Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Rasesh Mody | 3837 | 90.97% | 13 | 68.42% |
Jing Huang | 324 | 7.68% | 1 | 5.26% |
Stephen Hemminger | 41 | 0.97% | 1 | 5.26% |
Ben Hutchings | 12 | 0.28% | 1 | 5.26% |
Thomas Gleixner | 2 | 0.05% | 1 | 5.26% |
Ivan Vecera | 1 | 0.02% | 1 | 5.26% |
Joe Perches | 1 | 0.02% | 1 | 5.26% |
Total | 4218 | 19 |
// SPDX-License-Identifier: GPL-2.0-only /* * Linux network driver for QLogic BR-series Converged Network Adapter. */ /* * Copyright (c) 2005-2014 Brocade Communications Systems, Inc. * Copyright (c) 2014-2015 QLogic Corporation * All rights reserved * www.qlogic.com */ #include "bfa_ioc.h" #include "cna.h" #include "bfi.h" #include "bfi_reg.h" #include "bfa_defs.h" #define bfa_ioc_ct_sync_pos(__ioc) BIT(bfa_ioc_pcifn(__ioc)) #define BFA_IOC_SYNC_REQD_SH 16 #define bfa_ioc_ct_get_sync_ackd(__val) (__val & 0x0000ffff) #define bfa_ioc_ct_clear_sync_ackd(__val) (__val & 0xffff0000) #define bfa_ioc_ct_get_sync_reqd(__val) (__val >> BFA_IOC_SYNC_REQD_SH) #define bfa_ioc_ct_sync_reqd_pos(__ioc) \ (bfa_ioc_ct_sync_pos(__ioc) << BFA_IOC_SYNC_REQD_SH) /* * forward declarations */ static bool bfa_ioc_ct_firmware_lock(struct bfa_ioc *ioc); static void bfa_ioc_ct_firmware_unlock(struct bfa_ioc *ioc); static void bfa_ioc_ct_reg_init(struct bfa_ioc *ioc); static void bfa_ioc_ct2_reg_init(struct bfa_ioc *ioc); static void bfa_ioc_ct_map_port(struct bfa_ioc *ioc); static void bfa_ioc_ct2_map_port(struct bfa_ioc *ioc); static void bfa_ioc_ct_isr_mode_set(struct bfa_ioc *ioc, bool msix); static void bfa_ioc_ct_notify_fail(struct bfa_ioc *ioc); static void bfa_ioc_ct_ownership_reset(struct bfa_ioc *ioc); static bool bfa_ioc_ct_sync_start(struct bfa_ioc *ioc); static void bfa_ioc_ct_sync_join(struct bfa_ioc *ioc); static void bfa_ioc_ct_sync_leave(struct bfa_ioc *ioc); static void bfa_ioc_ct_sync_ack(struct bfa_ioc *ioc); static bool bfa_ioc_ct_sync_complete(struct bfa_ioc *ioc); static void bfa_ioc_ct_set_cur_ioc_fwstate( struct bfa_ioc *ioc, enum bfi_ioc_state fwstate); static enum bfi_ioc_state bfa_ioc_ct_get_cur_ioc_fwstate(struct bfa_ioc *ioc); static void bfa_ioc_ct_set_alt_ioc_fwstate( struct bfa_ioc *ioc, enum bfi_ioc_state fwstate); static enum bfi_ioc_state bfa_ioc_ct_get_alt_ioc_fwstate(struct bfa_ioc *ioc); static enum bfa_status bfa_ioc_ct_pll_init(void __iomem *rb, enum bfi_asic_mode asic_mode); static enum bfa_status bfa_ioc_ct2_pll_init(void __iomem *rb, enum bfi_asic_mode asic_mode); static bool bfa_ioc_ct2_lpu_read_stat(struct bfa_ioc *ioc); static const struct bfa_ioc_hwif nw_hwif_ct = { .ioc_pll_init = bfa_ioc_ct_pll_init, .ioc_firmware_lock = bfa_ioc_ct_firmware_lock, .ioc_firmware_unlock = bfa_ioc_ct_firmware_unlock, .ioc_reg_init = bfa_ioc_ct_reg_init, .ioc_map_port = bfa_ioc_ct_map_port, .ioc_isr_mode_set = bfa_ioc_ct_isr_mode_set, .ioc_notify_fail = bfa_ioc_ct_notify_fail, .ioc_ownership_reset = bfa_ioc_ct_ownership_reset, .ioc_sync_start = bfa_ioc_ct_sync_start, .ioc_sync_join = bfa_ioc_ct_sync_join, .ioc_sync_leave = bfa_ioc_ct_sync_leave, .ioc_sync_ack = bfa_ioc_ct_sync_ack, .ioc_sync_complete = bfa_ioc_ct_sync_complete, .ioc_set_fwstate = bfa_ioc_ct_set_cur_ioc_fwstate, .ioc_get_fwstate = bfa_ioc_ct_get_cur_ioc_fwstate, .ioc_set_alt_fwstate = bfa_ioc_ct_set_alt_ioc_fwstate, .ioc_get_alt_fwstate = bfa_ioc_ct_get_alt_ioc_fwstate, }; static const struct bfa_ioc_hwif nw_hwif_ct2 = { .ioc_pll_init = bfa_ioc_ct2_pll_init, .ioc_firmware_lock = bfa_ioc_ct_firmware_lock, .ioc_firmware_unlock = bfa_ioc_ct_firmware_unlock, .ioc_reg_init = bfa_ioc_ct2_reg_init, .ioc_map_port = bfa_ioc_ct2_map_port, .ioc_lpu_read_stat = bfa_ioc_ct2_lpu_read_stat, .ioc_isr_mode_set = NULL, .ioc_notify_fail = bfa_ioc_ct_notify_fail, .ioc_ownership_reset = bfa_ioc_ct_ownership_reset, .ioc_sync_start = bfa_ioc_ct_sync_start, .ioc_sync_join = bfa_ioc_ct_sync_join, .ioc_sync_leave = bfa_ioc_ct_sync_leave, .ioc_sync_ack = bfa_ioc_ct_sync_ack, .ioc_sync_complete = bfa_ioc_ct_sync_complete, .ioc_set_fwstate = bfa_ioc_ct_set_cur_ioc_fwstate, .ioc_get_fwstate = bfa_ioc_ct_get_cur_ioc_fwstate, .ioc_set_alt_fwstate = bfa_ioc_ct_set_alt_ioc_fwstate, .ioc_get_alt_fwstate = bfa_ioc_ct_get_alt_ioc_fwstate, }; /* Called from bfa_ioc_attach() to map asic specific calls. */ void bfa_nw_ioc_set_ct_hwif(struct bfa_ioc *ioc) { ioc->ioc_hwif = &nw_hwif_ct; } void bfa_nw_ioc_set_ct2_hwif(struct bfa_ioc *ioc) { ioc->ioc_hwif = &nw_hwif_ct2; } /* Return true if firmware of current driver matches the running firmware. */ static bool bfa_ioc_ct_firmware_lock(struct bfa_ioc *ioc) { enum bfi_ioc_state ioc_fwstate; u32 usecnt; struct bfi_ioc_image_hdr fwhdr; /** * If bios boot (flash based) -- do not increment usage count */ if (bfa_cb_image_get_size(bfa_ioc_asic_gen(ioc)) < BFA_IOC_FWIMG_MINSZ) return true; bfa_nw_ioc_sem_get(ioc->ioc_regs.ioc_usage_sem_reg); usecnt = readl(ioc->ioc_regs.ioc_usage_reg); /** * If usage count is 0, always return TRUE. */ if (usecnt == 0) { writel(1, ioc->ioc_regs.ioc_usage_reg); bfa_nw_ioc_sem_release(ioc->ioc_regs.ioc_usage_sem_reg); writel(0, ioc->ioc_regs.ioc_fail_sync); return true; } ioc_fwstate = readl(ioc->ioc_regs.ioc_fwstate); /** * Use count cannot be non-zero and chip in uninitialized state. */ BUG_ON(!(ioc_fwstate != BFI_IOC_UNINIT)); /** * Check if another driver with a different firmware is active */ bfa_nw_ioc_fwver_get(ioc, &fwhdr); if (!bfa_nw_ioc_fwver_cmp(ioc, &fwhdr)) { bfa_nw_ioc_sem_release(ioc->ioc_regs.ioc_usage_sem_reg); return false; } /** * Same firmware version. Increment the reference count. */ usecnt++; writel(usecnt, ioc->ioc_regs.ioc_usage_reg); bfa_nw_ioc_sem_release(ioc->ioc_regs.ioc_usage_sem_reg); return true; } static void bfa_ioc_ct_firmware_unlock(struct bfa_ioc *ioc) { u32 usecnt; /** * If bios boot (flash based) -- do not decrement usage count */ if (bfa_cb_image_get_size(bfa_ioc_asic_gen(ioc)) < BFA_IOC_FWIMG_MINSZ) return; /** * decrement usage count */ bfa_nw_ioc_sem_get(ioc->ioc_regs.ioc_usage_sem_reg); usecnt = readl(ioc->ioc_regs.ioc_usage_reg); BUG_ON(!(usecnt > 0)); usecnt--; writel(usecnt, ioc->ioc_regs.ioc_usage_reg); bfa_nw_ioc_sem_release(ioc->ioc_regs.ioc_usage_sem_reg); } /* Notify other functions on HB failure. */ static void bfa_ioc_ct_notify_fail(struct bfa_ioc *ioc) { writel(__FW_INIT_HALT_P, ioc->ioc_regs.ll_halt); writel(__FW_INIT_HALT_P, ioc->ioc_regs.alt_ll_halt); /* Wait for halt to take effect */ readl(ioc->ioc_regs.ll_halt); readl(ioc->ioc_regs.alt_ll_halt); } /* Host to LPU mailbox message addresses */ static const struct { u32 hfn_mbox; u32 lpu_mbox; u32 hfn_pgn; } ct_fnreg[] = { { HOSTFN0_LPU_MBOX0_0, LPU_HOSTFN0_MBOX0_0, HOST_PAGE_NUM_FN0 }, { HOSTFN1_LPU_MBOX0_8, LPU_HOSTFN1_MBOX0_8, HOST_PAGE_NUM_FN1 }, { HOSTFN2_LPU_MBOX0_0, LPU_HOSTFN2_MBOX0_0, HOST_PAGE_NUM_FN2 }, { HOSTFN3_LPU_MBOX0_8, LPU_HOSTFN3_MBOX0_8, HOST_PAGE_NUM_FN3 } }; /* Host <-> LPU mailbox command/status registers - port 0 */ static const struct { u32 hfn; u32 lpu; } ct_p0reg[] = { { HOSTFN0_LPU0_CMD_STAT, LPU0_HOSTFN0_CMD_STAT }, { HOSTFN1_LPU0_CMD_STAT, LPU0_HOSTFN1_CMD_STAT }, { HOSTFN2_LPU0_CMD_STAT, LPU0_HOSTFN2_CMD_STAT }, { HOSTFN3_LPU0_CMD_STAT, LPU0_HOSTFN3_CMD_STAT } }; /* Host <-> LPU mailbox command/status registers - port 1 */ static const struct { u32 hfn; u32 lpu; } ct_p1reg[] = { { HOSTFN0_LPU1_CMD_STAT, LPU1_HOSTFN0_CMD_STAT }, { HOSTFN1_LPU1_CMD_STAT, LPU1_HOSTFN1_CMD_STAT }, { HOSTFN2_LPU1_CMD_STAT, LPU1_HOSTFN2_CMD_STAT }, { HOSTFN3_LPU1_CMD_STAT, LPU1_HOSTFN3_CMD_STAT } }; static const struct { u32 hfn_mbox; u32 lpu_mbox; u32 hfn_pgn; u32 hfn; u32 lpu; u32 lpu_read; } ct2_reg[] = { { CT2_HOSTFN_LPU0_MBOX0, CT2_LPU0_HOSTFN_MBOX0, CT2_HOSTFN_PAGE_NUM, CT2_HOSTFN_LPU0_CMD_STAT, CT2_LPU0_HOSTFN_CMD_STAT, CT2_HOSTFN_LPU0_READ_STAT}, { CT2_HOSTFN_LPU1_MBOX0, CT2_LPU1_HOSTFN_MBOX0, CT2_HOSTFN_PAGE_NUM, CT2_HOSTFN_LPU1_CMD_STAT, CT2_LPU1_HOSTFN_CMD_STAT, CT2_HOSTFN_LPU1_READ_STAT}, }; static void bfa_ioc_ct_reg_init(struct bfa_ioc *ioc) { void __iomem *rb; int pcifn = bfa_ioc_pcifn(ioc); rb = bfa_ioc_bar0(ioc); ioc->ioc_regs.hfn_mbox = rb + ct_fnreg[pcifn].hfn_mbox; ioc->ioc_regs.lpu_mbox = rb + ct_fnreg[pcifn].lpu_mbox; ioc->ioc_regs.host_page_num_fn = rb + ct_fnreg[pcifn].hfn_pgn; if (ioc->port_id == 0) { ioc->ioc_regs.heartbeat = rb + BFA_IOC0_HBEAT_REG; ioc->ioc_regs.ioc_fwstate = rb + BFA_IOC0_STATE_REG; ioc->ioc_regs.alt_ioc_fwstate = rb + BFA_IOC1_STATE_REG; ioc->ioc_regs.hfn_mbox_cmd = rb + ct_p0reg[pcifn].hfn; ioc->ioc_regs.lpu_mbox_cmd = rb + ct_p0reg[pcifn].lpu; ioc->ioc_regs.ll_halt = rb + FW_INIT_HALT_P0; ioc->ioc_regs.alt_ll_halt = rb + FW_INIT_HALT_P1; } else { ioc->ioc_regs.heartbeat = rb + BFA_IOC1_HBEAT_REG; ioc->ioc_regs.ioc_fwstate = rb + BFA_IOC1_STATE_REG; ioc->ioc_regs.alt_ioc_fwstate = rb + BFA_IOC0_STATE_REG; ioc->ioc_regs.hfn_mbox_cmd = rb + ct_p1reg[pcifn].hfn; ioc->ioc_regs.lpu_mbox_cmd = rb + ct_p1reg[pcifn].lpu; ioc->ioc_regs.ll_halt = rb + FW_INIT_HALT_P1; ioc->ioc_regs.alt_ll_halt = rb + FW_INIT_HALT_P0; } /* * PSS control registers */ ioc->ioc_regs.pss_ctl_reg = rb + PSS_CTL_REG; ioc->ioc_regs.pss_err_status_reg = rb + PSS_ERR_STATUS_REG; ioc->ioc_regs.app_pll_fast_ctl_reg = rb + APP_PLL_LCLK_CTL_REG; ioc->ioc_regs.app_pll_slow_ctl_reg = rb + APP_PLL_SCLK_CTL_REG; /* * IOC semaphore registers and serialization */ ioc->ioc_regs.ioc_sem_reg = rb + HOST_SEM0_REG; ioc->ioc_regs.ioc_usage_sem_reg = rb + HOST_SEM1_REG; ioc->ioc_regs.ioc_init_sem_reg = rb + HOST_SEM2_REG; ioc->ioc_regs.ioc_usage_reg = rb + BFA_FW_USE_COUNT; ioc->ioc_regs.ioc_fail_sync = rb + BFA_IOC_FAIL_SYNC; /** * sram memory access */ ioc->ioc_regs.smem_page_start = rb + PSS_SMEM_PAGE_START; ioc->ioc_regs.smem_pg0 = BFI_IOC_SMEM_PG0_CT; /* * err set reg : for notification of hb failure in fcmode */ ioc->ioc_regs.err_set = (rb + ERR_SET_REG); } static void bfa_ioc_ct2_reg_init(struct bfa_ioc *ioc) { void __iomem *rb; int port = bfa_ioc_portid(ioc); rb = bfa_ioc_bar0(ioc); ioc->ioc_regs.hfn_mbox = rb + ct2_reg[port].hfn_mbox; ioc->ioc_regs.lpu_mbox = rb + ct2_reg[port].lpu_mbox; ioc->ioc_regs.host_page_num_fn = rb + ct2_reg[port].hfn_pgn; ioc->ioc_regs.hfn_mbox_cmd = rb + ct2_reg[port].hfn; ioc->ioc_regs.lpu_mbox_cmd = rb + ct2_reg[port].lpu; ioc->ioc_regs.lpu_read_stat = rb + ct2_reg[port].lpu_read; if (port == 0) { ioc->ioc_regs.heartbeat = rb + CT2_BFA_IOC0_HBEAT_REG; ioc->ioc_regs.ioc_fwstate = rb + CT2_BFA_IOC0_STATE_REG; ioc->ioc_regs.alt_ioc_fwstate = rb + CT2_BFA_IOC1_STATE_REG; ioc->ioc_regs.ll_halt = rb + FW_INIT_HALT_P0; ioc->ioc_regs.alt_ll_halt = rb + FW_INIT_HALT_P1; } else { ioc->ioc_regs.heartbeat = rb + CT2_BFA_IOC1_HBEAT_REG; ioc->ioc_regs.ioc_fwstate = rb + CT2_BFA_IOC1_STATE_REG; ioc->ioc_regs.alt_ioc_fwstate = rb + CT2_BFA_IOC0_STATE_REG; ioc->ioc_regs.ll_halt = rb + FW_INIT_HALT_P1; ioc->ioc_regs.alt_ll_halt = rb + FW_INIT_HALT_P0; } /* * PSS control registers */ ioc->ioc_regs.pss_ctl_reg = rb + PSS_CTL_REG; ioc->ioc_regs.pss_err_status_reg = rb + PSS_ERR_STATUS_REG; ioc->ioc_regs.app_pll_fast_ctl_reg = rb + CT2_APP_PLL_LCLK_CTL_REG; ioc->ioc_regs.app_pll_slow_ctl_reg = rb + CT2_APP_PLL_SCLK_CTL_REG; /* * IOC semaphore registers and serialization */ ioc->ioc_regs.ioc_sem_reg = rb + CT2_HOST_SEM0_REG; ioc->ioc_regs.ioc_usage_sem_reg = rb + CT2_HOST_SEM1_REG; ioc->ioc_regs.ioc_init_sem_reg = rb + CT2_HOST_SEM2_REG; ioc->ioc_regs.ioc_usage_reg = rb + CT2_BFA_FW_USE_COUNT; ioc->ioc_regs.ioc_fail_sync = rb + CT2_BFA_IOC_FAIL_SYNC; /** * sram memory access */ ioc->ioc_regs.smem_page_start = rb + PSS_SMEM_PAGE_START; ioc->ioc_regs.smem_pg0 = BFI_IOC_SMEM_PG0_CT; /* * err set reg : for notification of hb failure in fcmode */ ioc->ioc_regs.err_set = rb + ERR_SET_REG; } /* Initialize IOC to port mapping. */ #define FNC_PERS_FN_SHIFT(__fn) ((__fn) * 8) static void bfa_ioc_ct_map_port(struct bfa_ioc *ioc) { void __iomem *rb = ioc->pcidev.pci_bar_kva; u32 r32; /** * For catapult, base port id on personality register and IOC type */ r32 = readl(rb + FNC_PERS_REG); r32 >>= FNC_PERS_FN_SHIFT(bfa_ioc_pcifn(ioc)); ioc->port_id = (r32 & __F0_PORT_MAP_MK) >> __F0_PORT_MAP_SH; } static void bfa_ioc_ct2_map_port(struct bfa_ioc *ioc) { void __iomem *rb = ioc->pcidev.pci_bar_kva; u32 r32; r32 = readl(rb + CT2_HOSTFN_PERSONALITY0); ioc->port_id = ((r32 & __FC_LL_PORT_MAP__MK) >> __FC_LL_PORT_MAP__SH); } /* Set interrupt mode for a function: INTX or MSIX */ static void bfa_ioc_ct_isr_mode_set(struct bfa_ioc *ioc, bool msix) { void __iomem *rb = ioc->pcidev.pci_bar_kva; u32 r32, mode; r32 = readl(rb + FNC_PERS_REG); mode = (r32 >> FNC_PERS_FN_SHIFT(bfa_ioc_pcifn(ioc))) & __F0_INTX_STATUS; /** * If already in desired mode, do not change anything */ if ((!msix && mode) || (msix && !mode)) return; if (msix) mode = __F0_INTX_STATUS_MSIX; else mode = __F0_INTX_STATUS_INTA; r32 &= ~(__F0_INTX_STATUS << FNC_PERS_FN_SHIFT(bfa_ioc_pcifn(ioc))); r32 |= (mode << FNC_PERS_FN_SHIFT(bfa_ioc_pcifn(ioc))); writel(r32, rb + FNC_PERS_REG); } static bool bfa_ioc_ct2_lpu_read_stat(struct bfa_ioc *ioc) { u32 r32; r32 = readl(ioc->ioc_regs.lpu_read_stat); if (r32) { writel(1, ioc->ioc_regs.lpu_read_stat); return true; } return false; } /* MSI-X resource allocation for 1860 with no asic block */ #define HOSTFN_MSIX_DEFAULT 64 #define HOSTFN_MSIX_VT_INDEX_MBOX_ERR 0x30138 #define HOSTFN_MSIX_VT_OFST_NUMVT 0x3013c #define __MSIX_VT_NUMVT__MK 0x003ff800 #define __MSIX_VT_NUMVT__SH 11 #define __MSIX_VT_NUMVT_(_v) ((_v) << __MSIX_VT_NUMVT__SH) #define __MSIX_VT_OFST_ 0x000007ff void bfa_nw_ioc_ct2_poweron(struct bfa_ioc *ioc) { void __iomem *rb = ioc->pcidev.pci_bar_kva; u32 r32; r32 = readl(rb + HOSTFN_MSIX_VT_OFST_NUMVT); if (r32 & __MSIX_VT_NUMVT__MK) { writel(r32 & __MSIX_VT_OFST_, rb + HOSTFN_MSIX_VT_INDEX_MBOX_ERR); return; } writel(__MSIX_VT_NUMVT_(HOSTFN_MSIX_DEFAULT - 1) | HOSTFN_MSIX_DEFAULT * bfa_ioc_pcifn(ioc), rb + HOSTFN_MSIX_VT_OFST_NUMVT); writel(HOSTFN_MSIX_DEFAULT * bfa_ioc_pcifn(ioc), rb + HOSTFN_MSIX_VT_INDEX_MBOX_ERR); } /* Cleanup hw semaphore and usecnt registers */ static void bfa_ioc_ct_ownership_reset(struct bfa_ioc *ioc) { bfa_nw_ioc_sem_get(ioc->ioc_regs.ioc_usage_sem_reg); writel(0, ioc->ioc_regs.ioc_usage_reg); bfa_nw_ioc_sem_release(ioc->ioc_regs.ioc_usage_sem_reg); /* * Read the hw sem reg to make sure that it is locked * before we clear it. If it is not locked, writing 1 * will lock it instead of clearing it. */ readl(ioc->ioc_regs.ioc_sem_reg); bfa_nw_ioc_hw_sem_release(ioc); } /* Synchronized IOC failure processing routines */ static bool bfa_ioc_ct_sync_start(struct bfa_ioc *ioc) { u32 r32 = readl(ioc->ioc_regs.ioc_fail_sync); u32 sync_reqd = bfa_ioc_ct_get_sync_reqd(r32); /* * Driver load time. If the sync required bit for this PCI fn * is set, it is due to an unclean exit by the driver for this * PCI fn in the previous incarnation. Whoever comes here first * should clean it up, no matter which PCI fn. */ if (sync_reqd & bfa_ioc_ct_sync_pos(ioc)) { writel(0, ioc->ioc_regs.ioc_fail_sync); writel(1, ioc->ioc_regs.ioc_usage_reg); writel(BFI_IOC_UNINIT, ioc->ioc_regs.ioc_fwstate); writel(BFI_IOC_UNINIT, ioc->ioc_regs.alt_ioc_fwstate); return true; } return bfa_ioc_ct_sync_complete(ioc); } /* Synchronized IOC failure processing routines */ static void bfa_ioc_ct_sync_join(struct bfa_ioc *ioc) { u32 r32 = readl(ioc->ioc_regs.ioc_fail_sync); u32 sync_pos = bfa_ioc_ct_sync_reqd_pos(ioc); writel((r32 | sync_pos), ioc->ioc_regs.ioc_fail_sync); } static void bfa_ioc_ct_sync_leave(struct bfa_ioc *ioc) { u32 r32 = readl(ioc->ioc_regs.ioc_fail_sync); u32 sync_msk = bfa_ioc_ct_sync_reqd_pos(ioc) | bfa_ioc_ct_sync_pos(ioc); writel((r32 & ~sync_msk), ioc->ioc_regs.ioc_fail_sync); } static void bfa_ioc_ct_sync_ack(struct bfa_ioc *ioc) { u32 r32 = readl(ioc->ioc_regs.ioc_fail_sync); writel(r32 | bfa_ioc_ct_sync_pos(ioc), ioc->ioc_regs.ioc_fail_sync); } static bool bfa_ioc_ct_sync_complete(struct bfa_ioc *ioc) { u32 r32 = readl(ioc->ioc_regs.ioc_fail_sync); u32 sync_reqd = bfa_ioc_ct_get_sync_reqd(r32); u32 sync_ackd = bfa_ioc_ct_get_sync_ackd(r32); u32 tmp_ackd; if (sync_ackd == 0) return true; /** * The check below is to see whether any other PCI fn * has reinitialized the ASIC (reset sync_ackd bits) * and failed again while this IOC was waiting for hw * semaphore (in bfa_iocpf_sm_semwait()). */ tmp_ackd = sync_ackd; if ((sync_reqd & bfa_ioc_ct_sync_pos(ioc)) && !(sync_ackd & bfa_ioc_ct_sync_pos(ioc))) sync_ackd |= bfa_ioc_ct_sync_pos(ioc); if (sync_reqd == sync_ackd) { writel(bfa_ioc_ct_clear_sync_ackd(r32), ioc->ioc_regs.ioc_fail_sync); writel(BFI_IOC_FAIL, ioc->ioc_regs.ioc_fwstate); writel(BFI_IOC_FAIL, ioc->ioc_regs.alt_ioc_fwstate); return true; } /** * If another PCI fn reinitialized and failed again while * this IOC was waiting for hw sem, the sync_ackd bit for * this IOC need to be set again to allow reinitialization. */ if (tmp_ackd != sync_ackd) writel((r32 | sync_ackd), ioc->ioc_regs.ioc_fail_sync); return false; } static void bfa_ioc_ct_set_cur_ioc_fwstate(struct bfa_ioc *ioc, enum bfi_ioc_state fwstate) { writel(fwstate, ioc->ioc_regs.ioc_fwstate); } static enum bfi_ioc_state bfa_ioc_ct_get_cur_ioc_fwstate(struct bfa_ioc *ioc) { return (enum bfi_ioc_state)readl(ioc->ioc_regs.ioc_fwstate); } static void bfa_ioc_ct_set_alt_ioc_fwstate(struct bfa_ioc *ioc, enum bfi_ioc_state fwstate) { writel(fwstate, ioc->ioc_regs.alt_ioc_fwstate); } static enum bfi_ioc_state bfa_ioc_ct_get_alt_ioc_fwstate(struct bfa_ioc *ioc) { return (enum bfi_ioc_state)readl(ioc->ioc_regs.alt_ioc_fwstate); } static enum bfa_status bfa_ioc_ct_pll_init(void __iomem *rb, enum bfi_asic_mode asic_mode) { u32 pll_sclk, pll_fclk, r32; bool fcmode = (asic_mode == BFI_ASIC_MODE_FC); pll_sclk = __APP_PLL_SCLK_LRESETN | __APP_PLL_SCLK_ENARST | __APP_PLL_SCLK_RSEL200500 | __APP_PLL_SCLK_P0_1(3U) | __APP_PLL_SCLK_JITLMT0_1(3U) | __APP_PLL_SCLK_CNTLMT0_1(1U); pll_fclk = __APP_PLL_LCLK_LRESETN | __APP_PLL_LCLK_ENARST | __APP_PLL_LCLK_RSEL200500 | __APP_PLL_LCLK_P0_1(3U) | __APP_PLL_LCLK_JITLMT0_1(3U) | __APP_PLL_LCLK_CNTLMT0_1(1U); if (fcmode) { writel(0, (rb + OP_MODE)); writel(__APP_EMS_CMLCKSEL | __APP_EMS_REFCKBUFEN2 | __APP_EMS_CHANNEL_SEL, (rb + ETH_MAC_SER_REG)); } else { writel(__GLOBAL_FCOE_MODE, (rb + OP_MODE)); writel(__APP_EMS_REFCKBUFEN1, (rb + ETH_MAC_SER_REG)); } writel(BFI_IOC_UNINIT, (rb + BFA_IOC0_STATE_REG)); writel(BFI_IOC_UNINIT, (rb + BFA_IOC1_STATE_REG)); writel(0xffffffffU, (rb + HOSTFN0_INT_MSK)); writel(0xffffffffU, (rb + HOSTFN1_INT_MSK)); writel(0xffffffffU, (rb + HOSTFN0_INT_STATUS)); writel(0xffffffffU, (rb + HOSTFN1_INT_STATUS)); writel(0xffffffffU, (rb + HOSTFN0_INT_MSK)); writel(0xffffffffU, (rb + HOSTFN1_INT_MSK)); writel(pll_sclk | __APP_PLL_SCLK_LOGIC_SOFT_RESET, rb + APP_PLL_SCLK_CTL_REG); writel(pll_fclk | __APP_PLL_LCLK_LOGIC_SOFT_RESET, rb + APP_PLL_LCLK_CTL_REG); writel(pll_sclk | __APP_PLL_SCLK_LOGIC_SOFT_RESET | __APP_PLL_SCLK_ENABLE, rb + APP_PLL_SCLK_CTL_REG); writel(pll_fclk | __APP_PLL_LCLK_LOGIC_SOFT_RESET | __APP_PLL_LCLK_ENABLE, rb + APP_PLL_LCLK_CTL_REG); readl(rb + HOSTFN0_INT_MSK); udelay(2000); writel(0xffffffffU, (rb + HOSTFN0_INT_STATUS)); writel(0xffffffffU, (rb + HOSTFN1_INT_STATUS)); writel(pll_sclk | __APP_PLL_SCLK_ENABLE, rb + APP_PLL_SCLK_CTL_REG); writel(pll_fclk | __APP_PLL_LCLK_ENABLE, rb + APP_PLL_LCLK_CTL_REG); if (!fcmode) { writel(__PMM_1T_RESET_P, (rb + PMM_1T_RESET_REG_P0)); writel(__PMM_1T_RESET_P, (rb + PMM_1T_RESET_REG_P1)); } r32 = readl(rb + PSS_CTL_REG); r32 &= ~__PSS_LMEM_RESET; writel(r32, (rb + PSS_CTL_REG)); udelay(1000); if (!fcmode) { writel(0, (rb + PMM_1T_RESET_REG_P0)); writel(0, (rb + PMM_1T_RESET_REG_P1)); } writel(__EDRAM_BISTR_START, (rb + MBIST_CTL_REG)); udelay(1000); r32 = readl(rb + MBIST_STAT_REG); writel(0, (rb + MBIST_CTL_REG)); return BFA_STATUS_OK; } static void bfa_ioc_ct2_sclk_init(void __iomem *rb) { u32 r32; /* * put s_clk PLL and PLL FSM in reset */ r32 = readl(rb + CT2_APP_PLL_SCLK_CTL_REG); r32 &= ~(__APP_PLL_SCLK_ENABLE | __APP_PLL_SCLK_LRESETN); r32 |= (__APP_PLL_SCLK_ENARST | __APP_PLL_SCLK_BYPASS | __APP_PLL_SCLK_LOGIC_SOFT_RESET); writel(r32, (rb + CT2_APP_PLL_SCLK_CTL_REG)); /* * Ignore mode and program for the max clock (which is FC16) * Firmware/NFC will do the PLL init appropriately */ r32 = readl(rb + CT2_APP_PLL_SCLK_CTL_REG); r32 &= ~(__APP_PLL_SCLK_REFCLK_SEL | __APP_PLL_SCLK_CLK_DIV2); writel(r32, (rb + CT2_APP_PLL_SCLK_CTL_REG)); /* * while doing PLL init dont clock gate ethernet subsystem */ r32 = readl(rb + CT2_CHIP_MISC_PRG); writel(r32 | __ETH_CLK_ENABLE_PORT0, rb + CT2_CHIP_MISC_PRG); r32 = readl(rb + CT2_PCIE_MISC_REG); writel(r32 | __ETH_CLK_ENABLE_PORT1, rb + CT2_PCIE_MISC_REG); /* * set sclk value */ r32 = readl(rb + CT2_APP_PLL_SCLK_CTL_REG); r32 &= (__P_SCLK_PLL_LOCK | __APP_PLL_SCLK_REFCLK_SEL | __APP_PLL_SCLK_CLK_DIV2); writel(r32 | 0x1061731b, rb + CT2_APP_PLL_SCLK_CTL_REG); /* * poll for s_clk lock or delay 1ms */ udelay(1000); /* * Dont do clock gating for ethernet subsystem, firmware/NFC will * do this appropriately */ } static void bfa_ioc_ct2_lclk_init(void __iomem *rb) { u32 r32; /* * put l_clk PLL and PLL FSM in reset */ r32 = readl(rb + CT2_APP_PLL_LCLK_CTL_REG); r32 &= ~(__APP_PLL_LCLK_ENABLE | __APP_PLL_LCLK_LRESETN); r32 |= (__APP_PLL_LCLK_ENARST | __APP_PLL_LCLK_BYPASS | __APP_PLL_LCLK_LOGIC_SOFT_RESET); writel(r32, rb + CT2_APP_PLL_LCLK_CTL_REG); /* * set LPU speed (set for FC16 which will work for other modes) */ r32 = readl(rb + CT2_CHIP_MISC_PRG); writel(r32, (rb + CT2_CHIP_MISC_PRG)); /* * set LPU half speed (set for FC16 which will work for other modes) */ r32 = readl(rb + CT2_APP_PLL_LCLK_CTL_REG); writel(r32, rb + CT2_APP_PLL_LCLK_CTL_REG); /* * set lclk for mode (set for FC16) */ r32 = readl(rb + CT2_APP_PLL_LCLK_CTL_REG); r32 &= (__P_LCLK_PLL_LOCK | __APP_LPUCLK_HALFSPEED); r32 |= 0x20c1731b; writel(r32, (rb + CT2_APP_PLL_LCLK_CTL_REG)); /* * poll for s_clk lock or delay 1ms */ udelay(1000); } static void bfa_ioc_ct2_mem_init(void __iomem *rb) { u32 r32; r32 = readl(rb + PSS_CTL_REG); r32 &= ~__PSS_LMEM_RESET; writel(r32, rb + PSS_CTL_REG); udelay(1000); writel(__EDRAM_BISTR_START, rb + CT2_MBIST_CTL_REG); udelay(1000); writel(0, rb + CT2_MBIST_CTL_REG); } static void bfa_ioc_ct2_mac_reset(void __iomem *rb) { volatile u32 r32; bfa_ioc_ct2_sclk_init(rb); bfa_ioc_ct2_lclk_init(rb); /* * release soft reset on s_clk & l_clk */ r32 = readl(rb + CT2_APP_PLL_SCLK_CTL_REG); writel(r32 & ~__APP_PLL_SCLK_LOGIC_SOFT_RESET, rb + CT2_APP_PLL_SCLK_CTL_REG); /* * release soft reset on s_clk & l_clk */ r32 = readl(rb + CT2_APP_PLL_LCLK_CTL_REG); writel(r32 & ~__APP_PLL_LCLK_LOGIC_SOFT_RESET, rb + CT2_APP_PLL_LCLK_CTL_REG); /* put port0, port1 MAC & AHB in reset */ writel(__CSI_MAC_RESET | __CSI_MAC_AHB_RESET, rb + CT2_CSI_MAC_CONTROL_REG(0)); writel(__CSI_MAC_RESET | __CSI_MAC_AHB_RESET, rb + CT2_CSI_MAC_CONTROL_REG(1)); } #define CT2_NFC_MAX_DELAY 1000 #define CT2_NFC_VER_VALID 0x143 #define BFA_IOC_PLL_POLL 1000000 static bool bfa_ioc_ct2_nfc_halted(void __iomem *rb) { volatile u32 r32; r32 = readl(rb + CT2_NFC_CSR_SET_REG); if (r32 & __NFC_CONTROLLER_HALTED) return true; return false; } static void bfa_ioc_ct2_nfc_resume(void __iomem *rb) { volatile u32 r32; int i; writel(__HALT_NFC_CONTROLLER, rb + CT2_NFC_CSR_CLR_REG); for (i = 0; i < CT2_NFC_MAX_DELAY; i++) { r32 = readl(rb + CT2_NFC_CSR_SET_REG); if (!(r32 & __NFC_CONTROLLER_HALTED)) return; udelay(1000); } BUG_ON(1); } static enum bfa_status bfa_ioc_ct2_pll_init(void __iomem *rb, enum bfi_asic_mode asic_mode) { volatile u32 wgn, r32; u32 nfc_ver, i; wgn = readl(rb + CT2_WGN_STATUS); nfc_ver = readl(rb + CT2_RSC_GPR15_REG); if (wgn == (__A2T_AHB_LOAD | __WGN_READY) && nfc_ver >= CT2_NFC_VER_VALID) { if (bfa_ioc_ct2_nfc_halted(rb)) bfa_ioc_ct2_nfc_resume(rb); writel(__RESET_AND_START_SCLK_LCLK_PLLS, rb + CT2_CSI_FW_CTL_SET_REG); for (i = 0; i < BFA_IOC_PLL_POLL; i++) { r32 = readl(rb + CT2_APP_PLL_LCLK_CTL_REG); if (r32 & __RESET_AND_START_SCLK_LCLK_PLLS) break; } BUG_ON(!(r32 & __RESET_AND_START_SCLK_LCLK_PLLS)); for (i = 0; i < BFA_IOC_PLL_POLL; i++) { r32 = readl(rb + CT2_APP_PLL_LCLK_CTL_REG); if (!(r32 & __RESET_AND_START_SCLK_LCLK_PLLS)) break; } BUG_ON(r32 & __RESET_AND_START_SCLK_LCLK_PLLS); udelay(1000); r32 = readl(rb + CT2_CSI_FW_CTL_REG); BUG_ON(r32 & __RESET_AND_START_SCLK_LCLK_PLLS); } else { writel(__HALT_NFC_CONTROLLER, (rb + CT2_NFC_CSR_SET_REG)); for (i = 0; i < CT2_NFC_MAX_DELAY; i++) { r32 = readl(rb + CT2_NFC_CSR_SET_REG); if (r32 & __NFC_CONTROLLER_HALTED) break; udelay(1000); } bfa_ioc_ct2_mac_reset(rb); bfa_ioc_ct2_sclk_init(rb); bfa_ioc_ct2_lclk_init(rb); /* release soft reset on s_clk & l_clk */ r32 = readl(rb + CT2_APP_PLL_SCLK_CTL_REG); writel(r32 & ~__APP_PLL_SCLK_LOGIC_SOFT_RESET, rb + CT2_APP_PLL_SCLK_CTL_REG); r32 = readl(rb + CT2_APP_PLL_LCLK_CTL_REG); writel(r32 & ~__APP_PLL_LCLK_LOGIC_SOFT_RESET, rb + CT2_APP_PLL_LCLK_CTL_REG); } /* Announce flash device presence, if flash was corrupted. */ if (wgn == (__WGN_READY | __GLBL_PF_VF_CFG_RDY)) { r32 = readl(rb + PSS_GPIO_OUT_REG); writel(r32 & ~1, rb + PSS_GPIO_OUT_REG); r32 = readl(rb + PSS_GPIO_OE_REG); writel(r32 | 1, rb + PSS_GPIO_OE_REG); } /* * Mask the interrupts and clear any * pending interrupts left by BIOS/EFI */ writel(1, rb + CT2_LPU0_HOSTFN_MBOX0_MSK); writel(1, rb + CT2_LPU1_HOSTFN_MBOX0_MSK); /* For first time initialization, no need to clear interrupts */ r32 = readl(rb + HOST_SEM5_REG); if (r32 & 0x1) { r32 = readl(rb + CT2_LPU0_HOSTFN_CMD_STAT); if (r32 == 1) { writel(1, rb + CT2_LPU0_HOSTFN_CMD_STAT); readl(rb + CT2_LPU0_HOSTFN_CMD_STAT); } r32 = readl(rb + CT2_LPU1_HOSTFN_CMD_STAT); if (r32 == 1) { writel(1, rb + CT2_LPU1_HOSTFN_CMD_STAT); readl(rb + CT2_LPU1_HOSTFN_CMD_STAT); } } bfa_ioc_ct2_mem_init(rb); writel(BFI_IOC_UNINIT, rb + CT2_BFA_IOC0_STATE_REG); writel(BFI_IOC_UNINIT, rb + CT2_BFA_IOC1_STATE_REG); return BFA_STATUS_OK; }
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