATUS, .max_rings = 1, .entry_size = (sizeof(struct hal_tlv_hdr) + sizeof(struct hal_tcl_status_ring)) >> 2, .lmac_ring = false, .ring_dir = HAL_SRNG_DIR_DST, .reg_start = { HAL_SEQ_WCSS_UMAC_TCL_REG + HAL_TCL_STATUS_RING_BASE_LSB, HAL_SEQ_WCSS_UMAC_TCL_REG + HAL_TCL_STATUS_RING_HP, }, .max_size = HAL_TCL_STATUS_RING_BASE_MSB_RING_SIZE, }, { /* CE_SRC */ .start_ring_id = HAL_SRNG_RING_ID_CE0_SRC, .max_rings = 12, .entry_size = sizeof(struct hal_ce_srng_src_desc) >> 2, .lmac_ring = false, .ring_dir = HAL_SRNG_DIR_SRC, .reg_start = { (HAL_SEQ_WCSS_UMAC_CE0_SRC_REG + HAL_CE_DST_RING_BASE_LSB), HAL_SEQ_WCSS_UMAC_CE0_SRC_REG + HAL_CE_DST_RING_HP, }, .reg_size = { (HAL_SEQ_WCSS_UMAC_CE1_SRC_REG - HAL_SEQ_WCSS_UMAC_CE0_SRC_REG), (HAL_SEQ_WCSS_UMAC_CE1_SRC_REG - HAL_SEQ_WCSS_UMAC_CE0_SRC_REG), }, .max_size = HAL_CE_SRC_RING_BASE_MSB_RING_SIZE, }, { /* CE_DST */ .start_ring_id = HAL_SRNG_RING_ID_CE0_DST, .max_rings = 12, .entry_size = sizeof(struct hal_ce_srng_dest_desc) >> 2, .lmac_ring = false, .ring_dir = HAL_SRNG_DIR_SRC, .reg_start = { (HAL_SEQ_WCSS_UMAC_CE0_DST_REG + HAL_CE_DST_RING_BASE_LSB), HAL_SEQ_WCSS_UMAC_CE0_DST_REG + HAL_CE_DST_RING_HP, }, .reg_size = { (HAL_SEQ_WCSS_UMAC_CE1_DST_REG - HAL_SEQ_WCSS_UMAC_CE0_DST_REG), (HAL_SEQ_WCSS_UMAC_CE1_DST_REG - HAL_SEQ_WCSS_UMAC_CE0_DST_REG), }, .max_size = HAL_CE_DST_RING_BASE_MSB_RING_SIZE, }, { /* CE_DST_STATUS */ .start_ring_id = HAL_SRNG_RING_ID_CE0_DST_STATUS, .max_rings = 12, .entry_size = sizeof(struct hal_ce_srng_dst_status_desc) >> 2, .lmac_ring = false, .ring_dir = HAL_SRNG_DIR_DST, .reg_start = { (HAL_SEQ_WCSS_UMAC_CE0_DST_REG + HAL_CE_DST_STATUS_RING_BASE_LSB), (HAL_SEQ_WCSS_UMAC_CE0_DST_REG + HAL_CE_DST_STATUS_RING_HP), }, .reg_size = { (HAL_SEQ_WCSS_UMAC_CE1_DST_REG - HAL_SEQ_WCSS_UMAC_CE0_DST_REG), (HAL_SEQ_WCSS_UMAC_CE1_DST_REG - HAL_SEQ_WCSS_UMAC_CE0_DST_REG), }, .max_size = HAL_CE_DST_STATUS_RING_BASE_MSB_RING_SIZE, }, { /* WBM_IDLE_LINK */ .start_ring_id = HAL_SRNG_RING_ID_WBM_IDLE_LINK, .max_rings = 1, .entry_size = sizeof(struct hal_wbm_link_desc) >> 2, .lmac_ring = false, .ring_dir = HAL_SRNG_DIR_SRC, .reg_start = { (HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM_IDLE_LINK_RING_BASE_LSB), (HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM_IDLE_LINK_RING_HP), }, .max_size = HAL_WBM_IDLE_LINK_RING_BASE_MSB_RING_SIZE, }, { /* SW2WBM_RELEASE */ .start_ring_id = HAL_SRNG_RING_ID_WBM_SW_RELEASE, .max_rings = 1, .entry_size = sizeof(struct hal_wbm_release_ring) >> 2, .lmac_ring = false, .ring_dir = HAL_SRNG_DIR_SRC, .reg_start = { (HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM_RELEASE_RING_BASE_LSB), (HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM_RELEASE_RING_HP), }, .max_size = HAL_SW2WBM_RELEASE_RING_BASE_MSB_RING_SIZE, }, { /* WBM2SW_RELEASE */ .start_ring_id = HAL_SRNG_RING_ID_WBM2SW0_RELEASE, .max_rings = 4, .entry_size = sizeof(struct hal_wbm_release_ring) >> 2, .lmac_ring = false, .ring_dir = HAL_SRNG_DIR_DST, .reg_start = { (HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM0_RELEASE_RING_BASE_LSB), (HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM0_RELEASE_RING_HP), }, .reg_size = { (HAL_WBM1_RELEASE_RING_BASE_LSB - HAL_WBM0_RELEASE_RING_BASE_LSB), (HAL_WBM1_RELEASE_RING_HP - HAL_WBM0_RELEASE_RING_HP), }, .max_size = HAL_WBM2SW_RELEASE_RING_BASE_MSB_RING_SIZE, }, { /* RXDMA_BUF */ .start_ring_id = HAL_SRNG_RING_ID_WMAC1_SW2RXDMA0_BUF, .max_rings = 2, .entry_size = sizeof(struct hal_wbm_buffer_ring) >> 2, .lmac_ring = true, .ring_dir = HAL_SRNG_DIR_SRC, .max_size = HAL_RXDMA_RING_MAX_SIZE, }, { /* RXDMA_DST */ .start_ring_id = HAL_SRNG_RING_ID_WMAC1_RXDMA2SW0, .max_rings = 1, .entry_size = sizeof(struct hal_reo_entrance_ring) >> 2, .lmac_ring = true, .ring_dir = HAL_SRNG_DIR_DST, .max_size = HAL_RXDMA_RING_MAX_SIZE, }, { /* RXDMA_MONITOR_BUF */ .start_ring_id = HAL_SRNG_RING_ID_WMAC1_SW2RXDMA2_BUF, .max_rings = 1, .entry_size = sizeof(struct hal_wbm_buffer_ring) >> 2, .lmac_ring = true, .ring_dir = HAL_SRNG_DIR_SRC, .max_size = HAL_RXDMA_RING_MAX_SIZE, }, { /* RXDMA_MONITOR_STATUS */ .start_ring_id = HAL_SRNG_RING_ID_WMAC1_SW2RXDMA1_STATBUF, .max_rings = 1, .entry_size = sizeof(struct hal_wbm_buffer_ring) >> 2, .lmac_ring = true, .ring_dir = HAL_SRNG_DIR_SRC, .max_size = HAL_RXDMA_RING_MAX_SIZE, }, { /* RXDMA_MONITOR_DST */ .start_ring_id = HAL_SRNG_RING_ID_WMAC1_RXDMA2SW1, .max_rings = 1, .entry_size = sizeof(struct hal_reo_entrance_ring) >> 2, .lmac_ring = true, .ring_dir = HAL_SRNG_DIR_DST, .max_size = HAL_RXDMA_RING_MAX_SIZE, }, { /* RXDMA_MONITOR_DESC */ .start_ring_id = HAL_SRNG_RING_ID_WMAC1_SW2RXDMA1_DESC, .max_rings = 1, .entry_size = sizeof(struct hal_wbm_buffer_ring) >> 2, .lmac_ring = true, .ring_dir = HAL_SRNG_DIR_SRC, .max_size = HAL_RXDMA_RING_MAX_SIZE, }, { /* RXDMA DIR BUF */ .start_ring_id = HAL_SRNG_RING_ID_RXDMA_DIR_BUF, .max_rings = 1, .entry_size = 8 >> 2, /* TODO: Define the struct */ .lmac_ring = true, .ring_dir = HAL_SRNG_DIR_SRC, .max_size = HAL_RXDMA_RING_MAX_SIZE, }, }; static int ath11k_hal_alloc_cont_rdp(struct ath11k_base *ab) { struct ath11k_hal *hal = &ab->hal; size_t size; size = sizeof(u32) * HAL_SRNG_RING_ID_MAX; hal->rdp.vaddr = dma_alloc_coherent(ab->dev, size, &hal->rdp.paddr, GFP_KERNEL); if (!hal->rdp.vaddr) return -ENOMEM; return 0; } static void ath11k_hal_free_cont_rdp(struct ath11k_base *ab) { struct ath11k_hal *hal = &ab->hal; size_t size; if (!hal->rdp.vaddr) return; size = sizeof(u32) * HAL_SRNG_RING_ID_MAX; dma_free_coherent(ab->dev, size, hal->rdp.vaddr, hal->rdp.paddr); hal->rdp.vaddr = NULL; } static int ath11k_hal_alloc_cont_wrp(struct ath11k_base *ab) { struct ath11k_hal *hal = &ab->hal; size_t size; size = sizeof(u32) * HAL_SRNG_NUM_LMAC_RINGS; hal->wrp.vaddr = dma_alloc_coherent(ab->dev, size, &hal->wrp.paddr, GFP_KERNEL); if (!hal->wrp.vaddr) return -ENOMEM; return 0; } static void ath11k_hal_free_cont_wrp(struct ath11k_base *ab) { struct ath11k_hal *hal = &ab->hal; size_t size; if (!hal->wrp.vaddr) return; size = sizeof(u32) * HAL_SRNG_NUM_LMAC_RINGS; dma_free_coherent(ab->dev, size, hal->wrp.vaddr, hal->wrp.paddr); hal->wrp.vaddr = NULL; } static void ath11k_hal_ce_dst_setup(struct ath11k_base *ab, struct hal_srng *srng, int ring_num) { const struct hal_srng_config *srng_config = &hw_srng_config[HAL_CE_DST]; u32 addr; u32 val; addr = HAL_CE_DST_RING_CTRL + srng_config->reg_start[HAL_SRNG_REG_GRP_R0] + ring_num * srng_config->reg_size[HAL_SRNG_REG_GRP_R0]; val = ath11k_ahb_read32(ab, addr); val &= ~HAL_CE_DST_R0_DEST_CTRL_MAX_LEN; val |= FIELD_PREP(HAL_CE_DST_R0_DEST_CTRL_MAX_LEN, srng->u.dst_ring.max_buffer_length); ath11k_ahb_write32(ab, addr, val); } static void ath11k_hal_srng_dst_hw_init(struct ath11k_base *ab, struct hal_srng *srng) { struct ath11k_hal *hal = &ab->hal; u32 val; u64 hp_addr; u32 reg_base; reg_base = srng->hwreg_base[HAL_SRNG_REG_GRP_R0]; if (srng->flags & HAL_SRNG_FLAGS_MSI_INTR) { ath11k_ahb_write32(ab, reg_base + HAL_REO1_RING_MSI1_BASE_LSB_OFFSET, (u32)srng->msi_addr); val = FIELD_PREP(HAL_REO1_RING_MSI1_BASE_MSB_ADDR, ((u64)srng->msi_addr >> HAL_ADDR_MSB_REG_SHIFT)) | HAL_REO1_RING_MSI1_BASE_MSB_MSI1_ENABLE; ath11k_ahb_write32(ab, reg_base + HAL_REO1_RING_MSI1_BASE_MSB_OFFSET, val); ath11k_ahb_write32(ab, reg_base + HAL_REO1_RING_MSI1_DATA_OFFSET, srng->msi_data); } ath11k_ahb_write32(ab, reg_base, (u32)srng->ring_base_paddr); val = FIELD_PREP(HAL_REO1_RING_BASE_MSB_RING_BASE_ADDR_MSB, ((u64)srng->ring_base_paddr >> HAL_ADDR_MSB_REG_SHIFT)) | FIELD_PREP(HAL_REO1_RING_BASE_MSB_RING_SIZE, (srng->entry_size * srng->num_entries)); ath11k_ahb_write32(ab, reg_base + HAL_REO1_RING_BASE_MSB_OFFSET, val); val = FIELD_PREP(HAL_REO1_RING_ID_RING_ID, srng->ring_id) | FIELD_PREP(HAL_REO1_RING_ID_ENTRY_SIZE, srng->entry_size); ath11k_ahb_write32(ab, reg_base + HAL_REO1_RING_ID_OFFSET, val); /* interrupt setup */ val = FIELD_PREP(HAL_REO1_RING_PRDR_INT_SETUP_INTR_TMR_THOLD, (srng->intr_timer_thres_us >> 3)); val |= FIELD_PREP(HAL_REO1_RING_PRDR_INT_SETUP_BATCH_COUNTER_THOLD, (srng->intr_batch_cntr_thres_entries * srng->entry_size)); ath11k_ahb_write32(ab, reg_base + HAL_REO1_RING_PRODUCER_INT_SETUP_OFFSET, val); hp_addr = hal->rdp.paddr + ((unsigned long)srng->u.dst_ring.hp_addr - (unsigned long)hal->rdp.vaddr); ath11k_ahb_write32(ab, reg_base + HAL_REO1_RING_HP_ADDR_LSB_OFFSET, hp_addr & HAL_ADDR_LSB_REG_MASK); ath11k_ahb_write32(ab, reg_base + HAL_REO1_RING_HP_ADDR_MSB_OFFSET, hp_addr >> HAL_ADDR_MSB_REG_SHIFT); /* Initialize head and tail pointers to indicate ring is empty */ reg_base = srng->hwreg_base[HAL_SRNG_REG_GRP_R2]; ath11k_ahb_write32(ab, reg_base, 0); ath11k_ahb_write32(ab, reg_base + HAL_REO1_RING_TP_OFFSET, 0); *srng->u.dst_ring.hp_addr = 0; reg_base = srng->hwreg_base[HAL_SRNG_REG_GRP_R0]; val = 0; if (srng->flags & HAL_SRNG_FLAGS_DATA_TLV_SWAP) val |= HAL_REO1_RING_MISC_DATA_TLV_SWAP; if (srng->flags & HAL_SRNG_FLAGS_RING_PTR_SWAP) val |= HAL_REO1_RING_MISC_HOST_FW_SWAP; if (srng->flags & HAL_SRNG_FLAGS_MSI_SWAP) val |= HAL_REO1_RING_MISC_MSI_SWAP; val |= HAL_REO1_RING_MISC_SRNG_ENABLE; ath11k_ahb_write32(ab, reg_base + HAL_REO1_RING_MISC_OFFSET, val); } static void ath11k_hal_srng_src_hw_init(struct ath11k_base *ab, struct hal_srng *srng) { struct ath11k_hal *hal = &ab->hal; u32 val; u64 tp_addr; u32 reg_base; reg_base = srng->hwreg_base[HAL_SRNG_REG_GRP_R0]; if (srng->flags & HAL_SRNG_FLAGS_MSI_INTR) { ath11k_ahb_write32(ab, reg_base + HAL_TCL1_RING_MSI1_BASE_LSB_OFFSET, (u32)srng->msi_addr); val = FIELD_PREP(HAL_TCL1_RING_MSI1_BASE_MSB_ADDR, ((u64)srng->msi_addr >> HAL_ADDR_MSB_REG_SHIFT)) | HAL_TCL1_RING_MSI1_BASE_MSB_MSI1_ENABLE; ath11k_ahb_write32(ab, reg_base + HAL_TCL1_RING_MSI1_BASE_MSB_OFFSET, val); ath11k_ahb_write32(ab, reg_base + HAL_TCL1_RING_MSI1_DATA_OFFSET, srng->msi_data); } ath11k_ahb_write32(ab, reg_base, (u32)srng->ring_base_paddr); val = FIELD_PREP(HAL_TCL1_RING_BASE_MSB_RING_BASE_ADDR_MSB, ((u64)srng->ring_base_paddr >> HAL_ADDR_MSB_REG_SHIFT)) | FIELD_PREP(HAL_TCL1_RING_BASE_MSB_RING_SIZE, (srng->entry_size * srng->num_entries)); ath11k_ahb_write32(ab, reg_base + HAL_TCL1_RING_BASE_MSB_OFFSET, val); val = FIELD_PREP(HAL_REO1_RING_ID_ENTRY_SIZE, srng->entry_size); ath11k_ahb_write32(ab, reg_base + HAL_TCL1_RING_ID_OFFSET, val); /* interrupt setup */ /* NOTE: IPQ8074 v2 requires the interrupt timer threshold in the * unit of 8 usecs instead of 1 usec (as required by v1). */ val = FIELD_PREP(HAL_TCL1_RING_CONSR_INT_SETUP_IX0_INTR_TMR_THOLD, srng->intr_timer_thres_us); val |= FIELD_PREP(HAL_TCL1_RING_CONSR_INT_SETUP_IX0_BATCH_COUNTER_THOLD, (srng->intr_batch_cntr_thres_entries * srng->entry_size)); ath11k_ahb_write32(ab, reg_base + HAL_TCL1_RING_CONSR_INT_SETUP_IX0_OFFSET, val); val = 0; if (srng->flags & HAL_SRNG_FLAGS_LOW_THRESH_INTR_EN) { val |= FIELD_PREP(HAL_TCL1_RING_CONSR_INT_SETUP_IX1_LOW_THOLD, srng->u.src_ring.low_threshold); } ath11k_ahb_write32(ab, reg_base + HAL_TCL1_RING_CONSR_INT_SETUP_IX1_OFFSET, val); if (srng->ring_id != HAL_SRNG_RING_ID_WBM_IDLE_LINK) { tp_addr = hal->rdp.paddr + ((unsigned long)srng->u.src_ring.tp_addr - (unsigned long)hal->rdp.vaddr); ath11k_ahb_write32(ab, reg_base + HAL_TCL1_RING_TP_ADDR_LSB_OFFSET, tp_addr & HAL_ADDR_LSB_REG_MASK); ath11k_ahb_write32(ab, reg_base + HAL_TCL1_RING_TP_ADDR_MSB_OFFSET, tp_addr >> HAL_ADDR_MSB_REG_SHIFT); } /* Initialize head and tail pointers to indicate ring is empty */ reg_base = srng->hwreg_base[HAL_SRNG_REG_GRP_R2]; ath11k_ahb_write32(ab, reg_base, 0); ath11k_ahb_write32(ab, reg_base + HAL_TCL1_RING_TP_OFFSET, 0); *srng->u.src_ring.tp_addr = 0; reg_base = srng->hwreg_base[HAL_SRNG_REG_GRP_R0]; val = 0; if (srng->flags & HAL_SRNG_FLAGS_DATA_TLV_SWAP) val |= HAL_TCL1_RING_MISC_DATA_TLV_SWAP; if (srng->flags & HAL_SRNG_FLAGS_RING_PTR_SWAP) val |= HAL_TCL1_RING_MISC_HOST_FW_SWAP; if (srng->flags & HAL_SRNG_FLAGS_MSI_SWAP) val |= HAL_TCL1_RING_MISC_MSI_SWAP; /* Loop count is not used for SRC rings */ val |= HAL_TCL1_RING_MISC_MSI_LOOPCNT_DISABLE; val |= HAL_TCL1_RING_MISC_SRNG_ENABLE; ath11k_ahb_write32(ab, reg_base + HAL_TCL1_RING_MISC_OFFSET, val); } static void ath11k_hal_srng_hw_init(struct ath11k_base *ab, struct hal_srng *srng) { if (srng->ring_dir == HAL_SRNG_DIR_SRC) ath11k_hal_srng_src_hw_init(ab, srng); else ath11k_hal_srng_dst_hw_init(ab, srng); } static int ath11k_hal_srng_get_ring_id(struct ath11k_base *ab, enum hal_ring_type type, int ring_num, int mac_id) { const struct hal_srng_config *srng_config = &hw_srng_config[type]; int ring_id; if (ring_num >= srng_config->max_rings) { ath11k_warn(ab, "invalid ring number :%d\n", ring_num); return -EINVAL; } ring_id = srng_config->start_ring_id + ring_num; if (srng_config->lmac_ring) ring_id += mac_id * HAL_SRNG_RINGS_PER_LMAC; if (WARN_ON(ring_id >= HAL_SRNG_RING_ID_MAX)) return -EINVAL; return ring_id; } int ath11k_hal_srng_get_entrysize(u32 ring_type) { const struct hal_srng_config *srng_config; if (WARN_ON(ring_type >= HAL_MAX_RING_TYPES)) return -EINVAL; srng_config = &hw_srng_config[ring_type]; return (srng_config->entry_size << 2); } int ath11k_hal_srng_get_max_entries(u32 ring_type) { const struct hal_srng_config *srng_config; if (WARN_ON(ring_type >= HAL_MAX_RING_TYPES)) return -EINVAL; srng_config = &hw_srng_config[ring_type]; return (srng_config->max_size / srng_config->entry_size); } void ath11k_hal_srng_get_params(struct ath11k_base *ab, struct hal_srng *srng, struct hal_srng_params *params) { params->ring_base_paddr = srng->ring_base_paddr; params->ring_base_vaddr = srng->ring_base_vaddr; params->num_entries = srng->num_entries; params->intr_timer_thres_us = srng->intr_timer_thres_us; params->intr_batch_cntr_thres_entries = srng->intr_batch_cntr_thres_entries; params->low_threshold = srng->u.src_ring.low_threshold; params->flags = srng->flags; } dma_addr_t ath11k_hal_srng_get_hp_addr(struct ath11k_base *ab, struct hal_srng *srng) { if (!(srng->flags & HAL_SRNG_FLAGS_LMAC_RING)) return 0; if (srng->ring_dir == HAL_SRNG_DIR_SRC) return ab->hal.wrp.paddr + ((unsigned long)srng->u.src_ring.hp_addr - (unsigned long)ab->hal.wrp.vaddr); else return ab->hal.rdp.paddr + ((unsigned long)srng->u.dst_ring.hp_addr - (unsigned long)ab->hal.rdp.vaddr); } dma_addr_t ath11k_hal_srng_get_tp_addr(struct ath11k_base *ab, struct hal_srng *srng) { if (!(srng->flags & HAL_SRNG_FLAGS_LMAC_RING)) return 0; if (srng->ring_dir == HAL_SRNG_DIR_SRC) return ab->hal.rdp.paddr + ((unsigned long)srng->u.src_ring.tp_addr - (unsigned long)ab->hal.rdp.vaddr); else return ab->hal.wrp.paddr + ((unsigned long)srng->u.dst_ring.tp_addr - (unsigned long)ab->hal.wrp.vaddr); } u32 ath11k_hal_ce_get_desc_size(enum hal_ce_desc type) { switch (type) { case HAL_CE_DESC_SRC: return sizeof(struct hal_ce_srng_src_desc); case HAL_CE_DESC_DST: return sizeof(struct hal_ce_srng_dest_desc); case HAL_CE_DESC_DST_STATUS: return sizeof(struct hal_ce_srng_dst_status_desc); } return 0; } void ath11k_hal_ce_src_set_desc(void *buf, dma_addr_t paddr, u32 len, u32 id, u8 byte_swap_data) { struct hal_ce_srng_src_desc *desc = (struct hal_ce_srng_src_desc *)buf; desc->buffer_addr_low = paddr & HAL_ADDR_LSB_REG_MASK; desc->buffer_addr_info = FIELD_PREP(HAL_CE_SRC_DESC_ADDR_INFO_ADDR_HI, ((u64)paddr >> HAL_ADDR_MSB_REG_SHIFT)) | FIELD_PREP(HAL_CE_SRC_DESC_ADDR_INFO_BYTE_SWAP, byte_swap_data) | FIELD_PREP(HAL_CE_SRC_DESC_ADDR_INFO_GATHER, 0) | FIELD_PREP(HAL_CE_SRC_DESC_ADDR_INFO_LEN, len); desc->meta_info = FIELD_PREP(HAL_CE_SRC_DESC_META_INFO_DATA, id); } void ath11k_hal_ce_dst_set_desc(void *buf, dma_addr_t paddr) { struct hal_ce_srng_dest_desc *desc = (struct hal_ce_srng_dest_desc *)buf; desc->buffer_addr_low = paddr & HAL_ADDR_LSB_REG_MASK; desc->buffer_addr_info = FIELD_PREP(HAL_CE_DEST_DESC_ADDR_INFO_ADDR_HI, ((u64)paddr >> HAL_ADDR_MSB_REG_SHIFT)); } u32 ath11k_hal_ce_dst_status_get_length(void *buf) { struct hal_ce_srng_dst_status_desc *desc = (struct hal_ce_srng_dst_status_desc *)buf; u32 len; len = FIELD_GET(HAL_CE_DST_STATUS_DESC_FLAGS_LEN, desc->flags); desc->flags &= ~HAL_CE_DST_STATUS_DESC_FLAGS_LEN; return len; } void ath11k_hal_set_link_desc_addr(struct hal_wbm_link_desc *desc, u32 cookie, dma_addr_t paddr) { desc->buf_addr_info.info0 = FIELD_PREP(BUFFER_ADDR_INFO0_ADDR, (paddr & HAL_ADDR_LSB_REG_MASK)); desc->buf_addr_info.info1 = FIELD_PREP(BUFFER_ADDR_INFO1_ADDR, ((u64)paddr >> HAL_ADDR_MSB_REG_SHIFT)) | FIELD_PREP(BUFFER_ADDR_INFO1_RET_BUF_MGR, 1) | FIELD_PREP(BUFFER_ADDR_INFO1_SW_COOKIE, cookie); } u32 *ath11k_hal_srng_dst_peek(struct ath11k_base *ab, struct hal_srng *srng) { lockdep_assert_held(&srng->lock); if (srng->u.dst_ring.tp != srng->u.dst_ring.cached_hp) return (srng->ring_base_vaddr + srng->u.dst_ring.tp); return NULL; } u32 *ath11k_hal_srng_dst_get_next_entry(struct ath11k_base *ab, struct hal_srng *srng) { u32 *desc; lockdep_assert_held(&srng->lock); if (srng->u.dst_ring.tp == srng->u.dst_ring.cached_hp) return NULL; desc = srng->ring_base_vaddr + srng->u.dst_ring.tp; srng->u.dst_ring.tp = (srng->u.dst_ring.tp + srng->entry_size) % srng->ring_size; return desc; } int ath11k_hal_srng_dst_num_free(struct ath11k_base *ab, struct hal_srng *srng, bool sync_hw_ptr) { u32 tp, hp; lockdep_assert_held(&srng->lock); tp = srng->u.dst_ring.tp; if (sync_hw_ptr) { hp = *srng->u.dst_ring.hp_addr; srng->u.dst_ring.cached_hp = hp; } else { hp = srng->u.dst_ring.cached_hp; } if (hp >= tp) return (hp - tp) / srng->entry_size; else return (srng->ring_size - tp + hp) / srng->entry_size; } /* Returns number of available entries in src ring */ int ath11k_hal_srng_src_num_free(struct ath11k_base *ab, struct hal_srng *srng, bool sync_hw_ptr) { u32 tp, hp; lockdep_assert_held(&srng->lock); hp = srng->u.src_ring.hp; if (sync_hw_ptr) { tp = *srng->u.src_ring.tp_addr; srng->u.src_ring.cached_tp = tp; } else { tp = srng->u.src_ring.cached_tp; } if (tp > hp) return ((tp - hp) / srng->entry_size) - 1; else return ((srng->ring_size - hp + tp) / srng->entry_size) - 1; } u32 *ath11k_hal_srng_src_get_next_entry(struct ath11k_base *ab, struct hal_srng *srng) { u32 *desc; u32 next_hp; lockdep_assert_held(&srng->lock); /* TODO: Using % is expensive, but we have to do this since size of some * SRNG rings is not power of 2 (due to descriptor sizes). Need to see * if separate function is defined for rings having power of 2 ring size * (TCL2SW, REO2SW, SW2RXDMA and CE rings) so that we can avoid the * overhead of % by using mask (with &). */ next_hp = (srng->u.src_ring.hp + srng->entry_size) % srng->ring_size; if (next_hp == srng->u.src_ring.cached_tp) return NULL; desc = srng->ring_base_vaddr + srng->u.src_ring.hp; srng->u.src_ring.hp = next_hp; /* TODO: Reap functionality is not used by all rings. If particular * ring does not use reap functionality, we need not update reap_hp * with next_hp pointer. Need to make sure a separate function is used * before doing any optimization by removing below code updating * reap_hp. */ srng->u.src_ring.reap_hp = next_hp; return desc; } u32 *ath11k_hal_srng_src_reap_next(struct ath11k_base *ab, struct hal_srng *srng) { u32 *desc; u32 next_reap_hp; lockdep_assert_held(&srng->lock); next_reap_hp = (srng->u.src_ring.reap_hp + srng->entry_size) % srng->ring_size; if (next_reap_hp == srng->u.src_ring.cached_tp) return NULL; desc = srng->ring_base_vaddr + next_reap_hp; srng->u.src_ring.reap_hp = next_reap_hp; return desc; } u32 *ath11k_hal_srng_src_get_next_reaped(struct ath11k_base *ab, struct hal_srng *srng) { u32 *desc; lockdep_assert_held(&srng->lock); if (srng->u.src_ring.hp == srng->u.src_ring.reap_hp) return NULL; desc = srng->ring_base_vaddr + srng->u.src_ring.hp; srng->u.src_ring.hp = (srng->u.src_ring.hp + srng->entry_size) % srng->ring_size; return desc; } u32 *ath11k_hal_srng_src_peek(struct ath11k_base *ab, struct hal_srng *srng) { lockdep_assert_held(&srng->lock); if (((srng->u.src_ring.hp + srng->entry_size) % srng->ring_size) == srng->u.src_ring.cached_tp) return NULL; return srng->ring_base_vaddr + srng->u.src_ring.hp; } void ath11k_hal_srng_access_begin(struct ath11k_base *ab, struct hal_srng *srng) { lockdep_assert_held(&srng->lock); if (srng->ring_dir == HAL_SRNG_DIR_SRC) srng->u.src_ring.cached_tp = *(volatile u32 *)srng->u.src_ring.tp_addr; else srng->u.dst_ring.cached_hp = *srng->u.dst_ring.hp_addr; } /* Update cached ring head/tail pointers to HW. ath11k_hal_srng_access_begin() * should have been called before this. */ void ath11k_hal_srng_access_end(struct ath11k_base *ab, struct hal_srng *srng) { lockdep_assert_held(&srng->lock); /* TODO: See if we need a write memory barrier here */ if (srng->flags & HAL_SRNG_FLAGS_LMAC_RING) { /* For LMAC rings, ring pointer updates are done through FW and * hence written to a shared memory location that is read by FW */ if (srng->ring_dir == HAL_SRNG_DIR_SRC) { srng->u.src_ring.last_tp = *(volatile u32 *)srng->u.src_ring.tp_addr; *srng->u.src_ring.hp_addr = srng->u.src_ring.hp; } else { srng->u.dst_ring.last_hp = *srng->u.dst_ring.hp_addr; *srng->u.dst_ring.tp_addr = srng->u.dst_ring.tp; } } else { if (srng->ring_dir == HAL_SRNG_DIR_SRC) { srng->u.src_ring.last_tp = *(volatile u32 *)srng->u.src_ring.tp_addr; ath11k_ahb_write32(ab, (unsigned long)srng->u.src_ring.hp_addr - (unsigned long)ab->mem, srng->u.src_ring.hp); } else { srng->u.dst_ring.last_hp = *srng->u.dst_ring.hp_addr; ath11k_ahb_write32(ab, (unsigned long)srng->u.dst_ring.tp_addr - (unsigned long)ab->mem, srng->u.dst_ring.tp); } } srng->timestamp = jiffies; } void ath11k_hal_setup_link_idle_list(struct ath11k_base *ab, struct hal_wbm_idle_scatter_list *sbuf, u32 nsbufs, u32 tot_link_desc, u32 end_offset) { struct ath11k_buffer_addr *link_addr; int i; u32 reg_scatter_buf_sz = HAL_WBM_IDLE_SCATTER_BUF_SIZE / 64; link_addr = (void *)sbuf[0].vaddr + HAL_WBM_IDLE_SCATTER_BUF_SIZE; for (i = 1; i < nsbufs; i++) { link_addr->info0 = sbuf[i].paddr & HAL_ADDR_LSB_REG_MASK; link_addr->info1 = FIELD_PREP( HAL_WBM_SCATTERED_DESC_MSB_BASE_ADDR_39_32, (u64)sbuf[i].paddr >> HAL_ADDR_MSB_REG_SHIFT) | FIELD_PREP( HAL_WBM_SCATTERED_DESC_MSB_BASE_ADDR_MATCH_TAG, BASE_ADDR_MATCH_TAG_VAL); link_addr = (void *)sbuf[i].vaddr + HAL_WBM_IDLE_SCATTER_BUF_SIZE; } ath11k_ahb_write32(ab, HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM_R0_IDLE_LIST_CONTROL_ADDR, FIELD_PREP(HAL_WBM_SCATTER_BUFFER_SIZE, reg_scatter_buf_sz) | FIELD_PREP(HAL_WBM_LINK_DESC_IDLE_LIST_MODE, 0x1)); ath11k_ahb_write32(ab, HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM_R0_IDLE_LIST_SIZE_ADDR, FIELD_PREP(HAL_WBM_SCATTER_RING_SIZE_OF_IDLE_LINK_DESC_LIST, reg_scatter_buf_sz * nsbufs)); ath11k_ahb_write32(ab, HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM_SCATTERED_RING_BASE_LSB, FIELD_PREP(BUFFER_ADDR_INFO0_ADDR, sbuf[0].paddr & HAL_ADDR_LSB_REG_MASK)); ath11k_ahb_write32(ab, HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM_SCATTERED_RING_BASE_MSB, FIELD_PREP( HAL_WBM_SCATTERED_DESC_MSB_BASE_ADDR_39_32, (u64)sbuf[0].paddr >> HAL_ADDR_MSB_REG_SHIFT) | FIELD_PREP( HAL_WBM_SCATTERED_DESC_MSB_BASE_ADDR_MATCH_TAG, BASE_ADDR_MATCH_TAG_VAL)); /* Setup head and tail pointers for the idle list */ ath11k_ahb_write32(ab, HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM_SCATTERED_DESC_PTR_HEAD_INFO_IX0, FIELD_PREP(BUFFER_ADDR_INFO0_ADDR, sbuf[nsbufs - 1].paddr)); ath11k_ahb_write32(ab, HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM_SCATTERED_DESC_PTR_HEAD_INFO_IX1, FIELD_PREP( HAL_WBM_SCATTERED_DESC_MSB_BASE_ADDR_39_32, ((u64)sbuf[nsbufs - 1].paddr >> HAL_ADDR_MSB_REG_SHIFT)) | FIELD_PREP(HAL_WBM_SCATTERED_DESC_HEAD_P_OFFSET_IX1, (end_offset >> 2))); ath11k_ahb_write32(ab, HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM_SCATTERED_DESC_PTR_HEAD_INFO_IX0, FIELD_PREP(BUFFER_ADDR_INFO0_ADDR, sbuf[0].paddr)); ath11k_ahb_write32(ab, HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM_SCATTERED_DESC_PTR_TAIL_INFO_IX0, FIELD_PREP(BUFFER_ADDR_INFO0_ADDR, sbuf[0].paddr)); ath11k_ahb_write32(ab, HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM_SCATTERED_DESC_PTR_TAIL_INFO_IX1, FIELD_PREP( HAL_WBM_SCATTERED_DESC_MSB_BASE_ADDR_39_32, ((u64)sbuf[0].paddr >> HAL_ADDR_MSB_REG_SHIFT)) | FIELD_PREP(HAL_WBM_SCATTERED_DESC_TAIL_P_OFFSET_IX1, 0)); ath11k_ahb_write32(ab, HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM_SCATTERED_DESC_PTR_HP_ADDR, 2 * tot_link_desc); /* Enable the SRNG */ ath11k_ahb_write32(ab, HAL_SEQ_WCSS_UMAC_WBM_REG + HAL_WBM_IDLE_LINK_RING_MISC_ADDR, 0x40); } int ath11k_hal_srng_setup(struct ath11k_base *ab, enum hal_ring_type type, int ring_num, int mac_id, struct hal_srng_params *params) { struct ath11k_hal *hal = &ab->hal; const struct hal_srng_config *srng_config = &hw_srng_config[type]; struct hal_srng *srng; int ring_id; u32 lmac_idx; int i; u32 reg_base; ring_id = ath11k_hal_srng_get_ring_id(ab, type, ring_num, mac_id); if (ring_id < 0) return ring_id; srng = &hal->srng_list[ring_id]; srng->ring_id = ring_id; srng->ring_dir = srng_config->ring_dir; srng->ring_base_paddr = params->ring_base_paddr; srng->ring_base_vaddr = params->ring_base_vaddr; srng->entry_size = srng_config->entry_size; srng->num_entries = params->num_entries; srng->ring_size = srng->entry_size * srng->num_entries; srng->intr_batch_cntr_thres_entries = params->intr_batch_cntr_thres_entries; srng->intr_timer_thres_us = params->intr_timer_thres_us; srng->flags = params->flags; srng->initialized = 1; spin_lock_init(&srng->lock); for (i = 0; i < HAL_SRNG_NUM_REG_GRP; i++) { srng->hwreg_base[i] = srng_config->reg_start[i] + (ring_num * srng_config->reg_size[i]); } memset(srng->ring_base_vaddr, 0, (srng->entry_size * srng->num_entries) << 2); /* TODO: Add comments on these swap configurations */ if (IS_ENABLED(CONFIG_CPU_BIG_ENDIAN)) srng->flags |= HAL_SRNG_FLAGS_MSI_SWAP | HAL_SRNG_FLAGS_DATA_TLV_SWAP | HAL_SRNG_FLAGS_RING_PTR_SWAP; reg_base = srng->hwreg_base[HAL_SRNG_REG_GRP_R2]; if (srng->ring_dir == HAL_SRNG_DIR_SRC) { srng->u.src_ring.hp = 0; srng->u.src_ring.cached_tp = 0; srng->u.src_ring.reap_hp = srng->ring_size - srng->entry_size; srng->u.src_ring.tp_addr = (void *)(hal->rdp.vaddr + ring_id); srng->u.src_ring.low_threshold = params->low_threshold * srng->entry_size; if (srng_config->lmac_ring) { lmac_idx = ring_id - HAL_SRNG_RING_ID_LMAC1_ID_START; srng->u.src_ring.hp_addr = (void *)(hal->wrp.vaddr + lmac_idx); srng->flags |= HAL_SRNG_FLAGS_LMAC_RING; } else { srng->u.src_ring.hp_addr = (u32 *)((unsigned long)ab->mem + reg_base); } } else { /* During initialization loop count in all the descriptors * will be set to zero, and HW will set it to 1 on completing * descriptor update in first loop, and increments it by 1 on * subsequent loops (loop count wraps around after reaching * 0xffff). The 'loop_cnt' in SW ring state is the expected * loop count in descriptors updated by HW (to be processed * by SW). */ srng->u.dst_ring.loop_cnt = 1; srng->u.dst_ring.tp = 0; srng->u.dst_ring.cached_hp = 0; srng->u.dst_ring.hp_addr = (void *)(hal->rdp.vaddr + ring_id); if (srng_config->lmac_ring) { /* For LMAC rings, tail pointer updates will be done * through FW by writing to a shared memory location */ lmac_idx = ring_id - HAL_SRNG_RING_ID_LMAC1_ID_START; srng->u.dst_ring.tp_addr = (void *)(hal->wrp.vaddr + lmac_idx); srng->flags |= HAL_SRNG_FLAGS_LMAC_RING; } else { srng->u.dst_ring.tp_addr = (u32 *)((unsigned long)ab->mem + reg_base + (HAL_REO1_RING_TP - HAL_REO1_RING_HP)); } } if (srng_config->lmac_ring) return ring_id; ath11k_hal_srng_hw_init(ab, srng); if (type == HAL_CE_DST) { srng->u.dst_ring.max_buffer_length = params->max_buffer_len; ath11k_hal_ce_dst_setup(ab, srng, ring_num); } return ring_id; } int ath11k_hal_srng_init(struct ath11k_base *ab) { struct ath11k_hal *hal = &ab->hal; int ret; memset(hal, 0, sizeof(*hal)); hal->srng_config = hw_srng_config; ret = ath11k_hal_alloc_cont_rdp(ab); if (ret) goto err_hal; ret = ath11k_hal_alloc_cont_wrp(ab); if (ret) goto err_free_cont_rdp; return 0; err_free_cont_rdp: ath11k_hal_free_cont_rdp(ab); err_hal: return ret; } void ath11k_hal_srng_deinit(struct ath11k_base *ab) { ath11k_hal_free_cont_rdp(ab); ath11k_hal_free_cont_wrp(ab); } void ath11k_hal_dump_srng_stats(struct ath11k_base *ab) { struct hal_srng *srng; struct ath11k_ext_irq_grp *irq_grp; struct ath11k_ce_pipe *ce_pipe; int i; ath11k_err(ab, "Last interrupt received for each CE:\n"); for (i = 0; i < CE_COUNT; i++) { ce_pipe = &ab->ce.ce_pipe[i]; if (ath11k_ce_get_attr_flags(i) & CE_ATTR_DIS_INTR) continue; ath11k_err(ab, "CE_id %d pipe_num %d %ums before\n", i, ce_pipe->pipe_num, jiffies_to_msecs(jiffies - ce_pipe->timestamp)); } ath11k_err(ab, "\nLast interrupt received for each group:\n"); for (i = 0; i < ATH11K_EXT_IRQ_GRP_NUM_MAX; i++) { irq_grp = &ab->ext_irq_grp[i]; ath11k_err(ab, "group_id %d %ums before\n", irq_grp->grp_id, jiffies_to_msecs(jiffies - irq_grp->timestamp)); } for (i = 0; i < HAL_SRNG_RING_ID_MAX; i++) { srng = &ab->hal.srng_list[i]; if (!srng->initialized) continue; if (srng->ring_dir == HAL_SRNG_DIR_SRC) ath11k_err(ab, "src srng id %u hp %u, reap_hp %u, cur tp %u, cached tp %u last tp %u napi processed before %ums\n", srng->ring_id, srng->u.src_ring.hp, srng->u.src_ring.reap_hp, *srng->u.src_ring.tp_addr, srng->u.src_ring.cached_tp, srng->u.src_ring.last_tp, jiffies_to_msecs(jiffies - srng->timestamp)); else if (srng->ring_dir == HAL_SRNG_DIR_DST) ath11k_err(ab, "dst srng id %u tp %u, cur hp %u, cached hp %u last hp %u napi processed before %ums\n", srng->ring_id, srng->u.dst_ring.tp, *srng->u.dst_ring.hp_addr, srng->u.dst_ring.cached_hp, srng->u.dst_ring.last_hp, jiffies_to_msecs(jiffies - srng->timestamp)); } }
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