/* * 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" /* * USBA: Solaris USB Architecture support * * all functions exposed to client drivers have prefix usb_ while all USBA * internal functions or functions exposed to HCD or hubd only have prefix * usba_ * * this file contains initializations, logging/tracing support and PM * support */ #define USBA_FRAMEWORK #include #include #include #include /* * print buffer protected by mutex for debug stuff. the mutex also * ensures serializing debug messages */ static kmutex_t usba_print_mutex; static char usba_print_buf[USBA_PRINT_BUF_LEN]; kmutex_t usbai_mutex; /* * debug stuff */ usb_log_handle_t usbai_log_handle; uint_t usbai_errlevel = USB_LOG_L4; uint_t usbai_errmask = (uint_t)-1; #define USBA_DEBUG_SIZE_EXTRA_ALLOC 8 #ifdef DEBUG #define USBA_DEBUG_BUF_SIZE \ (0x40000 - USBA_DEBUG_SIZE_EXTRA_ALLOC) #else #define USBA_DEBUG_BUF_SIZE \ (0x4000 - USBA_DEBUG_SIZE_EXTRA_ALLOC) #endif /* DEBUG */ #define USBA_POWER_STR_SIZE 40 int usba_suppress_dprintf; /* Suppress debug printing */ int usba_clear_debug_buf_flag; /* clear debug buf */ int usba_buffer_dprintf = 1; /* Use a debug print buffer */ int usba_timestamp_dprintf = 0; /* get time stamps in trace */ int usba_debug_buf_size = USBA_DEBUG_BUF_SIZE; /* Size of debug buf */ int usba_debug_chatty; /* L1 msg on console */ static char *usba_debug_buf = NULL; /* The debug buf */ static char *usba_buf_sptr, *usba_buf_eptr; static hrtime_t usba_last_timestamp; /* last time stamp in trace */ /* * Set to 1 to enable PM. */ int usb_force_enable_pm = 0; /* USBA framework initializations */ void usba_usbai_initialization() { usbai_log_handle = usb_alloc_log_hdl(NULL, "usbai", &usbai_errlevel, &usbai_errmask, NULL, 0); USB_DPRINTF_L4(DPRINT_MASK_USBAI, usbai_log_handle, "usba_usbai_initialization"); mutex_init(&usba_print_mutex, NULL, MUTEX_DRIVER, NULL); mutex_init(&usbai_mutex, NULL, MUTEX_DRIVER, NULL); } /* USBA framework destroys */ void usba_usbai_destroy() { USB_DPRINTF_L4(DPRINT_MASK_USBAI, usbai_log_handle, "usba_usbai_destroy"); mutex_destroy(&usba_print_mutex); mutex_destroy(&usbai_mutex); if (usba_debug_buf) { kmem_free(usba_debug_buf, usba_debug_buf_size + USBA_DEBUG_SIZE_EXTRA_ALLOC); } usb_free_log_hdl(usbai_log_handle); } /* * debug, log, and console message handling */ usb_log_handle_t usb_alloc_log_hdl(dev_info_t *dip, char *name, uint_t *errlevel, uint_t *mask, uint_t *instance_filter, usb_flags_t flags) { usba_log_handle_impl_t *hdl; USBA_CHECK_CONTEXT(); hdl = kmem_zalloc(sizeof (*hdl), KM_SLEEP); hdl->lh_dip = dip; if (dip && (name == NULL)) { hdl->lh_name = (char *)ddi_driver_name(dip); } else { hdl->lh_name = name; } hdl->lh_errlevel = errlevel; hdl->lh_mask = mask; hdl->lh_instance_filter = instance_filter; hdl->lh_flags = flags; #ifdef __lock_lint (void) usb_alloc_log_handle(dip, name, errlevel, mask, instance_filter, 0, flags); usb_free_log_handle(NULL); #endif return ((usb_log_handle_t)hdl); } /*ARGSUSED*/ usb_log_handle_t usb_alloc_log_handle(dev_info_t *dip, char *name, uint_t *errlevel, uint_t *mask, uint_t *instance_filter, uint_t reserved, usb_flags_t flags) { return (usb_alloc_log_hdl(dip, name, errlevel, mask, instance_filter, flags)); } void usb_free_log_handle(usb_log_handle_t handle) { if (handle) { kmem_free(handle, sizeof (usba_log_handle_impl_t)); } } void usb_free_log_hdl(usb_log_handle_t handle) { if (handle) { kmem_free(handle, sizeof (usba_log_handle_impl_t)); } } static void usba_clear_dprint_buf() { if (usba_debug_buf) { usba_buf_sptr = usba_debug_buf; usba_buf_eptr = usba_debug_buf + usba_debug_buf_size; bzero(usba_debug_buf, usba_debug_buf_size + USBA_DEBUG_SIZE_EXTRA_ALLOC); } } #ifdef DEBUG char * usba_dbuf_tail(uint_t lines) { int count; char *r = NULL; mutex_enter(&usba_print_mutex); if (usba_debug_buf) { count = 0; r = usba_buf_sptr; while ((count < lines) && (r > usba_debug_buf)) { if (*r == '\n') { count++; } r--; } } mutex_exit(&usba_print_mutex); return (r); } #endif /* DEBUG */ static void usb_vprintf(dev_info_t *, int, char *, char *, va_list) __KVPRINTFLIKE(4); static void usb_vprintf(dev_info_t *dip, int level, char *label, char *fmt, va_list ap) { size_t len; int instance; char driver_name[USBA_DRVNAME_LEN]; char *msg_ptr; if (usba_suppress_dprintf) { return; } *driver_name = '\0'; mutex_enter(&usba_print_mutex); /* * Check if we have a valid buf size? * Suppress logging to usb_buffer if so. */ if (usba_debug_buf_size <= 0) { usba_buffer_dprintf = 0; } /* * if there is label and dip, use : * otherwise just use the label */ if (dip) { instance = ddi_get_instance(dip); (void) snprintf(driver_name, USBA_DRVNAME_LEN, "%s%d", ddi_driver_name(dip), instance); } if (label == (char *)NULL) { len = snprintf(usba_print_buf, USBA_PRINT_BUF_LEN, "\t"); } else if (usba_timestamp_dprintf) { hrtime_t t = gethrtime(); hrtime_t elapsed = (t - usba_last_timestamp)/1000; usba_last_timestamp = t; if (dip) { len = snprintf(usba_print_buf, USBA_PRINT_BUF_LEN, "+%lld->%p: %s%d: ", elapsed, (void *)curthread, label, instance); } else { len = snprintf(usba_print_buf, USBA_PRINT_BUF_LEN, "+%lld->%p: %s: ", elapsed, (void *)curthread, label); } } else { if (dip) { len = snprintf(usba_print_buf, USBA_PRINT_BUF_LEN, "%s%d:\t", label, instance); } else { len = snprintf(usba_print_buf, USBA_PRINT_BUF_LEN, "%s:\t", label); } } msg_ptr = usba_print_buf + len; (void) vsnprintf(msg_ptr, USBA_PRINT_BUF_LEN - len - 2, fmt, ap); len = min(strlen(usba_print_buf), USBA_PRINT_BUF_LEN - 2); usba_print_buf[len++] = '\n'; usba_print_buf[len] = '\0'; /* * stuff the message in the debug buf */ if (usba_buffer_dprintf) { if (usba_debug_buf == NULL) { usba_debug_buf = kmem_alloc( usba_debug_buf_size + USBA_DEBUG_SIZE_EXTRA_ALLOC, KM_SLEEP); usba_clear_dprint_buf(); } else if (usba_clear_debug_buf_flag) { usba_clear_dprint_buf(); usba_clear_debug_buf_flag = 0; } /* * overwrite >>>> that might be over the end of the * the buffer */ *(usba_debug_buf + usba_debug_buf_size) = '\0'; if ((usba_buf_sptr + len) > usba_buf_eptr) { size_t left = usba_buf_eptr - usba_buf_sptr; bcopy(usba_print_buf, usba_buf_sptr, left); bcopy((caddr_t)usba_print_buf + left, usba_debug_buf, len - left); usba_buf_sptr = usba_debug_buf + len - left; } else { bcopy(usba_print_buf, usba_buf_sptr, len); usba_buf_sptr += len; } /* add marker */ (void) sprintf(usba_buf_sptr, ">>>>"); } /* * L4-L2 message may go to the log buf if not logged in usba_debug_buf * L1 messages will go to the log buf in non-debug kernels and * to console and log buf in debug kernels if usba_debug_chatty * has been set * L0 messages are warnings and will go to console and log buf and * include the pathname, if available */ switch (level) { case USB_LOG_L4: case USB_LOG_L3: case USB_LOG_L2: if (!usba_buffer_dprintf) { cmn_err(CE_CONT, "^%s", usba_print_buf); } break; case USB_LOG_L1: if (dip) { char *pathname = kmem_alloc(MAXPATHLEN, KM_NOSLEEP); if (pathname) { cmn_err(CE_CONT, usba_debug_chatty ? "%s (%s): %s" : "?%s (%s): %s", ddi_pathname(dip, pathname), driver_name, msg_ptr); kmem_free(pathname, MAXPATHLEN); } else { cmn_err(CE_CONT, usba_debug_chatty ? "%s" : "?%s", usba_print_buf); } } else { cmn_err(CE_CONT, usba_debug_chatty ? "%s" : "?%s", usba_print_buf); } break; case USB_LOG_L0: /* Strip the "\n" added earlier */ if (usba_print_buf[len - 1] == '\n') { usba_print_buf[len - 1] = '\0'; } if (msg_ptr[len - 1] == '\n') { msg_ptr[len - 1] = '\0'; } if (dip) { char *pathname = kmem_alloc(MAXPATHLEN, KM_NOSLEEP); if (pathname) { cmn_err(CE_WARN, "%s (%s): %s", ddi_pathname(dip, pathname), driver_name, msg_ptr); kmem_free(pathname, MAXPATHLEN); } else { cmn_err(CE_WARN, usba_print_buf); } } else { cmn_err(CE_WARN, usba_print_buf); } break; } mutex_exit(&usba_print_mutex); } int usba_vlog(usb_log_handle_t, uint_t, uint_t, char *, va_list) __KVPRINTFLIKE(4); /* When usba10_calls.c goes away, this function can be made static again. */ int usba_vlog(usb_log_handle_t handle, uint_t level, uint_t mask, char *fmt, va_list ap) { usba_log_handle_impl_t *hdl = (usba_log_handle_impl_t *)handle; char *label; uint_t hdl_errlevel, hdl_mask, hdl_instance_filter; /* if there is no handle, use usba as label */ if (hdl == NULL) { usb_vprintf(NULL, level, "usba", fmt, ap); return (USB_SUCCESS); } /* look up the filters and set defaults */ if (hdl->lh_errlevel) { hdl_errlevel = *(hdl->lh_errlevel); } else { hdl_errlevel = 0; } if (hdl->lh_mask) { hdl_mask = *(hdl->lh_mask); } else { hdl_mask = (uint_t)-1; } if (hdl->lh_instance_filter) { hdl_instance_filter = *(hdl->lh_instance_filter); } else { hdl_instance_filter = (uint_t)-1; } /* if threshold is lower or mask doesn't match, we are done */ if ((level > hdl_errlevel) || ((mask & hdl_mask) == 0)) { return (USB_FAILURE); } /* * if we have a dip, and it is not a warning, check * the instance number */ if (hdl->lh_dip && (level > USB_LOG_L0)) { if ((hdl_instance_filter != (uint_t)-1) && (ddi_get_instance(hdl->lh_dip) != hdl_instance_filter)) { return (USB_FAILURE); } } label = hdl->lh_name; usb_vprintf(hdl->lh_dip, level, label, fmt, ap); return (USB_SUCCESS); } void usb_dprintf4(uint_t mask, usb_log_handle_t handle, char *fmt, ...) { va_list ap; va_start(ap, fmt); (void) usba_vlog(handle, USB_LOG_L4, mask, fmt, ap); va_end(ap); } void usb_dprintf3(uint_t mask, usb_log_handle_t handle, char *fmt, ...) { va_list ap; va_start(ap, fmt); (void) usba_vlog(handle, USB_LOG_L3, mask, fmt, ap); va_end(ap); } void usb_dprintf2(uint_t mask, usb_log_handle_t handle, char *fmt, ...) { va_list ap; va_start(ap, fmt); (void) usba_vlog(handle, USB_LOG_L2, mask, fmt, ap); va_end(ap); } void usb_dprintf1(uint_t mask, usb_log_handle_t handle, char *fmt, ...) { va_list ap; va_start(ap, fmt); (void) usba_vlog(handle, USB_LOG_L1, mask, fmt, ap); va_end(ap); } void usb_dprintf0(uint_t mask, usb_log_handle_t handle, char *fmt, ...) { va_list ap; va_start(ap, fmt); (void) usba_vlog(handle, USB_LOG_L0, mask, fmt, ap); va_end(ap); } int usb_log(usb_log_handle_t handle, uint_t level, uint_t mask, char *fmt, ...) { va_list ap; int rval; va_start(ap, fmt); rval = usba_vlog(handle, level, mask, fmt, ap); va_end(ap); return (rval); } /* * Provide a default configuration power descriptor */ usba_cfg_pwr_descr_t default_cfg_power = { 18, /* bLength */ USBA_DESCR_TYPE_CFG_PWR_1_1, /* bDescriptorType */ 0, /* SelfPowerConsumedD0_l */ 0, /* SelfPowerConsumedD0_h */ 0, /* bPowerSummaryId */ 0, /* bBusPowerSavingD1 */ 0, /* bSelfPowerSavingD1 */ 0, /* bBusPowerSavingD2 */ 0, /* bSelfPowerSavingD2 */ 100, /* bBusPowerSavingD3 */ 100, /* bSelfPowerSavingD3 */ 0, /* TransitionTimeFromD1 */ 0, /* TransitionTimeFromD2 */ 10, /* TransitionTimeFromD3 1 Second */ }; /* * Provide a default interface power descriptor */ usba_if_pwr_descr_t default_if_power = { 15, /* bLength */ USBA_DESCR_TYPE_IF_PWR_1_1, /* bDescriptorType */ 8, /* bmCapabilitiesFlags */ 0, /* bBusPowerSavingD1 */ 0, /* bSelfPowerSavingD1 */ 0, /* bBusPowerSavingD2 */ 0, /* bSelfPowerSavingD2 */ 100, /* bBusPowerSavingD3 */ 100, /* bSelfPowerSavingD3 */ 0, /* TransitionTimeFromD1 */ 0, /* TransitionTimeFromD2 */ 10, /* TransitionTimeFromD3 1 Second */ }; static void usba_async_req_raise_power(void *arg) { usba_pm_req_t *pmrq = (usba_pm_req_t *)arg; int rval; /* * To eliminate race condition between the call to power entry * point and our call to raise power level, we first mark the * component busy and later idle */ (void) pm_busy_component(pmrq->dip, pmrq->comp); rval = pm_raise_power(pmrq->dip, pmrq->comp, pmrq->level); (void) pm_idle_component(pmrq->dip, pmrq->comp); pmrq->cb(pmrq->arg, rval); /* We are done with pmrq. Free it now */ kmem_free(pmrq, sizeof (usba_pm_req_t)); } /* usb function to perform async pm_request_power_change */ int usb_req_raise_power(dev_info_t *dip, int comp, int level, void (*callback)(void *, int), void *arg, usb_flags_t flags) { usba_pm_req_t *pmrq; if (flags & USB_FLAGS_SLEEP) { return (pm_raise_power(dip, comp, level)); } if ((pmrq = kmem_alloc(sizeof (usba_pm_req_t), KM_NOSLEEP)) == NULL) { return (USB_FAILURE); } pmrq->dip = dip; pmrq->comp = comp; pmrq->level = level; pmrq->cb = callback; pmrq->arg = arg; pmrq->flags = flags; if (usb_async_req(dip, usba_async_req_raise_power, (void *)pmrq, USB_FLAGS_NOSLEEP | USB_FLAGS_NOQUEUE) != USB_SUCCESS) { kmem_free(pmrq, sizeof (usba_pm_req_t)); return (USB_FAILURE); } return (USB_SUCCESS); } static void usba_async_req_lower_power(void *arg) { usba_pm_req_t *pmrq = (usba_pm_req_t *)arg; int rval; /* * To eliminate race condition between the call to power entry * point and our call to lower power level, we call idle component * to push ahead the PM timestamp */ (void) pm_idle_component(pmrq->dip, pmrq->comp); rval = pm_lower_power(pmrq->dip, pmrq->comp, pmrq->level); pmrq->cb(pmrq->arg, rval); } /* usb function to perform async pm_request_power_change */ int usb_req_lower_power(dev_info_t *dip, int comp, int level, void (*callback)(void *, int), void *arg, usb_flags_t flags) { usba_pm_req_t *pmrq; if (flags & USB_FLAGS_SLEEP) { return (pm_lower_power(dip, comp, level)); } if ((pmrq = kmem_alloc(sizeof (usba_pm_req_t), KM_NOSLEEP)) == NULL) { return (USB_FAILURE); } pmrq->dip = dip; pmrq->comp = comp; pmrq->level = level; pmrq->cb = callback; pmrq->arg = arg; pmrq->flags = flags; if (usb_async_req(dip, usba_async_req_lower_power, (void *)pmrq, USB_FLAGS_NOSLEEP | USB_FLAGS_NOQUEUE) != USB_SUCCESS) { kmem_free(pmrq, sizeof (usba_pm_req_t)); return (USB_FAILURE); } return (USB_SUCCESS); } /* function to see if pm is enabled for this device */ /*ARGSUSED*/ int usb_is_pm_enabled(dev_info_t *dip) { usba_device_t *usba_device = usba_get_usba_device(dip); switch (usb_force_enable_pm) { case -1: /* no PM at all */ return (USB_FAILURE); case 1: /* PM on all platforms, regardless of hcd */ return (USB_SUCCESS); case 0: default: break; } if (usba_device) { dev_info_t *root_hub_dip; usba_hcdi_t *hcdi; int rval; root_hub_dip = usba_device->usb_root_hub_dip; if (root_hub_dip == NULL) { return (USB_FAILURE); } hcdi = usba_hcdi_get_hcdi(root_hub_dip); if (hcdi && hcdi->hcdi_ops->usba_hcdi_pm_support) { rval = hcdi->hcdi_ops-> usba_hcdi_pm_support(root_hub_dip); if (rval != USB_SUCCESS) { USB_DPRINTF_L2(DPRINT_MASK_USBA, usbai_log_handle, "%s%d: no PM enabled for this device", ddi_driver_name(dip), ddi_get_instance(dip)); } return (rval); } } return (USB_FAILURE); } /* * usba_handle_device_remote_wakeup: * internal function to enable/disable remote wakeup in the device * or interface */ static int usba_handle_device_remote_wakeup(dev_info_t *dip, int cmd) { int rval; uint8_t bmRequest = USB_DEV_REQ_HOST_TO_DEV; uchar_t bRequest; uint16_t wIndex = 0; usb_cr_t completion_reason = 0; usb_cb_flags_t cb_flags; usb_pipe_handle_t ph; USB_DPRINTF_L4(DPRINT_MASK_USBA, usbai_log_handle, "usba_handle_device_remote_wakeup: dip = 0x%p", (void *)dip); USBA_CHECK_CONTEXT(); /* get the default pipe */ ph = usba_get_dflt_pipe_handle(dip); /* do we own the device? */ if (usb_owns_device(dip)) { bmRequest |= USB_DEV_REQ_RCPT_DEV; } else { bmRequest |= USB_DEV_REQ_RCPT_IF; wIndex = usba_get_ifno(dip); } bRequest = ((cmd == USB_REMOTE_WAKEUP_ENABLE) ? USB_REQ_SET_FEATURE : USB_REQ_CLEAR_FEATURE); if ((rval = usb_pipe_sync_ctrl_xfer(dip, ph, bmRequest, /* bmRequest */ bRequest, /* bRequest */ USB_DEV_REMOTE_WAKEUP, /* wValue */ wIndex, /* wIndex */ 0, /* wLength */ NULL, 0, &completion_reason, &cb_flags, USB_FLAGS_SLEEP)) != USB_SUCCESS) { USB_DPRINTF_L2(DPRINT_MASK_USBAI, usbai_log_handle, "Set/ClearFeature (RemoteWakep) failed: " "rval = %d, cmd = %d, cr = 0x%x cb = 0x%x", rval, cmd, completion_reason, cb_flags); } return (rval); } void usb_enable_parent_notification(dev_info_t *dip) { USBA_CHECK_CONTEXT(); (void) ndi_prop_create_boolean(DDI_DEV_T_NONE, dip, "pm-want-child-notification?"); } /* * usb_handle_remote_wakeup: * check if device supports remote wakeup and, if so, enable/disable * remote wake up in the device depending upon the command */ int usb_handle_remote_wakeup(dev_info_t *dip, int cmd) { usb_cfg_descr_t cfg_descr; uchar_t *usb_cfg; /* buf for config descriptor */ size_t cfg_length; int rval; USBA_CHECK_CONTEXT(); /* Obtain the raw configuration descriptor */ usb_cfg = usb_get_raw_cfg_data(dip, &cfg_length); /* get configuration descriptor, must succeed */ rval = usb_parse_cfg_descr(usb_cfg, cfg_length, &cfg_descr, USB_CFG_DESCR_SIZE); ASSERT(rval == USB_CFG_DESCR_SIZE); /* * If the device supports remote wakeup, and PM is enabled, * we enable remote wakeup in the device */ if ((usb_is_pm_enabled(dip) == USB_SUCCESS) && (cfg_descr.bmAttributes & USB_CFG_ATTR_REMOTE_WAKEUP)) { rval = usba_handle_device_remote_wakeup(dip, cmd); } else { rval = USB_FAILURE; } return (rval); } /* * usb_create_pm_components: * map descriptor into pm properties */ int usb_create_pm_components(dev_info_t *dip, uint_t *pwr_states) { uchar_t *usb_cfg; /* buf for config descriptor */ usb_cfg_descr_t cfg_descr; size_t cfg_length; usba_cfg_pwr_descr_t confpwr_descr; usba_if_pwr_descr_t ifpwr_descr; uint8_t cfg_attrib; int i, lvl, rval; int n_prop = 0; uint8_t *ptr; char *drvname; char str[USBA_POWER_STR_SIZE]; char *pm_comp[USBA_N_PMCOMP]; USBA_CHECK_CONTEXT(); if (usb_is_pm_enabled(dip) != USB_SUCCESS) { return (USB_FAILURE); } /* Obtain the raw configuration descriptor */ usb_cfg = usb_get_raw_cfg_data(dip, &cfg_length); /* get configuration descriptor, must succceed */ rval = usb_parse_cfg_descr(usb_cfg, cfg_length, &cfg_descr, USB_CFG_DESCR_SIZE); ASSERT(rval == USB_CFG_DESCR_SIZE); cfg_attrib = cfg_descr.bmAttributes; *pwr_states = 0; /* * Now start creating the pm-components strings */ drvname = (char *)ddi_driver_name(dip); (void) snprintf(str, USBA_POWER_STR_SIZE, "NAME= %s%d Power", drvname, ddi_get_instance(dip)); pm_comp[n_prop] = kmem_zalloc(strlen(str) + 1, KM_SLEEP); (void) strcpy(pm_comp[n_prop++], str); /* * if the device is bus powered we look at the bBusPowerSavingDx * fields else we look at bSelfPowerSavingDx fields. * OS and USB power states are numerically reversed, * * Here is the mapping :- * OS State USB State * 0 D3 (minimal or no power) * 1 D2 * 2 D1 * 3 D0 (Full power) * * if we own the whole device, we look at the config pwr descr * else at the interface pwr descr. */ if (usb_owns_device(dip)) { /* Parse the configuration power descriptor */ rval = usba_parse_cfg_pwr_descr(usb_cfg, cfg_length, &confpwr_descr, USBA_CFG_PWR_DESCR_SIZE); if (rval != USBA_CFG_PWR_DESCR_SIZE) { USB_DPRINTF_L2(DPRINT_MASK_USBAI, usbai_log_handle, "usb_create_pm_components: " "usb_parse_cfg_pwr_descr returns length of %d, " "expecting %d", rval, USBA_CFG_PWR_DESCR_SIZE); return (USB_FAILURE); } if (cfg_attrib & USB_CFG_ATTR_SELFPWR) { ptr = &confpwr_descr.bSelfPowerSavingD3; } else { ptr = &confpwr_descr.bBusPowerSavingD3; } } else { /* Parse the interface power descriptor */ rval = usba_parse_if_pwr_descr(usb_cfg, cfg_length, usba_get_ifno(dip), /* interface index */ 0, /* XXXX alt interface index */ &ifpwr_descr, USBA_IF_PWR_DESCR_SIZE); if (rval != USBA_IF_PWR_DESCR_SIZE) { USB_DPRINTF_L2(DPRINT_MASK_USBAI, usbai_log_handle, "usb_create_pm_components: " "usb_parse_if_pwr_descr " "returns length of %d, " "expecting %d", rval, USBA_CFG_PWR_DESCR_SIZE); return (USB_FAILURE); } if (cfg_attrib & USB_CFG_ATTR_SELFPWR) { ptr = &ifpwr_descr.bSelfPowerSavingD3; } else { ptr = &ifpwr_descr.bBusPowerSavingD3; } } /* walk thru levels and create prop level=name strings */ for (lvl = USB_DEV_OS_PWR_0; lvl <= USB_DEV_OS_PWR_3; lvl++) { if (*ptr || (lvl == USB_DEV_OS_PWR_3)) { (void) snprintf(str, USBA_POWER_STR_SIZE, "%d=USB D%d State", lvl, USB_DEV_OS_PWR2USB_PWR(lvl)); pm_comp[n_prop] = kmem_zalloc(strlen(str) + 1, KM_SLEEP); (void) strcpy(pm_comp[n_prop++], str); *pwr_states |= USB_DEV_PWRMASK(lvl); } ptr -= 2; /* skip to the next power state */ } USB_DPRINTF_L3(DPRINT_MASK_USBAI, usbai_log_handle, "usb_create_pm_components: pwr_states: %x", *pwr_states); /* now create the actual components */ rval = ddi_prop_update_string_array(DDI_DEV_T_NONE, dip, "pm-components", pm_comp, n_prop); if (rval == DDI_PROP_SUCCESS) { rval = USB_SUCCESS; } else { rval = USB_FAILURE; } /* display & delete properties */ USB_DPRINTF_L3(DPRINT_MASK_USBAI, usbai_log_handle, "usb_create_pm_components: The properties are:"); for (i = 0; i < n_prop; i++) { USB_DPRINTF_L3(DPRINT_MASK_USBAI, usbai_log_handle, "\t%s", pm_comp[i]); kmem_free(pm_comp[i], strlen(pm_comp[i]) + 1); } return (rval); } /* * Generic Functions to set the power level of any usb device * * Since OS and USB power states are numerically reverse, * Here is the mapping :- * OS State USB State * 0 D3 (minimal or no power) * 1 D2 * 2 D1 * 3 D0 (Full power) */ /* set device power level to 0 (full power) */ /*ARGSUSED*/ int usb_set_device_pwrlvl0(dev_info_t *dip) { USB_DPRINTF_L4(DPRINT_MASK_USBAI, usbai_log_handle, "usb_set_device_pwrlvl0 : Not Yet Implemented"); return (USB_SUCCESS); } /* set device power level to 1 */ /*ARGSUSED*/ int usb_set_device_pwrlvl1(dev_info_t *dip) { USB_DPRINTF_L4(DPRINT_MASK_USBAI, usbai_log_handle, "usb_set_device_pwrlvl1 : Not Yet Implemented"); return (USB_SUCCESS); } /* set device power level to 2 */ /*ARGSUSED*/ int usb_set_device_pwrlvl2(dev_info_t *dip) { USB_DPRINTF_L4(DPRINT_MASK_USBAI, usbai_log_handle, "usb_set_device_pwrlvl2 : Not Yet Implemented"); return (USB_SUCCESS); } /* set device power level to 3 */ /*ARGSUSED*/ int usb_set_device_pwrlvl3(dev_info_t *dip) { USB_DPRINTF_L4(DPRINT_MASK_USBAI, usbai_log_handle, "usb_set_device_pwrlvl3 : Not Yet Implemented"); return (USB_SUCCESS); } /* * USB event management */ typedef void (*peh_t)(dev_info_t *, ddi_eventcookie_t, void *, void *); /* * usb_register_hotplug_cbs: * Register to get callbacks for hotplug events */ /*ARGSUSED*/ int usb_register_hotplug_cbs(dev_info_t *dip, int (*disconnect_event_handler)(dev_info_t *), int (*reconnect_event_handler)(dev_info_t *)) { usba_device_t *usba_device; usba_evdata_t *evdata; if ((dip == NULL) || (disconnect_event_handler == NULL) || (reconnect_event_handler == NULL)) { USB_DPRINTF_L2(DPRINT_MASK_USBAI, usbai_log_handle, "usb_register_hotplug_cbs: Bad argument(s)"); return (USB_FAILURE); } USB_DPRINTF_L4(DPRINT_MASK_USBAI, usbai_log_handle, "usb_register_hotplug_cbs: entry"); /* * The event list searches by ddi_get_eventcookie calls below, go * through hubd and so do not apply to host controllers. */ ASSERT(!usba_is_root_hub(dip)); usba_device = usba_get_usba_device(dip); evdata = usba_get_evdata(dip); if (usba_device->rm_cookie == NULL) { if (ddi_get_eventcookie(dip, DDI_DEVI_REMOVE_EVENT, &usba_device->rm_cookie) != DDI_SUCCESS) { USB_DPRINTF_L2(DPRINT_MASK_USBAI, usbai_log_handle, "usb_register_hotplug_cbs: get rm cookie failed"); goto fail; } } if (ddi_add_event_handler(dip, usba_device->rm_cookie, (peh_t)disconnect_event_handler, NULL, &evdata->ev_rm_cb_id) != DDI_SUCCESS) { USB_DPRINTF_L2(DPRINT_MASK_USBAI, usbai_log_handle, "usb_register_hotplug_cbs: add disconnect handler failed"); goto fail; } if (usba_device->ins_cookie == NULL) { if (ddi_get_eventcookie(dip, DDI_DEVI_INSERT_EVENT, &usba_device->ins_cookie) != DDI_SUCCESS) { USB_DPRINTF_L2(DPRINT_MASK_USBAI, usbai_log_handle, "usb_register_hotplug_cbs: get ins cookie failed"); goto fail; } } if (ddi_add_event_handler(dip, usba_device->ins_cookie, (peh_t)reconnect_event_handler, NULL, &evdata->ev_ins_cb_id) != DDI_SUCCESS) { USB_DPRINTF_L2(DPRINT_MASK_USBAI, usbai_log_handle, "usb_register_hotplug_cbs: add reconnect handler failed"); goto fail; } mutex_enter(&usba_device->usb_mutex); usba_device->usb_client_flags[usba_get_ifno(dip)] |= USBA_CLIENT_FLAG_EV_CBS; usba_device->usb_client_ev_cb_list->dip = dip; mutex_exit(&usba_device->usb_mutex); return (USB_SUCCESS); fail: usb_unregister_hotplug_cbs(dip); return (USB_FAILURE); } /* * usb_unregister_hotplug_cbs: * Unregister hotplug callbacks */ /*ARGSUSED*/ void usb_unregister_hotplug_cbs(dev_info_t *dip) { usb_unregister_event_cbs(dip, NULL); } /* * usb_register_event_cbs: * Register to get callbacks for USB events */ /*ARGSUSED*/ int usb_register_event_cbs(dev_info_t *dip, usb_event_t *usb_evdata, usb_flags_t flags) { usba_device_t *usba_device; usba_evdata_t *evdata; if ((dip == NULL) || (usb_evdata == NULL)) { return (USB_FAILURE); } /* * The event list searches by ddi_get_eventcookie calls below, go * through hubd and so do not apply to host controllers. */ ASSERT(!usba_is_root_hub(dip)); usba_device = usba_get_usba_device(dip); evdata = usba_get_evdata(dip); if (usb_evdata->disconnect_event_handler != NULL) { if (usba_device->rm_cookie == NULL) { if (ddi_get_eventcookie(dip, DDI_DEVI_REMOVE_EVENT, &usba_device->rm_cookie) != DDI_SUCCESS) { goto fail; } } if (ddi_add_event_handler(dip, usba_device->rm_cookie, (peh_t)usb_evdata->disconnect_event_handler, NULL, &evdata->ev_rm_cb_id) != DDI_SUCCESS) { goto fail; } } if (usb_evdata->reconnect_event_handler != NULL) { if (usba_device->ins_cookie == NULL) { if (ddi_get_eventcookie(dip, DDI_DEVI_INSERT_EVENT, &usba_device->ins_cookie) != DDI_SUCCESS) { goto fail; } } if (ddi_add_event_handler(dip, usba_device->ins_cookie, (peh_t)usb_evdata->reconnect_event_handler, NULL, &evdata->ev_ins_cb_id) != DDI_SUCCESS) { goto fail; } } if (usb_evdata->post_resume_event_handler != NULL) { if (usba_device->resume_cookie == NULL) { if (ddi_get_eventcookie(dip, USBA_POST_RESUME_EVENT, &usba_device->resume_cookie) != DDI_SUCCESS) { goto fail; } } if (ddi_add_event_handler(dip, usba_device->resume_cookie, (peh_t)usb_evdata->post_resume_event_handler, NULL, &evdata->ev_resume_cb_id) != DDI_SUCCESS) { goto fail; } } if (usb_evdata->pre_suspend_event_handler != NULL) { if (usba_device->suspend_cookie == NULL) { if (ddi_get_eventcookie(dip, USBA_PRE_SUSPEND_EVENT, &usba_device->suspend_cookie) != DDI_SUCCESS) { goto fail; } } if (ddi_add_event_handler(dip, usba_device->suspend_cookie, (peh_t)usb_evdata->pre_suspend_event_handler, NULL, &evdata->ev_suspend_cb_id) != DDI_SUCCESS) { goto fail; } } mutex_enter(&usba_device->usb_mutex); usba_device->usb_client_flags[usba_get_ifno(dip)] |= USBA_CLIENT_FLAG_EV_CBS; usba_device->usb_client_ev_cb_list->dip = dip; usba_device->usb_client_ev_cb_list->ev_data = usb_evdata; mutex_exit(&usba_device->usb_mutex); return (USB_SUCCESS); fail: usb_unregister_event_cbs(dip, usb_evdata); return (USB_FAILURE); } /* * usb_unregister_event_cbs: * Unregister all event callbacks */ /*ARGSUSED*/ void usb_unregister_event_cbs(dev_info_t *dip, usb_event_t *usb_evdata) { usba_evdata_t *evdata; usba_device_t *usba_device = usba_get_usba_device(dip); evdata = usba_get_evdata(dip); if (evdata->ev_rm_cb_id != NULL) { (void) ddi_remove_event_handler(evdata->ev_rm_cb_id); evdata->ev_rm_cb_id = NULL; } if (evdata->ev_ins_cb_id != NULL) { (void) ddi_remove_event_handler(evdata->ev_ins_cb_id); evdata->ev_ins_cb_id = NULL; } if (evdata->ev_suspend_cb_id != NULL) { (void) ddi_remove_event_handler(evdata->ev_suspend_cb_id); evdata->ev_suspend_cb_id = NULL; } if (evdata->ev_resume_cb_id != NULL) { (void) ddi_remove_event_handler(evdata->ev_resume_cb_id); evdata->ev_resume_cb_id = NULL; } mutex_enter(&usba_device->usb_mutex); usba_device->usb_client_flags[usba_get_ifno(dip)] &= ~USBA_CLIENT_FLAG_EV_CBS; mutex_exit(&usba_device->usb_mutex); } int usb_reset_device(dev_info_t *dip, usb_dev_reset_lvl_t reset_level) { return (usba_hubdi_reset_device(dip, reset_level)); }