/* * Linux DHD Bus Module for PCIE * * Copyright (C) 1999-2019, Broadcom. * * Unless you and Broadcom execute a separate written software license * agreement governing use of this software, this software is licensed to you * under the terms of the GNU General Public License version 2 (the "GPL"), * available at http://www.broadcom.com/licenses/GPLv2.php, with the * following added to such license: * * As a special exception, the copyright holders of this software give you * permission to link this software with independent modules, and to copy and * distribute the resulting executable under terms of your choice, provided that * you also meet, for each linked independent module, the terms and conditions of * the license of that module. An independent module is a module which is not * derived from this software. The special exception does not apply to any * modifications of the software. * * Notwithstanding the above, under no circumstances may you combine this * software in any way with any other Broadcom software provided under a license * other than the GPL, without Broadcom's express prior written consent. * * * <> * * $Id: dhd_pcie_linux.c 821650 2019-05-24 10:41:54Z $ */ /* include files */ #include #include #include #include #include #include #include #if defined(DHD_DEBUG) #include #include #endif /* defined(DHD_DEBUG) */ #include #include #include #include #include #include #include #include #include #include #include #ifdef CONFIG_ARCH_MSM #if defined(CONFIG_PCI_MSM) || defined(CONFIG_ARCH_MSM8996) #include #else #include #endif /* CONFIG_PCI_MSM */ #endif /* CONFIG_ARCH_MSM */ #ifdef DHD_PCIE_NATIVE_RUNTIMEPM #include #endif /* DHD_PCIE_NATIVE_RUNTIMEPM */ #ifdef DHD_PCIE_NATIVE_RUNTIMEPM #ifndef AUTO_SUSPEND_TIMEOUT #define AUTO_SUSPEND_TIMEOUT 1000 #endif /* AUTO_SUSPEND_TIMEOUT */ #endif /* DHD_PCIE_NATIVE_RUNTIMEPM */ #include #ifdef USE_SMMU_ARCH_MSM #include #include #include #include #endif /* USE_SMMU_ARCH_MSM */ #define PCI_CFG_RETRY 10 #define OS_HANDLE_MAGIC 0x1234abcd /* Magic # to recognize osh */ #define BCM_MEM_FILENAME_LEN 24 /* Mem. filename length */ #ifdef FORCE_TPOWERON extern uint32 tpoweron_scale; #endif /* FORCE_TPOWERON */ /* user defined data structures */ typedef bool (*dhdpcie_cb_fn_t)(void *); typedef struct dhdpcie_info { dhd_bus_t *bus; osl_t *osh; struct pci_dev *dev; /* pci device handle */ volatile char *regs; /* pci device memory va */ volatile char *tcm; /* pci device memory va */ uint32 bar1_size; /* pci device memory size */ uint32 curr_bar1_win; /* current PCIEBar1Window setting */ struct pcos_info *pcos_info; uint16 last_intrstatus; /* to cache intrstatus */ int irq; char pciname[32]; struct pci_saved_state* default_state; struct pci_saved_state* state; #ifdef BCMPCIE_OOB_HOST_WAKE void *os_cxt; /* Pointer to per-OS private data */ #endif /* BCMPCIE_OOB_HOST_WAKE */ #ifdef DHD_WAKE_STATUS spinlock_t pcie_lock; unsigned int total_wake_count; int pkt_wake; int wake_irq; #endif /* DHD_WAKE_STATUS */ #ifdef USE_SMMU_ARCH_MSM void *smmu_cxt; #endif /* USE_SMMU_ARCH_MSM */ } dhdpcie_info_t; struct pcos_info { dhdpcie_info_t *pc; spinlock_t lock; wait_queue_head_t intr_wait_queue; struct timer_list tuning_timer; int tuning_timer_exp; atomic_t timer_enab; struct tasklet_struct tuning_tasklet; }; #ifdef BCMPCIE_OOB_HOST_WAKE typedef struct dhdpcie_os_info { int oob_irq_num; /* valid when hardware or software oob in use */ unsigned long oob_irq_flags; /* valid when hardware or software oob in use */ bool oob_irq_registered; bool oob_irq_enabled; bool oob_irq_wake_enabled; spinlock_t oob_irq_spinlock; void *dev; /* handle to the underlying device */ } dhdpcie_os_info_t; static irqreturn_t wlan_oob_irq(int irq, void *data); #ifdef CUSTOMER_HW2 extern struct brcm_pcie_wake brcm_pcie_wake; #endif /* CUSTOMER_HW2 */ #endif /* BCMPCIE_OOB_HOST_WAKE */ #ifdef USE_SMMU_ARCH_MSM typedef struct dhdpcie_smmu_info { struct dma_iommu_mapping *smmu_mapping; dma_addr_t smmu_iova_start; size_t smmu_iova_len; } dhdpcie_smmu_info_t; #endif /* USE_SMMU_ARCH_MSM */ /* function declarations */ static int __devinit dhdpcie_pci_probe(struct pci_dev *pdev, const struct pci_device_id *ent); static void __devexit dhdpcie_pci_remove(struct pci_dev *pdev); static int dhdpcie_init(struct pci_dev *pdev); static irqreturn_t dhdpcie_isr(int irq, void *arg); /* OS Routine functions for PCI suspend/resume */ #ifdef DHD_PCIE_NATIVE_RUNTIMEPM static int dhdpcie_set_suspend_resume(struct pci_dev *dev, bool state, bool byint); #else static int dhdpcie_set_suspend_resume(dhd_bus_t *bus, bool state); #endif /* DHD_PCIE_NATIVE_RUNTIMEPM */ static int dhdpcie_resume_host_dev(dhd_bus_t *bus); static int dhdpcie_suspend_host_dev(dhd_bus_t *bus); static int dhdpcie_resume_dev(struct pci_dev *dev); static int dhdpcie_suspend_dev(struct pci_dev *dev); #ifdef DHD_PCIE_NATIVE_RUNTIMEPM static int dhdpcie_pm_system_suspend_noirq(struct device * dev); static int dhdpcie_pm_system_resume_noirq(struct device * dev); #else static int dhdpcie_pci_suspend(struct pci_dev *dev, pm_message_t state); static int dhdpcie_pci_resume(struct pci_dev *dev); #endif /* DHD_PCIE_NATIVE_RUNTIMEPM */ #ifdef DHD_PCIE_NATIVE_RUNTIMEPM static int dhdpcie_pm_runtime_suspend(struct device * dev); static int dhdpcie_pm_runtime_resume(struct device * dev); static int dhdpcie_pm_system_suspend_noirq(struct device * dev); static int dhdpcie_pm_system_resume_noirq(struct device * dev); #endif /* DHD_PCIE_NATIVE_RUNTIMEPM */ static void dhdpcie_config_save_restore_coherent(dhd_bus_t *bus, bool state); uint32 dhdpcie_access_cap(struct pci_dev *pdev, int cap, uint offset, bool is_ext, bool is_write, uint32 writeval); static struct pci_device_id dhdpcie_pci_devid[] __devinitdata = { { vendor: 0x14e4, device: PCI_ANY_ID, subvendor: PCI_ANY_ID, subdevice: PCI_ANY_ID, class: PCI_CLASS_NETWORK_OTHER << 8, class_mask: 0xffff00, driver_data: 0, }, { 0, 0, 0, 0, 0, 0, 0} }; MODULE_DEVICE_TABLE(pci, dhdpcie_pci_devid); /* Power Management Hooks */ #ifdef DHD_PCIE_NATIVE_RUNTIMEPM static const struct dev_pm_ops dhdpcie_pm_ops = { SET_RUNTIME_PM_OPS(dhdpcie_pm_runtime_suspend, dhdpcie_pm_runtime_resume, NULL) .suspend_noirq = dhdpcie_pm_system_suspend_noirq, .resume_noirq = dhdpcie_pm_system_resume_noirq }; #endif /* DHD_PCIE_NATIVE_RUNTIMEPM */ static struct pci_driver dhdpcie_driver = { node: {&dhdpcie_driver.node, &dhdpcie_driver.node}, name: "pcieh", id_table: dhdpcie_pci_devid, probe: dhdpcie_pci_probe, remove: dhdpcie_pci_remove, #if defined(DHD_PCIE_NATIVE_RUNTIMEPM) .driver.pm = &dhd_pcie_pm_ops, #else suspend: dhdpcie_pci_suspend, resume: dhdpcie_pci_resume, #endif // endif }; int dhdpcie_init_succeeded = FALSE; #ifdef USE_SMMU_ARCH_MSM static int dhdpcie_smmu_init(struct pci_dev *pdev, void *smmu_cxt) { struct dma_iommu_mapping *mapping; struct device_node *root_node = NULL; dhdpcie_smmu_info_t *smmu_info = (dhdpcie_smmu_info_t *)smmu_cxt; int smmu_iova_address[2]; char *wlan_node = "android,bcmdhd_wlan"; char *wlan_smmu_node = "wlan-smmu-iova-address"; int atomic_ctx = 1; int s1_bypass = 1; int ret = 0; DHD_ERROR(("%s: SMMU initialize\n", __FUNCTION__)); root_node = of_find_compatible_node(NULL, NULL, wlan_node); if (!root_node) { WARN(1, "failed to get device node of BRCM WLAN\n"); return -ENODEV; } if (of_property_read_u32_array(root_node, wlan_smmu_node, smmu_iova_address, 2) == 0) { DHD_ERROR(("%s : get SMMU start address 0x%x, size 0x%x\n", __FUNCTION__, smmu_iova_address[0], smmu_iova_address[1])); smmu_info->smmu_iova_start = smmu_iova_address[0]; smmu_info->smmu_iova_len = smmu_iova_address[1]; } else { printf("%s : can't get smmu iova address property\n", __FUNCTION__); return -ENODEV; } if (smmu_info->smmu_iova_len <= 0) { DHD_ERROR(("%s: Invalid smmu iova len %d\n", __FUNCTION__, (int)smmu_info->smmu_iova_len)); return -EINVAL; } DHD_ERROR(("%s : SMMU init start\n", __FUNCTION__)); if (pci_set_dma_mask(pdev, DMA_BIT_MASK(64)) || pci_set_consistent_dma_mask(pdev, DMA_BIT_MASK(64))) { DHD_ERROR(("%s: DMA set 64bit mask failed.\n", __FUNCTION__)); return -EINVAL; } mapping = arm_iommu_create_mapping(&platform_bus_type, smmu_info->smmu_iova_start, smmu_info->smmu_iova_len); if (IS_ERR(mapping)) { DHD_ERROR(("%s: create mapping failed, err = %d\n", __FUNCTION__, ret)); ret = PTR_ERR(mapping); goto map_fail; } ret = iommu_domain_set_attr(mapping->domain, DOMAIN_ATTR_ATOMIC, &atomic_ctx); if (ret) { DHD_ERROR(("%s: set atomic_ctx attribute failed, err = %d\n", __FUNCTION__, ret)); goto set_attr_fail; } ret = iommu_domain_set_attr(mapping->domain, DOMAIN_ATTR_S1_BYPASS, &s1_bypass); if (ret < 0) { DHD_ERROR(("%s: set s1_bypass attribute failed, err = %d\n", __FUNCTION__, ret)); goto set_attr_fail; } ret = arm_iommu_attach_device(&pdev->dev, mapping); if (ret) { DHD_ERROR(("%s: attach device failed, err = %d\n", __FUNCTION__, ret)); goto attach_fail; } smmu_info->smmu_mapping = mapping; return ret; attach_fail: set_attr_fail: arm_iommu_release_mapping(mapping); map_fail: return ret; } static void dhdpcie_smmu_remove(struct pci_dev *pdev, void *smmu_cxt) { dhdpcie_smmu_info_t *smmu_info; if (!smmu_cxt) { return; } smmu_info = (dhdpcie_smmu_info_t *)smmu_cxt; if (smmu_info->smmu_mapping) { arm_iommu_detach_device(&pdev->dev); arm_iommu_release_mapping(smmu_info->smmu_mapping); smmu_info->smmu_mapping = NULL; } } #endif /* USE_SMMU_ARCH_MSM */ #ifdef FORCE_TPOWERON static void dhd_bus_get_tpoweron(dhd_bus_t *bus) { uint32 tpoweron_rc; uint32 tpoweron_ep; tpoweron_rc = dhdpcie_rc_access_cap(bus, PCIE_EXTCAP_ID_L1SS, PCIE_EXTCAP_L1SS_CONTROL2_OFFSET, TRUE, FALSE, 0); tpoweron_ep = dhdpcie_ep_access_cap(bus, PCIE_EXTCAP_ID_L1SS, PCIE_EXTCAP_L1SS_CONTROL2_OFFSET, TRUE, FALSE, 0); DHD_ERROR(("%s: tpoweron_rc:0x%x tpoweron_ep:0x%x\n", __FUNCTION__, tpoweron_rc, tpoweron_ep)); } static void dhd_bus_set_tpoweron(dhd_bus_t *bus, uint16 tpoweron) { dhd_bus_get_tpoweron(bus); /* Set the tpoweron */ DHD_ERROR(("%s tpoweron: 0x%x\n", __FUNCTION__, tpoweron)); dhdpcie_rc_access_cap(bus, PCIE_EXTCAP_ID_L1SS, PCIE_EXTCAP_L1SS_CONTROL2_OFFSET, TRUE, TRUE, tpoweron); dhdpcie_ep_access_cap(bus, PCIE_EXTCAP_ID_L1SS, PCIE_EXTCAP_L1SS_CONTROL2_OFFSET, TRUE, TRUE, tpoweron); dhd_bus_get_tpoweron(bus); } static bool dhdpcie_chip_req_forced_tpoweron(dhd_bus_t *bus) { /* * On Fire's reference platform, coming out of L1.2, * there is a constant delay of 45us between CLKREQ# and stable REFCLK * Due to this delay, with tPowerOn < 50 * there is a chance of the refclk sense to trigger on noise. * * Which ever chip needs forced tPowerOn of 50us should be listed below. */ if (si_chipid(bus->sih) == BCM4377_CHIP_ID) { return TRUE; } return FALSE; } #endif /* FORCE_TPOWERON */ static bool dhd_bus_aspm_enable_dev(dhd_bus_t *bus, struct pci_dev *dev, bool enable) { uint32 linkctrl_before; uint32 linkctrl_after = 0; uint8 linkctrl_asm; char *device; device = (dev == bus->dev) ? "EP" : "RC"; linkctrl_before = dhdpcie_access_cap(dev, PCIE_CAP_ID_EXP, PCIE_CAP_LINKCTRL_OFFSET, FALSE, FALSE, 0); linkctrl_asm = (linkctrl_before & PCIE_ASPM_CTRL_MASK); if (enable) { if (linkctrl_asm == PCIE_ASPM_L1_ENAB) { DHD_ERROR(("%s: %s already enabled linkctrl: 0x%x\n", __FUNCTION__, device, linkctrl_before)); return FALSE; } /* Enable only L1 ASPM (bit 1) */ dhdpcie_access_cap(dev, PCIE_CAP_ID_EXP, PCIE_CAP_LINKCTRL_OFFSET, FALSE, TRUE, (linkctrl_before | PCIE_ASPM_L1_ENAB)); } else { if (linkctrl_asm == 0) { DHD_ERROR(("%s: %s already disabled linkctrl: 0x%x\n", __FUNCTION__, device, linkctrl_before)); return FALSE; } /* Disable complete ASPM (bit 1 and bit 0) */ dhdpcie_access_cap(dev, PCIE_CAP_ID_EXP, PCIE_CAP_LINKCTRL_OFFSET, FALSE, TRUE, (linkctrl_before & (~PCIE_ASPM_ENAB))); } linkctrl_after = dhdpcie_access_cap(dev, PCIE_CAP_ID_EXP, PCIE_CAP_LINKCTRL_OFFSET, FALSE, FALSE, 0); DHD_ERROR(("%s: %s %s, linkctrl_before: 0x%x linkctrl_after: 0x%x\n", __FUNCTION__, device, (enable ? "ENABLE " : "DISABLE"), linkctrl_before, linkctrl_after)); return TRUE; } static bool dhd_bus_is_rc_ep_aspm_capable(dhd_bus_t *bus) { uint32 rc_aspm_cap; uint32 ep_aspm_cap; /* RC ASPM capability */ rc_aspm_cap = dhdpcie_access_cap(bus->rc_dev, PCIE_CAP_ID_EXP, PCIE_CAP_LINKCTRL_OFFSET, FALSE, FALSE, 0); if (rc_aspm_cap == BCME_ERROR) { DHD_ERROR(("%s RC is not ASPM capable\n", __FUNCTION__)); return FALSE; } /* EP ASPM capability */ ep_aspm_cap = dhdpcie_access_cap(bus->dev, PCIE_CAP_ID_EXP, PCIE_CAP_LINKCTRL_OFFSET, FALSE, FALSE, 0); if (ep_aspm_cap == BCME_ERROR) { DHD_ERROR(("%s EP is not ASPM capable\n", __FUNCTION__)); return FALSE; } return TRUE; } bool dhd_bus_aspm_enable_rc_ep(dhd_bus_t *bus, bool enable) { bool ret; if (!bus->rc_ep_aspm_cap) { DHD_ERROR(("%s: NOT ASPM CAPABLE rc_ep_aspm_cap: %d\n", __FUNCTION__, bus->rc_ep_aspm_cap)); return FALSE; } if (enable) { /* Enable only L1 ASPM first RC then EP */ ret = dhd_bus_aspm_enable_dev(bus, bus->rc_dev, enable); ret = dhd_bus_aspm_enable_dev(bus, bus->dev, enable); } else { /* Disable complete ASPM first EP then RC */ ret = dhd_bus_aspm_enable_dev(bus, bus->dev, enable); ret = dhd_bus_aspm_enable_dev(bus, bus->rc_dev, enable); } return ret; } static void dhd_bus_l1ss_enable_dev(dhd_bus_t *bus, struct pci_dev *dev, bool enable) { uint32 l1ssctrl_before; uint32 l1ssctrl_after = 0; uint8 l1ss_ep; char *device; device = (dev == bus->dev) ? "EP" : "RC"; /* Extendend Capacility Reg */ l1ssctrl_before = dhdpcie_access_cap(dev, PCIE_EXTCAP_ID_L1SS, PCIE_EXTCAP_L1SS_CONTROL_OFFSET, TRUE, FALSE, 0); l1ss_ep = (l1ssctrl_before & PCIE_EXT_L1SS_MASK); if (enable) { if (l1ss_ep == PCIE_EXT_L1SS_ENAB) { DHD_ERROR(("%s: %s already enabled, l1ssctrl: 0x%x\n", __FUNCTION__, device, l1ssctrl_before)); return; } dhdpcie_access_cap(dev, PCIE_EXTCAP_ID_L1SS, PCIE_EXTCAP_L1SS_CONTROL_OFFSET, TRUE, TRUE, (l1ssctrl_before | PCIE_EXT_L1SS_ENAB)); } else { if (l1ss_ep == 0) { DHD_ERROR(("%s: %s already disabled, l1ssctrl: 0x%x\n", __FUNCTION__, device, l1ssctrl_before)); return; } dhdpcie_access_cap(dev, PCIE_EXTCAP_ID_L1SS, PCIE_EXTCAP_L1SS_CONTROL_OFFSET, TRUE, TRUE, (l1ssctrl_before & (~PCIE_EXT_L1SS_ENAB))); } l1ssctrl_after = dhdpcie_access_cap(dev, PCIE_EXTCAP_ID_L1SS, PCIE_EXTCAP_L1SS_CONTROL_OFFSET, TRUE, FALSE, 0); DHD_ERROR(("%s: %s %s, l1ssctrl_before: 0x%x l1ssctrl_after: 0x%x\n", __FUNCTION__, device, (enable ? "ENABLE " : "DISABLE"), l1ssctrl_before, l1ssctrl_after)); } static bool dhd_bus_is_rc_ep_l1ss_capable(dhd_bus_t *bus) { uint32 rc_l1ss_cap; uint32 ep_l1ss_cap; /* RC Extendend Capacility */ rc_l1ss_cap = dhdpcie_access_cap(bus->rc_dev, PCIE_EXTCAP_ID_L1SS, PCIE_EXTCAP_L1SS_CONTROL_OFFSET, TRUE, FALSE, 0); if (rc_l1ss_cap == BCME_ERROR) { DHD_ERROR(("%s RC is not l1ss capable\n", __FUNCTION__)); return FALSE; } /* EP Extendend Capacility */ ep_l1ss_cap = dhdpcie_access_cap(bus->dev, PCIE_EXTCAP_ID_L1SS, PCIE_EXTCAP_L1SS_CONTROL_OFFSET, TRUE, FALSE, 0); if (ep_l1ss_cap == BCME_ERROR) { DHD_ERROR(("%s EP is not l1ss capable\n", __FUNCTION__)); return FALSE; } return TRUE; } void dhd_bus_l1ss_enable_rc_ep(dhd_bus_t *bus, bool enable) { bool ret; if ((!bus->rc_ep_aspm_cap) || (!bus->rc_ep_l1ss_cap)) { DHD_ERROR(("%s: NOT L1SS CAPABLE rc_ep_aspm_cap: %d rc_ep_l1ss_cap: %d\n", __FUNCTION__, bus->rc_ep_aspm_cap, bus->rc_ep_l1ss_cap)); return; } /* Disable ASPM of RC and EP */ ret = dhd_bus_aspm_enable_rc_ep(bus, FALSE); if (enable) { /* Enable RC then EP */ dhd_bus_l1ss_enable_dev(bus, bus->rc_dev, enable); dhd_bus_l1ss_enable_dev(bus, bus->dev, enable); } else { /* Disable EP then RC */ dhd_bus_l1ss_enable_dev(bus, bus->dev, enable); dhd_bus_l1ss_enable_dev(bus, bus->rc_dev, enable); } /* Enable ASPM of RC and EP only if this API disabled */ if (ret == TRUE) { dhd_bus_aspm_enable_rc_ep(bus, TRUE); } } void dhd_bus_aer_config(dhd_bus_t *bus) { uint32 val; DHD_ERROR(("%s: Configure AER registers for EP\n", __FUNCTION__)); val = dhdpcie_ep_access_cap(bus, PCIE_ADVERRREP_CAPID, PCIE_ADV_CORR_ERR_MASK_OFFSET, TRUE, FALSE, 0); if (val != (uint32)-1) { val &= ~CORR_ERR_AE; dhdpcie_ep_access_cap(bus, PCIE_ADVERRREP_CAPID, PCIE_ADV_CORR_ERR_MASK_OFFSET, TRUE, TRUE, val); } else { DHD_ERROR(("%s: Invalid EP's PCIE_ADV_CORR_ERR_MASK: 0x%x\n", __FUNCTION__, val)); } DHD_ERROR(("%s: Configure AER registers for RC\n", __FUNCTION__)); val = dhdpcie_rc_access_cap(bus, PCIE_ADVERRREP_CAPID, PCIE_ADV_CORR_ERR_MASK_OFFSET, TRUE, FALSE, 0); if (val != (uint32)-1) { val &= ~CORR_ERR_AE; dhdpcie_rc_access_cap(bus, PCIE_ADVERRREP_CAPID, PCIE_ADV_CORR_ERR_MASK_OFFSET, TRUE, TRUE, val); } else { DHD_ERROR(("%s: Invalid RC's PCIE_ADV_CORR_ERR_MASK: 0x%x\n", __FUNCTION__, val)); } } static int dhdpcie_pci_suspend(struct pci_dev * pdev, pm_message_t state) { int ret = 0; dhdpcie_info_t *pch = pci_get_drvdata(pdev); dhd_bus_t *bus = NULL; unsigned long flags; uint32 i = 0; if (pch) { bus = pch->bus; } if (!bus) { return ret; } BCM_REFERENCE(state); if (!DHD_BUS_BUSY_CHECK_IDLE(bus->dhd)) { DHD_ERROR(("%s: Bus not IDLE!! dhd_bus_busy_state = 0x%x\n", __FUNCTION__, bus->dhd->dhd_bus_busy_state)); OSL_DELAY(1000); /* retry till the transaction is complete */ while (i < 100) { OSL_DELAY(1000); i++; if (DHD_BUS_BUSY_CHECK_IDLE(bus->dhd)) { DHD_ERROR(("%s: Bus enter IDLE!! after %d ms\n", __FUNCTION__, i)); break; } } if (!DHD_BUS_BUSY_CHECK_IDLE(bus->dhd)) { DHD_ERROR(("%s: Bus not IDLE!! Failed after %d ms, " "dhd_bus_busy_state = 0x%x\n", __FUNCTION__, i, bus->dhd->dhd_bus_busy_state)); return -EBUSY; } } DHD_GENERAL_LOCK(bus->dhd, flags); DHD_BUS_BUSY_SET_SUSPEND_IN_PROGRESS(bus->dhd); DHD_GENERAL_UNLOCK(bus->dhd, flags); if (!bus->dhd->dongle_reset) ret = dhdpcie_set_suspend_resume(bus, TRUE); DHD_GENERAL_LOCK(bus->dhd, flags); DHD_BUS_BUSY_CLEAR_SUSPEND_IN_PROGRESS(bus->dhd); dhd_os_busbusy_wake(bus->dhd); DHD_GENERAL_UNLOCK(bus->dhd, flags); return ret; } static int dhdpcie_pci_resume(struct pci_dev *pdev) { int ret = 0; dhdpcie_info_t *pch = pci_get_drvdata(pdev); dhd_bus_t *bus = NULL; unsigned long flags; if (pch) { bus = pch->bus; } if (!bus) { return ret; } DHD_GENERAL_LOCK(bus->dhd, flags); DHD_BUS_BUSY_SET_RESUME_IN_PROGRESS(bus->dhd); DHD_GENERAL_UNLOCK(bus->dhd, flags); if (!bus->dhd->dongle_reset) ret = dhdpcie_set_suspend_resume(bus, FALSE); DHD_GENERAL_LOCK(bus->dhd, flags); DHD_BUS_BUSY_CLEAR_RESUME_IN_PROGRESS(bus->dhd); dhd_os_busbusy_wake(bus->dhd); DHD_GENERAL_UNLOCK(bus->dhd, flags); return ret; } static int #ifdef DHD_PCIE_NATIVE_RUNTIMEPM dhdpcie_set_suspend_resume(dhd_bus_t *bus, bool state, bool byint) #else dhdpcie_set_suspend_resume(dhd_bus_t *bus, bool state) #endif /* DHD_PCIE_NATIVE_RUNTIMEPM */ { int ret = 0; ASSERT(bus && !bus->dhd->dongle_reset); /* When firmware is not loaded do the PCI bus */ /* suspend/resume only */ if (bus->dhd->busstate == DHD_BUS_DOWN) { ret = dhdpcie_pci_suspend_resume(bus, state); return ret; } #ifdef DHD_PCIE_NATIVE_RUNTIMEPM ret = dhdpcie_bus_suspend(bus, state, byint); #else ret = dhdpcie_bus_suspend(bus, state); #endif /* DHD_PCIE_NATIVE_RUNTIMEPM */ return ret; } #ifdef DHD_PCIE_NATIVE_RUNTIMEPM static int dhdpcie_pm_runtime_suspend(struct device * dev) { struct pci_dev *pdev = to_pci_dev(dev); dhdpcie_info_t *pch = pci_get_drvdata(pdev); dhd_bus_t *bus = NULL; int ret = 0; if (!pch) return -EBUSY; bus = pch->bus; DHD_RPM(("%s Enter\n", __FUNCTION__)); if (atomic_read(&bus->dhd->block_bus)) return -EHOSTDOWN; dhd_netif_stop_queue(bus); atomic_set(&bus->dhd->block_bus, TRUE); if (dhdpcie_set_suspend_resume(pdev, TRUE, TRUE)) { pm_runtime_mark_last_busy(dev); ret = -EAGAIN; } atomic_set(&bus->dhd->block_bus, FALSE); dhd_bus_start_queue(bus); return ret; } static int dhdpcie_pm_runtime_resume(struct device * dev) { struct pci_dev *pdev = to_pci_dev(dev); dhdpcie_info_t *pch = pci_get_drvdata(pdev); dhd_bus_t *bus = pch->bus; DHD_RPM(("%s Enter\n", __FUNCTION__)); if (atomic_read(&bus->dhd->block_bus)) return -EHOSTDOWN; if (dhdpcie_set_suspend_resume(pdev, FALSE, TRUE)) return -EAGAIN; return 0; } static int dhdpcie_pm_system_suspend_noirq(struct device * dev) { struct pci_dev *pdev = to_pci_dev(dev); dhdpcie_info_t *pch = pci_get_drvdata(pdev); dhd_bus_t *bus = NULL; int ret; DHD_RPM(("%s Enter\n", __FUNCTION__)); if (!pch) return -EBUSY; bus = pch->bus; if (atomic_read(&bus->dhd->block_bus)) return -EHOSTDOWN; dhd_netif_stop_queue(bus); atomic_set(&bus->dhd->block_bus, TRUE); ret = dhdpcie_set_suspend_resume(pdev, TRUE, FALSE); if (ret) { dhd_bus_start_queue(bus); atomic_set(&bus->dhd->block_bus, FALSE); } return ret; } static int dhdpcie_pm_system_resume_noirq(struct device * dev) { struct pci_dev *pdev = to_pci_dev(dev); dhdpcie_info_t *pch = pci_get_drvdata(pdev); dhd_bus_t *bus = NULL; int ret; if (!pch) return -EBUSY; bus = pch->bus; DHD_RPM(("%s Enter\n", __FUNCTION__)); ret = dhdpcie_set_suspend_resume(pdev, FALSE, FALSE); atomic_set(&bus->dhd->block_bus, FALSE); dhd_bus_start_queue(bus); pm_runtime_mark_last_busy(dhd_bus_to_dev(bus)); return ret; } #endif /* DHD_PCIE_NATIVE_RUNTIMEPM */ #if (LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0)) extern void dhd_dpc_tasklet_kill(dhd_pub_t *dhdp); #endif /* OEM_ANDROID && LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0) */ static void dhdpcie_suspend_dump_cfgregs(struct dhd_bus *bus, char *suspend_state) { DHD_ERROR(("%s: BaseAddress0(0x%x)=0x%x, " "BaseAddress1(0x%x)=0x%x PCIE_CFG_PMCSR(0x%x)=0x%x\n", suspend_state, PCIECFGREG_BASEADDR0, dhd_pcie_config_read(bus->osh, PCIECFGREG_BASEADDR0, sizeof(uint32)), PCIECFGREG_BASEADDR1, dhd_pcie_config_read(bus->osh, PCIECFGREG_BASEADDR1, sizeof(uint32)), PCIE_CFG_PMCSR, dhd_pcie_config_read(bus->osh, PCIE_CFG_PMCSR, sizeof(uint32)))); } static int dhdpcie_suspend_dev(struct pci_dev *dev) { int ret; dhdpcie_info_t *pch = pci_get_drvdata(dev); dhd_bus_t *bus = pch->bus; #if (LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0)) if (bus->is_linkdown) { DHD_ERROR(("%s: PCIe link is down\n", __FUNCTION__)); return BCME_ERROR; } #endif /* OEM_ANDROID && LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0) */ DHD_ERROR(("%s: Enter\n", __FUNCTION__)); dhdpcie_suspend_dump_cfgregs(bus, "BEFORE_EP_SUSPEND"); #if (LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0)) dhd_dpc_tasklet_kill(bus->dhd); #endif /* OEM_ANDROID && LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0) */ pci_save_state(dev); #if (LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0)) pch->state = pci_store_saved_state(dev); #endif /* OEM_ANDROID && LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0) */ pci_enable_wake(dev, PCI_D0, TRUE); if (pci_is_enabled(dev)) pci_disable_device(dev); ret = pci_set_power_state(dev, PCI_D3hot); if (ret) { DHD_ERROR(("%s: pci_set_power_state error %d\n", __FUNCTION__, ret)); } // dev->state_saved = FALSE; dhdpcie_suspend_dump_cfgregs(bus, "AFTER_EP_SUSPEND"); return ret; } #ifdef DHD_WAKE_STATUS int bcmpcie_get_total_wake(struct dhd_bus *bus) { dhdpcie_info_t *pch = pci_get_drvdata(bus->dev); return pch->total_wake_count; } int bcmpcie_set_get_wake(struct dhd_bus *bus, int flag) { dhdpcie_info_t *pch = pci_get_drvdata(bus->dev); unsigned long flags; int ret; spin_lock_irqsave(&pch->pcie_lock, flags); ret = pch->pkt_wake; pch->total_wake_count += flag; pch->pkt_wake = flag; spin_unlock_irqrestore(&pch->pcie_lock, flags); return ret; } #endif /* DHD_WAKE_STATUS */ static int dhdpcie_resume_dev(struct pci_dev *dev) { int err = 0; dhdpcie_info_t *pch = pci_get_drvdata(dev); #if (LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0)) pci_load_and_free_saved_state(dev, &pch->state); #endif /* OEM_ANDROID && LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0) */ DHD_ERROR(("%s: Enter\n", __FUNCTION__)); // dev->state_saved = TRUE; pci_restore_state(dev); #ifdef FORCE_TPOWERON if (dhdpcie_chip_req_forced_tpoweron(pch->bus)) { dhd_bus_set_tpoweron(pch->bus, tpoweron_scale); } #endif /* FORCE_TPOWERON */ err = pci_enable_device(dev); if (err) { printf("%s:pci_enable_device error %d \n", __FUNCTION__, err); goto out; } pci_set_master(dev); err = pci_set_power_state(dev, PCI_D0); if (err) { printf("%s:pci_set_power_state error %d \n", __FUNCTION__, err); goto out; } BCM_REFERENCE(pch); dhdpcie_suspend_dump_cfgregs(pch->bus, "AFTER_EP_RESUME"); out: return err; } static int dhdpcie_resume_host_dev(dhd_bus_t *bus) { int bcmerror = 0; #ifdef USE_EXYNOS_PCIE_RC_PMPATCH bcmerror = exynos_pcie_pm_resume(SAMSUNG_PCIE_CH_NUM); #endif /* USE_EXYNOS_PCIE_RC_PMPATCH */ #ifdef CONFIG_ARCH_MSM bcmerror = dhdpcie_start_host_pcieclock(bus); #endif /* CONFIG_ARCH_MSM */ #ifdef CONFIG_ARCH_TEGRA bcmerror = tegra_pcie_pm_resume(); #endif /* CONFIG_ARCH_TEGRA */ if (bcmerror < 0) { DHD_ERROR(("%s: PCIe RC resume failed!!! (%d)\n", __FUNCTION__, bcmerror)); bus->is_linkdown = 1; } return bcmerror; } static int dhdpcie_suspend_host_dev(dhd_bus_t *bus) { int bcmerror = 0; #ifdef USE_EXYNOS_PCIE_RC_PMPATCH if (bus->rc_dev) { pci_save_state(bus->rc_dev); } else { DHD_ERROR(("%s: RC %x:%x handle is NULL\n", __FUNCTION__, PCIE_RC_VENDOR_ID, PCIE_RC_DEVICE_ID)); } exynos_pcie_pm_suspend(SAMSUNG_PCIE_CH_NUM); #endif /* USE_EXYNOS_PCIE_RC_PMPATCH */ #ifdef CONFIG_ARCH_MSM bcmerror = dhdpcie_stop_host_pcieclock(bus); #endif /* CONFIG_ARCH_MSM */ #ifdef CONFIG_ARCH_TEGRA bcmerror = tegra_pcie_pm_suspend(); #endif /* CONFIG_ARCH_TEGRA */ return bcmerror; } /** * dhdpcie_os_setbar1win * * Interface function for setting bar1 window in order to allow * os layer to be aware of current window positon. * * @bus: dhd bus context * @addr: new backplane windows address for BAR1 */ void dhdpcie_os_setbar1win(dhd_bus_t *bus, uint32 addr) { dhdpcie_info_t *pch = pci_get_drvdata(bus->dev); osl_pci_write_config(bus->osh, PCI_BAR1_WIN, 4, addr); pch->curr_bar1_win = addr; } /** * dhdpcie_os_chkbpoffset * * Check the provided address is within the current BAR1 window, * if not, shift the window * * @bus: dhd bus context * @offset: back plane address that the caller wants to access * * Return: new offset for access */ static ulong dhdpcie_os_chkbpoffset(dhdpcie_info_t *pch, ulong offset) { /* Determine BAR1 backplane window using window size * Window address mask should be ~(size - 1) */ uint32 bpwin = (uint32)(offset & ~(pch->bar1_size - 1)); if (bpwin != pch->curr_bar1_win) { /* Move BAR1 window */ dhdpcie_os_setbar1win(pch->bus, bpwin); } return offset - bpwin; } /** * dhdpcie os layer tcm read/write interface */ void dhdpcie_os_wtcm8(dhd_bus_t *bus, ulong offset, uint8 data) { dhdpcie_info_t *pch = pci_get_drvdata(bus->dev); offset = dhdpcie_os_chkbpoffset(pch, offset); W_REG(bus->dhd->osh, (volatile uint8 *)(bus->tcm + offset), data); } uint8 dhdpcie_os_rtcm8(dhd_bus_t *bus, ulong offset) { volatile uint8 data; dhdpcie_info_t *pch = pci_get_drvdata(bus->dev); offset = dhdpcie_os_chkbpoffset(pch, offset); data = R_REG(bus->dhd->osh, (volatile uint8 *)(bus->tcm + offset)); return data; } void dhdpcie_os_wtcm16(dhd_bus_t *bus, ulong offset, uint16 data) { dhdpcie_info_t *pch = pci_get_drvdata(bus->dev); offset = dhdpcie_os_chkbpoffset(pch, offset); W_REG(bus->dhd->osh, (volatile uint16 *)(bus->tcm + offset), data); } uint16 dhdpcie_os_rtcm16(dhd_bus_t *bus, ulong offset) { volatile uint16 data; dhdpcie_info_t *pch = pci_get_drvdata(bus->dev); offset = dhdpcie_os_chkbpoffset(pch, offset); data = R_REG(bus->dhd->osh, (volatile uint16 *)(bus->tcm + offset)); return data; } void dhdpcie_os_wtcm32(dhd_bus_t *bus, ulong offset, uint32 data) { dhdpcie_info_t *pch = pci_get_drvdata(bus->dev); offset = dhdpcie_os_chkbpoffset(pch, offset); W_REG(bus->dhd->osh, (volatile uint32 *)(bus->tcm + offset), data); } uint32 dhdpcie_os_rtcm32(dhd_bus_t *bus, ulong offset) { volatile uint32 data; dhdpcie_info_t *pch = pci_get_drvdata(bus->dev); offset = dhdpcie_os_chkbpoffset(pch, offset); data = R_REG(bus->dhd->osh, (volatile uint32 *)(bus->tcm + offset)); return data; } #ifdef DHD_SUPPORT_64BIT void dhdpcie_os_wtcm64(dhd_bus_t *bus, ulong offset, uint64 data) { dhdpcie_info_t *pch = pci_get_drvdata(bus->dev); offset = dhdpcie_os_chkbpoffset(pch, offset); W_REG(bus->dhd->osh, (volatile uint64 *)(bus->tcm + offset), data); } uint64 dhdpcie_os_rtcm64(dhd_bus_t *bus, ulong offset) { volatile uint64 data; dhdpcie_info_t *pch = pci_get_drvdata(bus->dev); offset = dhdpcie_os_chkbpoffset(pch, offset); data = R_REG(bus->dhd->osh, (volatile uint64 *)(bus->tcm + offset)); return data; } #endif /* DHD_SUPPORT_64BIT */ uint32 dhdpcie_rc_config_read(dhd_bus_t *bus, uint offset) { uint val = -1; /* Initialise to 0xfffffff */ if (bus->rc_dev) { pci_read_config_dword(bus->rc_dev, offset, &val); OSL_DELAY(100); } else { DHD_ERROR(("%s: RC %x:%x handle is NULL\n", __FUNCTION__, PCIE_RC_VENDOR_ID, PCIE_RC_DEVICE_ID)); } DHD_ERROR(("%s: RC %x:%x offset 0x%x val 0x%x\n", __FUNCTION__, PCIE_RC_VENDOR_ID, PCIE_RC_DEVICE_ID, offset, val)); return (val); } /* * Reads/ Writes the value of capability register * from the given CAP_ID section of PCI Root Port * * Arguements * @bus current dhd_bus_t pointer * @cap Capability or Extended Capability ID to get * @offset offset of Register to Read * @is_ext TRUE if @cap is given for Extended Capability * @is_write is set to TRUE to indicate write * @val value to write * * Return Value * Returns 0xffffffff on error * on write success returns BCME_OK (0) * on Read Success returns the value of register requested * Note: caller shoud ensure valid capability ID and Ext. Capability ID. */ uint32 dhdpcie_access_cap(struct pci_dev *pdev, int cap, uint offset, bool is_ext, bool is_write, uint32 writeval) { int cap_ptr = 0; uint32 ret = -1; uint32 readval; if (!(pdev)) { DHD_ERROR(("%s: pdev is NULL\n", __FUNCTION__)); return ret; } /* Find Capability offset */ if (is_ext) { /* removing max EXT_CAP_ID check as * linux kernel definition's max value is not upadted yet as per spec */ cap_ptr = pci_find_ext_capability(pdev, cap); } else { /* removing max PCI_CAP_ID_MAX check as * pervious kernel versions dont have this definition */ cap_ptr = pci_find_capability(pdev, cap); } /* Return if capability with given ID not found */ if (cap_ptr == 0) { DHD_ERROR(("%s: PCI Cap(0x%02x) not supported.\n", __FUNCTION__, cap)); return BCME_ERROR; } if (is_write) { pci_write_config_dword(pdev, (cap_ptr + offset), writeval); ret = BCME_OK; } else { pci_read_config_dword(pdev, (cap_ptr + offset), &readval); ret = readval; } return ret; } uint32 dhdpcie_rc_access_cap(dhd_bus_t *bus, int cap, uint offset, bool is_ext, bool is_write, uint32 writeval) { if (!(bus->rc_dev)) { DHD_ERROR(("%s: RC %x:%x handle is NULL\n", __FUNCTION__, PCIE_RC_VENDOR_ID, PCIE_RC_DEVICE_ID)); return BCME_ERROR; } return dhdpcie_access_cap(bus->rc_dev, cap, offset, is_ext, is_write, writeval); } uint32 dhdpcie_ep_access_cap(dhd_bus_t *bus, int cap, uint offset, bool is_ext, bool is_write, uint32 writeval) { if (!(bus->dev)) { DHD_ERROR(("%s: EP handle is NULL\n", __FUNCTION__)); return BCME_ERROR; } return dhdpcie_access_cap(bus->dev, cap, offset, is_ext, is_write, writeval); } /* API wrapper to read Root Port link capability * Returns 2 = GEN2 1 = GEN1 BCME_ERR on linkcap not found */ uint32 dhd_debug_get_rc_linkcap(dhd_bus_t *bus) { uint32 linkcap = -1; linkcap = dhdpcie_rc_access_cap(bus, PCIE_CAP_ID_EXP, PCIE_CAP_LINKCAP_OFFSET, FALSE, FALSE, 0); linkcap &= PCIE_CAP_LINKCAP_LNKSPEED_MASK; return linkcap; } static void dhdpcie_config_save_restore_coherent(dhd_bus_t *bus, bool state) { if (bus->coreid == ARMCA7_CORE_ID) { if (state) { /* Sleep */ bus->coherent_state = dhdpcie_bus_cfg_read_dword(bus, PCIE_CFG_SUBSYSTEM_CONTROL, 4) & PCIE_BARCOHERENTACCEN_MASK; } else { uint32 val = (dhdpcie_bus_cfg_read_dword(bus, PCIE_CFG_SUBSYSTEM_CONTROL, 4) & ~PCIE_BARCOHERENTACCEN_MASK) | bus->coherent_state; dhdpcie_bus_cfg_write_dword(bus, PCIE_CFG_SUBSYSTEM_CONTROL, 4, val); } } } int dhdpcie_pci_suspend_resume(dhd_bus_t *bus, bool state) { int rc; struct pci_dev *dev = bus->dev; if (state) { dhdpcie_config_save_restore_coherent(bus, state); #if !defined(BCMPCIE_OOB_HOST_WAKE) dhdpcie_pme_active(bus->osh, state); #endif // endif rc = dhdpcie_suspend_dev(dev); if (!rc) { dhdpcie_suspend_host_dev(bus); } } else { rc = dhdpcie_resume_host_dev(bus); if (!rc) { rc = dhdpcie_resume_dev(dev); if (PCIECTO_ENAB(bus)) { /* reinit CTO configuration * because cfg space got reset at D3 (PERST) */ dhdpcie_cto_cfg_init(bus, TRUE); } if (PCIE_ENUM_RESET_WAR_ENAB(bus->sih->buscorerev)) { dhdpcie_ssreset_dis_enum_rst(bus); } #if !defined(BCMPCIE_OOB_HOST_WAKE) dhdpcie_pme_active(bus->osh, state); #endif // endif } dhdpcie_config_save_restore_coherent(bus, state); if (bus->is_linkdown) { bus->dhd->hang_reason = HANG_REASON_PCIE_RC_LINK_UP_FAIL; dhd_os_send_hang_message(bus->dhd); } } return rc; } static int dhdpcie_device_scan(struct device *dev, void *data) { struct pci_dev *pcidev; int *cnt = data; #if defined(STRICT_GCC_WARNINGS) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wcast-qual" #endif // endif pcidev = container_of(dev, struct pci_dev, dev); #if defined(STRICT_GCC_WARNINGS) && defined(__GNUC__) #pragma GCC diagnostic pop #endif // endif if (pcidev->vendor != 0x14e4) return 0; DHD_INFO(("Found Broadcom PCI device 0x%04x\n", pcidev->device)); *cnt += 1; if (pcidev->driver && strcmp(pcidev->driver->name, dhdpcie_driver.name)) DHD_ERROR(("Broadcom PCI Device 0x%04x has allocated with driver %s\n", pcidev->device, pcidev->driver->name)); return 0; } int dhdpcie_bus_register(void) { int error = 0; if (!(error = pci_register_driver(&dhdpcie_driver))) { bus_for_each_dev(dhdpcie_driver.driver.bus, NULL, &error, dhdpcie_device_scan); if (!error) { DHD_ERROR(("No Broadcom PCI device enumerated!\n")); } else if (!dhdpcie_init_succeeded) { DHD_ERROR(("%s: dhdpcie initialize failed.\n", __FUNCTION__)); } else { return 0; } pci_unregister_driver(&dhdpcie_driver); error = BCME_ERROR; } return error; } void dhdpcie_bus_unregister(void) { pci_unregister_driver(&dhdpcie_driver); } int __devinit dhdpcie_pci_probe(struct pci_dev *pdev, const struct pci_device_id *ent) { int err = 0; DHD_MUTEX_LOCK(); if (dhdpcie_chipmatch (pdev->vendor, pdev->device)) { DHD_ERROR(("%s: chipmatch failed!!\n", __FUNCTION__)); err = -ENODEV; goto exit; } printf("PCI_PROBE: bus %X, slot %X,vendor %X, device %X" "(good PCI location)\n", pdev->bus->number, PCI_SLOT(pdev->devfn), pdev->vendor, pdev->device); if (dhdpcie_init_succeeded == TRUE) { DHD_ERROR(("%s(): === Driver Already attached to a BRCM device === \r\n", __FUNCTION__)); err = -ENODEV; goto exit; } if (dhdpcie_init (pdev)) { DHD_ERROR(("%s: PCIe Enumeration failed\n", __FUNCTION__)); err = -ENODEV; goto exit; } #ifdef DHD_PCIE_NATIVE_RUNTIMEPM /* Since MSM PCIe RC dev usage conunt already incremented +2 even before dhdpcie_pci_probe() called, then we inevitably to call pm_runtime_put_noidle() two times to make the count start with zero. */ pm_runtime_put_noidle(&pdev->dev); pm_runtime_put_noidle(&pdev->dev); pm_runtime_set_suspended(&pdev->dev); #endif /* DHD_PCIE_NATIVE_RUNTIMEPM */ #ifdef BCMPCIE_DISABLE_ASYNC_SUSPEND /* disable async suspend */ device_disable_async_suspend(&pdev->dev); #endif /* BCMPCIE_DISABLE_ASYNC_SUSPEND */ DHD_TRACE(("%s: PCIe Enumeration done!!\n", __FUNCTION__)); exit: DHD_MUTEX_UNLOCK(); return err; } int dhdpcie_detach(dhdpcie_info_t *pch) { if (pch) { #if (LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0)) if (!dhd_download_fw_on_driverload) { pci_load_and_free_saved_state(pch->dev, &pch->default_state); } #endif /* OEM_ANDROID && LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0) */ MFREE(pch->osh, pch, sizeof(dhdpcie_info_t)); } return 0; } void __devexit dhdpcie_pci_remove(struct pci_dev *pdev) { osl_t *osh = NULL; dhdpcie_info_t *pch = NULL; dhd_bus_t *bus = NULL; DHD_TRACE(("%s Enter\n", __FUNCTION__)); DHD_MUTEX_LOCK(); pch = pci_get_drvdata(pdev); bus = pch->bus; osh = pch->osh; #ifdef DHD_PCIE_NATIVE_RUNTIMEPM pm_runtime_get_noresume(&pdev->dev); pm_runtime_get_noresume(&pdev->dev); #endif /* DHD_PCIE_NATIVE_RUNTIMEPM */ if (bus) { bus->rc_dev = NULL; dhdpcie_bus_release(bus); } if (pci_is_enabled(pdev)) pci_disable_device(pdev); #ifdef BCMPCIE_OOB_HOST_WAKE /* pcie os info detach */ MFREE(osh, pch->os_cxt, sizeof(dhdpcie_os_info_t)); #endif /* BCMPCIE_OOB_HOST_WAKE */ #ifdef USE_SMMU_ARCH_MSM /* smmu info detach */ dhdpcie_smmu_remove(pdev, pch->smmu_cxt); MFREE(osh, pch->smmu_cxt, sizeof(dhdpcie_smmu_info_t)); #endif /* USE_SMMU_ARCH_MSM */ /* pcie info detach */ dhdpcie_detach(pch); /* osl detach */ osl_detach(osh); #if defined(BCMPCIE_OOB_HOST_WAKE) && defined(CUSTOMER_HW2) && \ defined(CONFIG_ARCH_APQ8084) brcm_pcie_wake.wake_irq = NULL; brcm_pcie_wake.data = NULL; #endif /* BCMPCIE_OOB_HOST_WAKE && CUSTOMR_HW2 && CONFIG_ARCH_APQ8084 */ dhdpcie_init_succeeded = FALSE; DHD_MUTEX_UNLOCK(); DHD_TRACE(("%s Exit\n", __FUNCTION__)); return; } /* Enable Linux Msi */ int dhdpcie_enable_msi(struct pci_dev *pdev, unsigned int min_vecs, unsigned int max_vecs) { #if (LINUX_VERSION_CODE >= KERNEL_VERSION(4, 8, 0)) return pci_alloc_irq_vectors(pdev, min_vecs, max_vecs, PCI_IRQ_MSI); #elif (LINUX_VERSION_CODE >= KERNEL_VERSION(3, 16, 0)) return pci_enable_msi_range(pdev, min_vecs, max_vecs); #else return pci_enable_msi_block(pdev, max_vecs); #endif // endif } /* Disable Linux Msi */ void dhdpcie_disable_msi(struct pci_dev *pdev) { #if (LINUX_VERSION_CODE >= KERNEL_VERSION(4, 8, 0)) pci_free_irq_vectors(pdev); #elif (LINUX_VERSION_CODE >= KERNEL_VERSION(4, 0, 0)) pci_disable_msi(pdev); #else pci_disable_msi(pdev); #endif // endif return; } /* Request Linux irq */ int dhdpcie_request_irq(dhdpcie_info_t *dhdpcie_info) { dhd_bus_t *bus = dhdpcie_info->bus; struct pci_dev *pdev = dhdpcie_info->bus->dev; int host_irq_disabled; if (!bus->irq_registered) { snprintf(dhdpcie_info->pciname, sizeof(dhdpcie_info->pciname), "dhdpcie:%s", pci_name(pdev)); if (bus->d2h_intr_method == PCIE_MSI) { if (dhdpcie_enable_msi(pdev, 1, 1) < 0) { DHD_ERROR(("%s: dhdpcie_enable_msi() failed\n", __FUNCTION__)); dhdpcie_disable_msi(pdev); bus->d2h_intr_method = PCIE_INTX; } } if (bus->d2h_intr_method == PCIE_MSI) printf("%s: MSI enabled\n", __FUNCTION__); else printf("%s: INTx enabled\n", __FUNCTION__); if (request_irq(pdev->irq, dhdpcie_isr, IRQF_SHARED, dhdpcie_info->pciname, bus) < 0) { DHD_ERROR(("%s: request_irq() failed\n", __FUNCTION__)); if (bus->d2h_intr_method == PCIE_MSI) { dhdpcie_disable_msi(pdev); } return -1; } else { bus->irq_registered = TRUE; } } else { DHD_ERROR(("%s: PCI IRQ is already registered\n", __FUNCTION__)); } host_irq_disabled = dhdpcie_irq_disabled(bus); if (host_irq_disabled) { DHD_ERROR(("%s: PCIe IRQ was disabled(%d), so, enabled it again\n", __FUNCTION__, host_irq_disabled)); dhdpcie_enable_irq(bus); } DHD_TRACE(("%s %s\n", __FUNCTION__, dhdpcie_info->pciname)); return 0; /* SUCCESS */ } /** * dhdpcie_get_pcieirq - return pcie irq number to linux-dhd */ int dhdpcie_get_pcieirq(struct dhd_bus *bus, unsigned int *irq) { struct pci_dev *pdev = bus->dev; if (!pdev) { DHD_ERROR(("%s : bus->dev is NULL\n", __FUNCTION__)); return -ENODEV; } *irq = pdev->irq; return 0; /* SUCCESS */ } #ifdef CONFIG_PHYS_ADDR_T_64BIT #define PRINTF_RESOURCE "0x%016llx" #else #define PRINTF_RESOURCE "0x%08x" #endif // endif #ifdef EXYNOS_PCIE_MODULE_PATCH #if (LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0)) extern struct pci_saved_state *bcm_pcie_default_state; #endif /* LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0) */ #endif /* EXYNOS_MODULE_PATCH */ /* Name: osl_pci_get_resource Parametrs: 1: struct pci_dev *pdev -- pci device structure 2: pci_res -- structure containing pci configuration space values Return value: int - Status (TRUE or FALSE) Description: Access PCI configuration space, retrieve PCI allocated resources , updates in resource structure. */ int dhdpcie_get_resource(dhdpcie_info_t *dhdpcie_info) { phys_addr_t bar0_addr, bar1_addr; ulong bar1_size; struct pci_dev *pdev = NULL; pdev = dhdpcie_info->dev; #ifdef EXYNOS_PCIE_MODULE_PATCH #if (LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0)) if (bcm_pcie_default_state) { pci_load_saved_state(pdev, bcm_pcie_default_state); pci_restore_state(pdev); } #endif /* LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0) */ #endif /* EXYNOS_MODULE_PATCH */ do { if (pci_enable_device(pdev)) { printf("%s: Cannot enable PCI device\n", __FUNCTION__); break; } pci_set_master(pdev); bar0_addr = pci_resource_start(pdev, 0); /* Bar-0 mapped address */ bar1_addr = pci_resource_start(pdev, 2); /* Bar-1 mapped address */ /* read Bar-1 mapped memory range */ bar1_size = pci_resource_len(pdev, 2); if ((bar1_size == 0) || (bar1_addr == 0)) { printf("%s: BAR1 Not enabled for this device size(%ld)," " addr(0x"PRINTF_RESOURCE")\n", __FUNCTION__, bar1_size, bar1_addr); goto err; } dhdpcie_info->regs = (volatile char *) REG_MAP(bar0_addr, DONGLE_REG_MAP_SIZE); dhdpcie_info->bar1_size = (bar1_size > DONGLE_TCM_MAP_SIZE) ? bar1_size : DONGLE_TCM_MAP_SIZE; dhdpcie_info->tcm = (volatile char *) REG_MAP(bar1_addr, dhdpcie_info->bar1_size); if (!dhdpcie_info->regs || !dhdpcie_info->tcm) { DHD_ERROR(("%s:ioremap() failed\n", __FUNCTION__)); break; } #ifdef EXYNOS_PCIE_MODULE_PATCH #if (LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0)) if (bcm_pcie_default_state == NULL) { pci_save_state(pdev); bcm_pcie_default_state = pci_store_saved_state(pdev); } #endif /* LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0) */ #endif /* EXYNOS_MODULE_PATCH */ #if (LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0)) /* Backup PCIe configuration so as to use Wi-Fi on/off process * in case of built in driver */ pci_save_state(pdev); dhdpcie_info->default_state = pci_store_saved_state(pdev); if (dhdpcie_info->default_state == NULL) { DHD_ERROR(("%s pci_store_saved_state returns NULL\n", __FUNCTION__)); REG_UNMAP(dhdpcie_info->regs); REG_UNMAP(dhdpcie_info->tcm); pci_disable_device(pdev); break; } #endif /* LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0) */ DHD_TRACE(("%s:Phys addr : reg space = %p base addr 0x"PRINTF_RESOURCE" \n", __FUNCTION__, dhdpcie_info->regs, bar0_addr)); DHD_TRACE(("%s:Phys addr : tcm_space = %p base addr 0x"PRINTF_RESOURCE" \n", __FUNCTION__, dhdpcie_info->tcm, bar1_addr)); return 0; /* SUCCESS */ } while (0); err: return -1; /* FAILURE */ } int dhdpcie_scan_resource(dhdpcie_info_t *dhdpcie_info) { DHD_TRACE(("%s: ENTER\n", __FUNCTION__)); do { /* define it here only!! */ if (dhdpcie_get_resource (dhdpcie_info)) { DHD_ERROR(("%s: Failed to get PCI resources\n", __FUNCTION__)); break; } DHD_TRACE(("%s:Exit - SUCCESS \n", __FUNCTION__)); return 0; /* SUCCESS */ } while (0); DHD_TRACE(("%s:Exit - FAILURE \n", __FUNCTION__)); return -1; /* FAILURE */ } void dhdpcie_dump_resource(dhd_bus_t *bus) { dhdpcie_info_t *pch; if (bus == NULL) { DHD_ERROR(("%s: bus is NULL\n", __FUNCTION__)); return; } if (bus->dev == NULL) { DHD_ERROR(("%s: bus->dev is NULL\n", __FUNCTION__)); return; } pch = pci_get_drvdata(bus->dev); if (pch == NULL) { DHD_ERROR(("%s: pch is NULL\n", __FUNCTION__)); return; } /* BAR0 */ DHD_ERROR(("%s: BAR0(VA): 0x%pK, BAR0(PA): "PRINTF_RESOURCE", SIZE: %d\n", __FUNCTION__, pch->regs, pci_resource_start(bus->dev, 0), DONGLE_REG_MAP_SIZE)); /* BAR1 */ DHD_ERROR(("%s: BAR1(VA): 0x%pK, BAR1(PA): "PRINTF_RESOURCE", SIZE: %d\n", __FUNCTION__, pch->tcm, pci_resource_start(bus->dev, 2), pch->bar1_size)); } int dhdpcie_init(struct pci_dev *pdev) { osl_t *osh = NULL; dhd_bus_t *bus = NULL; dhdpcie_info_t *dhdpcie_info = NULL; wifi_adapter_info_t *adapter = NULL; #ifdef BCMPCIE_OOB_HOST_WAKE dhdpcie_os_info_t *dhdpcie_osinfo = NULL; #endif /* BCMPCIE_OOB_HOST_WAKE */ #ifdef USE_SMMU_ARCH_MSM dhdpcie_smmu_info_t *dhdpcie_smmu_info = NULL; #endif /* USE_SMMU_ARCH_MSM */ int ret = 0; do { /* osl attach */ if (!(osh = osl_attach(pdev, PCI_BUS, FALSE))) { DHD_ERROR(("%s: osl_attach failed\n", __FUNCTION__)); break; } /* initialize static buffer */ adapter = dhd_wifi_platform_get_adapter(PCI_BUS, pdev->bus->number, PCI_SLOT(pdev->devfn)); if (adapter != NULL) { DHD_ERROR(("%s: found adapter info '%s'\n", __FUNCTION__, adapter->name)); #ifdef BUS_POWER_RESTORE adapter->pci_dev = pdev; #endif } else DHD_ERROR(("%s: can't find adapter info for this chip\n", __FUNCTION__)); osl_static_mem_init(osh, adapter); /* Set ACP coherence flag */ if (OSL_ACP_WAR_ENAB() || OSL_ARCH_IS_COHERENT()) osl_flag_set(osh, OSL_ACP_COHERENCE); /* allocate linux spcific pcie structure here */ if (!(dhdpcie_info = MALLOC(osh, sizeof(dhdpcie_info_t)))) { DHD_ERROR(("%s: MALLOC of dhd_bus_t failed\n", __FUNCTION__)); break; } bzero(dhdpcie_info, sizeof(dhdpcie_info_t)); dhdpcie_info->osh = osh; dhdpcie_info->dev = pdev; #ifdef BCMPCIE_OOB_HOST_WAKE /* allocate OS speicific structure */ dhdpcie_osinfo = MALLOC(osh, sizeof(dhdpcie_os_info_t)); if (dhdpcie_osinfo == NULL) { DHD_ERROR(("%s: MALLOC of dhdpcie_os_info_t failed\n", __FUNCTION__)); break; } bzero(dhdpcie_osinfo, sizeof(dhdpcie_os_info_t)); dhdpcie_info->os_cxt = (void *)dhdpcie_osinfo; /* Initialize host wake IRQ */ spin_lock_init(&dhdpcie_osinfo->oob_irq_spinlock); /* Get customer specific host wake IRQ parametres: IRQ number as IRQ type */ dhdpcie_osinfo->oob_irq_num = wifi_platform_get_irq_number(adapter, &dhdpcie_osinfo->oob_irq_flags); if (dhdpcie_osinfo->oob_irq_num < 0) { DHD_ERROR(("%s: Host OOB irq is not defined\n", __FUNCTION__)); } #endif /* BCMPCIE_OOB_HOST_WAKE */ #ifdef USE_SMMU_ARCH_MSM /* allocate private structure for using SMMU */ dhdpcie_smmu_info = MALLOC(osh, sizeof(dhdpcie_smmu_info_t)); if (dhdpcie_smmu_info == NULL) { DHD_ERROR(("%s: MALLOC of dhdpcie_smmu_info_t failed\n", __FUNCTION__)); break; } bzero(dhdpcie_smmu_info, sizeof(dhdpcie_smmu_info_t)); dhdpcie_info->smmu_cxt = (void *)dhdpcie_smmu_info; /* Initialize smmu structure */ if (dhdpcie_smmu_init(pdev, dhdpcie_info->smmu_cxt) < 0) { DHD_ERROR(("%s: Failed to initialize SMMU\n", __FUNCTION__)); break; } #endif /* USE_SMMU_ARCH_MSM */ #ifdef DHD_WAKE_STATUS /* Initialize pcie_lock */ spin_lock_init(&dhdpcie_info->pcie_lock); #endif /* DHD_WAKE_STATUS */ /* Find the PCI resources, verify the */ /* vendor and device ID, map BAR regions and irq, update in structures */ if (dhdpcie_scan_resource(dhdpcie_info)) { DHD_ERROR(("%s: dhd_Scan_PCI_Res failed\n", __FUNCTION__)); break; } /* Bus initialization */ ret = dhdpcie_bus_attach(osh, &bus, dhdpcie_info->regs, dhdpcie_info->tcm, pdev); if (ret != BCME_OK) { DHD_ERROR(("%s:dhdpcie_bus_attach() failed\n", __FUNCTION__)); break; } dhdpcie_info->bus = bus; bus->is_linkdown = 0; bus->no_bus_init = FALSE; bus->cto_triggered = 0; bus->rc_dev = NULL; /* Get RC Device Handle */ if (bus->dev->bus) { /* self member of structure pci_bus is bridge device as seen by parent */ bus->rc_dev = bus->dev->bus->self; if (bus->rc_dev) DHD_ERROR(("%s: rc_dev from dev->bus->self (%x:%x) is %pK\n", __FUNCTION__, bus->rc_dev->vendor, bus->rc_dev->device, bus->rc_dev)); else DHD_ERROR(("%s: bus->dev->bus->self is NULL\n", __FUNCTION__)); } else { DHD_ERROR(("%s: unable to get rc_dev as dev->bus is NULL\n", __FUNCTION__)); } /* if rc_dev is still NULL, try to get from vendor/device IDs */ if (bus->rc_dev == NULL) { bus->rc_dev = pci_get_device(PCIE_RC_VENDOR_ID, PCIE_RC_DEVICE_ID, NULL); DHD_ERROR(("%s: rc_dev from pci_get_device (%x:%x) is %p\n", __FUNCTION__, PCIE_RC_VENDOR_ID, PCIE_RC_DEVICE_ID, bus->rc_dev)); } bus->rc_ep_aspm_cap = dhd_bus_is_rc_ep_aspm_capable(bus); bus->rc_ep_l1ss_cap = dhd_bus_is_rc_ep_l1ss_capable(bus); DHD_ERROR(("%s: rc_ep_aspm_cap: %d rc_ep_l1ss_cap: %d\n", __FUNCTION__, bus->rc_ep_aspm_cap, bus->rc_ep_l1ss_cap)); #ifdef FORCE_TPOWERON if (dhdpcie_chip_req_forced_tpoweron(bus)) { dhd_bus_set_tpoweron(bus, tpoweron_scale); } #endif /* FORCE_TPOWERON */ #if defined(BCMPCIE_OOB_HOST_WAKE) && defined(CUSTOMER_HW2) && \ defined(CONFIG_ARCH_APQ8084) brcm_pcie_wake.wake_irq = wlan_oob_irq; brcm_pcie_wake.data = bus; #endif /* BCMPCIE_OOB_HOST_WAKE && CUSTOMR_HW2 && CONFIG_ARCH_APQ8084 */ #ifdef DONGLE_ENABLE_ISOLATION bus->dhd->dongle_isolation = TRUE; #endif /* DONGLE_ENABLE_ISOLATION */ if (bus->intr) { /* Register interrupt callback, but mask it (not operational yet). */ DHD_INTR(("%s: Registering and masking interrupts\n", __FUNCTION__)); dhdpcie_bus_intr_disable(bus); if (dhdpcie_request_irq(dhdpcie_info)) { DHD_ERROR(("%s: request_irq() failed\n", __FUNCTION__)); break; } } else { bus->pollrate = 1; DHD_INFO(("%s: PCIe interrupt function is NOT registered " "due to polling mode\n", __FUNCTION__)); } #if defined(BCM_REQUEST_FW) if (dhd_bus_download_firmware(bus, osh, NULL, NULL) < 0) { DHD_ERROR(("%s: failed to download firmware\n", __FUNCTION__)); } bus->nv_path = NULL; bus->fw_path = NULL; #endif /* BCM_REQUEST_FW */ /* set private data for pci_dev */ pci_set_drvdata(pdev, dhdpcie_info); if (dhd_download_fw_on_driverload) { if (dhd_bus_start(bus->dhd)) { DHD_ERROR(("%s: dhd_bud_start() failed\n", __FUNCTION__)); if (!allow_delay_fwdl) break; } } else { /* Set ramdom MAC address during boot time */ get_random_bytes(&bus->dhd->mac.octet[3], 3); /* Adding BRCM OUI */ bus->dhd->mac.octet[0] = 0; bus->dhd->mac.octet[1] = 0x90; bus->dhd->mac.octet[2] = 0x4C; } /* Attach to the OS network interface */ DHD_TRACE(("%s(): Calling dhd_register_if() \n", __FUNCTION__)); if (dhd_attach_net(bus->dhd, TRUE)) { DHD_ERROR(("%s(): ERROR.. dhd_register_if() failed\n", __FUNCTION__)); break; } dhdpcie_init_succeeded = TRUE; #ifdef DHD_PCIE_NATIVE_RUNTIMEPM pm_runtime_set_autosuspend_delay(&pdev->dev, AUTO_SUSPEND_TIMEOUT); pm_runtime_use_autosuspend(&pdev->dev); atomic_set(&bus->dhd->block_bus, FALSE); #endif /* DHD_PCIE_NATIVE_RUNTIMEPM */ #if defined(MULTIPLE_SUPPLICANT) wl_android_post_init(); // terence 20120530: fix critical section in dhd_open and dhdsdio_probe #endif /* MULTIPLE_SUPPLICANT */ DHD_TRACE(("%s:Exit - SUCCESS \n", __FUNCTION__)); return 0; /* return SUCCESS */ } while (0); /* reverse the initialization in order in case of error */ if (bus) dhdpcie_bus_release(bus); #ifdef BCMPCIE_OOB_HOST_WAKE if (dhdpcie_osinfo) { MFREE(osh, dhdpcie_osinfo, sizeof(dhdpcie_os_info_t)); } #endif /* BCMPCIE_OOB_HOST_WAKE */ #ifdef USE_SMMU_ARCH_MSM if (dhdpcie_smmu_info) { MFREE(osh, dhdpcie_smmu_info, sizeof(dhdpcie_smmu_info_t)); dhdpcie_info->smmu_cxt = NULL; } #endif /* USE_SMMU_ARCH_MSM */ if (dhdpcie_info) dhdpcie_detach(dhdpcie_info); pci_disable_device(pdev); if (osh) osl_detach(osh); dhdpcie_init_succeeded = FALSE; DHD_TRACE(("%s:Exit - FAILURE \n", __FUNCTION__)); return -1; /* return FAILURE */ } /* Free Linux irq */ void dhdpcie_free_irq(dhd_bus_t *bus) { struct pci_dev *pdev = NULL; DHD_TRACE(("%s: freeing up the IRQ\n", __FUNCTION__)); if (bus) { pdev = bus->dev; if (bus->irq_registered) { #if defined(SET_PCIE_IRQ_CPU_CORE) && defined(CONFIG_ARCH_SM8150) /* clean up the affinity_hint before * the unregistration of PCIe irq */ (void)irq_set_affinity_hint(pdev->irq, NULL); #endif /* SET_PCIE_IRQ_CPU_CORE && CONFIG_ARCH_SM8150 */ free_irq(pdev->irq, bus); bus->irq_registered = FALSE; if (bus->d2h_intr_method == PCIE_MSI) { dhdpcie_disable_msi(pdev); } } else { DHD_ERROR(("%s: PCIe IRQ is not registered\n", __FUNCTION__)); } } DHD_TRACE(("%s: Exit\n", __FUNCTION__)); return; } /* Name: dhdpcie_isr Parametrs: 1: IN int irq -- interrupt vector 2: IN void *arg -- handle to private data structure Return value: Status (TRUE or FALSE) Description: Interrupt Service routine checks for the status register, disable interrupt and queue DPC if mail box interrupts are raised. */ irqreturn_t dhdpcie_isr(int irq, void *arg) { dhd_bus_t *bus = (dhd_bus_t*)arg; bus->isr_entry_time = OSL_LOCALTIME_NS(); if (!dhdpcie_bus_isr(bus)) { DHD_LOG_MEM(("%s: dhdpcie_bus_isr returns with FALSE\n", __FUNCTION__)); } bus->isr_exit_time = OSL_LOCALTIME_NS(); return IRQ_HANDLED; } int dhdpcie_disable_irq_nosync(dhd_bus_t *bus) { struct pci_dev *dev; if ((bus == NULL) || (bus->dev == NULL)) { DHD_ERROR(("%s: bus or bus->dev is NULL\n", __FUNCTION__)); return BCME_ERROR; } dev = bus->dev; disable_irq_nosync(dev->irq); return BCME_OK; } int dhdpcie_disable_irq(dhd_bus_t *bus) { struct pci_dev *dev; if ((bus == NULL) || (bus->dev == NULL)) { DHD_ERROR(("%s: bus or bus->dev is NULL\n", __FUNCTION__)); return BCME_ERROR; } dev = bus->dev; disable_irq(dev->irq); return BCME_OK; } int dhdpcie_enable_irq(dhd_bus_t *bus) { struct pci_dev *dev; if ((bus == NULL) || (bus->dev == NULL)) { DHD_ERROR(("%s: bus or bus->dev is NULL\n", __FUNCTION__)); return BCME_ERROR; } dev = bus->dev; enable_irq(dev->irq); return BCME_OK; } int dhdpcie_irq_disabled(dhd_bus_t *bus) { #if (LINUX_VERSION_CODE >= KERNEL_VERSION(3, 4, 0)) struct irq_desc *desc = irq_to_desc(bus->dev->irq); /* depth will be zero, if enabled */ return desc->depth; #else /* return ERROR by default as there is no support for lower versions */ return BCME_ERROR; #endif /* LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0) */ } int dhdpcie_start_host_pcieclock(dhd_bus_t *bus) { int ret = 0; #ifdef CONFIG_ARCH_MSM #endif /* CONFIG_ARCH_MSM */ DHD_TRACE(("%s Enter:\n", __FUNCTION__)); if (bus == NULL) { return BCME_ERROR; } if (bus->dev == NULL) { return BCME_ERROR; } #ifdef CONFIG_ARCH_MSM ret = msm_pcie_pm_control(MSM_PCIE_RESUME, bus->dev->bus->number, bus->dev, NULL, 0); if (ret) { DHD_ERROR(("%s Failed to bring up PCIe link\n", __FUNCTION__)); goto done; } done: #endif /* CONFIG_ARCH_MSM */ DHD_TRACE(("%s Exit:\n", __FUNCTION__)); return ret; } int dhdpcie_stop_host_pcieclock(dhd_bus_t *bus) { int ret = 0; #ifdef CONFIG_ARCH_MSM #endif /* CONFIG_ARCH_MSM */ DHD_TRACE(("%s Enter:\n", __FUNCTION__)); if (bus == NULL) { return BCME_ERROR; } if (bus->dev == NULL) { return BCME_ERROR; } #ifdef CONFIG_ARCH_MSM ret = msm_pcie_pm_control(MSM_PCIE_SUSPEND, bus->dev->bus->number, bus->dev, NULL, 0); if (ret) { DHD_ERROR(("Failed to stop PCIe link\n")); goto done; } done: #endif /* CONFIG_ARCH_MSM */ DHD_TRACE(("%s Exit:\n", __FUNCTION__)); return ret; } int dhdpcie_disable_device(dhd_bus_t *bus) { DHD_TRACE(("%s Enter:\n", __FUNCTION__)); if (bus == NULL) { return BCME_ERROR; } if (bus->dev == NULL) { return BCME_ERROR; } if (pci_is_enabled(bus->dev)) pci_disable_device(bus->dev); return 0; } int dhdpcie_enable_device(dhd_bus_t *bus) { int ret = BCME_ERROR; #if (LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0)) dhdpcie_info_t *pch; #endif /* LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0) */ DHD_TRACE(("%s Enter:\n", __FUNCTION__)); if (bus == NULL) { return BCME_ERROR; } if (bus->dev == NULL) { return BCME_ERROR; } #if (LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0)) pch = pci_get_drvdata(bus->dev); if (pch == NULL) { return BCME_ERROR; } #if (LINUX_VERSION_CODE >= KERNEL_VERSION(3, 14, 0)) && (LINUX_VERSION_CODE < \ KERNEL_VERSION(3, 19, 0)) && !defined(CONFIG_SOC_EXYNOS8890) /* Updated with pci_load_and_free_saved_state to compatible * with Kernel version 3.14.0 to 3.18.41. */ pci_load_and_free_saved_state(bus->dev, &pch->default_state); pch->default_state = pci_store_saved_state(bus->dev); #else pci_load_saved_state(bus->dev, pch->default_state); #endif /* LINUX_VERSION >= 3.14.0 && LINUX_VERSION < 3.19.0 && !CONFIG_SOC_EXYNOS8890 */ /* Check if Device ID is valid */ if (bus->dev->state_saved) { uint32 vid, saved_vid; pci_read_config_dword(bus->dev, PCI_CFG_VID, &vid); saved_vid = bus->dev->saved_config_space[PCI_CFG_VID]; if (vid != saved_vid) { DHD_ERROR(("%s: VID(0x%x) is different from saved VID(0x%x) " "Skip the bus init\n", __FUNCTION__, vid, saved_vid)); bus->no_bus_init = TRUE; /* Check if the PCIe link is down */ if (vid == (uint32)-1) { bus->is_linkdown = 1; } return BCME_ERROR; } } pci_restore_state(bus->dev); #endif /* (LINUX_VERSION_CODE >= KERNEL_VERSION(3, 0, 0)) */ ret = pci_enable_device(bus->dev); if (ret) { pci_disable_device(bus->dev); } else { pci_set_master(bus->dev); } return ret; } int dhdpcie_alloc_resource(dhd_bus_t *bus) { dhdpcie_info_t *dhdpcie_info; phys_addr_t bar0_addr, bar1_addr; ulong bar1_size; do { if (bus == NULL) { DHD_ERROR(("%s: bus is NULL\n", __FUNCTION__)); break; } if (bus->dev == NULL) { DHD_ERROR(("%s: bus->dev is NULL\n", __FUNCTION__)); break; } dhdpcie_info = pci_get_drvdata(bus->dev); if (dhdpcie_info == NULL) { DHD_ERROR(("%s: dhdpcie_info is NULL\n", __FUNCTION__)); break; } bar0_addr = pci_resource_start(bus->dev, 0); /* Bar-0 mapped address */ bar1_addr = pci_resource_start(bus->dev, 2); /* Bar-1 mapped address */ /* read Bar-1 mapped memory range */ bar1_size = pci_resource_len(bus->dev, 2); if ((bar1_size == 0) || (bar1_addr == 0)) { printf("%s: BAR1 Not enabled for this device size(%ld)," " addr(0x"PRINTF_RESOURCE")\n", __FUNCTION__, bar1_size, bar1_addr); break; } dhdpcie_info->regs = (volatile char *) REG_MAP(bar0_addr, DONGLE_REG_MAP_SIZE); if (!dhdpcie_info->regs) { DHD_ERROR(("%s: ioremap() for regs is failed\n", __FUNCTION__)); break; } bus->regs = dhdpcie_info->regs; dhdpcie_info->bar1_size = (bar1_size > DONGLE_TCM_MAP_SIZE) ? bar1_size : DONGLE_TCM_MAP_SIZE; dhdpcie_info->tcm = (volatile char *) REG_MAP(bar1_addr, dhdpcie_info->bar1_size); if (!dhdpcie_info->tcm) { DHD_ERROR(("%s: ioremap() for regs is failed\n", __FUNCTION__)); REG_UNMAP(dhdpcie_info->regs); bus->regs = NULL; break; } bus->tcm = dhdpcie_info->tcm; DHD_TRACE(("%s:Phys addr : reg space = %p base addr 0x"PRINTF_RESOURCE" \n", __FUNCTION__, dhdpcie_info->regs, bar0_addr)); DHD_TRACE(("%s:Phys addr : tcm_space = %p base addr 0x"PRINTF_RESOURCE" \n", __FUNCTION__, dhdpcie_info->tcm, bar1_addr)); return 0; } while (0); return BCME_ERROR; } void dhdpcie_free_resource(dhd_bus_t *bus) { dhdpcie_info_t *dhdpcie_info; if (bus == NULL) { DHD_ERROR(("%s: bus is NULL\n", __FUNCTION__)); return; } if (bus->dev == NULL) { DHD_ERROR(("%s: bus->dev is NULL\n", __FUNCTION__)); return; } dhdpcie_info = pci_get_drvdata(bus->dev); if (dhdpcie_info == NULL) { DHD_ERROR(("%s: dhdpcie_info is NULL\n", __FUNCTION__)); return; } if (bus->regs) { REG_UNMAP(dhdpcie_info->regs); bus->regs = NULL; } if (bus->tcm) { REG_UNMAP(dhdpcie_info->tcm); bus->tcm = NULL; } } int dhdpcie_bus_request_irq(struct dhd_bus *bus) { dhdpcie_info_t *dhdpcie_info; int ret = 0; if (bus == NULL) { DHD_ERROR(("%s: bus is NULL\n", __FUNCTION__)); return BCME_ERROR; } if (bus->dev == NULL) { DHD_ERROR(("%s: bus->dev is NULL\n", __FUNCTION__)); return BCME_ERROR; } dhdpcie_info = pci_get_drvdata(bus->dev); if (dhdpcie_info == NULL) { DHD_ERROR(("%s: dhdpcie_info is NULL\n", __FUNCTION__)); return BCME_ERROR; } if (bus->intr) { /* Register interrupt callback, but mask it (not operational yet). */ DHD_INTR(("%s: Registering and masking interrupts\n", __FUNCTION__)); dhdpcie_bus_intr_disable(bus); ret = dhdpcie_request_irq(dhdpcie_info); if (ret) { DHD_ERROR(("%s: request_irq() failed, ret=%d\n", __FUNCTION__, ret)); return ret; } } return ret; } #ifdef BCMPCIE_OOB_HOST_WAKE #ifdef CONFIG_BCMDHD_GET_OOB_STATE extern int dhd_get_wlan_oob_gpio(void); #endif /* CONFIG_BCMDHD_GET_OOB_STATE */ int dhdpcie_get_oob_irq_level(void) { int gpio_level; #ifdef CONFIG_BCMDHD_GET_OOB_STATE gpio_level = dhd_get_wlan_oob_gpio(); #else gpio_level = BCME_UNSUPPORTED; #endif /* CONFIG_BCMDHD_GET_OOB_STATE */ return gpio_level; } int dhdpcie_get_oob_irq_status(struct dhd_bus *bus) { dhdpcie_info_t *pch; dhdpcie_os_info_t *dhdpcie_osinfo; if (bus == NULL) { DHD_ERROR(("%s: bus is NULL\n", __FUNCTION__)); return 0; } if (bus->dev == NULL) { DHD_ERROR(("%s: bus->dev is NULL\n", __FUNCTION__)); return 0; } pch = pci_get_drvdata(bus->dev); if (pch == NULL) { DHD_ERROR(("%s: pch is NULL\n", __FUNCTION__)); return 0; } dhdpcie_osinfo = (dhdpcie_os_info_t *)pch->os_cxt; return dhdpcie_osinfo ? dhdpcie_osinfo->oob_irq_enabled : 0; } int dhdpcie_get_oob_irq_num(struct dhd_bus *bus) { dhdpcie_info_t *pch; dhdpcie_os_info_t *dhdpcie_osinfo; if (bus == NULL) { DHD_ERROR(("%s: bus is NULL\n", __FUNCTION__)); return 0; } if (bus->dev == NULL) { DHD_ERROR(("%s: bus->dev is NULL\n", __FUNCTION__)); return 0; } pch = pci_get_drvdata(bus->dev); if (pch == NULL) { DHD_ERROR(("%s: pch is NULL\n", __FUNCTION__)); return 0; } dhdpcie_osinfo = (dhdpcie_os_info_t *)pch->os_cxt; return dhdpcie_osinfo ? dhdpcie_osinfo->oob_irq_num : 0; } void dhdpcie_oob_intr_set(dhd_bus_t *bus, bool enable) { unsigned long flags; dhdpcie_info_t *pch; dhdpcie_os_info_t *dhdpcie_osinfo; if (bus == NULL) { DHD_ERROR(("%s: bus is NULL\n", __FUNCTION__)); return; } if (bus->dev == NULL) { DHD_ERROR(("%s: bus->dev is NULL\n", __FUNCTION__)); return; } pch = pci_get_drvdata(bus->dev); if (pch == NULL) { DHD_ERROR(("%s: pch is NULL\n", __FUNCTION__)); return; } dhdpcie_osinfo = (dhdpcie_os_info_t *)pch->os_cxt; spin_lock_irqsave(&dhdpcie_osinfo->oob_irq_spinlock, flags); if ((dhdpcie_osinfo->oob_irq_enabled != enable) && (dhdpcie_osinfo->oob_irq_num > 0)) { if (enable) { enable_irq(dhdpcie_osinfo->oob_irq_num); bus->oob_intr_enable_count++; bus->last_oob_irq_enable_time = OSL_LOCALTIME_NS(); } else { disable_irq_nosync(dhdpcie_osinfo->oob_irq_num); bus->oob_intr_disable_count++; bus->last_oob_irq_disable_time = OSL_LOCALTIME_NS(); } dhdpcie_osinfo->oob_irq_enabled = enable; } spin_unlock_irqrestore(&dhdpcie_osinfo->oob_irq_spinlock, flags); } static irqreturn_t wlan_oob_irq(int irq, void *data) { dhd_bus_t *bus; unsigned long flags_bus; DHD_TRACE(("%s: IRQ Triggered\n", __FUNCTION__)); bus = (dhd_bus_t *)data; dhdpcie_oob_intr_set(bus, FALSE); bus->last_oob_irq_time = OSL_LOCALTIME_NS(); bus->oob_intr_count++; #ifdef DHD_WAKE_STATUS { bcmpcie_set_get_wake(bus, 1); } #endif /* DHD_WAKE_STATUS */ #ifdef DHD_PCIE_NATIVE_RUNTIMEPM dhd_bus_wakeup_work(bus->dhd); #endif /* DHD_PCIE_NATIVE_RUNTIMEPM */ DHD_BUS_LOCK(bus->bus_lock, flags_bus); /* Hold wakelock if bus_low_power_state is * DHD_BUS_D3_INFORM_SENT OR DHD_BUS_D3_ACK_RECIEVED */ if (bus->dhd->up && bus->bus_low_power_state != DHD_BUS_NO_LOW_POWER_STATE) { DHD_OS_OOB_IRQ_WAKE_LOCK_TIMEOUT(bus->dhd, OOB_WAKE_LOCK_TIMEOUT); } DHD_BUS_UNLOCK(bus->bus_lock, flags_bus); return IRQ_HANDLED; } int dhdpcie_oob_intr_register(dhd_bus_t *bus) { int err = 0; dhdpcie_info_t *pch; dhdpcie_os_info_t *dhdpcie_osinfo; DHD_TRACE(("%s: Enter\n", __FUNCTION__)); if (bus == NULL) { DHD_ERROR(("%s: bus is NULL\n", __FUNCTION__)); return -EINVAL; } if (bus->dev == NULL) { DHD_ERROR(("%s: bus->dev is NULL\n", __FUNCTION__)); return -EINVAL; } pch = pci_get_drvdata(bus->dev); if (pch == NULL) { DHD_ERROR(("%s: pch is NULL\n", __FUNCTION__)); return -EINVAL; } dhdpcie_osinfo = (dhdpcie_os_info_t *)pch->os_cxt; if (dhdpcie_osinfo->oob_irq_registered) { DHD_ERROR(("%s: irq is already registered\n", __FUNCTION__)); return -EBUSY; } if (dhdpcie_osinfo->oob_irq_num > 0) { printf("%s OOB irq=%d flags=0x%X\n", __FUNCTION__, (int)dhdpcie_osinfo->oob_irq_num, (int)dhdpcie_osinfo->oob_irq_flags); err = request_irq(dhdpcie_osinfo->oob_irq_num, wlan_oob_irq, dhdpcie_osinfo->oob_irq_flags, "dhdpcie_host_wake", bus); if (err) { DHD_ERROR(("%s: request_irq failed with %d\n", __FUNCTION__, err)); return err; } #if defined(DISABLE_WOWLAN) printf("%s: disable_irq_wake\n", __FUNCTION__); dhdpcie_osinfo->oob_irq_wake_enabled = FALSE; #else printf("%s: enable_irq_wake\n", __FUNCTION__); err = enable_irq_wake(dhdpcie_osinfo->oob_irq_num); if (!err) { dhdpcie_osinfo->oob_irq_wake_enabled = TRUE; } else printf("%s: enable_irq_wake failed with %d\n", __FUNCTION__, err); #endif dhdpcie_osinfo->oob_irq_enabled = TRUE; } dhdpcie_osinfo->oob_irq_registered = TRUE; return 0; } void dhdpcie_oob_intr_unregister(dhd_bus_t *bus) { int err = 0; dhdpcie_info_t *pch; dhdpcie_os_info_t *dhdpcie_osinfo; DHD_TRACE(("%s: Enter\n", __FUNCTION__)); if (bus == NULL) { DHD_ERROR(("%s: bus is NULL\n", __FUNCTION__)); return; } if (bus->dev == NULL) { DHD_ERROR(("%s: bus->dev is NULL\n", __FUNCTION__)); return; } pch = pci_get_drvdata(bus->dev); if (pch == NULL) { DHD_ERROR(("%s: pch is NULL\n", __FUNCTION__)); return; } dhdpcie_osinfo = (dhdpcie_os_info_t *)pch->os_cxt; if (!dhdpcie_osinfo->oob_irq_registered) { DHD_ERROR(("%s: irq is not registered\n", __FUNCTION__)); return; } if (dhdpcie_osinfo->oob_irq_num > 0) { if (dhdpcie_osinfo->oob_irq_wake_enabled) { err = disable_irq_wake(dhdpcie_osinfo->oob_irq_num); if (!err) { dhdpcie_osinfo->oob_irq_wake_enabled = FALSE; } } if (dhdpcie_osinfo->oob_irq_enabled) { disable_irq(dhdpcie_osinfo->oob_irq_num); dhdpcie_osinfo->oob_irq_enabled = FALSE; } free_irq(dhdpcie_osinfo->oob_irq_num, bus); } dhdpcie_osinfo->oob_irq_registered = FALSE; } #endif /* BCMPCIE_OOB_HOST_WAKE */ struct device * dhd_bus_to_dev(dhd_bus_t *bus) { struct pci_dev *pdev; pdev = bus->dev; if (pdev) return &pdev->dev; else return NULL; } #define KIRQ_PRINT_BUF_LEN 256 void dhd_print_kirqstats(dhd_pub_t *dhd, unsigned int irq_num) { unsigned long flags = 0; struct irq_desc *desc; int i; /* cpu iterator */ struct bcmstrbuf strbuf; char tmp_buf[KIRQ_PRINT_BUF_LEN]; desc = irq_to_desc(irq_num); if (!desc) { DHD_ERROR(("%s : irqdesc is not found \n", __FUNCTION__)); return; } bcm_binit(&strbuf, tmp_buf, KIRQ_PRINT_BUF_LEN); raw_spin_lock_irqsave(&desc->lock, flags); bcm_bprintf(&strbuf, "dhd irq %u:", irq_num); for_each_online_cpu(i) bcm_bprintf(&strbuf, "%10u ", desc->kstat_irqs ? *per_cpu_ptr(desc->kstat_irqs, i) : 0); if (desc->irq_data.chip) { if (desc->irq_data.chip->name) bcm_bprintf(&strbuf, " %8s", desc->irq_data.chip->name); else bcm_bprintf(&strbuf, " %8s", "-"); } else { bcm_bprintf(&strbuf, " %8s", "None"); } #if (LINUX_VERSION_CODE >= KERNEL_VERSION(3, 1, 0)) if (desc->irq_data.domain) bcm_bprintf(&strbuf, " %d", (int)desc->irq_data.hwirq); #ifdef CONFIG_GENERIC_IRQ_SHOW_LEVEL bcm_bprintf(&strbuf, " %-8s", irqd_is_level_type(&desc->irq_data) ? "Level" : "Edge"); #endif // endif #endif /* LINUX VERSION > 3.1.0 */ if (desc->name) bcm_bprintf(&strbuf, "-%-8s", desc->name); DHD_ERROR(("%s\n", strbuf.origbuf)); raw_spin_unlock_irqrestore(&desc->lock, flags); } void dhd_show_kirqstats(dhd_pub_t *dhd) { unsigned int irq = -1; #ifdef BCMPCIE dhdpcie_get_pcieirq(dhd->bus, &irq); #endif /* BCMPCIE */ #ifdef BCMSDIO irq = ((wifi_adapter_info_t *)dhd->info->adapter)->irq_num; #endif /* BCMSDIO */ if (irq != -1) { #ifdef BCMPCIE DHD_ERROR(("DUMP data kernel irq stats : \n")); #endif /* BCMPCIE */ #ifdef BCMSDIO DHD_ERROR(("DUMP data/host wakeup kernel irq stats : \n")); #endif /* BCMSDIO */ dhd_print_kirqstats(dhd, irq); } #ifdef BCMPCIE_OOB_HOST_WAKE irq = dhdpcie_get_oob_irq_num(dhd->bus); if (irq) { DHD_ERROR(("DUMP PCIE host wakeup kernel irq stats : \n")); dhd_print_kirqstats(dhd, irq); } #endif /* BCMPCIE_OOB_HOST_WAKE */ } #ifdef DHD_FW_COREDUMP int dhd_dongle_mem_dump(void) { if (!g_dhd_bus) { DHD_ERROR(("%s: Bus is NULL\n", __FUNCTION__)); return -ENODEV; } dhd_bus_dump_console_buffer(g_dhd_bus); dhd_prot_debug_info_print(g_dhd_bus->dhd); g_dhd_bus->dhd->memdump_enabled = DUMP_MEMFILE_BUGON; g_dhd_bus->dhd->memdump_type = DUMP_TYPE_AP_ABNORMAL_ACCESS; dhd_bus_mem_dump(g_dhd_bus->dhd); return 0; } EXPORT_SYMBOL(dhd_dongle_mem_dump); #endif /* DHD_FW_COREDUMP */ bool dhd_bus_check_driver_up(void) { dhd_bus_t *bus; dhd_pub_t *dhdp; bool isup = FALSE; bus = (dhd_bus_t *)g_dhd_bus; if (!bus) { DHD_ERROR(("%s: bus is NULL\n", __FUNCTION__)); return isup; } dhdp = bus->dhd; if (dhdp) { isup = dhdp->up; } return isup; } EXPORT_SYMBOL(dhd_bus_check_driver_up);