/* * aQuantia Corporation Network Driver * Copyright (C) 2014-2017 aQuantia Corporation. All rights reserved * * This program is free software; you can redistribute it and/or modify it * under the terms and conditions of the GNU General Public License, * version 2, as published by the Free Software Foundation. */ /* File hw_atl_utils.c: Definition of common functions for Atlantic hardware * abstraction layer. */ #include "../aq_nic.h" #include "../aq_hw_utils.h" #include "hw_atl_utils.h" #include "hw_atl_llh.h" #include "hw_atl_llh_internal.h" #include #define HW_ATL_UCP_0X370_REG 0x0370U #define HW_ATL_MIF_CMD 0x0200U #define HW_ATL_MIF_ADDR 0x0208U #define HW_ATL_MIF_VAL 0x020CU #define HW_ATL_RPC_CONTROL_ADR 0x0338U #define HW_ATL_RPC_STATE_ADR 0x033CU #define HW_ATL_MPI_FW_VERSION 0x18 #define HW_ATL_MPI_CONTROL_ADR 0x0368U #define HW_ATL_MPI_STATE_ADR 0x036CU #define HW_ATL_MPI_STATE_MSK 0x00FFU #define HW_ATL_MPI_STATE_SHIFT 0U #define HW_ATL_MPI_SPEED_MSK 0x00FF0000U #define HW_ATL_MPI_SPEED_SHIFT 16U #define HW_ATL_MPI_DIRTY_WAKE_MSK 0x02000000U #define HW_ATL_MPI_DAISY_CHAIN_STATUS 0x704 #define HW_ATL_MPI_BOOT_EXIT_CODE 0x388 #define HW_ATL_MAC_PHY_CONTROL 0x4000 #define HW_ATL_MAC_PHY_MPI_RESET_BIT 0x1D #define HW_ATL_FW_VER_1X 0x01050006U #define HW_ATL_FW_VER_2X 0x02000000U #define HW_ATL_FW_VER_3X 0x03000000U #define FORCE_FLASHLESS 0 static int hw_atl_utils_ver_match(u32 ver_expected, u32 ver_actual); static int hw_atl_utils_mpi_set_state(struct aq_hw_s *self, enum hal_atl_utils_fw_state_e state); static u32 hw_atl_utils_get_mpi_mbox_tid(struct aq_hw_s *self); static u32 hw_atl_utils_mpi_get_state(struct aq_hw_s *self); static u32 hw_atl_utils_mif_cmd_get(struct aq_hw_s *self); static u32 hw_atl_utils_mif_addr_get(struct aq_hw_s *self); static u32 hw_atl_utils_rpc_state_get(struct aq_hw_s *self); int hw_atl_utils_initfw(struct aq_hw_s *self, const struct aq_fw_ops **fw_ops) { int err = 0; err = hw_atl_utils_soft_reset(self); if (err) return err; hw_atl_utils_hw_chip_features_init(self, &self->chip_features); hw_atl_utils_get_fw_version(self, &self->fw_ver_actual); if (hw_atl_utils_ver_match(HW_ATL_FW_VER_1X, self->fw_ver_actual) == 0) { *fw_ops = &aq_fw_1x_ops; } else if (hw_atl_utils_ver_match(HW_ATL_FW_VER_2X, self->fw_ver_actual) == 0) { *fw_ops = &aq_fw_2x_ops; } else if (hw_atl_utils_ver_match(HW_ATL_FW_VER_3X, self->fw_ver_actual) == 0) { *fw_ops = &aq_fw_2x_ops; } else { aq_pr_err("Bad FW version detected: %x\n", self->fw_ver_actual); return -EOPNOTSUPP; } self->aq_fw_ops = *fw_ops; err = self->aq_fw_ops->init(self); return err; } static int hw_atl_utils_soft_reset_flb(struct aq_hw_s *self) { u32 gsr, val; int k = 0; aq_hw_write_reg(self, 0x404, 0x40e1); AQ_HW_SLEEP(50); /* Cleanup SPI */ val = aq_hw_read_reg(self, 0x53C); aq_hw_write_reg(self, 0x53C, val | 0x10); gsr = aq_hw_read_reg(self, HW_ATL_GLB_SOFT_RES_ADR); aq_hw_write_reg(self, HW_ATL_GLB_SOFT_RES_ADR, (gsr & 0xBFFF) | 0x8000); /* Kickstart MAC */ aq_hw_write_reg(self, 0x404, 0x80e0); aq_hw_write_reg(self, 0x32a8, 0x0); aq_hw_write_reg(self, 0x520, 0x1); /* Reset SPI again because of possible interrupted SPI burst */ val = aq_hw_read_reg(self, 0x53C); aq_hw_write_reg(self, 0x53C, val | 0x10); AQ_HW_SLEEP(10); /* Clear SPI reset state */ aq_hw_write_reg(self, 0x53C, val & ~0x10); aq_hw_write_reg(self, 0x404, 0x180e0); for (k = 0; k < 1000; k++) { u32 flb_status = aq_hw_read_reg(self, HW_ATL_MPI_DAISY_CHAIN_STATUS); flb_status = flb_status & 0x10; if (flb_status) break; AQ_HW_SLEEP(10); } if (k == 1000) { aq_pr_err("MAC kickstart failed\n"); return -EIO; } /* FW reset */ aq_hw_write_reg(self, 0x404, 0x80e0); AQ_HW_SLEEP(50); aq_hw_write_reg(self, 0x3a0, 0x1); /* Kickstart PHY - skipped */ /* Global software reset*/ hw_atl_rx_rx_reg_res_dis_set(self, 0U); hw_atl_tx_tx_reg_res_dis_set(self, 0U); aq_hw_write_reg_bit(self, HW_ATL_MAC_PHY_CONTROL, BIT(HW_ATL_MAC_PHY_MPI_RESET_BIT), HW_ATL_MAC_PHY_MPI_RESET_BIT, 0x0); gsr = aq_hw_read_reg(self, HW_ATL_GLB_SOFT_RES_ADR); aq_hw_write_reg(self, HW_ATL_GLB_SOFT_RES_ADR, (gsr & 0xBFFF) | 0x8000); for (k = 0; k < 1000; k++) { u32 fw_state = aq_hw_read_reg(self, HW_ATL_MPI_FW_VERSION); if (fw_state) break; AQ_HW_SLEEP(10); } if (k == 1000) { aq_pr_err("FW kickstart failed\n"); return -EIO; } /* Old FW requires fixed delay after init */ AQ_HW_SLEEP(15); return 0; } static int hw_atl_utils_soft_reset_rbl(struct aq_hw_s *self) { u32 gsr, val, rbl_status; int k; aq_hw_write_reg(self, 0x404, 0x40e1); aq_hw_write_reg(self, 0x3a0, 0x1); aq_hw_write_reg(self, 0x32a8, 0x0); /* Alter RBL status */ aq_hw_write_reg(self, 0x388, 0xDEAD); /* Cleanup SPI */ val = aq_hw_read_reg(self, 0x53C); aq_hw_write_reg(self, 0x53C, val | 0x10); /* Global software reset*/ hw_atl_rx_rx_reg_res_dis_set(self, 0U); hw_atl_tx_tx_reg_res_dis_set(self, 0U); aq_hw_write_reg_bit(self, HW_ATL_MAC_PHY_CONTROL, BIT(HW_ATL_MAC_PHY_MPI_RESET_BIT), HW_ATL_MAC_PHY_MPI_RESET_BIT, 0x0); gsr = aq_hw_read_reg(self, HW_ATL_GLB_SOFT_RES_ADR); aq_hw_write_reg(self, HW_ATL_GLB_SOFT_RES_ADR, (gsr & 0xFFFFBFFF) | 0x8000); if (FORCE_FLASHLESS) aq_hw_write_reg(self, 0x534, 0x0); aq_hw_write_reg(self, 0x404, 0x40e0); /* Wait for RBL boot */ for (k = 0; k < 1000; k++) { rbl_status = aq_hw_read_reg(self, 0x388) & 0xFFFF; if (rbl_status && rbl_status != 0xDEAD) break; AQ_HW_SLEEP(10); } if (!rbl_status || rbl_status == 0xDEAD) { aq_pr_err("RBL Restart failed"); return -EIO; } /* Restore NVR */ if (FORCE_FLASHLESS) aq_hw_write_reg(self, 0x534, 0xA0); if (rbl_status == 0xF1A7) { aq_pr_err("No FW detected. Dynamic FW load not implemented\n"); return -ENOTSUPP; } for (k = 0; k < 1000; k++) { u32 fw_state = aq_hw_read_reg(self, HW_ATL_MPI_FW_VERSION); if (fw_state) break; AQ_HW_SLEEP(10); } if (k == 1000) { aq_pr_err("FW kickstart failed\n"); return -EIO; } /* Old FW requires fixed delay after init */ AQ_HW_SLEEP(15); return 0; } int hw_atl_utils_soft_reset(struct aq_hw_s *self) { int k; u32 boot_exit_code = 0; u32 val; for (k = 0; k < 1000; ++k) { u32 flb_status = aq_hw_read_reg(self, HW_ATL_MPI_DAISY_CHAIN_STATUS); boot_exit_code = aq_hw_read_reg(self, HW_ATL_MPI_BOOT_EXIT_CODE); if (flb_status != 0x06000000 || boot_exit_code != 0) break; } if (k == 1000) { aq_pr_err("Neither RBL nor FLB firmware started\n"); return -EOPNOTSUPP; } self->rbl_enabled = (boot_exit_code != 0); /* FW 1.x may bootup in an invalid POWER state (WOL feature). * We should work around this by forcing its state back to DEINIT */ if (!hw_atl_utils_ver_match(HW_ATL_FW_VER_1X, aq_hw_read_reg(self, HW_ATL_MPI_FW_VERSION))) { int err = 0; hw_atl_utils_mpi_set_state(self, MPI_DEINIT); err = readx_poll_timeout_atomic(hw_atl_utils_mpi_get_state, self, val, (val & HW_ATL_MPI_STATE_MSK) == MPI_DEINIT, 10, 10000U); if (err) return err; } if (self->rbl_enabled) return hw_atl_utils_soft_reset_rbl(self); else return hw_atl_utils_soft_reset_flb(self); } int hw_atl_utils_fw_downld_dwords(struct aq_hw_s *self, u32 a, u32 *p, u32 cnt) { int err = 0; u32 val; err = readx_poll_timeout_atomic(hw_atl_sem_ram_get, self, val, val == 1U, 1U, 10000U); if (err < 0) { bool is_locked; hw_atl_reg_glb_cpu_sem_set(self, 1U, HW_ATL_FW_SM_RAM); is_locked = hw_atl_sem_ram_get(self); if (!is_locked) { err = -ETIME; goto err_exit; } } aq_hw_write_reg(self, HW_ATL_MIF_ADDR, a); for (++cnt; --cnt && !err;) { aq_hw_write_reg(self, HW_ATL_MIF_CMD, 0x00008000U); if (IS_CHIP_FEATURE(REVISION_B1)) err = readx_poll_timeout_atomic(hw_atl_utils_mif_addr_get, self, val, val != a, 1U, 1000U); else err = readx_poll_timeout_atomic(hw_atl_utils_mif_cmd_get, self, val, !(val & 0x100), 1U, 1000U); *(p++) = aq_hw_read_reg(self, HW_ATL_MIF_VAL); a += 4; } hw_atl_reg_glb_cpu_sem_set(self, 1U, HW_ATL_FW_SM_RAM); err_exit: return err; } static int hw_atl_utils_fw_upload_dwords(struct aq_hw_s *self, u32 a, u32 *p, u32 cnt) { u32 val; int err = 0; err = readx_poll_timeout_atomic(hw_atl_sem_ram_get, self, val, val == 1U, 10U, 100000U); if (err < 0) goto err_exit; if (IS_CHIP_FEATURE(REVISION_B1)) { u32 offset = 0; for (; offset < cnt; ++offset) { aq_hw_write_reg(self, 0x328, p[offset]); aq_hw_write_reg(self, 0x32C, (0x80000000 | (0xFFFF & (offset * 4)))); hw_atl_mcp_up_force_intr_set(self, 1); /* 1000 times by 10us = 10ms */ err = readx_poll_timeout_atomic(hw_atl_scrpad12_get, self, val, (val & 0xF0000000) != 0x80000000, 10U, 10000U); } } else { u32 offset = 0; aq_hw_write_reg(self, 0x208, a); for (; offset < cnt; ++offset) { aq_hw_write_reg(self, 0x20C, p[offset]); aq_hw_write_reg(self, 0x200, 0xC000); err = readx_poll_timeout_atomic(hw_atl_utils_mif_cmd_get, self, val, (val & 0x100) == 0, 1000U, 10000U); } } hw_atl_reg_glb_cpu_sem_set(self, 1U, HW_ATL_FW_SM_RAM); err_exit: return err; } static int hw_atl_utils_ver_match(u32 ver_expected, u32 ver_actual) { int err = 0; const u32 dw_major_mask = 0xff000000U; const u32 dw_minor_mask = 0x00ffffffU; err = (dw_major_mask & (ver_expected ^ ver_actual)) ? -EOPNOTSUPP : 0; if (err < 0) goto err_exit; err = ((dw_minor_mask & ver_expected) > (dw_minor_mask & ver_actual)) ? -EOPNOTSUPP : 0; err_exit: return err; } static int hw_atl_utils_init_ucp(struct aq_hw_s *self, const struct aq_hw_caps_s *aq_hw_caps) { int err = 0; if (!aq_hw_read_reg(self, 0x370U)) { unsigned int rnd = 0U; unsigned int ucp_0x370 = 0U; get_random_bytes(&rnd, sizeof(unsigned int)); ucp_0x370 = 0x02020202U | (0xFEFEFEFEU & rnd); aq_hw_write_reg(self, HW_ATL_UCP_0X370_REG, ucp_0x370); } hw_atl_reg_glb_cpu_scratch_scp_set(self, 0x00000000U, 25U); /* check 10 times by 1ms */ err = readx_poll_timeout_atomic(hw_atl_scrpad25_get, self, self->mbox_addr, self->mbox_addr != 0U, 1000U, 10000U); return err; } struct aq_hw_atl_utils_fw_rpc_tid_s { union { u32 val; struct { u16 tid; u16 len; }; }; }; #define hw_atl_utils_fw_rpc_init(_H_) hw_atl_utils_fw_rpc_wait(_H_, NULL) int hw_atl_utils_fw_rpc_call(struct aq_hw_s *self, unsigned int rpc_size) { int err = 0; struct aq_hw_atl_utils_fw_rpc_tid_s sw; if (!IS_CHIP_FEATURE(MIPS)) { err = -1; goto err_exit; } err = hw_atl_utils_fw_upload_dwords(self, self->rpc_addr, (u32 *)(void *)&self->rpc, (rpc_size + sizeof(u32) - sizeof(u8)) / sizeof(u32)); if (err < 0) goto err_exit; sw.tid = 0xFFFFU & (++self->rpc_tid); sw.len = (u16)rpc_size; aq_hw_write_reg(self, HW_ATL_RPC_CONTROL_ADR, sw.val); err_exit: return err; } int hw_atl_utils_fw_rpc_wait(struct aq_hw_s *self, struct hw_atl_utils_fw_rpc **rpc) { int err = 0; struct aq_hw_atl_utils_fw_rpc_tid_s sw; struct aq_hw_atl_utils_fw_rpc_tid_s fw; do { sw.val = aq_hw_read_reg(self, HW_ATL_RPC_CONTROL_ADR); self->rpc_tid = sw.tid; err = readx_poll_timeout_atomic(hw_atl_utils_rpc_state_get, self, fw.val, sw.tid == fw.tid, 1000U, 100000U); if (fw.len == 0xFFFFU) { err = hw_atl_utils_fw_rpc_call(self, sw.len); if (err < 0) goto err_exit; } } while (sw.tid != fw.tid || 0xFFFFU == fw.len); if (rpc) { if (fw.len) { err = hw_atl_utils_fw_downld_dwords(self, self->rpc_addr, (u32 *)(void *) &self->rpc, (fw.len + sizeof(u32) - sizeof(u8)) / sizeof(u32)); if (err < 0) goto err_exit; } *rpc = &self->rpc; } err_exit: return err; } static int hw_atl_utils_mpi_create(struct aq_hw_s *self) { int err = 0; err = hw_atl_utils_init_ucp(self, self->aq_nic_cfg->aq_hw_caps); if (err < 0) goto err_exit; err = hw_atl_utils_fw_rpc_init(self); if (err < 0) goto err_exit; err_exit: return err; } int hw_atl_utils_mpi_read_mbox(struct aq_hw_s *self, struct hw_atl_utils_mbox_header *pmbox) { return hw_atl_utils_fw_downld_dwords(self, self->mbox_addr, (u32 *)(void *)pmbox, sizeof(*pmbox) / sizeof(u32)); } void hw_atl_utils_mpi_read_stats(struct aq_hw_s *self, struct hw_atl_utils_mbox *pmbox) { int err = 0; err = hw_atl_utils_fw_downld_dwords(self, self->mbox_addr, (u32 *)(void *)pmbox, sizeof(*pmbox) / sizeof(u32)); if (err < 0) goto err_exit; if (IS_CHIP_FEATURE(REVISION_A0)) { unsigned int mtu = self->aq_nic_cfg ? self->aq_nic_cfg->mtu : 1514U; pmbox->stats.ubrc = pmbox->stats.uprc * mtu; pmbox->stats.ubtc = pmbox->stats.uptc * mtu; pmbox->stats.dpc = atomic_read(&self->dpc); } else { pmbox->stats.dpc = hw_atl_rpb_rx_dma_drop_pkt_cnt_get(self); } err_exit:; } static int hw_atl_utils_mpi_set_speed(struct aq_hw_s *self, u32 speed) { u32 val = aq_hw_read_reg(self, HW_ATL_MPI_CONTROL_ADR); val = val & ~HW_ATL_MPI_SPEED_MSK; val |= speed << HW_ATL_MPI_SPEED_SHIFT; aq_hw_write_reg(self, HW_ATL_MPI_CONTROL_ADR, val); return 0; } static int hw_atl_utils_mpi_set_state(struct aq_hw_s *self, enum hal_atl_utils_fw_state_e state) { int err = 0; u32 transaction_id = 0; struct hw_atl_utils_mbox_header mbox; u32 val = aq_hw_read_reg(self, HW_ATL_MPI_CONTROL_ADR); if (state == MPI_RESET) { hw_atl_utils_mpi_read_mbox(self, &mbox); transaction_id = mbox.transaction_id; err = readx_poll_timeout_atomic(hw_atl_utils_get_mpi_mbox_tid, self, mbox.transaction_id, transaction_id != mbox.transaction_id, 1000U, 100000U); if (err < 0) goto err_exit; } /* On interface DEINIT we disable DW (raise bit) * Otherwise enable DW (clear bit) */ if (state == MPI_DEINIT || state == MPI_POWER) val |= HW_ATL_MPI_DIRTY_WAKE_MSK; else val &= ~HW_ATL_MPI_DIRTY_WAKE_MSK; /* Set new state bits */ val = val & ~HW_ATL_MPI_STATE_MSK; val |= state & HW_ATL_MPI_STATE_MSK; aq_hw_write_reg(self, HW_ATL_MPI_CONTROL_ADR, val); err_exit: return err; } int hw_atl_utils_mpi_get_link_status(struct aq_hw_s *self) { u32 cp0x036C = hw_atl_utils_mpi_get_state(self); u32 link_speed_mask = cp0x036C >> HW_ATL_MPI_SPEED_SHIFT; struct aq_hw_link_status_s *link_status = &self->aq_link_status; if (!link_speed_mask) { link_status->mbps = 0U; } else { switch (link_speed_mask) { case HAL_ATLANTIC_RATE_10G: link_status->mbps = 10000U; break; case HAL_ATLANTIC_RATE_5G: case HAL_ATLANTIC_RATE_5GSR: link_status->mbps = 5000U; break; case HAL_ATLANTIC_RATE_2GS: link_status->mbps = 2500U; break; case HAL_ATLANTIC_RATE_1G: link_status->mbps = 1000U; break; case HAL_ATLANTIC_RATE_100M: link_status->mbps = 100U; break; default: return -EBUSY; } } return 0; } int hw_atl_utils_get_mac_permanent(struct aq_hw_s *self, u8 *mac) { int err = 0; u32 h = 0U; u32 l = 0U; u32 mac_addr[2]; if (!aq_hw_read_reg(self, HW_ATL_UCP_0X370_REG)) { unsigned int rnd = 0; unsigned int ucp_0x370 = 0; get_random_bytes(&rnd, sizeof(unsigned int)); ucp_0x370 = 0x02020202 | (0xFEFEFEFE & rnd); aq_hw_write_reg(self, HW_ATL_UCP_0X370_REG, ucp_0x370); } err = hw_atl_utils_fw_downld_dwords(self, aq_hw_read_reg(self, 0x00000374U) + (40U * 4U), mac_addr, ARRAY_SIZE(mac_addr)); if (err < 0) { mac_addr[0] = 0U; mac_addr[1] = 0U; err = 0; } else { mac_addr[0] = __swab32(mac_addr[0]); mac_addr[1] = __swab32(mac_addr[1]); } ether_addr_copy(mac, (u8 *)mac_addr); if ((mac[0] & 0x01U) || ((mac[0] | mac[1] | mac[2]) == 0x00U)) { /* chip revision */ l = 0xE3000000U | (0xFFFFU & aq_hw_read_reg(self, HW_ATL_UCP_0X370_REG)) | (0x00 << 16); h = 0x8001300EU; mac[5] = (u8)(0xFFU & l); l >>= 8; mac[4] = (u8)(0xFFU & l); l >>= 8; mac[3] = (u8)(0xFFU & l); l >>= 8; mac[2] = (u8)(0xFFU & l); mac[1] = (u8)(0xFFU & h); h >>= 8; mac[0] = (u8)(0xFFU & h); } return err; } unsigned int hw_atl_utils_mbps_2_speed_index(unsigned int mbps) { unsigned int ret = 0U; switch (mbps) { case 100U: ret = 5U; break; case 1000U: ret = 4U; break; case 2500U: ret = 3U; break; case 5000U: ret = 1U; break; case 10000U: ret = 0U; break; default: break; } return ret; } void hw_atl_utils_hw_chip_features_init(struct aq_hw_s *self, u32 *p) { u32 chip_features = 0U; u32 val = hw_atl_reg_glb_mif_id_get(self); u32 mif_rev = val & 0xFFU; if ((0xFU & mif_rev) == 1U) { chip_features |= HAL_ATLANTIC_UTILS_CHIP_REVISION_A0 | HAL_ATLANTIC_UTILS_CHIP_MPI_AQ | HAL_ATLANTIC_UTILS_CHIP_MIPS; } else if ((0xFU & mif_rev) == 2U) { chip_features |= HAL_ATLANTIC_UTILS_CHIP_REVISION_B0 | HAL_ATLANTIC_UTILS_CHIP_MPI_AQ | HAL_ATLANTIC_UTILS_CHIP_MIPS | HAL_ATLANTIC_UTILS_CHIP_TPO2 | HAL_ATLANTIC_UTILS_CHIP_RPF2; } else if ((0xFU & mif_rev) == 0xAU) { chip_features |= HAL_ATLANTIC_UTILS_CHIP_REVISION_B1 | HAL_ATLANTIC_UTILS_CHIP_MPI_AQ | HAL_ATLANTIC_UTILS_CHIP_MIPS | HAL_ATLANTIC_UTILS_CHIP_TPO2 | HAL_ATLANTIC_UTILS_CHIP_RPF2; } *p = chip_features; } static int hw_atl_fw1x_deinit(struct aq_hw_s *self) { hw_atl_utils_mpi_set_speed(self, 0); hw_atl_utils_mpi_set_state(self, MPI_DEINIT); return 0; } int hw_atl_utils_update_stats(struct aq_hw_s *self) { struct hw_atl_utils_mbox mbox; struct aq_stats_s *cs = &self->curr_stats; hw_atl_utils_mpi_read_stats(self, &mbox); #define AQ_SDELTA(_N_) (self->curr_stats._N_ += \ mbox.stats._N_ - self->last_stats._N_) if (self->aq_link_status.mbps) { AQ_SDELTA(uprc); AQ_SDELTA(mprc); AQ_SDELTA(bprc); AQ_SDELTA(erpt); AQ_SDELTA(uptc); AQ_SDELTA(mptc); AQ_SDELTA(bptc); AQ_SDELTA(erpr); AQ_SDELTA(ubrc); AQ_SDELTA(ubtc); AQ_SDELTA(mbrc); AQ_SDELTA(mbtc); AQ_SDELTA(bbrc); AQ_SDELTA(bbtc); AQ_SDELTA(dpc); } #undef AQ_SDELTA cs->dma_pkt_rc = hw_atl_stats_rx_dma_good_pkt_counter_get(self); cs->dma_pkt_tc = hw_atl_stats_tx_dma_good_pkt_counter_get(self); cs->dma_oct_rc = hw_atl_stats_rx_dma_good_octet_counter_get(self); cs->dma_oct_tc = hw_atl_stats_tx_dma_good_octet_counter_get(self); memcpy(&self->last_stats, &mbox.stats, sizeof(mbox.stats)); return 0; } struct aq_stats_s *hw_atl_utils_get_hw_stats(struct aq_hw_s *self) { return &self->curr_stats; } static const u32 hw_atl_utils_hw_mac_regs[] = { 0x00005580U, 0x00005590U, 0x000055B0U, 0x000055B4U, 0x000055C0U, 0x00005B00U, 0x00005B04U, 0x00005B08U, 0x00005B0CU, 0x00005B10U, 0x00005B14U, 0x00005B18U, 0x00005B1CU, 0x00005B20U, 0x00005B24U, 0x00005B28U, 0x00005B2CU, 0x00005B30U, 0x00005B34U, 0x00005B38U, 0x00005B3CU, 0x00005B40U, 0x00005B44U, 0x00005B48U, 0x00005B4CU, 0x00005B50U, 0x00005B54U, 0x00005B58U, 0x00005B5CU, 0x00005B60U, 0x00005B64U, 0x00005B68U, 0x00005B6CU, 0x00005B70U, 0x00005B74U, 0x00005B78U, 0x00005B7CU, 0x00007C00U, 0x00007C04U, 0x00007C08U, 0x00007C0CU, 0x00007C10U, 0x00007C14U, 0x00007C18U, 0x00007C1CU, 0x00007C20U, 0x00007C40U, 0x00007C44U, 0x00007C48U, 0x00007C4CU, 0x00007C50U, 0x00007C54U, 0x00007C58U, 0x00007C5CU, 0x00007C60U, 0x00007C80U, 0x00007C84U, 0x00007C88U, 0x00007C8CU, 0x00007C90U, 0x00007C94U, 0x00007C98U, 0x00007C9CU, 0x00007CA0U, 0x00007CC0U, 0x00007CC4U, 0x00007CC8U, 0x00007CCCU, 0x00007CD0U, 0x00007CD4U, 0x00007CD8U, 0x00007CDCU, 0x00007CE0U, 0x00000300U, 0x00000304U, 0x00000308U, 0x0000030cU, 0x00000310U, 0x00000314U, 0x00000318U, 0x0000031cU, 0x00000360U, 0x00000364U, 0x00000368U, 0x0000036cU, 0x00000370U, 0x00000374U, 0x00006900U, }; int hw_atl_utils_hw_get_regs(struct aq_hw_s *self, const struct aq_hw_caps_s *aq_hw_caps, u32 *regs_buff) { unsigned int i = 0U; for (i = 0; i < aq_hw_caps->mac_regs_count; i++) regs_buff[i] = aq_hw_read_reg(self, hw_atl_utils_hw_mac_regs[i]); return 0; } int hw_atl_utils_get_fw_version(struct aq_hw_s *self, u32 *fw_version) { *fw_version = aq_hw_read_reg(self, 0x18U); return 0; } static int aq_fw1x_set_wol(struct aq_hw_s *self, bool wol_enabled, u8 *mac) { struct hw_atl_utils_fw_rpc *prpc = NULL; unsigned int rpc_size = 0U; int err = 0; err = hw_atl_utils_fw_rpc_wait(self, &prpc); if (err < 0) goto err_exit; memset(prpc, 0, sizeof(*prpc)); if (wol_enabled) { rpc_size = sizeof(prpc->msg_id) + sizeof(prpc->msg_wol); prpc->msg_id = HAL_ATLANTIC_UTILS_FW_MSG_WOL_ADD; prpc->msg_wol.priority = HAL_ATLANTIC_UTILS_FW_MSG_WOL_PRIOR; prpc->msg_wol.pattern_id = HAL_ATLANTIC_UTILS_FW_MSG_WOL_PATTERN; prpc->msg_wol.wol_packet_type = HAL_ATLANTIC_UTILS_FW_MSG_WOL_MAG_PKT; ether_addr_copy((u8 *)&prpc->msg_wol.wol_pattern, mac); } else { rpc_size = sizeof(prpc->msg_id) + sizeof(prpc->msg_del_id); prpc->msg_id = HAL_ATLANTIC_UTILS_FW_MSG_WOL_DEL; prpc->msg_wol.pattern_id = HAL_ATLANTIC_UTILS_FW_MSG_WOL_PATTERN; } err = hw_atl_utils_fw_rpc_call(self, rpc_size); err_exit: return err; } static int aq_fw1x_set_power(struct aq_hw_s *self, unsigned int power_state, u8 *mac) { struct hw_atl_utils_fw_rpc *prpc = NULL; unsigned int rpc_size = 0U; int err = 0; if (self->aq_nic_cfg->wol & AQ_NIC_WOL_ENABLED) { err = aq_fw1x_set_wol(self, 1, mac); if (err < 0) goto err_exit; rpc_size = sizeof(prpc->msg_id) + sizeof(prpc->msg_enable_wakeup); err = hw_atl_utils_fw_rpc_wait(self, &prpc); if (err < 0) goto err_exit; memset(prpc, 0, rpc_size); prpc->msg_id = HAL_ATLANTIC_UTILS_FW_MSG_ENABLE_WAKEUP; prpc->msg_enable_wakeup.pattern_mask = 0x00000002; err = hw_atl_utils_fw_rpc_call(self, rpc_size); if (err < 0) goto err_exit; } hw_atl_utils_mpi_set_speed(self, 0); hw_atl_utils_mpi_set_state(self, MPI_POWER); err_exit: return err; } static u32 hw_atl_utils_get_mpi_mbox_tid(struct aq_hw_s *self) { struct hw_atl_utils_mbox_header mbox; hw_atl_utils_mpi_read_mbox(self, &mbox); return mbox.transaction_id; } static u32 hw_atl_utils_mpi_get_state(struct aq_hw_s *self) { return aq_hw_read_reg(self, HW_ATL_MPI_STATE_ADR); } static u32 hw_atl_utils_mif_cmd_get(struct aq_hw_s *self) { return aq_hw_read_reg(self, HW_ATL_MIF_CMD); } static u32 hw_atl_utils_mif_addr_get(struct aq_hw_s *self) { return aq_hw_read_reg(self, HW_ATL_MIF_ADDR); } static u32 hw_atl_utils_rpc_state_get(struct aq_hw_s *self) { return aq_hw_read_reg(self, HW_ATL_RPC_STATE_ADR); } const struct aq_fw_ops aq_fw_1x_ops = { .init = hw_atl_utils_mpi_create, .deinit = hw_atl_fw1x_deinit, .reset = NULL, .get_mac_permanent = hw_atl_utils_get_mac_permanent, .set_link_speed = hw_atl_utils_mpi_set_speed, .set_state = hw_atl_utils_mpi_set_state, .update_link_status = hw_atl_utils_mpi_get_link_status, .update_stats = hw_atl_utils_update_stats, .get_phy_temp = NULL, .set_power = aq_fw1x_set_power, .set_eee_rate = NULL, .get_eee_rate = NULL, .set_flow_control = NULL, };