/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * SunOs MT STREAMS Hydra 10Gb Ethernet Device Driver. */ #include #include /* * PSARC/2007/453 MSI-X interrupt limit override * (This PSARC case is limited to MSI-X vectors * and SPARC platforms only). */ #if defined(_BIG_ENDIAN) uint32_t hxge_msi_enable = 2; #else uint32_t hxge_msi_enable = 1; #endif /* * Globals: tunable parameters (/etc/system or adb) * */ uint32_t hxge_rbr_size = HXGE_RBR_RBB_DEFAULT; uint32_t hxge_rbr_spare_size = 0; uint32_t hxge_rcr_size = HXGE_RCR_DEFAULT; uint32_t hxge_tx_ring_size = HXGE_TX_RING_DEFAULT; uint32_t hxge_bcopy_thresh = TX_BCOPY_MAX; uint32_t hxge_dvma_thresh = TX_FASTDVMA_MIN; uint32_t hxge_dma_stream_thresh = TX_STREAM_MIN; uint32_t hxge_jumbo_mtu = TX_JUMBO_MTU; boolean_t hxge_jumbo_enable = B_FALSE; static hxge_os_mutex_t hxgedebuglock; static int hxge_debug_init = 0; /* * Debugging flags: * hxge_no_tx_lb : transmit load balancing * hxge_tx_lb_policy: 0 - TCP/UDP port (default) * 1 - From the Stack * 2 - Destination IP Address */ uint32_t hxge_no_tx_lb = 0; uint32_t hxge_tx_lb_policy = HXGE_TX_LB_TCPUDP; /* * Add tunable to reduce the amount of time spent in the * ISR doing Rx Processing. */ uint32_t hxge_max_rx_pkts = 1024; /* * Tunables to manage the receive buffer blocks. * * hxge_rx_threshold_hi: copy all buffers. * hxge_rx_bcopy_size_type: receive buffer block size type. * hxge_rx_threshold_lo: copy only up to tunable block size type. */ hxge_rxbuf_threshold_t hxge_rx_threshold_hi = HXGE_RX_COPY_6; hxge_rxbuf_type_t hxge_rx_buf_size_type = RCR_PKTBUFSZ_0; hxge_rxbuf_threshold_t hxge_rx_threshold_lo = HXGE_RX_COPY_3; rtrace_t hpi_rtracebuf; /* * Function Prototypes */ static int hxge_attach(dev_info_t *, ddi_attach_cmd_t); static int hxge_detach(dev_info_t *, ddi_detach_cmd_t); static void hxge_unattach(p_hxge_t); static hxge_status_t hxge_setup_system_dma_pages(p_hxge_t); static hxge_status_t hxge_setup_mutexes(p_hxge_t); static void hxge_destroy_mutexes(p_hxge_t); static hxge_status_t hxge_map_regs(p_hxge_t hxgep); static void hxge_unmap_regs(p_hxge_t hxgep); hxge_status_t hxge_add_intrs(p_hxge_t hxgep); static hxge_status_t hxge_add_soft_intrs(p_hxge_t hxgep); static void hxge_remove_intrs(p_hxge_t hxgep); static void hxge_remove_soft_intrs(p_hxge_t hxgep); static hxge_status_t hxge_add_intrs_adv(p_hxge_t hxgep); static hxge_status_t hxge_add_intrs_adv_type(p_hxge_t, uint32_t); static hxge_status_t hxge_add_intrs_adv_type_fix(p_hxge_t, uint32_t); void hxge_intrs_enable(p_hxge_t hxgep); static void hxge_intrs_disable(p_hxge_t hxgep); static void hxge_suspend(p_hxge_t); static hxge_status_t hxge_resume(p_hxge_t); hxge_status_t hxge_setup_dev(p_hxge_t); static void hxge_destroy_dev(p_hxge_t); hxge_status_t hxge_alloc_mem_pool(p_hxge_t); static void hxge_free_mem_pool(p_hxge_t); static hxge_status_t hxge_alloc_rx_mem_pool(p_hxge_t); static void hxge_free_rx_mem_pool(p_hxge_t); static hxge_status_t hxge_alloc_tx_mem_pool(p_hxge_t); static void hxge_free_tx_mem_pool(p_hxge_t); static hxge_status_t hxge_dma_mem_alloc(p_hxge_t, dma_method_t, struct ddi_dma_attr *, size_t, ddi_device_acc_attr_t *, uint_t, p_hxge_dma_common_t); static void hxge_dma_mem_free(p_hxge_dma_common_t); static hxge_status_t hxge_alloc_rx_buf_dma(p_hxge_t, uint16_t, p_hxge_dma_common_t *, size_t, size_t, uint32_t *); static void hxge_free_rx_buf_dma(p_hxge_t, p_hxge_dma_common_t, uint32_t); static hxge_status_t hxge_alloc_rx_cntl_dma(p_hxge_t, uint16_t, p_hxge_dma_common_t *, size_t); static void hxge_free_rx_cntl_dma(p_hxge_t, p_hxge_dma_common_t); static hxge_status_t hxge_alloc_tx_buf_dma(p_hxge_t, uint16_t, p_hxge_dma_common_t *, size_t, size_t, uint32_t *); static void hxge_free_tx_buf_dma(p_hxge_t, p_hxge_dma_common_t, uint32_t); static hxge_status_t hxge_alloc_tx_cntl_dma(p_hxge_t, uint16_t, p_hxge_dma_common_t *, size_t); static void hxge_free_tx_cntl_dma(p_hxge_t, p_hxge_dma_common_t); static int hxge_init_common_dev(p_hxge_t); static void hxge_uninit_common_dev(p_hxge_t); /* * The next declarations are for the GLDv3 interface. */ static int hxge_m_start(void *); static void hxge_m_stop(void *); static int hxge_m_unicst(void *, const uint8_t *); static int hxge_m_multicst(void *, boolean_t, const uint8_t *); static int hxge_m_promisc(void *, boolean_t); static void hxge_m_ioctl(void *, queue_t *, mblk_t *); static void hxge_m_resources(void *); static hxge_status_t hxge_mac_register(p_hxge_t hxgep); static int hxge_m_mmac_add(void *arg, mac_multi_addr_t *maddr); static int hxge_m_mmac_remove(void *arg, mac_addr_slot_t slot); static int hxge_m_mmac_modify(void *arg, mac_multi_addr_t *maddr); static int hxge_m_mmac_get(void *arg, mac_multi_addr_t *maddr); static boolean_t hxge_m_getcapab(void *, mac_capab_t, void *); #define HXGE_MAGIC 0x4E584745UL #define MAX_DUMP_SZ 256 #define HXGE_M_CALLBACK_FLAGS (MC_RESOURCES | MC_IOCTL | MC_GETCAPAB) extern mblk_t *hxge_m_tx(void *arg, mblk_t *mp); extern hxge_status_t hxge_pfc_set_default_mac_addr(p_hxge_t hxgep); static mac_callbacks_t hxge_m_callbacks = { HXGE_M_CALLBACK_FLAGS, hxge_m_stat, hxge_m_start, hxge_m_stop, hxge_m_promisc, hxge_m_multicst, hxge_m_unicst, hxge_m_tx, hxge_m_resources, hxge_m_ioctl, hxge_m_getcapab }; /* Enable debug messages as necessary. */ uint64_t hxge_debug_level = 0x0; /* * This list contains the instance structures for the Hydra * devices present in the system. The lock exists to guarantee * mutually exclusive access to the list. */ void *hxge_list = NULL; void *hxge_hw_list = NULL; hxge_os_mutex_t hxge_common_lock; extern uint64_t hpi_debug_level; extern hxge_status_t hxge_ldgv_init(); extern hxge_status_t hxge_ldgv_uninit(); extern hxge_status_t hxge_intr_ldgv_init(); extern void hxge_fm_init(p_hxge_t hxgep, ddi_device_acc_attr_t *reg_attr, ddi_device_acc_attr_t *desc_attr, ddi_dma_attr_t *dma_attr); extern void hxge_fm_fini(p_hxge_t hxgep); /* * Count used to maintain the number of buffers being used * by Hydra instances and loaned up to the upper layers. */ uint32_t hxge_mblks_pending = 0; /* * Device register access attributes for PIO. */ static ddi_device_acc_attr_t hxge_dev_reg_acc_attr = { DDI_DEVICE_ATTR_V0, DDI_STRUCTURE_LE_ACC, DDI_STRICTORDER_ACC, }; /* * Device descriptor access attributes for DMA. */ static ddi_device_acc_attr_t hxge_dev_desc_dma_acc_attr = { DDI_DEVICE_ATTR_V0, DDI_STRUCTURE_LE_ACC, DDI_STRICTORDER_ACC }; /* * Device buffer access attributes for DMA. */ static ddi_device_acc_attr_t hxge_dev_buf_dma_acc_attr = { DDI_DEVICE_ATTR_V0, DDI_STRUCTURE_BE_ACC, DDI_STRICTORDER_ACC }; ddi_dma_attr_t hxge_desc_dma_attr = { DMA_ATTR_V0, /* version number. */ 0, /* low address */ 0xffffffffffffffff, /* high address */ 0xffffffffffffffff, /* address counter max */ 0x100000, /* alignment */ 0xfc00fc, /* dlim_burstsizes */ 0x1, /* minimum transfer size */ 0xffffffffffffffff, /* maximum transfer size */ 0xffffffffffffffff, /* maximum segment size */ 1, /* scatter/gather list length */ (unsigned int)1, /* granularity */ 0 /* attribute flags */ }; ddi_dma_attr_t hxge_tx_dma_attr = { DMA_ATTR_V0, /* version number. */ 0, /* low address */ 0xffffffffffffffff, /* high address */ 0xffffffffffffffff, /* address counter max */ #if defined(_BIG_ENDIAN) 0x2000, /* alignment */ #else 0x1000, /* alignment */ #endif 0xfc00fc, /* dlim_burstsizes */ 0x1, /* minimum transfer size */ 0xffffffffffffffff, /* maximum transfer size */ 0xffffffffffffffff, /* maximum segment size */ 5, /* scatter/gather list length */ (unsigned int)1, /* granularity */ 0 /* attribute flags */ }; ddi_dma_attr_t hxge_rx_dma_attr = { DMA_ATTR_V0, /* version number. */ 0, /* low address */ 0xffffffffffffffff, /* high address */ 0xffffffffffffffff, /* address counter max */ 0x10000, /* alignment */ 0xfc00fc, /* dlim_burstsizes */ 0x1, /* minimum transfer size */ 0xffffffffffffffff, /* maximum transfer size */ 0xffffffffffffffff, /* maximum segment size */ 1, /* scatter/gather list length */ (unsigned int)1, /* granularity */ DDI_DMA_RELAXED_ORDERING /* attribute flags */ }; ddi_dma_lim_t hxge_dma_limits = { (uint_t)0, /* dlim_addr_lo */ (uint_t)0xffffffff, /* dlim_addr_hi */ (uint_t)0xffffffff, /* dlim_cntr_max */ (uint_t)0xfc00fc, /* dlim_burstsizes for 32 and 64 bit xfers */ 0x1, /* dlim_minxfer */ 1024 /* dlim_speed */ }; dma_method_t hxge_force_dma = DVMA; /* * dma chunk sizes. * * Try to allocate the largest possible size * so that fewer number of dma chunks would be managed */ size_t alloc_sizes[] = { 0x1000, 0x2000, 0x4000, 0x8000, 0x10000, 0x20000, 0x40000, 0x80000, 0x100000, 0x200000, 0x400000, 0x800000, 0x1000000 }; /* * Translate "dev_t" to a pointer to the associated "dev_info_t". */ static int hxge_attach(dev_info_t *dip, ddi_attach_cmd_t cmd) { p_hxge_t hxgep = NULL; int instance; int status = DDI_SUCCESS; HXGE_DEBUG_MSG((hxgep, DDI_CTL, "==> hxge_attach")); /* * Get the device instance since we'll need to setup or retrieve a soft * state for this instance. */ instance = ddi_get_instance(dip); switch (cmd) { case DDI_ATTACH: HXGE_DEBUG_MSG((hxgep, DDI_CTL, "doing DDI_ATTACH")); break; case DDI_RESUME: HXGE_DEBUG_MSG((hxgep, DDI_CTL, "doing DDI_RESUME")); hxgep = (p_hxge_t)ddi_get_soft_state(hxge_list, instance); if (hxgep == NULL) { status = DDI_FAILURE; break; } if (hxgep->dip != dip) { status = DDI_FAILURE; break; } if (hxgep->suspended == DDI_PM_SUSPEND) { status = ddi_dev_is_needed(hxgep->dip, 0, 1); } else { (void) hxge_resume(hxgep); } goto hxge_attach_exit; case DDI_PM_RESUME: HXGE_DEBUG_MSG((hxgep, DDI_CTL, "doing DDI_PM_RESUME")); hxgep = (p_hxge_t)ddi_get_soft_state(hxge_list, instance); if (hxgep == NULL) { status = DDI_FAILURE; break; } if (hxgep->dip != dip) { status = DDI_FAILURE; break; } (void) hxge_resume(hxgep); goto hxge_attach_exit; default: HXGE_DEBUG_MSG((hxgep, DDI_CTL, "doing unknown")); status = DDI_FAILURE; goto hxge_attach_exit; } if (ddi_soft_state_zalloc(hxge_list, instance) == DDI_FAILURE) { status = DDI_FAILURE; HXGE_ERROR_MSG((hxgep, DDI_CTL, "ddi_soft_state_zalloc failed")); goto hxge_attach_exit; } hxgep = ddi_get_soft_state(hxge_list, instance); if (hxgep == NULL) { status = HXGE_ERROR; HXGE_ERROR_MSG((hxgep, DDI_CTL, "ddi_get_soft_state failed")); goto hxge_attach_fail2; } hxgep->drv_state = 0; hxgep->dip = dip; hxgep->instance = instance; hxgep->p_dip = ddi_get_parent(dip); hxgep->hxge_debug_level = hxge_debug_level; hpi_debug_level = hxge_debug_level; hxge_fm_init(hxgep, &hxge_dev_reg_acc_attr, &hxge_dev_desc_dma_acc_attr, &hxge_rx_dma_attr); status = hxge_map_regs(hxgep); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "hxge_map_regs failed")); goto hxge_attach_fail3; } status = hxge_init_common_dev(hxgep); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "hxge_init_common_dev failed")); goto hxge_attach_fail4; } /* * Setup the Ndd parameters for this instance. */ hxge_init_param(hxgep); /* * Setup Register Tracing Buffer. */ hpi_rtrace_buf_init((rtrace_t *)&hpi_rtracebuf); /* init stats ptr */ hxge_init_statsp(hxgep); status = hxge_get_config_properties(hxgep); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "get_hw create failed")); goto hxge_attach_fail; } /* * Setup the Kstats for the driver. */ hxge_setup_kstats(hxgep); hxge_setup_param(hxgep); status = hxge_setup_system_dma_pages(hxgep); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "set dma page failed")); goto hxge_attach_fail; } hxge_hw_id_init(hxgep); hxge_hw_init_niu_common(hxgep); status = hxge_setup_mutexes(hxgep); if (status != HXGE_OK) { HXGE_DEBUG_MSG((hxgep, DDI_CTL, "set mutex failed")); goto hxge_attach_fail; } status = hxge_setup_dev(hxgep); if (status != DDI_SUCCESS) { HXGE_DEBUG_MSG((hxgep, DDI_CTL, "set dev failed")); goto hxge_attach_fail; } status = hxge_add_intrs(hxgep); if (status != DDI_SUCCESS) { HXGE_DEBUG_MSG((hxgep, DDI_CTL, "add_intr failed")); goto hxge_attach_fail; } status = hxge_add_soft_intrs(hxgep); if (status != DDI_SUCCESS) { HXGE_DEBUG_MSG((hxgep, HXGE_ERR_CTL, "add_soft_intr failed")); goto hxge_attach_fail; } /* * Enable interrupts. */ hxge_intrs_enable(hxgep); if ((status = hxge_mac_register(hxgep)) != HXGE_OK) { HXGE_DEBUG_MSG((hxgep, DDI_CTL, "unable to register to mac layer (%d)", status)); goto hxge_attach_fail; } mac_link_update(hxgep->mach, LINK_STATE_UP); HXGE_DEBUG_MSG((hxgep, DDI_CTL, "registered to mac (instance %d)", instance)); goto hxge_attach_exit; hxge_attach_fail: hxge_unattach(hxgep); goto hxge_attach_fail1; hxge_attach_fail5: /* * Tear down the ndd parameters setup. */ hxge_destroy_param(hxgep); /* * Tear down the kstat setup. */ hxge_destroy_kstats(hxgep); hxge_attach_fail4: if (hxgep->hxge_hw_p) { hxge_uninit_common_dev(hxgep); hxgep->hxge_hw_p = NULL; } hxge_attach_fail3: /* * Unmap the register setup. */ hxge_unmap_regs(hxgep); hxge_fm_fini(hxgep); hxge_attach_fail2: ddi_soft_state_free(hxge_list, hxgep->instance); hxge_attach_fail1: if (status != HXGE_OK) status = (HXGE_ERROR | HXGE_DDI_FAILED); hxgep = NULL; hxge_attach_exit: HXGE_DEBUG_MSG((hxgep, DDI_CTL, "<== hxge_attach status = 0x%08x", status)); return (status); } static int hxge_detach(dev_info_t *dip, ddi_detach_cmd_t cmd) { int status = DDI_SUCCESS; int instance; p_hxge_t hxgep = NULL; HXGE_DEBUG_MSG((hxgep, DDI_CTL, "==> hxge_detach")); instance = ddi_get_instance(dip); hxgep = ddi_get_soft_state(hxge_list, instance); if (hxgep == NULL) { status = DDI_FAILURE; goto hxge_detach_exit; } switch (cmd) { case DDI_DETACH: HXGE_DEBUG_MSG((hxgep, DDI_CTL, "doing DDI_DETACH")); break; case DDI_PM_SUSPEND: HXGE_DEBUG_MSG((hxgep, DDI_CTL, "doing DDI_PM_SUSPEND")); hxgep->suspended = DDI_PM_SUSPEND; hxge_suspend(hxgep); break; case DDI_SUSPEND: HXGE_DEBUG_MSG((hxgep, DDI_CTL, "doing DDI_SUSPEND")); if (hxgep->suspended != DDI_PM_SUSPEND) { hxgep->suspended = DDI_SUSPEND; hxge_suspend(hxgep); } break; default: status = DDI_FAILURE; break; } if (cmd != DDI_DETACH) goto hxge_detach_exit; /* * Stop the xcvr polling. */ hxgep->suspended = cmd; if (hxgep->mach && (status = mac_unregister(hxgep->mach)) != 0) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "<== hxge_detach status = 0x%08X", status)); return (DDI_FAILURE); } HXGE_DEBUG_MSG((hxgep, DDI_CTL, "<== hxge_detach (mac_unregister) status = 0x%08X", status)); hxge_unattach(hxgep); hxgep = NULL; hxge_detach_exit: HXGE_DEBUG_MSG((hxgep, DDI_CTL, "<== hxge_detach status = 0x%08X", status)); return (status); } static void hxge_unattach(p_hxge_t hxgep) { HXGE_DEBUG_MSG((hxgep, DDI_CTL, "==> hxge_unattach")); if (hxgep == NULL || hxgep->dev_regs == NULL) { return; } if (hxgep->hxge_hw_p) { hxge_uninit_common_dev(hxgep); hxgep->hxge_hw_p = NULL; } if (hxgep->hxge_timerid) { hxge_stop_timer(hxgep, hxgep->hxge_timerid); hxgep->hxge_timerid = 0; } /* Stop any further interrupts. */ hxge_remove_intrs(hxgep); /* Remove soft interrups */ hxge_remove_soft_intrs(hxgep); /* Stop the device and free resources. */ hxge_destroy_dev(hxgep); /* Tear down the ndd parameters setup. */ hxge_destroy_param(hxgep); /* Tear down the kstat setup. */ hxge_destroy_kstats(hxgep); /* * Remove the list of ndd parameters which were setup during attach. */ if (hxgep->dip) { HXGE_DEBUG_MSG((hxgep, OBP_CTL, " hxge_unattach: remove all properties")); (void) ddi_prop_remove_all(hxgep->dip); } /* * Reset RDC, TDC, PFC, and VMAC blocks from PEU to clear any * previous state before unmapping the registers. */ HXGE_REG_WR32(hxgep->hpi_handle, BLOCK_RESET, 0x0000001E); HXGE_DELAY(1000); /* * Unmap the register setup. */ hxge_unmap_regs(hxgep); hxge_fm_fini(hxgep); /* * Free the soft state data structures allocated with this instance. */ ddi_soft_state_free(hxge_list, hxgep->instance); /* Destroy all mutexes. */ hxge_destroy_mutexes(hxgep); HXGE_DEBUG_MSG((NULL, DDI_CTL, "<== hxge_unattach")); } static hxge_status_t hxge_map_regs(p_hxge_t hxgep) { int ddi_status = DDI_SUCCESS; p_dev_regs_t dev_regs; #ifdef HXGE_DEBUG char *sysname; #endif off_t regsize; hxge_status_t status = HXGE_OK; int nregs; HXGE_DEBUG_MSG((hxgep, DDI_CTL, "==> hxge_map_regs")); if (ddi_dev_nregs(hxgep->dip, &nregs) != DDI_SUCCESS) return (HXGE_ERROR); HXGE_DEBUG_MSG((hxgep, DDI_CTL, "hxge_map_regs: nregs: %d", nregs)); hxgep->dev_regs = NULL; dev_regs = KMEM_ZALLOC(sizeof (dev_regs_t), KM_SLEEP); dev_regs->hxge_regh = NULL; dev_regs->hxge_pciregh = NULL; dev_regs->hxge_msix_regh = NULL; (void) ddi_dev_regsize(hxgep->dip, 0, ®size); HXGE_DEBUG_MSG((hxgep, DDI_CTL, "hxge_map_regs: pci config size 0x%x", regsize)); ddi_status = ddi_regs_map_setup(hxgep->dip, 0, (caddr_t *)&(dev_regs->hxge_pciregp), 0, 0, &hxge_dev_reg_acc_attr, &dev_regs->hxge_pciregh); if (ddi_status != DDI_SUCCESS) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "ddi_map_regs, hxge bus config regs failed")); goto hxge_map_regs_fail0; } HXGE_DEBUG_MSG((hxgep, DDI_CTL, "hxge_map_reg: PCI config addr 0x%0llx handle 0x%0llx", dev_regs->hxge_pciregp, dev_regs->hxge_pciregh)); (void) ddi_dev_regsize(hxgep->dip, 1, ®size); HXGE_DEBUG_MSG((hxgep, DDI_CTL, "hxge_map_regs: pio size 0x%x", regsize)); /* set up the device mapped register */ ddi_status = ddi_regs_map_setup(hxgep->dip, 1, (caddr_t *)&(dev_regs->hxge_regp), 0, 0, &hxge_dev_reg_acc_attr, &dev_regs->hxge_regh); if (ddi_status != DDI_SUCCESS) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "ddi_map_regs for Hydra global reg failed")); goto hxge_map_regs_fail1; } /* set up the msi/msi-x mapped register */ (void) ddi_dev_regsize(hxgep->dip, 2, ®size); HXGE_DEBUG_MSG((hxgep, DDI_CTL, "hxge_map_regs: msix size 0x%x", regsize)); ddi_status = ddi_regs_map_setup(hxgep->dip, 2, (caddr_t *)&(dev_regs->hxge_msix_regp), 0, 0, &hxge_dev_reg_acc_attr, &dev_regs->hxge_msix_regh); if (ddi_status != DDI_SUCCESS) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "ddi_map_regs for msi reg failed")); goto hxge_map_regs_fail2; } hxgep->dev_regs = dev_regs; HPI_PCI_ACC_HANDLE_SET(hxgep, dev_regs->hxge_pciregh); HPI_PCI_ADD_HANDLE_SET(hxgep, (hpi_reg_ptr_t)dev_regs->hxge_pciregp); HPI_MSI_ACC_HANDLE_SET(hxgep, dev_regs->hxge_msix_regh); HPI_MSI_ADD_HANDLE_SET(hxgep, (hpi_reg_ptr_t)dev_regs->hxge_msix_regp); HPI_ACC_HANDLE_SET(hxgep, dev_regs->hxge_regh); HPI_ADD_HANDLE_SET(hxgep, (hpi_reg_ptr_t)dev_regs->hxge_regp); HPI_REG_ACC_HANDLE_SET(hxgep, dev_regs->hxge_regh); HPI_REG_ADD_HANDLE_SET(hxgep, (hpi_reg_ptr_t)dev_regs->hxge_regp); HXGE_DEBUG_MSG((hxgep, DDI_CTL, "hxge_map_reg: hardware addr 0x%0llx " " handle 0x%0llx", dev_regs->hxge_regp, dev_regs->hxge_regh)); goto hxge_map_regs_exit; hxge_map_regs_fail3: if (dev_regs->hxge_msix_regh) { ddi_regs_map_free(&dev_regs->hxge_msix_regh); } hxge_map_regs_fail2: if (dev_regs->hxge_regh) { ddi_regs_map_free(&dev_regs->hxge_regh); } hxge_map_regs_fail1: if (dev_regs->hxge_pciregh) { ddi_regs_map_free(&dev_regs->hxge_pciregh); } hxge_map_regs_fail0: HXGE_DEBUG_MSG((hxgep, DDI_CTL, "Freeing register set memory")); kmem_free(dev_regs, sizeof (dev_regs_t)); hxge_map_regs_exit: if (ddi_status != DDI_SUCCESS) status |= (HXGE_ERROR | HXGE_DDI_FAILED); HXGE_DEBUG_MSG((hxgep, DDI_CTL, "<== hxge_map_regs")); return (status); } static void hxge_unmap_regs(p_hxge_t hxgep) { HXGE_DEBUG_MSG((hxgep, DDI_CTL, "==> hxge_unmap_regs")); if (hxgep->dev_regs) { if (hxgep->dev_regs->hxge_pciregh) { HXGE_DEBUG_MSG((hxgep, DDI_CTL, "==> hxge_unmap_regs: bus")); ddi_regs_map_free(&hxgep->dev_regs->hxge_pciregh); hxgep->dev_regs->hxge_pciregh = NULL; } if (hxgep->dev_regs->hxge_regh) { HXGE_DEBUG_MSG((hxgep, DDI_CTL, "==> hxge_unmap_regs: device registers")); ddi_regs_map_free(&hxgep->dev_regs->hxge_regh); hxgep->dev_regs->hxge_regh = NULL; } if (hxgep->dev_regs->hxge_msix_regh) { HXGE_DEBUG_MSG((hxgep, DDI_CTL, "==> hxge_unmap_regs: device interrupts")); ddi_regs_map_free(&hxgep->dev_regs->hxge_msix_regh); hxgep->dev_regs->hxge_msix_regh = NULL; } kmem_free(hxgep->dev_regs, sizeof (dev_regs_t)); hxgep->dev_regs = NULL; } HXGE_DEBUG_MSG((hxgep, DDI_CTL, "<== hxge_unmap_regs")); } static hxge_status_t hxge_setup_mutexes(p_hxge_t hxgep) { int ddi_status = DDI_SUCCESS; hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, DDI_CTL, "==> hxge_setup_mutexes")); /* * Get the interrupt cookie so the mutexes can be Initialised. */ ddi_status = ddi_get_iblock_cookie(hxgep->dip, 0, &hxgep->interrupt_cookie); if (ddi_status != DDI_SUCCESS) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "<== hxge_setup_mutexes: failed 0x%x", ddi_status)); goto hxge_setup_mutexes_exit; } /* * Initialize mutex's for this device. */ MUTEX_INIT(hxgep->genlock, NULL, MUTEX_DRIVER, (void *) hxgep->interrupt_cookie); MUTEX_INIT(&hxgep->ouraddr_lock, NULL, MUTEX_DRIVER, (void *) hxgep->interrupt_cookie); RW_INIT(&hxgep->filter_lock, NULL, RW_DRIVER, (void *) hxgep->interrupt_cookie); MUTEX_INIT(&hxgep->pio_lock, NULL, MUTEX_DRIVER, (void *) hxgep->interrupt_cookie); hxge_setup_mutexes_exit: HXGE_DEBUG_MSG((hxgep, DDI_CTL, "<== hxge_setup_mutexes status = %x", status)); if (ddi_status != DDI_SUCCESS) status |= (HXGE_ERROR | HXGE_DDI_FAILED); return (status); } static void hxge_destroy_mutexes(p_hxge_t hxgep) { HXGE_DEBUG_MSG((hxgep, DDI_CTL, "==> hxge_destroy_mutexes")); RW_DESTROY(&hxgep->filter_lock); MUTEX_DESTROY(&hxgep->ouraddr_lock); MUTEX_DESTROY(hxgep->genlock); MUTEX_DESTROY(&hxgep->pio_lock); if (hxge_debug_init == 1) { MUTEX_DESTROY(&hxgedebuglock); hxge_debug_init = 0; } HXGE_DEBUG_MSG((hxgep, DDI_CTL, "<== hxge_destroy_mutexes")); } hxge_status_t hxge_init(p_hxge_t hxgep) { hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, STR_CTL, "==> hxge_init")); if (hxgep->drv_state & STATE_HW_INITIALIZED) { return (status); } /* * Allocate system memory for the receive/transmit buffer blocks and * receive/transmit descriptor rings. */ status = hxge_alloc_mem_pool(hxgep); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "alloc mem failed\n")); goto hxge_init_fail1; } /* * Initialize and enable TXDMA channels. */ status = hxge_init_txdma_channels(hxgep); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "init txdma failed\n")); goto hxge_init_fail3; } /* * Initialize and enable RXDMA channels. */ status = hxge_init_rxdma_channels(hxgep); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "init rxdma failed\n")); goto hxge_init_fail4; } /* * Initialize TCAM */ status = hxge_classify_init(hxgep); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "init classify failed\n")); goto hxge_init_fail5; } /* * Initialize the VMAC block. */ status = hxge_vmac_init(hxgep); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "init MAC failed\n")); goto hxge_init_fail5; } /* Bringup - this may be unnecessary when PXE and FCODE available */ status = hxge_pfc_set_default_mac_addr(hxgep); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "Default Address Failure\n")); goto hxge_init_fail5; } hxge_intrs_enable(hxgep); /* * Enable hardware interrupts. */ hxge_intr_hw_enable(hxgep); hxgep->drv_state |= STATE_HW_INITIALIZED; goto hxge_init_exit; hxge_init_fail5: hxge_uninit_rxdma_channels(hxgep); hxge_init_fail4: hxge_uninit_txdma_channels(hxgep); hxge_init_fail3: hxge_free_mem_pool(hxgep); hxge_init_fail1: HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "<== hxge_init status (failed) = 0x%08x", status)); return (status); hxge_init_exit: HXGE_DEBUG_MSG((hxgep, DDI_CTL, "<== hxge_init status = 0x%08x", status)); return (status); } timeout_id_t hxge_start_timer(p_hxge_t hxgep, fptrv_t func, int msec) { if ((hxgep->suspended == 0) || (hxgep->suspended == DDI_RESUME)) { return (timeout(func, (caddr_t)hxgep, drv_usectohz(1000 * msec))); } return (NULL); } /*ARGSUSED*/ void hxge_stop_timer(p_hxge_t hxgep, timeout_id_t timerid) { if (timerid) { (void) untimeout(timerid); } } void hxge_uninit(p_hxge_t hxgep) { HXGE_DEBUG_MSG((hxgep, DDI_CTL, "==> hxge_uninit")); if (!(hxgep->drv_state & STATE_HW_INITIALIZED)) { HXGE_DEBUG_MSG((hxgep, DDI_CTL, "==> hxge_uninit: not initialized")); HXGE_DEBUG_MSG((hxgep, DDI_CTL, "<== hxge_uninit")); return; } /* Stop timer */ if (hxgep->hxge_timerid) { hxge_stop_timer(hxgep, hxgep->hxge_timerid); hxgep->hxge_timerid = 0; } (void) hxge_intr_hw_disable(hxgep); /* Reset the receive VMAC side. */ (void) hxge_rx_vmac_disable(hxgep); /* Free classification resources */ (void) hxge_classify_uninit(hxgep); /* Reset the transmit/receive DMA side. */ (void) hxge_txdma_hw_mode(hxgep, HXGE_DMA_STOP); (void) hxge_rxdma_hw_mode(hxgep, HXGE_DMA_STOP); hxge_uninit_txdma_channels(hxgep); hxge_uninit_rxdma_channels(hxgep); /* Reset the transmit VMAC side. */ (void) hxge_tx_vmac_disable(hxgep); hxge_free_mem_pool(hxgep); hxgep->drv_state &= ~STATE_HW_INITIALIZED; HXGE_DEBUG_MSG((hxgep, DDI_CTL, "<== hxge_uninit")); } void hxge_get64(p_hxge_t hxgep, p_mblk_t mp) { #if defined(__i386) size_t reg; #else uint64_t reg; #endif uint64_t regdata; int i, retry; bcopy((char *)mp->b_rptr, (char *)®, sizeof (uint64_t)); regdata = 0; retry = 1; for (i = 0; i < retry; i++) { HXGE_REG_RD64(hxgep->hpi_handle, reg, ®data); } bcopy((char *)®data, (char *)mp->b_rptr, sizeof (uint64_t)); } void hxge_put64(p_hxge_t hxgep, p_mblk_t mp) { #if defined(__i386) size_t reg; #else uint64_t reg; #endif uint64_t buf[2]; bcopy((char *)mp->b_rptr, (char *)&buf[0], 2 * sizeof (uint64_t)); #if defined(__i386) reg = (size_t)buf[0]; #else reg = buf[0]; #endif HXGE_HPI_PIO_WRITE64(hxgep->hpi_handle, reg, buf[1]); } /*ARGSUSED*/ /*VARARGS*/ void hxge_debug_msg(p_hxge_t hxgep, uint64_t level, char *fmt, ...) { char msg_buffer[1048]; char prefix_buffer[32]; int instance; uint64_t debug_level; int cmn_level = CE_CONT; va_list ap; debug_level = (hxgep == NULL) ? hxge_debug_level : hxgep->hxge_debug_level; if ((level & debug_level) || (level == HXGE_NOTE) || (level == HXGE_ERR_CTL)) { /* do the msg processing */ if (hxge_debug_init == 0) { MUTEX_INIT(&hxgedebuglock, NULL, MUTEX_DRIVER, NULL); hxge_debug_init = 1; } MUTEX_ENTER(&hxgedebuglock); if ((level & HXGE_NOTE)) { cmn_level = CE_NOTE; } if (level & HXGE_ERR_CTL) { cmn_level = CE_WARN; } va_start(ap, fmt); (void) vsprintf(msg_buffer, fmt, ap); va_end(ap); if (hxgep == NULL) { instance = -1; (void) sprintf(prefix_buffer, "%s :", "hxge"); } else { instance = hxgep->instance; (void) sprintf(prefix_buffer, "%s%d :", "hxge", instance); } MUTEX_EXIT(&hxgedebuglock); cmn_err(cmn_level, "%s %s\n", prefix_buffer, msg_buffer); } } char * hxge_dump_packet(char *addr, int size) { uchar_t *ap = (uchar_t *)addr; int i; static char etherbuf[1024]; char *cp = etherbuf; char digits[] = "0123456789abcdef"; if (!size) size = 60; if (size > MAX_DUMP_SZ) { /* Dump the leading bytes */ for (i = 0; i < MAX_DUMP_SZ / 2; i++) { if (*ap > 0x0f) *cp++ = digits[*ap >> 4]; *cp++ = digits[*ap++ & 0xf]; *cp++ = ':'; } for (i = 0; i < 20; i++) *cp++ = '.'; /* Dump the last MAX_DUMP_SZ/2 bytes */ ap = (uchar_t *)(addr + (size - MAX_DUMP_SZ / 2)); for (i = 0; i < MAX_DUMP_SZ / 2; i++) { if (*ap > 0x0f) *cp++ = digits[*ap >> 4]; *cp++ = digits[*ap++ & 0xf]; *cp++ = ':'; } } else { for (i = 0; i < size; i++) { if (*ap > 0x0f) *cp++ = digits[*ap >> 4]; *cp++ = digits[*ap++ & 0xf]; *cp++ = ':'; } } *--cp = 0; return (etherbuf); } static void hxge_suspend(p_hxge_t hxgep) { HXGE_DEBUG_MSG((hxgep, DDI_CTL, "==> hxge_suspend")); hxge_intrs_disable(hxgep); hxge_destroy_dev(hxgep); HXGE_DEBUG_MSG((hxgep, DDI_CTL, "<== hxge_suspend")); } static hxge_status_t hxge_resume(p_hxge_t hxgep) { hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, DDI_CTL, "==> hxge_resume")); hxgep->suspended = DDI_RESUME; (void) hxge_rxdma_hw_mode(hxgep, HXGE_DMA_START); (void) hxge_txdma_hw_mode(hxgep, HXGE_DMA_START); (void) hxge_rx_vmac_enable(hxgep); (void) hxge_tx_vmac_enable(hxgep); hxge_intrs_enable(hxgep); hxgep->suspended = 0; HXGE_DEBUG_MSG((hxgep, DDI_CTL, "<== hxge_resume status = 0x%x", status)); return (status); } hxge_status_t hxge_setup_dev(p_hxge_t hxgep) { hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, DDI_CTL, "==> hxge_setup_dev")); status = hxge_link_init(hxgep); if (fm_check_acc_handle(hxgep->dev_regs->hxge_regh) != DDI_FM_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "Bad register acc handle")); status = HXGE_ERROR; } if (status != HXGE_OK) { HXGE_DEBUG_MSG((hxgep, MAC_CTL, " hxge_setup_dev status (link init 0x%08x)", status)); goto hxge_setup_dev_exit; } hxge_setup_dev_exit: HXGE_DEBUG_MSG((hxgep, DDI_CTL, "<== hxge_setup_dev status = 0x%08x", status)); return (status); } static void hxge_destroy_dev(p_hxge_t hxgep) { HXGE_DEBUG_MSG((hxgep, DDI_CTL, "==> hxge_destroy_dev")); (void) hxge_hw_stop(hxgep); HXGE_DEBUG_MSG((hxgep, DDI_CTL, "<== hxge_destroy_dev")); } static hxge_status_t hxge_setup_system_dma_pages(p_hxge_t hxgep) { int ddi_status = DDI_SUCCESS; uint_t count; ddi_dma_cookie_t cookie; uint_t iommu_pagesize; hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, DDI_CTL, "==> hxge_setup_system_dma_pages")); hxgep->sys_page_sz = ddi_ptob(hxgep->dip, (ulong_t)1); iommu_pagesize = dvma_pagesize(hxgep->dip); HXGE_DEBUG_MSG((hxgep, DDI_CTL, " hxge_setup_system_dma_pages: page %d (ddi_ptob %d) " " default_block_size %d iommu_pagesize %d", hxgep->sys_page_sz, ddi_ptob(hxgep->dip, (ulong_t)1), hxgep->rx_default_block_size, iommu_pagesize)); if (iommu_pagesize != 0) { if (hxgep->sys_page_sz == iommu_pagesize) { /* Hydra support up to 8K pages */ if (iommu_pagesize > 0x2000) hxgep->sys_page_sz = 0x2000; } else { if (hxgep->sys_page_sz > iommu_pagesize) hxgep->sys_page_sz = iommu_pagesize; } } hxgep->sys_page_mask = ~(hxgep->sys_page_sz - 1); HXGE_DEBUG_MSG((hxgep, DDI_CTL, "==> hxge_setup_system_dma_pages: page %d (ddi_ptob %d) " "default_block_size %d page mask %d", hxgep->sys_page_sz, ddi_ptob(hxgep->dip, (ulong_t)1), hxgep->rx_default_block_size, hxgep->sys_page_mask)); switch (hxgep->sys_page_sz) { default: hxgep->sys_page_sz = 0x1000; hxgep->sys_page_mask = ~(hxgep->sys_page_sz - 1); hxgep->rx_default_block_size = 0x1000; hxgep->rx_bksize_code = RBR_BKSIZE_4K; break; case 0x1000: hxgep->rx_default_block_size = 0x1000; hxgep->rx_bksize_code = RBR_BKSIZE_4K; break; case 0x2000: hxgep->rx_default_block_size = 0x2000; hxgep->rx_bksize_code = RBR_BKSIZE_8K; break; } hxge_rx_dma_attr.dma_attr_align = hxgep->sys_page_sz; hxge_tx_dma_attr.dma_attr_align = hxgep->sys_page_sz; hxge_desc_dma_attr.dma_attr_align = hxgep->sys_page_sz; /* * Get the system DMA burst size. */ ddi_status = ddi_dma_alloc_handle(hxgep->dip, &hxge_tx_dma_attr, DDI_DMA_DONTWAIT, 0, &hxgep->dmasparehandle); if (ddi_status != DDI_SUCCESS) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "ddi_dma_alloc_handle: failed status 0x%x", ddi_status)); goto hxge_get_soft_properties_exit; } ddi_status = ddi_dma_addr_bind_handle(hxgep->dmasparehandle, NULL, (caddr_t)hxgep->dmasparehandle, sizeof (hxgep->dmasparehandle), DDI_DMA_RDWR | DDI_DMA_CONSISTENT, DDI_DMA_DONTWAIT, 0, &cookie, &count); if (ddi_status != DDI_DMA_MAPPED) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "Binding spare handle to find system burstsize failed.")); ddi_status = DDI_FAILURE; goto hxge_get_soft_properties_fail1; } hxgep->sys_burst_sz = ddi_dma_burstsizes(hxgep->dmasparehandle); (void) ddi_dma_unbind_handle(hxgep->dmasparehandle); hxge_get_soft_properties_fail1: ddi_dma_free_handle(&hxgep->dmasparehandle); hxge_get_soft_properties_exit: if (ddi_status != DDI_SUCCESS) status |= (HXGE_ERROR | HXGE_DDI_FAILED); HXGE_DEBUG_MSG((hxgep, DDI_CTL, "<== hxge_setup_system_dma_pages status = 0x%08x", status)); return (status); } hxge_status_t hxge_alloc_mem_pool(p_hxge_t hxgep) { hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, DDI_CTL, "==> hxge_alloc_mem_pool")); status = hxge_alloc_rx_mem_pool(hxgep); if (status != HXGE_OK) { return (HXGE_ERROR); } status = hxge_alloc_tx_mem_pool(hxgep); if (status != HXGE_OK) { hxge_free_rx_mem_pool(hxgep); return (HXGE_ERROR); } HXGE_DEBUG_MSG((hxgep, DDI_CTL, "<== hxge_alloc_mem_pool")); return (HXGE_OK); } static void hxge_free_mem_pool(p_hxge_t hxgep) { HXGE_DEBUG_MSG((hxgep, MEM_CTL, "==> hxge_free_mem_pool")); hxge_free_rx_mem_pool(hxgep); hxge_free_tx_mem_pool(hxgep); HXGE_DEBUG_MSG((hxgep, MEM_CTL, "<== hxge_free_mem_pool")); } static hxge_status_t hxge_alloc_rx_mem_pool(p_hxge_t hxgep) { int i, j; uint32_t ndmas, st_rdc; p_hxge_dma_pt_cfg_t p_all_cfgp; p_hxge_hw_pt_cfg_t p_cfgp; p_hxge_dma_pool_t dma_poolp; p_hxge_dma_common_t *dma_buf_p; p_hxge_dma_pool_t dma_cntl_poolp; p_hxge_dma_common_t *dma_cntl_p; size_t rx_buf_alloc_size; size_t rx_cntl_alloc_size; uint32_t *num_chunks; /* per dma */ hxge_status_t status = HXGE_OK; uint32_t hxge_port_rbr_size; uint32_t hxge_port_rbr_spare_size; uint32_t hxge_port_rcr_size; HXGE_DEBUG_MSG((hxgep, DMA_CTL, "==> hxge_alloc_rx_mem_pool")); p_all_cfgp = (p_hxge_dma_pt_cfg_t)&hxgep->pt_config; p_cfgp = (p_hxge_hw_pt_cfg_t)&p_all_cfgp->hw_config; st_rdc = p_cfgp->start_rdc; ndmas = p_cfgp->max_rdcs; HXGE_DEBUG_MSG((hxgep, DMA_CTL, " hxge_alloc_rx_mem_pool st_rdc %d ndmas %d", st_rdc, ndmas)); /* * Allocate memory for each receive DMA channel. */ dma_poolp = (p_hxge_dma_pool_t)KMEM_ZALLOC(sizeof (hxge_dma_pool_t), KM_SLEEP); dma_buf_p = (p_hxge_dma_common_t *)KMEM_ZALLOC( sizeof (p_hxge_dma_common_t) * ndmas, KM_SLEEP); dma_cntl_poolp = (p_hxge_dma_pool_t) KMEM_ZALLOC(sizeof (hxge_dma_pool_t), KM_SLEEP); dma_cntl_p = (p_hxge_dma_common_t *)KMEM_ZALLOC( sizeof (p_hxge_dma_common_t) * ndmas, KM_SLEEP); num_chunks = (uint32_t *)KMEM_ZALLOC(sizeof (uint32_t) * ndmas, KM_SLEEP); /* * Assume that each DMA channel will be configured with default block * size. rbr block counts are mod of batch count (16). */ hxge_port_rbr_size = p_all_cfgp->rbr_size; hxge_port_rcr_size = p_all_cfgp->rcr_size; if (!hxge_port_rbr_size) { hxge_port_rbr_size = HXGE_RBR_RBB_DEFAULT; } if (hxge_port_rbr_size % HXGE_RXDMA_POST_BATCH) { hxge_port_rbr_size = (HXGE_RXDMA_POST_BATCH * (hxge_port_rbr_size / HXGE_RXDMA_POST_BATCH + 1)); } p_all_cfgp->rbr_size = hxge_port_rbr_size; hxge_port_rbr_spare_size = hxge_rbr_spare_size; if (hxge_port_rbr_spare_size % HXGE_RXDMA_POST_BATCH) { hxge_port_rbr_spare_size = (HXGE_RXDMA_POST_BATCH * (hxge_port_rbr_spare_size / HXGE_RXDMA_POST_BATCH + 1)); } rx_buf_alloc_size = (hxgep->rx_default_block_size * (hxge_port_rbr_size + hxge_port_rbr_spare_size)); /* * Addresses of receive block ring, receive completion ring and the * mailbox must be all cache-aligned (64 bytes). */ rx_cntl_alloc_size = hxge_port_rbr_size + hxge_port_rbr_spare_size; rx_cntl_alloc_size *= (sizeof (rx_desc_t)); rx_cntl_alloc_size += (sizeof (rcr_entry_t) * hxge_port_rcr_size); rx_cntl_alloc_size += sizeof (rxdma_mailbox_t); HXGE_DEBUG_MSG((hxgep, MEM2_CTL, "==> hxge_alloc_rx_mem_pool: " "hxge_port_rbr_size = %d hxge_port_rbr_spare_size = %d " "hxge_port_rcr_size = %d rx_cntl_alloc_size = %d", hxge_port_rbr_size, hxge_port_rbr_spare_size, hxge_port_rcr_size, rx_cntl_alloc_size)); hxgep->hxge_port_rbr_size = hxge_port_rbr_size; hxgep->hxge_port_rcr_size = hxge_port_rcr_size; /* * Allocate memory for receive buffers and descriptor rings. Replace * allocation functions with interface functions provided by the * partition manager when it is available. */ /* * Allocate memory for the receive buffer blocks. */ for (i = 0; i < ndmas; i++) { HXGE_DEBUG_MSG((hxgep, MEM2_CTL, " hxge_alloc_rx_mem_pool to alloc mem: " " dma %d dma_buf_p %llx &dma_buf_p %llx", i, dma_buf_p[i], &dma_buf_p[i])); num_chunks[i] = 0; status = hxge_alloc_rx_buf_dma(hxgep, st_rdc, &dma_buf_p[i], rx_buf_alloc_size, hxgep->rx_default_block_size, &num_chunks[i]); if (status != HXGE_OK) { break; } st_rdc++; HXGE_DEBUG_MSG((hxgep, MEM2_CTL, " hxge_alloc_rx_mem_pool DONE alloc mem: " "dma %d dma_buf_p %llx &dma_buf_p %llx", i, dma_buf_p[i], &dma_buf_p[i])); } if (i < ndmas) { goto hxge_alloc_rx_mem_fail1; } /* * Allocate memory for descriptor rings and mailbox. */ st_rdc = p_cfgp->start_rdc; for (j = 0; j < ndmas; j++) { status = hxge_alloc_rx_cntl_dma(hxgep, st_rdc, &dma_cntl_p[j], rx_cntl_alloc_size); if (status != HXGE_OK) { break; } st_rdc++; } if (j < ndmas) { goto hxge_alloc_rx_mem_fail2; } dma_poolp->ndmas = ndmas; dma_poolp->num_chunks = num_chunks; dma_poolp->buf_allocated = B_TRUE; hxgep->rx_buf_pool_p = dma_poolp; dma_poolp->dma_buf_pool_p = dma_buf_p; dma_cntl_poolp->ndmas = ndmas; dma_cntl_poolp->buf_allocated = B_TRUE; hxgep->rx_cntl_pool_p = dma_cntl_poolp; dma_cntl_poolp->dma_buf_pool_p = dma_cntl_p; goto hxge_alloc_rx_mem_pool_exit; hxge_alloc_rx_mem_fail2: /* Free control buffers */ j--; HXGE_DEBUG_MSG((hxgep, DMA_CTL, "==> hxge_alloc_rx_mem_pool: freeing control bufs (%d)", j)); for (; j >= 0; j--) { hxge_free_rx_cntl_dma(hxgep, (p_hxge_dma_common_t)dma_cntl_p[j]); HXGE_DEBUG_MSG((hxgep, DMA_CTL, "==> hxge_alloc_rx_mem_pool: control bufs freed (%d)", j)); } HXGE_DEBUG_MSG((hxgep, DMA_CTL, "==> hxge_alloc_rx_mem_pool: control bufs freed (%d)", j)); hxge_alloc_rx_mem_fail1: /* Free data buffers */ i--; HXGE_DEBUG_MSG((hxgep, DMA_CTL, "==> hxge_alloc_rx_mem_pool: freeing data bufs (%d)", i)); for (; i >= 0; i--) { hxge_free_rx_buf_dma(hxgep, (p_hxge_dma_common_t)dma_buf_p[i], num_chunks[i]); } HXGE_DEBUG_MSG((hxgep, DMA_CTL, "==> hxge_alloc_rx_mem_pool: data bufs freed (%d)", i)); KMEM_FREE(num_chunks, sizeof (uint32_t) * ndmas); KMEM_FREE(dma_poolp, sizeof (hxge_dma_pool_t)); KMEM_FREE(dma_buf_p, ndmas * sizeof (p_hxge_dma_common_t)); KMEM_FREE(dma_cntl_poolp, sizeof (hxge_dma_pool_t)); KMEM_FREE(dma_cntl_p, ndmas * sizeof (p_hxge_dma_common_t)); hxge_alloc_rx_mem_pool_exit: HXGE_DEBUG_MSG((hxgep, DMA_CTL, "<== hxge_alloc_rx_mem_pool:status 0x%08x", status)); return (status); } static void hxge_free_rx_mem_pool(p_hxge_t hxgep) { uint32_t i, ndmas; p_hxge_dma_pool_t dma_poolp; p_hxge_dma_common_t *dma_buf_p; p_hxge_dma_pool_t dma_cntl_poolp; p_hxge_dma_common_t *dma_cntl_p; uint32_t *num_chunks; HXGE_DEBUG_MSG((hxgep, MEM2_CTL, "==> hxge_free_rx_mem_pool")); dma_poolp = hxgep->rx_buf_pool_p; if (dma_poolp == NULL || (!dma_poolp->buf_allocated)) { HXGE_DEBUG_MSG((hxgep, MEM2_CTL, "<== hxge_free_rx_mem_pool " "(null rx buf pool or buf not allocated")); return; } dma_cntl_poolp = hxgep->rx_cntl_pool_p; if (dma_cntl_poolp == NULL || (!dma_cntl_poolp->buf_allocated)) { HXGE_DEBUG_MSG((hxgep, MEM2_CTL, "<== hxge_free_rx_mem_pool " "(null rx cntl buf pool or cntl buf not allocated")); return; } dma_buf_p = dma_poolp->dma_buf_pool_p; num_chunks = dma_poolp->num_chunks; dma_cntl_p = dma_cntl_poolp->dma_buf_pool_p; ndmas = dma_cntl_poolp->ndmas; for (i = 0; i < ndmas; i++) { hxge_free_rx_buf_dma(hxgep, dma_buf_p[i], num_chunks[i]); } for (i = 0; i < ndmas; i++) { hxge_free_rx_cntl_dma(hxgep, dma_cntl_p[i]); } for (i = 0; i < ndmas; i++) { KMEM_FREE(dma_buf_p[i], sizeof (hxge_dma_common_t) * HXGE_DMA_BLOCK); KMEM_FREE(dma_cntl_p[i], sizeof (hxge_dma_common_t)); } KMEM_FREE(num_chunks, sizeof (uint32_t) * ndmas); KMEM_FREE(dma_cntl_p, ndmas * sizeof (p_hxge_dma_common_t)); KMEM_FREE(dma_cntl_poolp, sizeof (hxge_dma_pool_t)); KMEM_FREE(dma_buf_p, ndmas * sizeof (p_hxge_dma_common_t)); KMEM_FREE(dma_poolp, sizeof (hxge_dma_pool_t)); hxgep->rx_buf_pool_p = NULL; hxgep->rx_cntl_pool_p = NULL; HXGE_DEBUG_MSG((hxgep, MEM2_CTL, "<== hxge_free_rx_mem_pool")); } static hxge_status_t hxge_alloc_rx_buf_dma(p_hxge_t hxgep, uint16_t dma_channel, p_hxge_dma_common_t *dmap, size_t alloc_size, size_t block_size, uint32_t *num_chunks) { p_hxge_dma_common_t rx_dmap; hxge_status_t status = HXGE_OK; size_t total_alloc_size; size_t allocated = 0; int i, size_index, array_size; HXGE_DEBUG_MSG((hxgep, DMA_CTL, "==> hxge_alloc_rx_buf_dma")); rx_dmap = (p_hxge_dma_common_t) KMEM_ZALLOC(sizeof (hxge_dma_common_t) * HXGE_DMA_BLOCK, KM_SLEEP); HXGE_DEBUG_MSG((hxgep, MEM2_CTL, " alloc_rx_buf_dma rdc %d asize %x bsize %x bbuf %llx ", dma_channel, alloc_size, block_size, dmap)); total_alloc_size = alloc_size; i = 0; size_index = 0; array_size = sizeof (alloc_sizes) / sizeof (size_t); while ((alloc_sizes[size_index] < alloc_size) && (size_index < array_size)) size_index++; if (size_index >= array_size) { size_index = array_size - 1; } while ((allocated < total_alloc_size) && (size_index >= 0) && (i < HXGE_DMA_BLOCK)) { rx_dmap[i].dma_chunk_index = i; rx_dmap[i].block_size = block_size; rx_dmap[i].alength = alloc_sizes[size_index]; rx_dmap[i].orig_alength = rx_dmap[i].alength; rx_dmap[i].nblocks = alloc_sizes[size_index] / block_size; rx_dmap[i].dma_channel = dma_channel; rx_dmap[i].contig_alloc_type = B_FALSE; HXGE_DEBUG_MSG((hxgep, MEM2_CTL, "alloc_rx_buf_dma rdc %d chunk %d bufp %llx size %x " "i %d nblocks %d alength %d", dma_channel, i, &rx_dmap[i], block_size, i, rx_dmap[i].nblocks, rx_dmap[i].alength)); status = hxge_dma_mem_alloc(hxgep, hxge_force_dma, &hxge_rx_dma_attr, rx_dmap[i].alength, &hxge_dev_buf_dma_acc_attr, DDI_DMA_READ | DDI_DMA_STREAMING, (p_hxge_dma_common_t)(&rx_dmap[i])); if (status != HXGE_OK) { HXGE_DEBUG_MSG((hxgep, DMA_CTL, " hxge_alloc_rx_buf_dma: Alloc Failed: " " for size: %d", alloc_sizes[size_index])); size_index--; } else { HXGE_DEBUG_MSG((hxgep, DMA_CTL, " alloc_rx_buf_dma allocated rdc %d " "chunk %d size %x dvma %x bufp %llx ", dma_channel, i, rx_dmap[i].alength, rx_dmap[i].ioaddr_pp, &rx_dmap[i])); i++; allocated += alloc_sizes[size_index]; } } if (allocated < total_alloc_size) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " hxge_alloc_rx_buf_dma failed due to" " allocated(%d) < required(%d)", allocated, total_alloc_size)); goto hxge_alloc_rx_mem_fail1; } HXGE_DEBUG_MSG((hxgep, DMA_CTL, " alloc_rx_buf_dma rdc %d allocated %d chunks", dma_channel, i)); *num_chunks = i; *dmap = rx_dmap; goto hxge_alloc_rx_mem_exit; hxge_alloc_rx_mem_fail1: KMEM_FREE(rx_dmap, sizeof (hxge_dma_common_t) * HXGE_DMA_BLOCK); hxge_alloc_rx_mem_exit: HXGE_DEBUG_MSG((hxgep, DMA_CTL, "<== hxge_alloc_rx_buf_dma status 0x%08x", status)); return (status); } /*ARGSUSED*/ static void hxge_free_rx_buf_dma(p_hxge_t hxgep, p_hxge_dma_common_t dmap, uint32_t num_chunks) { int i; HXGE_DEBUG_MSG((hxgep, MEM2_CTL, "==> hxge_free_rx_buf_dma: # of chunks %d", num_chunks)); for (i = 0; i < num_chunks; i++) { HXGE_DEBUG_MSG((hxgep, MEM2_CTL, "==> hxge_free_rx_buf_dma: chunk %d dmap 0x%llx", i, dmap)); hxge_dma_mem_free(dmap++); } HXGE_DEBUG_MSG((hxgep, MEM2_CTL, "<== hxge_free_rx_buf_dma")); } /*ARGSUSED*/ static hxge_status_t hxge_alloc_rx_cntl_dma(p_hxge_t hxgep, uint16_t dma_channel, p_hxge_dma_common_t *dmap, size_t size) { p_hxge_dma_common_t rx_dmap; hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, DMA_CTL, "==> hxge_alloc_rx_cntl_dma")); rx_dmap = (p_hxge_dma_common_t) KMEM_ZALLOC(sizeof (hxge_dma_common_t), KM_SLEEP); rx_dmap->contig_alloc_type = B_FALSE; status = hxge_dma_mem_alloc(hxgep, hxge_force_dma, &hxge_desc_dma_attr, size, &hxge_dev_desc_dma_acc_attr, DDI_DMA_RDWR | DDI_DMA_CONSISTENT, rx_dmap); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " hxge_alloc_rx_cntl_dma: Alloc Failed: " " for size: %d", size)); goto hxge_alloc_rx_cntl_dma_fail1; } *dmap = rx_dmap; goto hxge_alloc_rx_cntl_dma_exit; hxge_alloc_rx_cntl_dma_fail1: KMEM_FREE(rx_dmap, sizeof (hxge_dma_common_t)); hxge_alloc_rx_cntl_dma_exit: HXGE_DEBUG_MSG((hxgep, DMA_CTL, "<== hxge_alloc_rx_cntl_dma status 0x%08x", status)); return (status); } /*ARGSUSED*/ static void hxge_free_rx_cntl_dma(p_hxge_t hxgep, p_hxge_dma_common_t dmap) { HXGE_DEBUG_MSG((hxgep, DMA_CTL, "==> hxge_free_rx_cntl_dma")); hxge_dma_mem_free(dmap); HXGE_DEBUG_MSG((hxgep, DMA_CTL, "<== hxge_free_rx_cntl_dma")); } static hxge_status_t hxge_alloc_tx_mem_pool(p_hxge_t hxgep) { hxge_status_t status = HXGE_OK; int i, j; uint32_t ndmas, st_tdc; p_hxge_dma_pt_cfg_t p_all_cfgp; p_hxge_hw_pt_cfg_t p_cfgp; p_hxge_dma_pool_t dma_poolp; p_hxge_dma_common_t *dma_buf_p; p_hxge_dma_pool_t dma_cntl_poolp; p_hxge_dma_common_t *dma_cntl_p; size_t tx_buf_alloc_size; size_t tx_cntl_alloc_size; uint32_t *num_chunks; /* per dma */ HXGE_DEBUG_MSG((hxgep, MEM_CTL, "==> hxge_alloc_tx_mem_pool")); p_all_cfgp = (p_hxge_dma_pt_cfg_t)&hxgep->pt_config; p_cfgp = (p_hxge_hw_pt_cfg_t)&p_all_cfgp->hw_config; st_tdc = p_cfgp->start_tdc; ndmas = p_cfgp->max_tdcs; HXGE_DEBUG_MSG((hxgep, MEM_CTL, "==> hxge_alloc_tx_mem_pool: " "p_cfgp 0x%016llx start_tdc %d ndmas %d hxgep->max_tdcs %d", p_cfgp, p_cfgp->start_tdc, p_cfgp->max_tdcs, hxgep->max_tdcs)); /* * Allocate memory for each transmit DMA channel. */ dma_poolp = (p_hxge_dma_pool_t)KMEM_ZALLOC(sizeof (hxge_dma_pool_t), KM_SLEEP); dma_buf_p = (p_hxge_dma_common_t *)KMEM_ZALLOC( sizeof (p_hxge_dma_common_t) * ndmas, KM_SLEEP); dma_cntl_poolp = (p_hxge_dma_pool_t) KMEM_ZALLOC(sizeof (hxge_dma_pool_t), KM_SLEEP); dma_cntl_p = (p_hxge_dma_common_t *)KMEM_ZALLOC( sizeof (p_hxge_dma_common_t) * ndmas, KM_SLEEP); hxgep->hxge_port_tx_ring_size = hxge_tx_ring_size; /* * Assume that each DMA channel will be configured with default * transmit bufer size for copying transmit data. (For packet payload * over this limit, packets will not be copied.) */ tx_buf_alloc_size = (hxge_bcopy_thresh * hxge_tx_ring_size); /* * Addresses of transmit descriptor ring and the mailbox must be all * cache-aligned (64 bytes). */ tx_cntl_alloc_size = hxge_tx_ring_size; tx_cntl_alloc_size *= (sizeof (tx_desc_t)); tx_cntl_alloc_size += sizeof (txdma_mailbox_t); num_chunks = (uint32_t *)KMEM_ZALLOC(sizeof (uint32_t) * ndmas, KM_SLEEP); /* * Allocate memory for transmit buffers and descriptor rings. Replace * allocation functions with interface functions provided by the * partition manager when it is available. * * Allocate memory for the transmit buffer pool. */ for (i = 0; i < ndmas; i++) { num_chunks[i] = 0; status = hxge_alloc_tx_buf_dma(hxgep, st_tdc, &dma_buf_p[i], tx_buf_alloc_size, hxge_bcopy_thresh, &num_chunks[i]); if (status != HXGE_OK) { break; } st_tdc++; } if (i < ndmas) { goto hxge_alloc_tx_mem_pool_fail1; } st_tdc = p_cfgp->start_tdc; /* * Allocate memory for descriptor rings and mailbox. */ for (j = 0; j < ndmas; j++) { status = hxge_alloc_tx_cntl_dma(hxgep, st_tdc, &dma_cntl_p[j], tx_cntl_alloc_size); if (status != HXGE_OK) { break; } st_tdc++; } if (j < ndmas) { goto hxge_alloc_tx_mem_pool_fail2; } dma_poolp->ndmas = ndmas; dma_poolp->num_chunks = num_chunks; dma_poolp->buf_allocated = B_TRUE; dma_poolp->dma_buf_pool_p = dma_buf_p; hxgep->tx_buf_pool_p = dma_poolp; dma_cntl_poolp->ndmas = ndmas; dma_cntl_poolp->buf_allocated = B_TRUE; dma_cntl_poolp->dma_buf_pool_p = dma_cntl_p; hxgep->tx_cntl_pool_p = dma_cntl_poolp; HXGE_DEBUG_MSG((hxgep, MEM_CTL, "==> hxge_alloc_tx_mem_pool: start_tdc %d " "ndmas %d poolp->ndmas %d", st_tdc, ndmas, dma_poolp->ndmas)); goto hxge_alloc_tx_mem_pool_exit; hxge_alloc_tx_mem_pool_fail2: /* Free control buffers */ j--; for (; j >= 0; j--) { hxge_free_tx_cntl_dma(hxgep, (p_hxge_dma_common_t)dma_cntl_p[j]); } hxge_alloc_tx_mem_pool_fail1: /* Free data buffers */ i--; for (; i >= 0; i--) { hxge_free_tx_buf_dma(hxgep, (p_hxge_dma_common_t)dma_buf_p[i], num_chunks[i]); } KMEM_FREE(dma_poolp, sizeof (hxge_dma_pool_t)); KMEM_FREE(dma_buf_p, ndmas * sizeof (p_hxge_dma_common_t)); KMEM_FREE(dma_cntl_poolp, sizeof (hxge_dma_pool_t)); KMEM_FREE(dma_cntl_p, ndmas * sizeof (p_hxge_dma_common_t)); KMEM_FREE(num_chunks, sizeof (uint32_t) * ndmas); hxge_alloc_tx_mem_pool_exit: HXGE_DEBUG_MSG((hxgep, MEM_CTL, "<== hxge_alloc_tx_mem_pool:status 0x%08x", status)); return (status); } static hxge_status_t hxge_alloc_tx_buf_dma(p_hxge_t hxgep, uint16_t dma_channel, p_hxge_dma_common_t *dmap, size_t alloc_size, size_t block_size, uint32_t *num_chunks) { p_hxge_dma_common_t tx_dmap; hxge_status_t status = HXGE_OK; size_t total_alloc_size; size_t allocated = 0; int i, size_index, array_size; HXGE_DEBUG_MSG((hxgep, DMA_CTL, "==> hxge_alloc_tx_buf_dma")); tx_dmap = (p_hxge_dma_common_t) KMEM_ZALLOC(sizeof (hxge_dma_common_t) * HXGE_DMA_BLOCK, KM_SLEEP); total_alloc_size = alloc_size; i = 0; size_index = 0; array_size = sizeof (alloc_sizes) / sizeof (size_t); while ((alloc_sizes[size_index] < alloc_size) && (size_index < array_size)) size_index++; if (size_index >= array_size) { size_index = array_size - 1; } while ((allocated < total_alloc_size) && (size_index >= 0) && (i < HXGE_DMA_BLOCK)) { tx_dmap[i].dma_chunk_index = i; tx_dmap[i].block_size = block_size; tx_dmap[i].alength = alloc_sizes[size_index]; tx_dmap[i].orig_alength = tx_dmap[i].alength; tx_dmap[i].nblocks = alloc_sizes[size_index] / block_size; tx_dmap[i].dma_channel = dma_channel; tx_dmap[i].contig_alloc_type = B_FALSE; status = hxge_dma_mem_alloc(hxgep, hxge_force_dma, &hxge_tx_dma_attr, tx_dmap[i].alength, &hxge_dev_buf_dma_acc_attr, DDI_DMA_WRITE | DDI_DMA_STREAMING, (p_hxge_dma_common_t)(&tx_dmap[i])); if (status != HXGE_OK) { HXGE_DEBUG_MSG((hxgep, DMA_CTL, " hxge_alloc_tx_buf_dma: Alloc Failed: " " for size: %d", alloc_sizes[size_index])); size_index--; } else { i++; allocated += alloc_sizes[size_index]; } } if (allocated < total_alloc_size) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " hxge_alloc_tx_buf_dma: failed due to" " allocated(%d) < required(%d)", allocated, total_alloc_size)); goto hxge_alloc_tx_mem_fail1; } *num_chunks = i; *dmap = tx_dmap; HXGE_DEBUG_MSG((hxgep, DMA_CTL, "==> hxge_alloc_tx_buf_dma dmap 0x%016llx num chunks %d", *dmap, i)); goto hxge_alloc_tx_mem_exit; hxge_alloc_tx_mem_fail1: KMEM_FREE(tx_dmap, sizeof (hxge_dma_common_t) * HXGE_DMA_BLOCK); hxge_alloc_tx_mem_exit: HXGE_DEBUG_MSG((hxgep, DMA_CTL, "<== hxge_alloc_tx_buf_dma status 0x%08x", status)); return (status); } /*ARGSUSED*/ static void hxge_free_tx_buf_dma(p_hxge_t hxgep, p_hxge_dma_common_t dmap, uint32_t num_chunks) { int i; HXGE_DEBUG_MSG((hxgep, MEM_CTL, "==> hxge_free_tx_buf_dma")); for (i = 0; i < num_chunks; i++) { hxge_dma_mem_free(dmap++); } HXGE_DEBUG_MSG((hxgep, MEM_CTL, "<== hxge_free_tx_buf_dma")); } /*ARGSUSED*/ static hxge_status_t hxge_alloc_tx_cntl_dma(p_hxge_t hxgep, uint16_t dma_channel, p_hxge_dma_common_t *dmap, size_t size) { p_hxge_dma_common_t tx_dmap; hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, DMA_CTL, "==> hxge_alloc_tx_cntl_dma")); tx_dmap = (p_hxge_dma_common_t)KMEM_ZALLOC(sizeof (hxge_dma_common_t), KM_SLEEP); tx_dmap->contig_alloc_type = B_FALSE; status = hxge_dma_mem_alloc(hxgep, hxge_force_dma, &hxge_desc_dma_attr, size, &hxge_dev_desc_dma_acc_attr, DDI_DMA_RDWR | DDI_DMA_CONSISTENT, tx_dmap); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " hxge_alloc_tx_cntl_dma: Alloc Failed: " " for size: %d", size)); goto hxge_alloc_tx_cntl_dma_fail1; } *dmap = tx_dmap; goto hxge_alloc_tx_cntl_dma_exit; hxge_alloc_tx_cntl_dma_fail1: KMEM_FREE(tx_dmap, sizeof (hxge_dma_common_t)); hxge_alloc_tx_cntl_dma_exit: HXGE_DEBUG_MSG((hxgep, DMA_CTL, "<== hxge_alloc_tx_cntl_dma status 0x%08x", status)); return (status); } /*ARGSUSED*/ static void hxge_free_tx_cntl_dma(p_hxge_t hxgep, p_hxge_dma_common_t dmap) { HXGE_DEBUG_MSG((hxgep, DMA_CTL, "==> hxge_free_tx_cntl_dma")); hxge_dma_mem_free(dmap); HXGE_DEBUG_MSG((hxgep, DMA_CTL, "<== hxge_free_tx_cntl_dma")); } static void hxge_free_tx_mem_pool(p_hxge_t hxgep) { uint32_t i, ndmas; p_hxge_dma_pool_t dma_poolp; p_hxge_dma_common_t *dma_buf_p; p_hxge_dma_pool_t dma_cntl_poolp; p_hxge_dma_common_t *dma_cntl_p; uint32_t *num_chunks; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_free_tx_mem_pool")); dma_poolp = hxgep->tx_buf_pool_p; if (dma_poolp == NULL || (!dma_poolp->buf_allocated)) { HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_free_tx_mem_pool " "(null rx buf pool or buf not allocated")); return; } dma_cntl_poolp = hxgep->tx_cntl_pool_p; if (dma_cntl_poolp == NULL || (!dma_cntl_poolp->buf_allocated)) { HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_free_tx_mem_pool " "(null tx cntl buf pool or cntl buf not allocated")); return; } dma_buf_p = dma_poolp->dma_buf_pool_p; num_chunks = dma_poolp->num_chunks; dma_cntl_p = dma_cntl_poolp->dma_buf_pool_p; ndmas = dma_cntl_poolp->ndmas; for (i = 0; i < ndmas; i++) { hxge_free_tx_buf_dma(hxgep, dma_buf_p[i], num_chunks[i]); } for (i = 0; i < ndmas; i++) { hxge_free_tx_cntl_dma(hxgep, dma_cntl_p[i]); } for (i = 0; i < ndmas; i++) { KMEM_FREE(dma_buf_p[i], sizeof (hxge_dma_common_t) * HXGE_DMA_BLOCK); KMEM_FREE(dma_cntl_p[i], sizeof (hxge_dma_common_t)); } KMEM_FREE(num_chunks, sizeof (uint32_t) * ndmas); KMEM_FREE(dma_cntl_p, ndmas * sizeof (p_hxge_dma_common_t)); KMEM_FREE(dma_cntl_poolp, sizeof (hxge_dma_pool_t)); KMEM_FREE(dma_buf_p, ndmas * sizeof (p_hxge_dma_common_t)); KMEM_FREE(dma_poolp, sizeof (hxge_dma_pool_t)); hxgep->tx_buf_pool_p = NULL; hxgep->tx_cntl_pool_p = NULL; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_free_tx_mem_pool")); } /*ARGSUSED*/ static hxge_status_t hxge_dma_mem_alloc(p_hxge_t hxgep, dma_method_t method, struct ddi_dma_attr *dma_attrp, size_t length, ddi_device_acc_attr_t *acc_attr_p, uint_t xfer_flags, p_hxge_dma_common_t dma_p) { caddr_t kaddrp; int ddi_status = DDI_SUCCESS; dma_p->dma_handle = NULL; dma_p->acc_handle = NULL; dma_p->kaddrp = NULL; ddi_status = ddi_dma_alloc_handle(hxgep->dip, dma_attrp, DDI_DMA_DONTWAIT, NULL, &dma_p->dma_handle); if (ddi_status != DDI_SUCCESS) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "hxge_dma_mem_alloc:ddi_dma_alloc_handle failed.")); return (HXGE_ERROR | HXGE_DDI_FAILED); } ddi_status = ddi_dma_mem_alloc(dma_p->dma_handle, length, acc_attr_p, xfer_flags, DDI_DMA_DONTWAIT, 0, &kaddrp, &dma_p->alength, &dma_p->acc_handle); if (ddi_status != DDI_SUCCESS) { /* The caller will decide whether it is fatal */ HXGE_DEBUG_MSG((hxgep, DMA_CTL, "hxge_dma_mem_alloc:ddi_dma_mem_alloc failed")); ddi_dma_free_handle(&dma_p->dma_handle); dma_p->dma_handle = NULL; return (HXGE_ERROR | HXGE_DDI_FAILED); } if (dma_p->alength < length) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "hxge_dma_mem_alloc:ddi_dma_mem_alloc < length.")); ddi_dma_mem_free(&dma_p->acc_handle); ddi_dma_free_handle(&dma_p->dma_handle); dma_p->acc_handle = NULL; dma_p->dma_handle = NULL; return (HXGE_ERROR); } ddi_status = ddi_dma_addr_bind_handle(dma_p->dma_handle, NULL, kaddrp, dma_p->alength, xfer_flags, DDI_DMA_DONTWAIT, 0, &dma_p->dma_cookie, &dma_p->ncookies); if (ddi_status != DDI_DMA_MAPPED) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "hxge_dma_mem_alloc:di_dma_addr_bind failed " "(staus 0x%x ncookies %d.)", ddi_status, dma_p->ncookies)); if (dma_p->acc_handle) { ddi_dma_mem_free(&dma_p->acc_handle); dma_p->acc_handle = NULL; } ddi_dma_free_handle(&dma_p->dma_handle); dma_p->dma_handle = NULL; return (HXGE_ERROR | HXGE_DDI_FAILED); } if (dma_p->ncookies != 1) { HXGE_DEBUG_MSG((hxgep, DMA_CTL, "hxge_dma_mem_alloc:ddi_dma_addr_bind > 1 cookie" "(staus 0x%x ncookies %d.)", ddi_status, dma_p->ncookies)); if (dma_p->acc_handle) { ddi_dma_mem_free(&dma_p->acc_handle); dma_p->acc_handle = NULL; } (void) ddi_dma_unbind_handle(dma_p->dma_handle); ddi_dma_free_handle(&dma_p->dma_handle); dma_p->dma_handle = NULL; return (HXGE_ERROR); } dma_p->kaddrp = kaddrp; #if defined(__i386) dma_p->ioaddr_pp = (unsigned char *)(uint32_t)dma_p->dma_cookie.dmac_laddress; #else dma_p->ioaddr_pp = (unsigned char *) dma_p->dma_cookie.dmac_laddress; #endif HPI_DMA_ACC_HANDLE_SET(dma_p, dma_p->acc_handle); HXGE_DEBUG_MSG((hxgep, DMA_CTL, "<== hxge_dma_mem_alloc: " "dma buffer allocated: dma_p $%p " "return dmac_ladress from cookie $%p dmac_size %d " "dma_p->ioaddr_p $%p " "dma_p->orig_ioaddr_p $%p " "orig_vatopa $%p " "alength %d (0x%x) " "kaddrp $%p " "length %d (0x%x)", dma_p, dma_p->dma_cookie.dmac_laddress, dma_p->dma_cookie.dmac_size, dma_p->ioaddr_pp, dma_p->orig_ioaddr_pp, dma_p->orig_vatopa, dma_p->alength, dma_p->alength, kaddrp, length, length)); return (HXGE_OK); } static void hxge_dma_mem_free(p_hxge_dma_common_t dma_p) { if (dma_p->dma_handle != NULL) { if (dma_p->ncookies) { (void) ddi_dma_unbind_handle(dma_p->dma_handle); dma_p->ncookies = 0; } ddi_dma_free_handle(&dma_p->dma_handle); dma_p->dma_handle = NULL; } if (dma_p->acc_handle != NULL) { ddi_dma_mem_free(&dma_p->acc_handle); dma_p->acc_handle = NULL; HPI_DMA_ACC_HANDLE_SET(dma_p, NULL); } dma_p->kaddrp = NULL; dma_p->alength = NULL; } /* * hxge_m_start() -- start transmitting and receiving. * * This function is called by the MAC layer when the first * stream is open to prepare the hardware ready for sending * and transmitting packets. */ static int hxge_m_start(void *arg) { p_hxge_t hxgep = (p_hxge_t)arg; HXGE_DEBUG_MSG((hxgep, NEMO_CTL, "==> hxge_m_start")); MUTEX_ENTER(hxgep->genlock); if (hxge_init(hxgep) != DDI_SUCCESS) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "<== hxge_m_start: initialization failed")); MUTEX_EXIT(hxgep->genlock); return (EIO); } if (hxgep->hxge_mac_state != HXGE_MAC_STARTED) { /* * Start timer to check the system error and tx hangs */ hxgep->hxge_timerid = hxge_start_timer(hxgep, hxge_check_hw_state, HXGE_CHECK_TIMER); hxgep->hxge_mac_state = HXGE_MAC_STARTED; } MUTEX_EXIT(hxgep->genlock); HXGE_DEBUG_MSG((hxgep, NEMO_CTL, "<== hxge_m_start")); return (0); } /* * hxge_m_stop(): stop transmitting and receiving. */ static void hxge_m_stop(void *arg) { p_hxge_t hxgep = (p_hxge_t)arg; HXGE_DEBUG_MSG((hxgep, NEMO_CTL, "==> hxge_m_stop")); if (hxgep->hxge_timerid) { hxge_stop_timer(hxgep, hxgep->hxge_timerid); hxgep->hxge_timerid = 0; } MUTEX_ENTER(hxgep->genlock); hxge_uninit(hxgep); hxgep->hxge_mac_state = HXGE_MAC_STOPPED; MUTEX_EXIT(hxgep->genlock); HXGE_DEBUG_MSG((hxgep, NEMO_CTL, "<== hxge_m_stop")); } static int hxge_m_unicst(void *arg, const uint8_t *macaddr) { p_hxge_t hxgep = (p_hxge_t)arg; struct ether_addr addrp; hxge_status_t status; HXGE_DEBUG_MSG((hxgep, MAC_CTL, "==> hxge_m_unicst")); bcopy(macaddr, (uint8_t *)&addrp, ETHERADDRL); status = hxge_set_mac_addr(hxgep, &addrp); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "<== hxge_m_unicst: set unitcast failed")); return (EINVAL); } HXGE_DEBUG_MSG((hxgep, MAC_CTL, "<== hxge_m_unicst")); return (0); } static int hxge_m_multicst(void *arg, boolean_t add, const uint8_t *mca) { p_hxge_t hxgep = (p_hxge_t)arg; struct ether_addr addrp; HXGE_DEBUG_MSG((hxgep, MAC_CTL, "==> hxge_m_multicst: add %d", add)); bcopy(mca, (uint8_t *)&addrp, ETHERADDRL); if (add) { if (hxge_add_mcast_addr(hxgep, &addrp)) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "<== hxge_m_multicst: add multicast failed")); return (EINVAL); } } else { if (hxge_del_mcast_addr(hxgep, &addrp)) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "<== hxge_m_multicst: del multicast failed")); return (EINVAL); } } HXGE_DEBUG_MSG((hxgep, MAC_CTL, "<== hxge_m_multicst")); return (0); } static int hxge_m_promisc(void *arg, boolean_t on) { p_hxge_t hxgep = (p_hxge_t)arg; HXGE_DEBUG_MSG((hxgep, MAC_CTL, "==> hxge_m_promisc: on %d", on)); if (hxge_set_promisc(hxgep, on)) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "<== hxge_m_promisc: set promisc failed")); return (EINVAL); } HXGE_DEBUG_MSG((hxgep, MAC_CTL, "<== hxge_m_promisc: on %d", on)); return (0); } static void hxge_m_ioctl(void *arg, queue_t *wq, mblk_t *mp) { p_hxge_t hxgep = (p_hxge_t)arg; struct iocblk *iocp = (struct iocblk *)mp->b_rptr; boolean_t need_privilege; int err; int cmd; HXGE_DEBUG_MSG((hxgep, NEMO_CTL, "==> hxge_m_ioctl")); iocp = (struct iocblk *)mp->b_rptr; iocp->ioc_error = 0; need_privilege = B_TRUE; cmd = iocp->ioc_cmd; HXGE_DEBUG_MSG((hxgep, NEMO_CTL, "==> hxge_m_ioctl: cmd 0x%08x", cmd)); switch (cmd) { default: miocnak(wq, mp, 0, EINVAL); HXGE_DEBUG_MSG((hxgep, NEMO_CTL, "<== hxge_m_ioctl: invalid")); return; case LB_GET_INFO_SIZE: case LB_GET_INFO: case LB_GET_MODE: need_privilege = B_FALSE; break; case LB_SET_MODE: break; case ND_GET: need_privilege = B_FALSE; break; case ND_SET: break; case HXGE_GET64: case HXGE_PUT64: case HXGE_GET_TX_RING_SZ: case HXGE_GET_TX_DESC: case HXGE_TX_SIDE_RESET: case HXGE_RX_SIDE_RESET: case HXGE_GLOBAL_RESET: case HXGE_RESET_MAC: case HXGE_PUT_TCAM: case HXGE_GET_TCAM: case HXGE_RTRACE: need_privilege = B_FALSE; break; } if (need_privilege) { err = secpolicy_net_config(iocp->ioc_cr, B_FALSE); if (err != 0) { miocnak(wq, mp, 0, err); HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "<== hxge_m_ioctl: no priv")); return; } } switch (cmd) { case ND_GET: HXGE_DEBUG_MSG((hxgep, NEMO_CTL, "ND_GET command")); case ND_SET: HXGE_DEBUG_MSG((hxgep, NEMO_CTL, "ND_SET command")); hxge_param_ioctl(hxgep, wq, mp, iocp); break; case LB_GET_MODE: case LB_SET_MODE: case LB_GET_INFO_SIZE: case LB_GET_INFO: hxge_loopback_ioctl(hxgep, wq, mp, iocp); break; case HXGE_PUT_TCAM: case HXGE_GET_TCAM: case HXGE_GET64: case HXGE_PUT64: case HXGE_GET_TX_RING_SZ: case HXGE_GET_TX_DESC: case HXGE_TX_SIDE_RESET: case HXGE_RX_SIDE_RESET: case HXGE_GLOBAL_RESET: case HXGE_RESET_MAC: HXGE_DEBUG_MSG((hxgep, NEMO_CTL, "==> hxge_m_ioctl: cmd 0x%x", cmd)); hxge_hw_ioctl(hxgep, wq, mp, iocp); break; } HXGE_DEBUG_MSG((hxgep, NEMO_CTL, "<== hxge_m_ioctl")); } extern void hxge_rx_hw_blank(void *arg, time_t ticks, uint_t count); static void hxge_m_resources(void *arg) { p_hxge_t hxgep = arg; mac_rx_fifo_t mrf; p_rx_rcr_rings_t rcr_rings; p_rx_rcr_ring_t *rcr_p; p_rx_rcr_ring_t rcrp; uint32_t i, ndmas; int status; HXGE_DEBUG_MSG((hxgep, RX_CTL, "==> hxge_m_resources")); MUTEX_ENTER(hxgep->genlock); if (!(hxgep->drv_state & STATE_HW_INITIALIZED)) { status = hxge_init(hxgep); if (status != HXGE_OK) { HXGE_DEBUG_MSG((hxgep, RX_CTL, "==> hxge_m_resources: " "hxge_init failed")); MUTEX_EXIT(hxgep->genlock); return; } } mrf.mrf_type = MAC_RX_FIFO; mrf.mrf_blank = hxge_rx_hw_blank; mrf.mrf_arg = (void *)hxgep; mrf.mrf_normal_blank_time = RXDMA_RCR_TO_DEFAULT; mrf.mrf_normal_pkt_count = RXDMA_RCR_PTHRES_DEFAULT; rcr_rings = hxgep->rx_rcr_rings; rcr_p = rcr_rings->rcr_rings; ndmas = rcr_rings->ndmas; /* * Export our receive resources to the MAC layer. */ for (i = 0; i < ndmas; i++) { rcrp = (void *)(p_rx_rcr_ring_t)rcr_p[i]; rcrp->rcr_mac_handle = mac_resource_add(hxgep->mach, (mac_resource_t *)&mrf); HXGE_DEBUG_MSG((hxgep, RX_CTL, "==> hxge_m_resources: vdma %d dma %d " "rcrptr 0x%016llx mac_handle 0x%016llx", i, rcrp->rdc, rcr_p[i], rcrp->rcr_mac_handle)); } MUTEX_EXIT(hxgep->genlock); HXGE_DEBUG_MSG((hxgep, RX_CTL, "<== hxge_m_resources")); } /* * Set an alternate MAC address */ static int hxge_altmac_set(p_hxge_t hxgep, uint8_t *maddr, mac_addr_slot_t slot) { uint64_t address; uint64_t tmp; hpi_status_t status; uint8_t addrn; int i; /* * Convert a byte array to a 48 bit value. * Need to check endianess if in doubt */ address = 0; for (i = 0; i < ETHERADDRL; i++) { tmp = maddr[i]; address <<= 8; address |= tmp; } addrn = (uint8_t)slot; status = hpi_pfc_set_mac_address(hxgep->hpi_handle, addrn, address); if (status != HPI_SUCCESS) return (EIO); return (0); } static void hxge_mmac_kstat_update(p_hxge_t hxgep, mac_addr_slot_t slot) { p_hxge_mmac_stats_t mmac_stats; int i; hxge_mmac_t *mmac_info; mmac_info = &hxgep->hxge_mmac_info; mmac_stats = &hxgep->statsp->mmac_stats; mmac_stats->mmac_max_cnt = mmac_info->num_mmac; mmac_stats->mmac_avail_cnt = mmac_info->naddrfree; for (i = 0; i < ETHERADDRL; i++) { mmac_stats->mmac_avail_pool[slot].ether_addr_octet[i] = mmac_info->mac_pool[slot].addr[(ETHERADDRL - 1) - i]; } } /* * Find an unused address slot, set the address value to the one specified, * enable the port to start filtering on the new MAC address. * Returns: 0 on success. */ int hxge_m_mmac_add(void *arg, mac_multi_addr_t *maddr) { p_hxge_t hxgep = arg; mac_addr_slot_t slot; hxge_mmac_t *mmac_info; int err; hxge_status_t status; mutex_enter(hxgep->genlock); /* * Make sure that hxge is initialized, if _start() has * not been called. */ if (!(hxgep->drv_state & STATE_HW_INITIALIZED)) { status = hxge_init(hxgep); if (status != HXGE_OK) { mutex_exit(hxgep->genlock); return (ENXIO); } } mmac_info = &hxgep->hxge_mmac_info; if (mmac_info->naddrfree == 0) { mutex_exit(hxgep->genlock); return (ENOSPC); } if (!mac_unicst_verify(hxgep->mach, maddr->mma_addr, maddr->mma_addrlen)) { mutex_exit(hxgep->genlock); return (EINVAL); } /* * Search for the first available slot. Because naddrfree * is not zero, we are guaranteed to find one. * Slot 0 is for unique (primary) MAC. The first alternate * MAC slot is slot 1. */ for (slot = 1; slot < mmac_info->num_mmac; slot++) { if (!(mmac_info->mac_pool[slot].flags & MMAC_SLOT_USED)) break; } ASSERT(slot < mmac_info->num_mmac); if ((err = hxge_altmac_set(hxgep, maddr->mma_addr, slot)) != 0) { mutex_exit(hxgep->genlock); return (err); } bcopy(maddr->mma_addr, mmac_info->mac_pool[slot].addr, ETHERADDRL); mmac_info->mac_pool[slot].flags |= MMAC_SLOT_USED; mmac_info->naddrfree--; hxge_mmac_kstat_update(hxgep, slot); maddr->mma_slot = slot; mutex_exit(hxgep->genlock); return (0); } /* * Remove the specified mac address and update * the h/w not to filter the mac address anymore. * Returns: 0, on success. */ int hxge_m_mmac_remove(void *arg, mac_addr_slot_t slot) { p_hxge_t hxgep = arg; hxge_mmac_t *mmac_info; int err = 0; hxge_status_t status; mutex_enter(hxgep->genlock); /* * Make sure that hxge is initialized, if _start() has * not been called. */ if (!(hxgep->drv_state & STATE_HW_INITIALIZED)) { status = hxge_init(hxgep); if (status != HXGE_OK) { mutex_exit(hxgep->genlock); return (ENXIO); } } mmac_info = &hxgep->hxge_mmac_info; if (slot <= 0 || slot >= mmac_info->num_mmac) { mutex_exit(hxgep->genlock); return (EINVAL); } if (mmac_info->mac_pool[slot].flags & MMAC_SLOT_USED) { if (hpi_pfc_mac_addr_disable(hxgep->hpi_handle, slot) == HPI_SUCCESS) { mmac_info->mac_pool[slot].flags &= ~MMAC_SLOT_USED; mmac_info->naddrfree++; /* * Clear mac_pool[slot].addr so that kstat shows 0 * alternate MAC address if the slot is not used. */ bzero(mmac_info->mac_pool[slot].addr, ETHERADDRL); hxge_mmac_kstat_update(hxgep, slot); } else { err = EIO; } } else { err = EINVAL; } mutex_exit(hxgep->genlock); return (err); } /* * Modify a mac address added by hxge_mmac_add(). * Returns: 0, on success. */ int hxge_m_mmac_modify(void *arg, mac_multi_addr_t *maddr) { p_hxge_t hxgep = arg; mac_addr_slot_t slot; hxge_mmac_t *mmac_info; int err = 0; hxge_status_t status; if (!mac_unicst_verify(hxgep->mach, maddr->mma_addr, maddr->mma_addrlen)) return (EINVAL); slot = maddr->mma_slot; mutex_enter(hxgep->genlock); /* * Make sure that hxge is initialized, if _start() has * not been called. */ if (!(hxgep->drv_state & STATE_HW_INITIALIZED)) { status = hxge_init(hxgep); if (status != HXGE_OK) { mutex_exit(hxgep->genlock); return (ENXIO); } } mmac_info = &hxgep->hxge_mmac_info; if (slot <= 0 || slot >= mmac_info->num_mmac) { mutex_exit(hxgep->genlock); return (EINVAL); } if (mmac_info->mac_pool[slot].flags & MMAC_SLOT_USED) { if ((err = hxge_altmac_set(hxgep, maddr->mma_addr, slot)) == 0) { bcopy(maddr->mma_addr, mmac_info->mac_pool[slot].addr, ETHERADDRL); hxge_mmac_kstat_update(hxgep, slot); } } else { err = EINVAL; } mutex_exit(hxgep->genlock); return (err); } /* * static int * hxge_m_mmac_get() - Get the MAC address and other information * related to the slot. mma_flags should be set to 0 in the call. * Note: although kstat shows MAC address as zero when a slot is * not used, Crossbow expects hxge_m_mmac_get to copy factory MAC * to the caller as long as the slot is not using a user MAC address. * The following table shows the rules, * * USED VENDOR mma_addr * ------------------------------------------------------------ * (1) Slot uses a user MAC: yes no user MAC * (2) Slot uses a factory MAC: yes yes factory MAC * (3) Slot is not used but is * factory MAC capable: no yes factory MAC * (4) Slot is not used and is * not factory MAC capable: no no 0 * ------------------------------------------------------------ */ int hxge_m_mmac_get(void *arg, mac_multi_addr_t *maddr) { hxge_t *hxgep = arg; mac_addr_slot_t slot; hxge_mmac_t *mmac_info; hxge_status_t status; slot = maddr->mma_slot; mutex_enter(hxgep->genlock); /* * Make sure that hxge is initialized, if _start() has * not been called. */ if (!(hxgep->drv_state & STATE_HW_INITIALIZED)) { status = hxge_init(hxgep); if (status != HXGE_OK) { mutex_exit(hxgep->genlock); return (ENXIO); } } mmac_info = &hxgep->hxge_mmac_info; if (slot <= 0 || slot >= mmac_info->num_mmac) { mutex_exit(hxgep->genlock); return (EINVAL); } maddr->mma_flags = 0; if (mmac_info->mac_pool[slot].flags & MMAC_SLOT_USED) { maddr->mma_flags |= MMAC_SLOT_USED; bcopy(mmac_info->mac_pool[slot].addr, maddr->mma_addr, ETHERADDRL); maddr->mma_addrlen = ETHERADDRL; } mutex_exit(hxgep->genlock); return (0); } /*ARGSUSED*/ boolean_t hxge_m_getcapab(void *arg, mac_capab_t cap, void *cap_data) { p_hxge_t hxgep = (p_hxge_t)arg; uint32_t *txflags = cap_data; multiaddress_capab_t *mmacp = cap_data; switch (cap) { case MAC_CAPAB_HCKSUM: *txflags = HCKSUM_INET_PARTIAL; break; case MAC_CAPAB_POLL: /* * There's nothing for us to fill in, simply returning B_TRUE * stating that we support polling is sufficient. */ break; case MAC_CAPAB_MULTIADDRESS: /* * The number of MAC addresses made available by * this capability is one less than the total as * the primary address in slot 0 is counted in * the total. */ mmacp->maddr_naddr = PFC_N_MAC_ADDRESSES - 1; mmacp->maddr_naddrfree = hxgep->hxge_mmac_info.naddrfree; mmacp->maddr_flag = 0; /* No multiple factory macs */ mmacp->maddr_handle = hxgep; mmacp->maddr_add = hxge_m_mmac_add; mmacp->maddr_remove = hxge_m_mmac_remove; mmacp->maddr_modify = hxge_m_mmac_modify; mmacp->maddr_get = hxge_m_mmac_get; mmacp->maddr_reserve = NULL; /* No multiple factory macs */ break; default: return (B_FALSE); } return (B_TRUE); } /* * Module loading and removing entry points. */ DDI_DEFINE_STREAM_OPS(hxge_dev_ops, nulldev, nulldev, hxge_attach, hxge_detach, nodev, NULL, D_MP, NULL); extern struct mod_ops mod_driverops; #define HXGE_DESC_VER "HXGE 10Gb Ethernet Driver" /* * Module linkage information for the kernel. */ static struct modldrv hxge_modldrv = { &mod_driverops, HXGE_DESC_VER, &hxge_dev_ops }; static struct modlinkage modlinkage = { MODREV_1, (void *) &hxge_modldrv, NULL }; int _init(void) { int status; HXGE_DEBUG_MSG((NULL, MOD_CTL, "==> _init")); mac_init_ops(&hxge_dev_ops, "hxge"); status = ddi_soft_state_init(&hxge_list, sizeof (hxge_t), 0); if (status != 0) { HXGE_ERROR_MSG((NULL, HXGE_ERR_CTL, "failed to init device soft state")); mac_fini_ops(&hxge_dev_ops); goto _init_exit; } status = mod_install(&modlinkage); if (status != 0) { ddi_soft_state_fini(&hxge_list); HXGE_ERROR_MSG((NULL, HXGE_ERR_CTL, "Mod install failed")); goto _init_exit; } MUTEX_INIT(&hxge_common_lock, NULL, MUTEX_DRIVER, NULL); _init_exit: HXGE_DEBUG_MSG((NULL, MOD_CTL, "_init status = 0x%X", status)); return (status); } int _fini(void) { int status; HXGE_DEBUG_MSG((NULL, MOD_CTL, "==> _fini")); HXGE_DEBUG_MSG((NULL, MOD_CTL, "==> _fini: mod_remove")); if (hxge_mblks_pending) return (EBUSY); status = mod_remove(&modlinkage); if (status != DDI_SUCCESS) { HXGE_DEBUG_MSG((NULL, MOD_CTL, "Module removal failed 0x%08x", status)); goto _fini_exit; } mac_fini_ops(&hxge_dev_ops); ddi_soft_state_fini(&hxge_list); MUTEX_DESTROY(&hxge_common_lock); _fini_exit: HXGE_DEBUG_MSG((NULL, MOD_CTL, "_fini status = 0x%08x", status)); return (status); } int _info(struct modinfo *modinfop) { int status; HXGE_DEBUG_MSG((NULL, MOD_CTL, "==> _info")); status = mod_info(&modlinkage, modinfop); HXGE_DEBUG_MSG((NULL, MOD_CTL, " _info status = 0x%X", status)); return (status); } /*ARGSUSED*/ hxge_status_t hxge_add_intrs(p_hxge_t hxgep) { int intr_types; int type = 0; int ddi_status = DDI_SUCCESS; hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_add_intrs")); hxgep->hxge_intr_type.intr_registered = B_FALSE; hxgep->hxge_intr_type.intr_enabled = B_FALSE; hxgep->hxge_intr_type.msi_intx_cnt = 0; hxgep->hxge_intr_type.intr_added = 0; hxgep->hxge_intr_type.niu_msi_enable = B_FALSE; hxgep->hxge_intr_type.intr_type = 0; if (hxge_msi_enable) { hxgep->hxge_intr_type.niu_msi_enable = B_TRUE; } /* Get the supported interrupt types */ if ((ddi_status = ddi_intr_get_supported_types(hxgep->dip, &intr_types)) != DDI_SUCCESS) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "<== hxge_add_intrs: " "ddi_intr_get_supported_types failed: status 0x%08x", ddi_status)); return (HXGE_ERROR | HXGE_DDI_FAILED); } hxgep->hxge_intr_type.intr_types = intr_types; HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_add_intrs: " "ddi_intr_get_supported_types: 0x%08x", intr_types)); /* * Pick the interrupt type to use MSIX, MSI, INTX hxge_msi_enable: * (1): 1 - MSI * (2): 2 - MSI-X * others - FIXED */ switch (hxge_msi_enable) { default: type = DDI_INTR_TYPE_FIXED; HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_add_intrs: " "use fixed (intx emulation) type %08x", type)); break; case 2: HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_add_intrs: " "ddi_intr_get_supported_types: 0x%08x", intr_types)); if (intr_types & DDI_INTR_TYPE_MSIX) { type = DDI_INTR_TYPE_MSIX; HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_add_intrs: " "ddi_intr_get_supported_types: MSIX 0x%08x", type)); } else if (intr_types & DDI_INTR_TYPE_MSI) { type = DDI_INTR_TYPE_MSI; HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_add_intrs: " "ddi_intr_get_supported_types: MSI 0x%08x", type)); } else if (intr_types & DDI_INTR_TYPE_FIXED) { type = DDI_INTR_TYPE_FIXED; HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_add_intrs: " "ddi_intr_get_supported_types: MSXED0x%08x", type)); } break; case 1: if (intr_types & DDI_INTR_TYPE_MSI) { type = DDI_INTR_TYPE_MSI; HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_add_intrs: " "ddi_intr_get_supported_types: MSI 0x%08x", type)); } else if (intr_types & DDI_INTR_TYPE_MSIX) { type = DDI_INTR_TYPE_MSIX; HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_add_intrs: " "ddi_intr_get_supported_types: MSIX 0x%08x", type)); } else if (intr_types & DDI_INTR_TYPE_FIXED) { type = DDI_INTR_TYPE_FIXED; HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_add_intrs: " "ddi_intr_get_supported_types: MSXED0x%08x", type)); } } hxgep->hxge_intr_type.intr_type = type; if ((type == DDI_INTR_TYPE_MSIX || type == DDI_INTR_TYPE_MSI || type == DDI_INTR_TYPE_FIXED) && hxgep->hxge_intr_type.niu_msi_enable) { if ((status = hxge_add_intrs_adv(hxgep)) != DDI_SUCCESS) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " hxge_add_intrs: " " hxge_add_intrs_adv failed: status 0x%08x", status)); return (status); } else { HXGE_DEBUG_MSG((hxgep, DDI_CTL, "==> hxge_add_intrs: " "interrupts registered : type %d", type)); hxgep->hxge_intr_type.intr_registered = B_TRUE; HXGE_DEBUG_MSG((hxgep, DDI_CTL, "\nAdded advanced hxge add_intr_adv " "intr type 0x%x\n", type)); return (status); } } if (!hxgep->hxge_intr_type.intr_registered) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "==> hxge_add_intrs: failed to register interrupts")); return (HXGE_ERROR | HXGE_DDI_FAILED); } HXGE_DEBUG_MSG((hxgep, INT_CTL, "<== hxge_add_intrs")); return (status); } /*ARGSUSED*/ static hxge_status_t hxge_add_soft_intrs(p_hxge_t hxgep) { int ddi_status = DDI_SUCCESS; hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, DDI_CTL, "==> hxge_add_soft_intrs")); hxgep->resched_id = NULL; hxgep->resched_running = B_FALSE; ddi_status = ddi_add_softintr(hxgep->dip, DDI_SOFTINT_LOW, &hxgep->resched_id, NULL, NULL, hxge_reschedule, (caddr_t)hxgep); if (ddi_status != DDI_SUCCESS) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "<== hxge_add_soft_intrs: " "ddi_add_softintrs failed: status 0x%08x", ddi_status)); return (HXGE_ERROR | HXGE_DDI_FAILED); } HXGE_DEBUG_MSG((hxgep, DDI_CTL, "<== hxge_ddi_add_soft_intrs")); return (status); } /*ARGSUSED*/ static hxge_status_t hxge_add_intrs_adv(p_hxge_t hxgep) { int intr_type; p_hxge_intr_t intrp; hxge_status_t status; HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_add_intrs_adv")); intrp = (p_hxge_intr_t)&hxgep->hxge_intr_type; intr_type = intrp->intr_type; HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_add_intrs_adv: type 0x%x", intr_type)); switch (intr_type) { case DDI_INTR_TYPE_MSI: /* 0x2 */ case DDI_INTR_TYPE_MSIX: /* 0x4 */ status = hxge_add_intrs_adv_type(hxgep, intr_type); break; case DDI_INTR_TYPE_FIXED: /* 0x1 */ status = hxge_add_intrs_adv_type_fix(hxgep, intr_type); break; default: status = HXGE_ERROR; break; } HXGE_DEBUG_MSG((hxgep, INT_CTL, "<== hxge_add_intrs_adv")); return (status); } /*ARGSUSED*/ static hxge_status_t hxge_add_intrs_adv_type(p_hxge_t hxgep, uint32_t int_type) { dev_info_t *dip = hxgep->dip; p_hxge_ldg_t ldgp; p_hxge_intr_t intrp; uint_t *inthandler; void *arg1, *arg2; int behavior; int nintrs, navail; int nactual, nrequired; int inum = 0; int loop = 0; int x, y; int ddi_status = DDI_SUCCESS; hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_add_intrs_adv_type")); intrp = (p_hxge_intr_t)&hxgep->hxge_intr_type; ddi_status = ddi_intr_get_nintrs(dip, int_type, &nintrs); if ((ddi_status != DDI_SUCCESS) || (nintrs == 0)) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "ddi_intr_get_nintrs() failed, status: 0x%x%, " "nintrs: %d", ddi_status, nintrs)); return (HXGE_ERROR | HXGE_DDI_FAILED); } ddi_status = ddi_intr_get_navail(dip, int_type, &navail); if ((ddi_status != DDI_SUCCESS) || (navail == 0)) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "ddi_intr_get_navail() failed, status: 0x%x%, " "nintrs: %d", ddi_status, navail)); return (HXGE_ERROR | HXGE_DDI_FAILED); } HXGE_DEBUG_MSG((hxgep, INT_CTL, "ddi_intr_get_navail() returned: intr type %d nintrs %d, navail %d", int_type, nintrs, navail)); if (int_type == DDI_INTR_TYPE_MSI && !ISP2(navail)) { /* MSI must be power of 2 */ if ((navail & 16) == 16) { navail = 16; } else if ((navail & 8) == 8) { navail = 8; } else if ((navail & 4) == 4) { navail = 4; } else if ((navail & 2) == 2) { navail = 2; } else { navail = 1; } HXGE_DEBUG_MSG((hxgep, INT_CTL, "ddi_intr_get_navail(): (msi power of 2) nintrs %d, " "navail %d", nintrs, navail)); } HXGE_DEBUG_MSG((hxgep, INT_CTL, "requesting: intr type %d nintrs %d, navail %d", int_type, nintrs, navail)); behavior = ((int_type == DDI_INTR_TYPE_FIXED) ? DDI_INTR_ALLOC_STRICT : DDI_INTR_ALLOC_NORMAL); intrp->intr_size = navail * sizeof (ddi_intr_handle_t); intrp->htable = kmem_zalloc(intrp->intr_size, KM_SLEEP); ddi_status = ddi_intr_alloc(dip, intrp->htable, int_type, inum, navail, &nactual, behavior); if (ddi_status != DDI_SUCCESS || nactual == 0) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " ddi_intr_alloc() failed: %d", ddi_status)); kmem_free(intrp->htable, intrp->intr_size); return (HXGE_ERROR | HXGE_DDI_FAILED); } HXGE_DEBUG_MSG((hxgep, INT_CTL, "ddi_intr_alloc() returned: navail %d nactual %d", navail, nactual)); if ((ddi_status = ddi_intr_get_pri(intrp->htable[0], (uint_t *)&intrp->pri)) != DDI_SUCCESS) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " ddi_intr_get_pri() failed: %d", ddi_status)); /* Free already allocated interrupts */ for (y = 0; y < nactual; y++) { (void) ddi_intr_free(intrp->htable[y]); } kmem_free(intrp->htable, intrp->intr_size); return (HXGE_ERROR | HXGE_DDI_FAILED); } nrequired = 0; status = hxge_ldgv_init(hxgep, &nactual, &nrequired); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "hxge_add_intrs_adv_typ:hxge_ldgv_init " "failed: 0x%x", status)); /* Free already allocated interrupts */ for (y = 0; y < nactual; y++) { (void) ddi_intr_free(intrp->htable[y]); } kmem_free(intrp->htable, intrp->intr_size); return (status); } ldgp = hxgep->ldgvp->ldgp; HXGE_DEBUG_MSG((hxgep, INT_CTL, "After hxge_ldgv_init(): nreq %d nactual %d", nrequired, nactual)); if (nactual < nrequired) loop = nactual; else loop = nrequired; for (x = 0; x < loop; x++, ldgp++) { ldgp->vector = (uint8_t)x; arg1 = ldgp->ldvp; arg2 = hxgep; if (ldgp->nldvs == 1) { inthandler = (uint_t *)ldgp->ldvp->ldv_intr_handler; HXGE_DEBUG_MSG((hxgep, INT_CTL, "hxge_add_intrs_adv_type: arg1 0x%x arg2 0x%x: " "1-1 int handler (entry %d)\n", arg1, arg2, x)); } else if (ldgp->nldvs > 1) { inthandler = (uint_t *)ldgp->sys_intr_handler; HXGE_DEBUG_MSG((hxgep, INT_CTL, "hxge_add_intrs_adv_type: arg1 0x%x arg2 0x%x: " "nldevs %d int handler (entry %d)\n", arg1, arg2, ldgp->nldvs, x)); } HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_add_intrs_adv_type: ddi_add_intr(inum) #%d " "htable 0x%llx", x, intrp->htable[x])); if ((ddi_status = ddi_intr_add_handler(intrp->htable[x], (ddi_intr_handler_t *)inthandler, arg1, arg2)) != DDI_SUCCESS) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "==> hxge_add_intrs_adv_type: failed #%d " "status 0x%x", x, ddi_status)); for (y = 0; y < intrp->intr_added; y++) { (void) ddi_intr_remove_handler( intrp->htable[y]); } /* Free already allocated intr */ for (y = 0; y < nactual; y++) { (void) ddi_intr_free(intrp->htable[y]); } kmem_free(intrp->htable, intrp->intr_size); (void) hxge_ldgv_uninit(hxgep); return (HXGE_ERROR | HXGE_DDI_FAILED); } intrp->intr_added++; } intrp->msi_intx_cnt = nactual; HXGE_DEBUG_MSG((hxgep, INT_CTL, "Requested: %d, Allowed: %d msi_intx_cnt %d intr_added %d", navail, nactual, intrp->msi_intx_cnt, intrp->intr_added)); (void) ddi_intr_get_cap(intrp->htable[0], &intrp->intr_cap); (void) hxge_intr_ldgv_init(hxgep); HXGE_DEBUG_MSG((hxgep, INT_CTL, "<== hxge_add_intrs_adv_type")); return (status); } /*ARGSUSED*/ static hxge_status_t hxge_add_intrs_adv_type_fix(p_hxge_t hxgep, uint32_t int_type) { dev_info_t *dip = hxgep->dip; p_hxge_ldg_t ldgp; p_hxge_intr_t intrp; uint_t *inthandler; void *arg1, *arg2; int behavior; int nintrs, navail; int nactual, nrequired; int inum = 0; int x, y; int ddi_status = DDI_SUCCESS; hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_add_intrs_adv_type_fix")); intrp = (p_hxge_intr_t)&hxgep->hxge_intr_type; ddi_status = ddi_intr_get_nintrs(dip, int_type, &nintrs); if ((ddi_status != DDI_SUCCESS) || (nintrs == 0)) { HXGE_DEBUG_MSG((hxgep, INT_CTL, "ddi_intr_get_nintrs() failed, status: 0x%x%, " "nintrs: %d", status, nintrs)); return (HXGE_ERROR | HXGE_DDI_FAILED); } ddi_status = ddi_intr_get_navail(dip, int_type, &navail); if ((ddi_status != DDI_SUCCESS) || (navail == 0)) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "ddi_intr_get_navail() failed, status: 0x%x%, " "nintrs: %d", ddi_status, navail)); return (HXGE_ERROR | HXGE_DDI_FAILED); } HXGE_DEBUG_MSG((hxgep, INT_CTL, "ddi_intr_get_navail() returned: nintrs %d, naavail %d", nintrs, navail)); behavior = ((int_type == DDI_INTR_TYPE_FIXED) ? DDI_INTR_ALLOC_STRICT : DDI_INTR_ALLOC_NORMAL); intrp->intr_size = navail * sizeof (ddi_intr_handle_t); intrp->htable = kmem_alloc(intrp->intr_size, KM_SLEEP); ddi_status = ddi_intr_alloc(dip, intrp->htable, int_type, inum, navail, &nactual, behavior); if (ddi_status != DDI_SUCCESS || nactual == 0) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " ddi_intr_alloc() failed: %d", ddi_status)); kmem_free(intrp->htable, intrp->intr_size); return (HXGE_ERROR | HXGE_DDI_FAILED); } if ((ddi_status = ddi_intr_get_pri(intrp->htable[0], (uint_t *)&intrp->pri)) != DDI_SUCCESS) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " ddi_intr_get_pri() failed: %d", ddi_status)); /* Free already allocated interrupts */ for (y = 0; y < nactual; y++) { (void) ddi_intr_free(intrp->htable[y]); } kmem_free(intrp->htable, intrp->intr_size); return (HXGE_ERROR | HXGE_DDI_FAILED); } nrequired = 0; status = hxge_ldgv_init(hxgep, &nactual, &nrequired); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "hxge_add_intrs_adv_type_fix:hxge_ldgv_init " "failed: 0x%x", status)); /* Free already allocated interrupts */ for (y = 0; y < nactual; y++) { (void) ddi_intr_free(intrp->htable[y]); } kmem_free(intrp->htable, intrp->intr_size); return (status); } ldgp = hxgep->ldgvp->ldgp; for (x = 0; x < nrequired; x++, ldgp++) { ldgp->vector = (uint8_t)x; arg1 = ldgp->ldvp; arg2 = hxgep; if (ldgp->nldvs == 1) { inthandler = (uint_t *)ldgp->ldvp->ldv_intr_handler; HXGE_DEBUG_MSG((hxgep, INT_CTL, "hxge_add_intrs_adv_type_fix: " "1-1 int handler(%d) ldg %d ldv %d " "arg1 $%p arg2 $%p\n", x, ldgp->ldg, ldgp->ldvp->ldv, arg1, arg2)); } else if (ldgp->nldvs > 1) { inthandler = (uint_t *)ldgp->sys_intr_handler; HXGE_DEBUG_MSG((hxgep, INT_CTL, "hxge_add_intrs_adv_type_fix: " "shared ldv %d int handler(%d) ldv %d ldg %d" "arg1 0x%016llx arg2 0x%016llx\n", x, ldgp->nldvs, ldgp->ldg, ldgp->ldvp->ldv, arg1, arg2)); } if ((ddi_status = ddi_intr_add_handler(intrp->htable[x], (ddi_intr_handler_t *)inthandler, arg1, arg2)) != DDI_SUCCESS) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "==> hxge_add_intrs_adv_type_fix: failed #%d " "status 0x%x", x, ddi_status)); for (y = 0; y < intrp->intr_added; y++) { (void) ddi_intr_remove_handler( intrp->htable[y]); } for (y = 0; y < nactual; y++) { (void) ddi_intr_free(intrp->htable[y]); } /* Free already allocated intr */ kmem_free(intrp->htable, intrp->intr_size); (void) hxge_ldgv_uninit(hxgep); return (HXGE_ERROR | HXGE_DDI_FAILED); } intrp->intr_added++; } intrp->msi_intx_cnt = nactual; (void) ddi_intr_get_cap(intrp->htable[0], &intrp->intr_cap); status = hxge_intr_ldgv_init(hxgep); HXGE_DEBUG_MSG((hxgep, INT_CTL, "<== hxge_add_intrs_adv_type_fix")); return (status); } /*ARGSUSED*/ static void hxge_remove_intrs(p_hxge_t hxgep) { int i, inum; p_hxge_intr_t intrp; HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_remove_intrs")); intrp = (p_hxge_intr_t)&hxgep->hxge_intr_type; if (!intrp->intr_registered) { HXGE_DEBUG_MSG((hxgep, INT_CTL, "<== hxge_remove_intrs: interrupts not registered")); return; } HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_remove_intrs:advanced")); if (intrp->intr_cap & DDI_INTR_FLAG_BLOCK) { (void) ddi_intr_block_disable(intrp->htable, intrp->intr_added); } else { for (i = 0; i < intrp->intr_added; i++) { (void) ddi_intr_disable(intrp->htable[i]); } } for (inum = 0; inum < intrp->intr_added; inum++) { if (intrp->htable[inum]) { (void) ddi_intr_remove_handler(intrp->htable[inum]); } } for (inum = 0; inum < intrp->msi_intx_cnt; inum++) { if (intrp->htable[inum]) { HXGE_DEBUG_MSG((hxgep, DDI_CTL, "hxge_remove_intrs: ddi_intr_free inum %d " "msi_intx_cnt %d intr_added %d", inum, intrp->msi_intx_cnt, intrp->intr_added)); (void) ddi_intr_free(intrp->htable[inum]); } } kmem_free(intrp->htable, intrp->intr_size); intrp->intr_registered = B_FALSE; intrp->intr_enabled = B_FALSE; intrp->msi_intx_cnt = 0; intrp->intr_added = 0; (void) hxge_ldgv_uninit(hxgep); HXGE_DEBUG_MSG((hxgep, INT_CTL, "<== hxge_remove_intrs")); } /*ARGSUSED*/ static void hxge_remove_soft_intrs(p_hxge_t hxgep) { HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_remove_soft_intrs")); if (hxgep->resched_id) { ddi_remove_softintr(hxgep->resched_id); HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_remove_soft_intrs: removed")); hxgep->resched_id = NULL; } HXGE_DEBUG_MSG((hxgep, INT_CTL, "<== hxge_remove_soft_intrs")); } /*ARGSUSED*/ void hxge_intrs_enable(p_hxge_t hxgep) { p_hxge_intr_t intrp; int i; int status; HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_intrs_enable")); intrp = (p_hxge_intr_t)&hxgep->hxge_intr_type; if (!intrp->intr_registered) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "<== hxge_intrs_enable: " "interrupts are not registered")); return; } if (intrp->intr_enabled) { HXGE_DEBUG_MSG((hxgep, INT_CTL, "<== hxge_intrs_enable: already enabled")); return; } if (intrp->intr_cap & DDI_INTR_FLAG_BLOCK) { status = ddi_intr_block_enable(intrp->htable, intrp->intr_added); HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_intrs_enable " "block enable - status 0x%x total inums #%d\n", status, intrp->intr_added)); } else { for (i = 0; i < intrp->intr_added; i++) { status = ddi_intr_enable(intrp->htable[i]); HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_intrs_enable " "ddi_intr_enable:enable - status 0x%x " "total inums %d enable inum #%d\n", status, intrp->intr_added, i)); if (status == DDI_SUCCESS) { intrp->intr_enabled = B_TRUE; } } } HXGE_DEBUG_MSG((hxgep, INT_CTL, "<== hxge_intrs_enable")); } /*ARGSUSED*/ static void hxge_intrs_disable(p_hxge_t hxgep) { p_hxge_intr_t intrp; int i; HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_intrs_disable")); intrp = (p_hxge_intr_t)&hxgep->hxge_intr_type; if (!intrp->intr_registered) { HXGE_DEBUG_MSG((hxgep, INT_CTL, "<== hxge_intrs_disable: " "interrupts are not registered")); return; } if (intrp->intr_cap & DDI_INTR_FLAG_BLOCK) { (void) ddi_intr_block_disable(intrp->htable, intrp->intr_added); } else { for (i = 0; i < intrp->intr_added; i++) { (void) ddi_intr_disable(intrp->htable[i]); } } intrp->intr_enabled = B_FALSE; HXGE_DEBUG_MSG((hxgep, INT_CTL, "<== hxge_intrs_disable")); } static hxge_status_t hxge_mac_register(p_hxge_t hxgep) { mac_register_t *macp; int status; HXGE_DEBUG_MSG((hxgep, DDI_CTL, "==> hxge_mac_register")); if ((macp = mac_alloc(MAC_VERSION)) == NULL) return (HXGE_ERROR); macp->m_type_ident = MAC_PLUGIN_IDENT_ETHER; macp->m_driver = hxgep; macp->m_dip = hxgep->dip; macp->m_src_addr = hxgep->ouraddr.ether_addr_octet; HXGE_DEBUG_MSG((hxgep, DDI_CTL, "hxge_mac_register: ether addr is %x:%x:%x:%x:%x:%x", macp->m_src_addr[0], macp->m_src_addr[1], macp->m_src_addr[2], macp->m_src_addr[3], macp->m_src_addr[4], macp->m_src_addr[5])); macp->m_callbacks = &hxge_m_callbacks; macp->m_min_sdu = 0; macp->m_max_sdu = hxgep->vmac.maxframesize - sizeof (struct ether_header) - ETHERFCSL - 4 - TX_PKT_HEADER_SIZE; status = mac_register(macp, &hxgep->mach); mac_free(macp); if (status != 0) { cmn_err(CE_WARN, "hxge_mac_register failed (status %d instance %d)", status, hxgep->instance); return (HXGE_ERROR); } HXGE_DEBUG_MSG((hxgep, DDI_CTL, "<== hxge_mac_register success " "(instance %d)", hxgep->instance)); return (HXGE_OK); } static int hxge_init_common_dev(p_hxge_t hxgep) { p_hxge_hw_list_t hw_p; dev_info_t *p_dip; HXGE_DEBUG_MSG((hxgep, MOD_CTL, "==> hxge_init_common_dev")); p_dip = hxgep->p_dip; MUTEX_ENTER(&hxge_common_lock); /* * Loop through existing per Hydra hardware list. */ for (hw_p = hxge_hw_list; hw_p; hw_p = hw_p->next) { HXGE_DEBUG_MSG((hxgep, MOD_CTL, "==> hxge_init_common_dev: hw_p $%p parent dip $%p", hw_p, p_dip)); if (hw_p->parent_devp == p_dip) { hxgep->hxge_hw_p = hw_p; hw_p->ndevs++; hw_p->hxge_p = hxgep; HXGE_DEBUG_MSG((hxgep, MOD_CTL, "==> hxge_init_common_device: " "hw_p $%p parent dip $%p ndevs %d (found)", hw_p, p_dip, hw_p->ndevs)); break; } } if (hw_p == NULL) { HXGE_DEBUG_MSG((hxgep, MOD_CTL, "==> hxge_init_common_dev: parent dip $%p (new)", p_dip)); hw_p = kmem_zalloc(sizeof (hxge_hw_list_t), KM_SLEEP); hw_p->parent_devp = p_dip; hw_p->magic = HXGE_MAGIC; hxgep->hxge_hw_p = hw_p; hw_p->ndevs++; hw_p->hxge_p = hxgep; hw_p->next = hxge_hw_list; MUTEX_INIT(&hw_p->hxge_cfg_lock, NULL, MUTEX_DRIVER, NULL); MUTEX_INIT(&hw_p->hxge_tcam_lock, NULL, MUTEX_DRIVER, NULL); MUTEX_INIT(&hw_p->hxge_vlan_lock, NULL, MUTEX_DRIVER, NULL); hxge_hw_list = hw_p; } MUTEX_EXIT(&hxge_common_lock); HXGE_DEBUG_MSG((hxgep, MOD_CTL, "==> hxge_init_common_dev (hxge_hw_list) $%p", hxge_hw_list)); HXGE_DEBUG_MSG((hxgep, MOD_CTL, "<== hxge_init_common_dev")); return (HXGE_OK); } static void hxge_uninit_common_dev(p_hxge_t hxgep) { p_hxge_hw_list_t hw_p, h_hw_p; dev_info_t *p_dip; HXGE_DEBUG_MSG((hxgep, MOD_CTL, "==> hxge_uninit_common_dev")); if (hxgep->hxge_hw_p == NULL) { HXGE_DEBUG_MSG((hxgep, MOD_CTL, "<== hxge_uninit_common_dev (no common)")); return; } MUTEX_ENTER(&hxge_common_lock); h_hw_p = hxge_hw_list; for (hw_p = hxge_hw_list; hw_p; hw_p = hw_p->next) { p_dip = hw_p->parent_devp; if (hxgep->hxge_hw_p == hw_p && p_dip == hxgep->p_dip && hxgep->hxge_hw_p->magic == HXGE_MAGIC && hw_p->magic == HXGE_MAGIC) { HXGE_DEBUG_MSG((hxgep, MOD_CTL, "==> hxge_uninit_common_dev: " "hw_p $%p parent dip $%p ndevs %d (found)", hw_p, p_dip, hw_p->ndevs)); hxgep->hxge_hw_p = NULL; if (hw_p->ndevs) { hw_p->ndevs--; } hw_p->hxge_p = NULL; if (!hw_p->ndevs) { MUTEX_DESTROY(&hw_p->hxge_vlan_lock); MUTEX_DESTROY(&hw_p->hxge_tcam_lock); MUTEX_DESTROY(&hw_p->hxge_cfg_lock); HXGE_DEBUG_MSG((hxgep, MOD_CTL, "==> hxge_uninit_common_dev: " "hw_p $%p parent dip $%p ndevs %d (last)", hw_p, p_dip, hw_p->ndevs)); if (hw_p == hxge_hw_list) { HXGE_DEBUG_MSG((hxgep, MOD_CTL, "==> hxge_uninit_common_dev:" "remove head " "hw_p $%p parent dip $%p " "ndevs %d (head)", hw_p, p_dip, hw_p->ndevs)); hxge_hw_list = hw_p->next; } else { HXGE_DEBUG_MSG((hxgep, MOD_CTL, "==> hxge_uninit_common_dev:" "remove middle " "hw_p $%p parent dip $%p " "ndevs %d (middle)", hw_p, p_dip, hw_p->ndevs)); h_hw_p->next = hw_p->next; } KMEM_FREE(hw_p, sizeof (hxge_hw_list_t)); } break; } else { h_hw_p = hw_p; } } MUTEX_EXIT(&hxge_common_lock); HXGE_DEBUG_MSG((hxgep, MOD_CTL, "==> hxge_uninit_common_dev (hxge_hw_list) $%p", hxge_hw_list)); HXGE_DEBUG_MSG((hxgep, MOD_CTL, "<= hxge_uninit_common_dev")); }