/* * 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 2010 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ /* * nxge_intr.c * * This file manages the interrupts for a hybrid I/O (hio) device. * In the future, it may manage interrupts for all Neptune-based * devices. * */ #include #include /* * External prototypes */ /* The following function may be found in nxge_[t|r]xdma.c */ extern uint_t nxge_tx_intr(char *, char *); extern uint_t nxge_rx_intr(char *, char *); /* * Local prototypes */ static int nxge_intr_vec_find(nxge_t *, vpc_type_t, int); /* * nxge_intr_add * * Add 's interrupt. * * Arguments: * nxge * type Tx or Rx * channel The channel whose interrupt we want to add. * * Notes: * Add here means: add a handler, enable, & arm the interrupt. * * Context: * Service domain * */ nxge_status_t nxge_intr_add( nxge_t *nxge, vpc_type_t type, int channel) { nxge_intr_t *interrupts; /* The global interrupt data. */ nxge_ldg_t *group; /* The logical device group data. */ nxge_ldv_t *ldvp; ddi_intr_handler_t *inthandler; int vector; int status1, status2; char c = (type == VP_BOUND_TX ? 'T' : 'R'); NXGE_DEBUG_MSG((nxge, HIO_CTL, "==> nxge_intr_add")); if ((vector = nxge_intr_vec_find(nxge, type, channel)) == -1) { NXGE_ERROR_MSG((nxge, NXGE_ERR_CTL, "nxge_intr_add(%cDC %d): vector not found", c, channel)); return (NXGE_ERROR); } ldvp = &nxge->ldgvp->ldvp[vector]; group = ldvp->ldgp; if (group->nldvs == 1) { inthandler = group->ldvp->ldv_intr_handler; } else if (group->nldvs > 1) { inthandler = group->sys_intr_handler; } else { inthandler = NULL; } interrupts = (nxge_intr_t *)&nxge->nxge_intr_type; status1 = DDI_SUCCESS; if ((status2 = ddi_intr_add_handler(interrupts->htable[vector], inthandler, group->ldvp, nxge)) != DDI_SUCCESS) { NXGE_ERROR_MSG((nxge, NXGE_ERR_CTL, "nxge_intr_add(%cDC %d): " "ddi_intr_add_handler(%d) returned %s", c, channel, vector, nxge_ddi_perror(status2))); status1 += status2; } interrupts->intr_added++; /* Enable the interrupt. */ if ((status2 = ddi_intr_enable(interrupts->htable[vector])) != DDI_SUCCESS) { NXGE_ERROR_MSG((nxge, NXGE_ERR_CTL, "nxge_intr_add(%cDC %d): " "ddi_intr_enable(%d) returned %s", c, channel, vector, nxge_ddi_perror(status2))); status1 += status2; } if (status1 == DDI_SUCCESS) { interrupts->intr_enabled = B_TRUE; /* Finally, arm the interrupt. */ if (group->nldvs == 1) { npi_handle_t handle = NXGE_DEV_NPI_HANDLE(nxge); (void) npi_intr_ldg_mgmt_set(handle, group->ldg, B_TRUE, group->ldg_timer); } } NXGE_DEBUG_MSG((nxge, HIO_CTL, "<== nxge_intr_add")); return (NXGE_OK); } /* * nxge_intr_remove * * Remove 's interrupt. * * Arguments: * nxge * type Tx or Rx * channel The channel whose interrupt we want to remove. * * Notes: * Remove here means: disarm, disable, & remove the handler. * * Context: * Service domain * */ nxge_status_t nxge_intr_remove( nxge_t *nxge, vpc_type_t type, int channel) { nxge_intr_t *interrupts; /* The global interrupt data. */ nxge_ldg_t *group; /* The logical device group data. */ nxge_ldv_t *ldvp; int vector; int status1, status2; char c = (type == VP_BOUND_TX ? 'T' : 'R'); NXGE_DEBUG_MSG((nxge, HIO_CTL, "==> nxge_intr_remove")); if ((vector = nxge_intr_vec_find(nxge, type, channel)) == -1) { NXGE_ERROR_MSG((nxge, NXGE_ERR_CTL, "nxge_intr_remove(%cDC %d): vector not found", c, channel)); return (NXGE_ERROR); } ldvp = &nxge->ldgvp->ldvp[vector]; group = ldvp->ldgp; /* Disarm the interrupt. */ if (group->nldvs == 1) { npi_handle_t handle = NXGE_DEV_NPI_HANDLE(nxge); group->arm = B_FALSE; (void) npi_intr_ldg_mgmt_set(handle, group->ldg, B_TRUE, group->ldg_timer); group->arm = B_TRUE; /* HIOXXX There IS a better way */ } interrupts = (nxge_intr_t *)&nxge->nxge_intr_type; status1 = DDI_SUCCESS; /* Disable the interrupt. */ if ((status2 = ddi_intr_disable(interrupts->htable[vector])) != DDI_SUCCESS) { NXGE_ERROR_MSG((nxge, NXGE_ERR_CTL, "nxge_intr_remove(%cDC %d)" ": ddi_intr_disable(%d) returned %s", c, channel, vector, nxge_ddi_perror(status2))); status1 += status2; } /* Remove the interrupt handler. */ if ((status2 = ddi_intr_remove_handler(interrupts->htable[vector])) != DDI_SUCCESS) { NXGE_ERROR_MSG((nxge, NXGE_ERR_CTL, "nxge_intr_remove(%cDC %d)" ": ddi_intr_remove_handler(%d) returned %s", c, channel, vector, nxge_ddi_perror(status2))); status1 += status2; } if (status1 == DDI_SUCCESS) { interrupts->intr_added--; if (interrupts->intr_added == 0) interrupts->intr_enabled = B_FALSE; } NXGE_DEBUG_MSG((nxge, HIO_CTL, "<== nxge_intr_remove")); return (NXGE_OK); } /* * nxge_intr_vec_find * * Find the interrupt vector associated with . * * Arguments: * nxge * type Tx or Rx * channel The channel whose vector we want to find. * * Notes: * * Context: * Service domain * */ static int nxge_intr_vec_find( nxge_t *nxge, vpc_type_t type, int channel) { nxge_hw_pt_cfg_t *hardware; nxge_ldgv_t *ldgvp; nxge_ldv_t *ldvp; int first, limit, vector; NXGE_DEBUG_MSG((nxge, HIO_CTL, "==> nxge_intr_vec_find(%cDC %d)", type == VP_BOUND_TX ? 'T' : 'R', channel)); if (nxge->ldgvp == 0) { NXGE_DEBUG_MSG((nxge, HIO_CTL, "nxge_hio_intr_vec_find(%cDC %d): ldgvp == 0", type == VP_BOUND_TX ? 'T' : 'R', channel)); return (-1); } hardware = &nxge->pt_config.hw_config; first = hardware->ldg_chn_start; if (type == VP_BOUND_TX) { first += 8; /* HIOXXX N2/NIU hack */ limit = first + hardware->tdc.count; } else { limit = first + hardware->max_rdcs; } ldgvp = nxge->ldgvp; for (vector = first; vector < limit; vector++) { ldvp = &ldgvp->ldvp[vector]; if (ldvp->channel == channel) break; } if (vector == limit) { return (-1); } NXGE_DEBUG_MSG((nxge, HIO_CTL, "<== nxge_intr_vec_find")); return (vector); } /* * --------------------------------------------------------------------- * HIO-specific interrupt functions. * --------------------------------------------------------------------- */ /* * nxge_hio_intr_add * * Add 's interrupt. * * Arguments: * nxge * type Tx or Rx * channel The channel whose interrupt we want to remove. * * Notes: * * Context: * Guest domain * */ nxge_status_t nxge_hio_intr_add( nxge_t *nxge, vpc_type_t type, int channel) { nxge_hio_dc_t *dc; /* The relevant DMA channel data structure. */ nxge_intr_t *interrupts; /* The global interrupt data. */ nxge_ldg_t *group; /* The logical device group data. */ ddi_intr_handler_t *inthandler; int vector; /* A shorthand variable */ int ddi_status; /* The response to ddi_intr_add_handler */ char c = (type == VP_BOUND_TX ? 'T' : 'R'); NXGE_DEBUG_MSG((nxge, HIO_CTL, "==> nxge_hio_intr_add(%cDC %d)", c, channel)); if (nxge->ldgvp == 0) { NXGE_DEBUG_MSG((nxge, HIO_CTL, "nxge_hio_intr_add(%cDC %d): ldgvp == 0", c, channel)); return (NXGE_ERROR); } if ((dc = nxge_grp_dc_find(nxge, type, channel)) == 0) { NXGE_DEBUG_MSG((nxge, HIO_CTL, "nxge_hio_intr_add: find(%s, %d) failed", c, channel)); return (NXGE_ERROR); } /* 'nxge_intr_type' is a bad name for this data structure. */ interrupts = (nxge_intr_t *)&nxge->nxge_intr_type; /* Set here to make the following code easier to read. */ vector = dc->ldg.vector; group = &nxge->ldgvp->ldgp[vector]; if (group->nldvs == 1) { inthandler = group->ldvp->ldv_intr_handler; } else if (group->nldvs > 1) { inthandler = group->sys_intr_handler; } else { inthandler = NULL; } if ((ddi_status = ddi_intr_add_handler(interrupts->htable[vector], inthandler, group->ldvp, nxge)) != DDI_SUCCESS) { NXGE_ERROR_MSG((nxge, NXGE_ERR_CTL, "nxge_hio_intr_add(%cDC %d): " "ddi_intr_add_handler(%d) returned %s", c, channel, vector, nxge_ddi_perror(ddi_status))); return (NXGE_ERROR); } interrupts->intr_added++; /* Enable the interrupt. */ if ((ddi_status = ddi_intr_enable(interrupts->htable[vector])) != DDI_SUCCESS) { NXGE_ERROR_MSG((nxge, NXGE_ERR_CTL, "nxge_hio_intr_add(%cDC %d): " "ddi_intr_enable(%d) returned %s", c, channel, vector, nxge_ddi_perror(ddi_status))); return (NXGE_ERROR); } interrupts->intr_enabled = B_TRUE; /* * Note: RDC interrupts will be armed in nxge_m_start(). This * prevents us from getting an interrupt before we are ready * to process packets. */ if (type == VP_BOUND_TX) { nxge_hio_ldgimgn(nxge, group); } dc->interrupting = B_TRUE; NXGE_DEBUG_MSG((nxge, HIO_CTL, "<== nxge_hio_intr_add")); return (NXGE_OK); } /* * nxge_hio_intr_remove * * Remove 's interrupt. * * Arguments: * nxge * type Tx or Rx * channel The channel whose interrupt we want to remove. * * Notes: * * Context: * Guest domain * */ nxge_status_t nxge_hio_intr_remove( nxge_t *nxge, vpc_type_t type, int channel) { nxge_hio_dc_t *dc; /* The relevant DMA channel data structure. */ nxge_intr_t *interrupts; /* The global interrupt data. */ nxge_ldg_t *group; /* The logical device group data. */ int vector; /* A shorthand variable */ int status1, status2; char c = (type == VP_BOUND_TX ? 'T' : 'R'); NXGE_DEBUG_MSG((nxge, HIO_CTL, "==> nxge_hio_intr_remove(%cDC %d)", c, channel)); if (nxge->ldgvp == 0) { NXGE_DEBUG_MSG((nxge, HIO_CTL, "nxge_hio_intr_remove(%cDC %d): ldgvp == 0", c, channel)); return (NXGE_ERROR); } if ((dc = nxge_grp_dc_find(nxge, type, channel)) == 0) { NXGE_ERROR_MSG((nxge, NXGE_ERR_CTL, "nxge_hio_intr_remove(%cDC %d): DC FIND failed", c, channel)); return (NXGE_ERROR); } if (dc->interrupting == B_FALSE) { NXGE_DEBUG_MSG((nxge, HIO_CTL, "nxge_hio_intr_remove(%cDC %d): interrupting == FALSE", c, channel)); return (NXGE_OK); } /* 'nxge_intr_type' is a bad name for this data structure. */ interrupts = (nxge_intr_t *)&nxge->nxge_intr_type; /* Set here to make the following code easier to read. */ vector = dc->ldg.vector; group = &nxge->ldgvp->ldgp[vector]; /* Disarm the interrupt. */ group->arm = B_FALSE; nxge_hio_ldgimgn(nxge, group); group->arm = B_TRUE; /* HIOXXX There IS a better way */ status1 = DDI_SUCCESS; /* Disable the interrupt. */ if ((status2 = ddi_intr_disable(interrupts->htable[vector])) != DDI_SUCCESS) { NXGE_ERROR_MSG((nxge, NXGE_ERR_CTL, "nxge_hio_intr_remove(%cDC %d): " "ddi_intr_disable(%d) returned %s", c, channel, vector, nxge_ddi_perror(status2))); status1 += status2; } /* Remove the interrupt handler. */ if ((status2 = ddi_intr_remove_handler(interrupts->htable[vector])) != DDI_SUCCESS) { NXGE_ERROR_MSG((nxge, NXGE_ERR_CTL, "nxge_hio_intr_remove(%cDC %d): " "ddi_intr_remove_handle(%d) returned %s", c, channel, vector, nxge_ddi_perror(status2))); status1 += status2; } if (status1 == DDI_SUCCESS) { dc->interrupting = B_FALSE; interrupts->intr_added--; if (interrupts->intr_added == 0) interrupts->intr_enabled = B_FALSE; } NXGE_DEBUG_MSG((nxge, HIO_CTL, "<== nxge_hio_intr_remove")); return (NXGE_OK); } /* * nxge_hio_intr_init * * Initialize interrupts in a guest domain. * * Arguments: * nxge * * Notes: * * Context: * Guest domain * */ nxge_status_t nxge_hio_intr_init( nxge_t *nxge) { int *prop_val; uint_t prop_len; nxge_intr_t *interrupts; int intr_type, behavior; int nintrs, navail, nactual; int inum = 0; int ddi_status = DDI_SUCCESS; nxge_hw_pt_cfg_t *hardware = &nxge->pt_config.hw_config; int i; NXGE_DEBUG_MSG((nxge, HIO_CTL, "==> nxge_hio_intr_init")); /* Look up the "interrupts" property. */ if ((ddi_prop_lookup_int_array(DDI_DEV_T_ANY, nxge->dip, 0, "interrupts", &prop_val, &prop_len)) != DDI_PROP_SUCCESS) { NXGE_ERROR_MSG((nxge, HIO_CTL, "==> nxge_hio_intr_init(obp): no 'interrupts' property")); return (NXGE_ERROR); } /* * For each device assigned, the content of each interrupts * property is its logical device group. * * Assignment of interrupts property is in the the following * order: * * two receive channels * two transmit channels */ for (i = 0; i < prop_len; i++) { hardware->ldg[i] = prop_val[i]; NXGE_DEBUG_MSG((nxge, HIO_CTL, "==> nxge_hio_intr_init(obp): F%d: interrupt #%d, ldg %d", nxge->function_num, i, hardware->ldg[i])); } ddi_prop_free(prop_val); hardware->max_grpids = prop_len; hardware->max_ldgs = prop_len; hardware->ldg_chn_start = 0; /* ----------------------------------------------------- */ interrupts = (nxge_intr_t *)&nxge->nxge_intr_type; interrupts->intr_registered = B_FALSE; interrupts->intr_enabled = B_FALSE; interrupts->start_inum = 0; ddi_status = ddi_intr_get_supported_types( nxge->dip, &interrupts->intr_types); if (ddi_status != DDI_SUCCESS) { NXGE_ERROR_MSG((nxge, NXGE_ERR_CTL, "ddi_intr_get_supported_types() returned 0x%x, " "types = 0x%x", ddi_status, interrupts->intr_types)); return (NXGE_ERROR); } NXGE_ERROR_MSG((nxge, HIO_CTL, "ddi_intr_get_supported_types() " "returned 0x%x, types = 0x%x", ddi_status, interrupts->intr_types)); /* HIOXXX hack */ interrupts->intr_type = DDI_INTR_TYPE_FIXED; /* HIOXXX hack */ intr_type = interrupts->intr_type; ddi_status = ddi_intr_get_navail(nxge->dip, intr_type, &navail); if (ddi_status != DDI_SUCCESS) { NXGE_ERROR_MSG((nxge, NXGE_ERR_CTL, "ddi_intr_get_navail() returned %s, navail: %d", ddi_status == DDI_FAILURE ? "DDI_FAILURE" : "DDI_INTR_NOTFOUND", navail)); return (NXGE_ERROR); } NXGE_DEBUG_MSG((nxge, HIO_CTL, "nxge_hio_intr_init: number of available interrupts: %d", navail)); ddi_status = ddi_intr_get_nintrs(nxge->dip, intr_type, &nintrs); if (ddi_status != DDI_SUCCESS) { NXGE_ERROR_MSG((nxge, NXGE_ERR_CTL, "ddi_intr_get_nintrs() returned %s, nintrs: %d", ddi_status == DDI_FAILURE ? "DDI_FAILURE" : "DDI_INTR_NOTFOUND", nintrs)); return (NXGE_ERROR); } NXGE_DEBUG_MSG((nxge, HIO_CTL, "nxge_hio_intr_init: number of interrupts: %d", nintrs)); interrupts->intr_size = navail * sizeof (ddi_intr_handle_t); interrupts->htable = kmem_alloc(interrupts->intr_size, KM_SLEEP); /* * When is set to DDI_INTR_ALLOC_STRICT, * ddi_intr_alloc() succeeds if and only if * interrupts are are allocated. Otherwise, it fails. */ behavior = ((intr_type == DDI_INTR_TYPE_FIXED) ? DDI_INTR_ALLOC_STRICT : DDI_INTR_ALLOC_NORMAL); ddi_status = ddi_intr_alloc(nxge->dip, interrupts->htable, intr_type, inum, navail, &nactual, behavior); if (ddi_status != DDI_SUCCESS) { NXGE_ERROR_MSG((nxge, NXGE_ERR_CTL, "ddi_intr_alloc() returned 0x%x%, " "number allocated: %d", ddi_status, nactual)); return (NXGE_ERROR); } NXGE_DEBUG_MSG((nxge, HIO_CTL, "nxge_hio_intr_init: number of interrupts allocated: %d", nactual)); /* is a dead variable: we may as well use it. */ hardware->ninterrupts = nactual; /* FOI: Get the interrupt priority. */ if ((ddi_status = ddi_intr_get_pri(interrupts->htable[0], (uint_t *)&interrupts->pri)) != DDI_SUCCESS) { NXGE_ERROR_MSG((nxge, NXGE_ERR_CTL, " ddi_intr_get_pri() failed: %d", ddi_status)); } NXGE_DEBUG_MSG((nxge, HIO_CTL, "nxge_hio_intr_init: interrupt priority: %d", interrupts->pri)); /* FOI: Get our interrupt capability flags. */ if ((ddi_status = ddi_intr_get_cap(interrupts->htable[0], &interrupts->intr_cap)) != DDI_SUCCESS) { NXGE_ERROR_MSG((nxge, NXGE_ERR_CTL, "ddi_intr_get_cap() failed: %d", ddi_status)); } NXGE_DEBUG_MSG((nxge, HIO_CTL, "nxge_hio_intr_init: interrupt capabilities: %d", interrupts->intr_cap)); interrupts->intr_registered = B_TRUE; NXGE_DEBUG_MSG((nxge, HIO_CTL, "<== nxge_hio_intr_init")); return (NXGE_OK); } /* * nxge_hio_intr_uninit * * Uninitialize interrupts in a guest domain. * * Arguments: * nxge * * Notes: * * Context: * Guest domain */ void nxge_hio_intr_uninit( nxge_t *nxge) { nxge_hw_pt_cfg_t *hardware; nxge_intr_t *interrupts; nxge_ldgv_t *control; int i; NXGE_DEBUG_MSG((nxge, HIO_CTL, "==> nxge_hio_intr_uninit")); /* ----------------------------------------------------- */ interrupts = (nxge_intr_t *)&nxge->nxge_intr_type; /* * If necessary, disable any currently active interrupts. */ if (interrupts->intr_enabled) { nxge_grp_set_t *set; nxge_grp_t *group; int channel; set = &nxge->tx_set; group = set->group[0]; /* Assumption: only one group! */ for (channel = 0; channel < NXGE_MAX_TDCS; channel++) { if ((1 << channel) & group->map) { (void) nxge_hio_intr_remove( nxge, VP_BOUND_TX, channel); } } set = &nxge->rx_set; group = set->group[0]; /* Assumption: only one group! */ for (channel = 0; channel < NXGE_MAX_RDCS; channel++) { if ((1 << channel) & group->map) { (void) nxge_hio_intr_remove( nxge, VP_BOUND_RX, channel); } } } /* * Free all of our allocated interrupts. */ hardware = &nxge->pt_config.hw_config; for (i = 0; i < hardware->ninterrupts; i++) { if (interrupts->htable[i]) (void) ddi_intr_free(interrupts->htable[i]); interrupts->htable[i] = 0; } interrupts->intr_registered = B_FALSE; KMEM_FREE(interrupts->htable, interrupts->intr_size); interrupts->htable = NULL; if (nxge->ldgvp == NULL) goto nxge_hio_intr_uninit_exit; control = nxge->ldgvp; if (control->ldgp) { KMEM_FREE(control->ldgp, sizeof (nxge_ldg_t) * NXGE_INT_MAX_LDGS); control->ldgp = 0; } if (control->ldvp) { KMEM_FREE(control->ldvp, sizeof (nxge_ldv_t) * NXGE_INT_MAX_LDS); control->ldvp = 0; } KMEM_FREE(control, sizeof (nxge_ldgv_t)); nxge->ldgvp = NULL; nxge_hio_intr_uninit_exit: NXGE_DEBUG_MSG((nxge, HIO_CTL, "<== nxge_hio_intr_uninit")); } /* * nxge_hio_tdsv_add * * Add a transmit device interrupt. * * Arguments: * nxge * dc The TDC whose interrupt we're adding * * Notes: * * Context: * Guest domain */ static hv_rv_t nxge_hio_tdsv_add( nxge_t *nxge, nxge_hio_dc_t *dc) { nxge_hio_data_t *nhd = (nxge_hio_data_t *)nxge->nxge_hw_p->hio; nxge_hw_pt_cfg_t *hardware = &nxge->pt_config.hw_config; nxhv_dc_fp_t *tx = &nhd->hio.tx; hv_rv_t hv_rv; if (tx->getinfo == 0) { NXGE_ERROR_MSG((nxge, NXGE_ERR_CTL, "nx_hio_tdsv_add: tx->getinfo absent")); return (EINVAL); } /* * Get the dma channel information. */ hv_rv = (*tx->getinfo)(dc->cookie, dc->page, &dc->ldg.index, &dc->ldg.ldsv); if (hv_rv != 0) { NXGE_ERROR_MSG((nxge, NXGE_ERR_CTL, "nx_hio_tdsv_add: tx->getinfo failed: %ld", hv_rv)); return (EIO); } NXGE_DEBUG_MSG((nxge, HIO_CTL, "nx_hio_tdsv_add: VRgroup = %d, LDSV = %d", (int)dc->ldg.index, (int)dc->ldg.ldsv)); if (hardware->tdc.count == 0) { hardware->tdc.start = dc->channel; } hardware->tdc.count++; hardware->tdc.owned++; /* * In version 1.0 of the hybrid I/O driver, there * are eight interrupt vectors per VR. * * Vectors 0 - 3 are reserved for RDCs. * Vectors 4 - 7 are reserved for TDCs. */ dc->ldg.vector = (dc->ldg.ldsv % 2) + HIO_INTR_BLOCK_SIZE; // Version 1.0 hack only! return (0); } /* * nxge_hio_rdsv_add * * Add a transmit device interrupt. * * Arguments: * nxge * dc The RDC whose interrupt we're adding * * Notes: * * Context: * Guest domain */ static hv_rv_t nxge_hio_rdsv_add( nxge_t *nxge, nxge_hio_dc_t *dc) { nxge_hio_data_t *nhd = (nxge_hio_data_t *)nxge->nxge_hw_p->hio; nxge_hw_pt_cfg_t *hardware = &nxge->pt_config.hw_config; nxhv_dc_fp_t *rx = &nhd->hio.rx; hv_rv_t hv_rv; if (rx->getinfo == 0) { NXGE_ERROR_MSG((nxge, NXGE_ERR_CTL, "nx_hio_tdsv_add: rx->getinfo absent")); return (EINVAL); } /* * Get DMA channel information. */ hv_rv = (*rx->getinfo)(dc->cookie, dc->page, &dc->ldg.index, &dc->ldg.ldsv); if (hv_rv != 0) { NXGE_ERROR_MSG((nxge, NXGE_ERR_CTL, "nx_hio_tdsv_add: rx->getinfo failed: %ld", hv_rv)); return (EIO); } NXGE_DEBUG_MSG((nxge, HIO_CTL, "nx_hio_rdsv_add: VRgroup = %d, LDSV = %d", (int)dc->ldg.index, (int)dc->ldg.ldsv)); if (hardware->max_rdcs == 0) { hardware->start_rdc = dc->channel; hardware->def_rdc = dc->channel; } hardware->max_rdcs++; /* * In version 1.0 of the hybrid I/O driver, there * are eight interrupt vectors per VR. * * Vectors 0 - 3 are reserved for RDCs. */ dc->ldg.vector = (dc->ldg.ldsv % 2); // Version 1.0 hack only! return (0); } /* * nxge_hio_ldsv_add * * Add a transmit or receive interrupt. * * Arguments: * nxge * dc The DMA channel whose interrupt we're adding * * Notes: * Guest domains can only add interrupts for DMA channels. * They cannot access the MAC, MIF, or SYSERR interrupts. * * Context: * Guest domain */ int nxge_hio_ldsv_add(nxge_t *nxge, nxge_hio_dc_t *dc) { nxge_ldgv_t *control; nxge_ldg_t *group; nxge_ldv_t *device; if (dc->type == VP_BOUND_TX) { NXGE_DEBUG_MSG((nxge, HIO_CTL, "==> nxge_hio_ldsv_add(TDC %d)", dc->channel)); if (nxge_hio_tdsv_add(nxge, dc) != 0) return (EIO); } else { NXGE_DEBUG_MSG((nxge, HIO_CTL, "==> nxge_hio_ldsv_add(RDC %d)", dc->channel)); if (nxge_hio_rdsv_add(nxge, dc) != 0) return (EIO); } dc->ldg.map |= (1 << dc->ldg.ldsv); control = nxge->ldgvp; if (control == NULL) { control = KMEM_ZALLOC(sizeof (nxge_ldgv_t), KM_SLEEP); nxge->ldgvp = control; control->maxldgs = 1; control->maxldvs = 1; control->ldgp = KMEM_ZALLOC( sizeof (nxge_ldg_t) * NXGE_INT_MAX_LDGS, KM_SLEEP); control->ldvp = KMEM_ZALLOC( sizeof (nxge_ldv_t) * NXGE_INT_MAX_LDS, KM_SLEEP); } else { control->maxldgs++; control->maxldvs++; } /* * Initialize the logical device group data structure first. */ group = &control->ldgp[dc->ldg.vector]; (void) memset(group, 0, sizeof (*group)); /* * is a copy of the "interrupts" property. */ group->ldg = nxge->pt_config.hw_config.ldg[dc->ldg.vector]; group->vldg_index = (uint8_t)dc->ldg.index; /* * Since is a dead variable, I'm reusing * it in Hybrid I/O to calculate the offset into the * virtual PIO_LDSV space. */ group->arm = B_TRUE; group->ldg_timer = NXGE_TIMER_LDG; group->func = nxge->function_num; group->vector = dc->ldg.vector; /* * appears to be a dead variable. * Though it is not used anywhere in the driver, * we'll set it anyway. */ group->intdata = SID_DATA(group->func, group->vector); group->sys_intr_handler = nxge_intr; /* HIOXXX Does this work? */ group->nxgep = nxge; /* * Initialize the logical device state vector next. */ device = &control->ldvp[dc->ldg.ldsv]; device->ldg_assigned = group->ldg; device->ldv = dc->ldg.ldsv; if (dc->type == VP_BOUND_TX) { device->is_txdma = B_TRUE; device->is_rxdma = B_FALSE; device->ldv_intr_handler = nxge_tx_intr; } else { device->is_rxdma = B_TRUE; device->is_txdma = B_FALSE; device->ldv_intr_handler = nxge_rx_intr; } device->is_mif = B_FALSE; device->is_mac = B_FALSE; device->is_syserr = B_FALSE; device->use_timer = B_FALSE; /* Set to B_TRUE for syserr only. */ device->channel = dc->channel; device->vdma_index = dc->page; device->func = nxge->function_num; device->ldgp = group; device->ldv_flags = 0; device->ldv_ldf_masks = 0; device->nxgep = nxge; /* * This code seems to imply a strict 1-to-1 correspondence. */ group->nldvs++; group->ldvp = device; control->nldvs++; control->ldg_intrs++; NXGE_DEBUG_MSG((nxge, HIO_CTL, "<== nxge_hio_ldsv_add")); return (0); } /* * nxge_hio_ldsv_im * * Manage a VLDG's interrupts. * * Arguments: * nxge * group The VLDG to manage * * Notes: * There are 8 sets of 4 64-bit registers per VR, 1 per LDG. * That sums to 256 bytes of virtual PIO_LDSV space. * * VLDG0 starts at offset 0, * VLDG1 starts at offset 32, etc. * * Each set consists of 4 registers: * Logical Device State Vector 0. LDSV0 * Logical Device State Vector 1. LDSV1 * Logical Device State Vector 2. LDSV2 * Logical Device Group Interrupt Management. LDGIMGN * * The first three (LDSVx) are read-only. The 4th register is the * LDGIMGN, the LDG Interrupt Management register, which is used to * arm the LDG, or set its timer. * * The offset to write to is calculated as follows: * * 0x2000 + (VLDG << 4) + offset, where: * VDLG is the virtual group, i.e., index of the LDG. * offset is the offset (alignment 8) of the register * to read or write. * * So, for example, if we wanted to arm the first TDC of VRx, we would * calculate the address as: * * 0x2000 + (0 << 4) + 0x18 = 0x18 * * Context: * Guest domain * */ void nxge_hio_ldsv_im( /* Read any register in the PIO_LDSV space. */ nxge_t *nxge, nxge_ldg_t *group, pio_ld_op_t op, uint64_t *value) { uint64_t offset = VLDG_OFFSET; offset += group->vldg_index << VLDG_SLL; /* bits 7:5 */ offset += (op * sizeof (uint64_t)); /* 0, 8, 16, 24 */ NXGE_REG_RD64(nxge->npi_handle, offset, value); } void nxge_hio_ldgimgn( /* Write the PIO_LDGIMGN register. */ nxge_t *nxge, nxge_ldg_t *group) { uint64_t offset = VLDG_OFFSET; ldgimgm_t mgm; offset += group->vldg_index << VLDG_SLL; /* bits 7:5 */ offset += (PIO_LDGIMGN * sizeof (uint64_t)); /* 24 */ mgm.value = 0; if (group->arm) { mgm.bits.ldw.arm = 1; mgm.bits.ldw.timer = group->ldg_timer; } else { mgm.bits.ldw.arm = 0; mgm.bits.ldw.timer = 0; } NXGE_REG_WR64(nxge->npi_handle, offset, mgm.value); }