/* gamma_dma.c -- DMA support for GMX 2000 -*- linux-c -*- * Created: Fri Mar 19 14:30:16 1999 by faith@precisioninsight.com * * Copyright 1999 Precision Insight, Inc., Cedar Park, Texas. * Copyright 2000 VA Linux Systems, Inc., Sunnyvale, California. * All Rights Reserved. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice (including the next * paragraph) shall be included in all copies or substantial portions of the * Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * PRECISION INSIGHT AND/OR ITS SUPPLIERS BE LIABLE FOR ANY CLAIM, DAMAGES OR * OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER * DEALINGS IN THE SOFTWARE. * * Authors: * Rickard E. (Rik) Faith * */ #define __NO_VERSION__ #include "drmP.h" #include "gamma_drv.h" #include /* For task queue support */ /* WARNING!!! MAGIC NUMBER!!! The number of regions already added to the kernel must be specified here. Currently, the number is 2. This must match the order the X server uses for instantiating register regions , or must be passed in a new ioctl. */ #define GAMMA_REG(reg) \ (2 \ + ((reg < 0x1000) \ ? 0 \ : ((reg < 0x10000) ? 1 : ((reg < 0x11000) ? 2 : 3)))) #define GAMMA_OFF(reg) \ ((reg < 0x1000) \ ? reg \ : ((reg < 0x10000) \ ? (reg - 0x1000) \ : ((reg < 0x11000) \ ? (reg - 0x10000) \ : (reg - 0x11000)))) #define GAMMA_BASE(reg) ((unsigned long)dev->maplist[GAMMA_REG(reg)]->handle) #define GAMMA_ADDR(reg) (GAMMA_BASE(reg) + GAMMA_OFF(reg)) #define GAMMA_DEREF(reg) *(__volatile__ int *)GAMMA_ADDR(reg) #define GAMMA_READ(reg) GAMMA_DEREF(reg) #define GAMMA_WRITE(reg,val) do { GAMMA_DEREF(reg) = val; } while (0) #define GAMMA_BROADCASTMASK 0x9378 #define GAMMA_COMMANDINTENABLE 0x0c48 #define GAMMA_DMAADDRESS 0x0028 #define GAMMA_DMACOUNT 0x0030 #define GAMMA_FILTERMODE 0x8c00 #define GAMMA_GCOMMANDINTFLAGS 0x0c50 #define GAMMA_GCOMMANDMODE 0x0c40 #define GAMMA_GCOMMANDSTATUS 0x0c60 #define GAMMA_GDELAYTIMER 0x0c38 #define GAMMA_GDMACONTROL 0x0060 #define GAMMA_GINTENABLE 0x0808 #define GAMMA_GINTFLAGS 0x0810 #define GAMMA_INFIFOSPACE 0x0018 #define GAMMA_OUTFIFOWORDS 0x0020 #define GAMMA_OUTPUTFIFO 0x2000 #define GAMMA_SYNC 0x8c40 #define GAMMA_SYNC_TAG 0x0188 static inline void gamma_dma_dispatch(drm_device_t *dev, unsigned long address, unsigned long length) { GAMMA_WRITE(GAMMA_DMAADDRESS, virt_to_phys((void *)address)); while (GAMMA_READ(GAMMA_GCOMMANDSTATUS) != 4) ; GAMMA_WRITE(GAMMA_DMACOUNT, length / 4); } static inline void gamma_dma_quiescent_single(drm_device_t *dev) { while (GAMMA_READ(GAMMA_DMACOUNT)) ; while (GAMMA_READ(GAMMA_INFIFOSPACE) < 3) ; GAMMA_WRITE(GAMMA_FILTERMODE, 1 << 10); GAMMA_WRITE(GAMMA_SYNC, 0); do { while (!GAMMA_READ(GAMMA_OUTFIFOWORDS)) ; } while (GAMMA_READ(GAMMA_OUTPUTFIFO) != GAMMA_SYNC_TAG); } static inline void gamma_dma_quiescent_dual(drm_device_t *dev) { while (GAMMA_READ(GAMMA_DMACOUNT)) ; while (GAMMA_READ(GAMMA_INFIFOSPACE) < 3) ; GAMMA_WRITE(GAMMA_BROADCASTMASK, 3); GAMMA_WRITE(GAMMA_FILTERMODE, 1 << 10); GAMMA_WRITE(GAMMA_SYNC, 0); /* Read from first MX */ do { while (!GAMMA_READ(GAMMA_OUTFIFOWORDS)) ; } while (GAMMA_READ(GAMMA_OUTPUTFIFO) != GAMMA_SYNC_TAG); /* Read from second MX */ do { while (!GAMMA_READ(GAMMA_OUTFIFOWORDS + 0x10000)) ; } while (GAMMA_READ(GAMMA_OUTPUTFIFO + 0x10000) != GAMMA_SYNC_TAG); } static inline void gamma_dma_ready(drm_device_t *dev) { while (GAMMA_READ(GAMMA_DMACOUNT)) ; } static inline int gamma_dma_is_ready(drm_device_t *dev) { return !GAMMA_READ(GAMMA_DMACOUNT); } static void gamma_dma_service(int irq, void *device, struct pt_regs *regs) { drm_device_t *dev = (drm_device_t *)device; drm_device_dma_t *dma = dev->dma; atomic_inc(&dev->total_irq); GAMMA_WRITE(GAMMA_GDELAYTIMER, 0xc350/2); /* 0x05S */ GAMMA_WRITE(GAMMA_GCOMMANDINTFLAGS, 8); GAMMA_WRITE(GAMMA_GINTFLAGS, 0x2001); if (gamma_dma_is_ready(dev)) { /* Free previous buffer */ if (test_and_set_bit(0, &dev->dma_flag)) { atomic_inc(&dma->total_missed_free); return; } if (dma->this_buffer) { drm_free_buffer(dev, dma->this_buffer); dma->this_buffer = NULL; } clear_bit(0, &dev->dma_flag); /* Dispatch new buffer */ queue_task(&dev->tq, &tq_immediate); mark_bh(IMMEDIATE_BH); } } /* Only called by gamma_dma_schedule. */ static int gamma_do_dma(drm_device_t *dev, int locked) { unsigned long address; unsigned long length; drm_buf_t *buf; int retcode = 0; drm_device_dma_t *dma = dev->dma; #if DRM_DMA_HISTOGRAM cycles_t dma_start, dma_stop; #endif if (test_and_set_bit(0, &dev->dma_flag)) { atomic_inc(&dma->total_missed_dma); return -EBUSY; } #if DRM_DMA_HISTOGRAM dma_start = get_cycles(); #endif if (!dma->next_buffer) { DRM_ERROR("No next_buffer\n"); clear_bit(0, &dev->dma_flag); return -EINVAL; } buf = dma->next_buffer; address = (unsigned long)buf->address; length = buf->used; DRM_DEBUG("context %d, buffer %d (%ld bytes)\n", buf->context, buf->idx, length); if (buf->list == DRM_LIST_RECLAIM) { drm_clear_next_buffer(dev); drm_free_buffer(dev, buf); clear_bit(0, &dev->dma_flag); return -EINVAL; } if (!length) { DRM_ERROR("0 length buffer\n"); drm_clear_next_buffer(dev); drm_free_buffer(dev, buf); clear_bit(0, &dev->dma_flag); return 0; } if (!gamma_dma_is_ready(dev)) { clear_bit(0, &dev->dma_flag); return -EBUSY; } if (buf->while_locked) { if (!_DRM_LOCK_IS_HELD(dev->lock.hw_lock->lock)) { DRM_ERROR("Dispatching buffer %d from pid %d" " \"while locked\", but no lock held\n", buf->idx, buf->pid); } } else { if (!locked && !drm_lock_take(&dev->lock.hw_lock->lock, DRM_KERNEL_CONTEXT)) { atomic_inc(&dma->total_missed_lock); clear_bit(0, &dev->dma_flag); return -EBUSY; } } if (dev->last_context != buf->context && !(dev->queuelist[buf->context]->flags & _DRM_CONTEXT_PRESERVED)) { /* PRE: dev->last_context != buf->context */ if (drm_context_switch(dev, dev->last_context, buf->context)) { drm_clear_next_buffer(dev); drm_free_buffer(dev, buf); } retcode = -EBUSY; goto cleanup; /* POST: we will wait for the context switch and will dispatch on a later call when dev->last_context == buf->context. NOTE WE HOLD THE LOCK THROUGHOUT THIS TIME! */ } drm_clear_next_buffer(dev); buf->pending = 1; buf->waiting = 0; buf->list = DRM_LIST_PEND; #if DRM_DMA_HISTOGRAM buf->time_dispatched = get_cycles(); #endif gamma_dma_dispatch(dev, address, length); drm_free_buffer(dev, dma->this_buffer); dma->this_buffer = buf; atomic_add(length, &dma->total_bytes); atomic_inc(&dma->total_dmas); if (!buf->while_locked && !dev->context_flag && !locked) { if (drm_lock_free(dev, &dev->lock.hw_lock->lock, DRM_KERNEL_CONTEXT)) { DRM_ERROR("\n"); } } cleanup: clear_bit(0, &dev->dma_flag); #if DRM_DMA_HISTOGRAM dma_stop = get_cycles(); atomic_inc(&dev->histo.dma[drm_histogram_slot(dma_stop - dma_start)]); #endif return retcode; } static void gamma_dma_schedule_timer_wrapper(unsigned long dev) { gamma_dma_schedule((drm_device_t *)dev, 0); } static void gamma_dma_schedule_tq_wrapper(void *dev) { gamma_dma_schedule(dev, 0); } int gamma_dma_schedule(drm_device_t *dev, int locked) { int next; drm_queue_t *q; drm_buf_t *buf; int retcode = 0; int processed = 0; int missed; int expire = 20; drm_device_dma_t *dma = dev->dma; #if DRM_DMA_HISTOGRAM cycles_t schedule_start; #endif if (test_and_set_bit(0, &dev->interrupt_flag)) { /* Not reentrant */ atomic_inc(&dma->total_missed_sched); return -EBUSY; } missed = atomic_read(&dma->total_missed_sched); #if DRM_DMA_HISTOGRAM schedule_start = get_cycles(); #endif again: if (dev->context_flag) { clear_bit(0, &dev->interrupt_flag); return -EBUSY; } if (dma->next_buffer) { /* Unsent buffer that was previously selected, but that couldn't be sent because the lock could not be obtained or the DMA engine wasn't ready. Try again. */ atomic_inc(&dma->total_tried); if (!(retcode = gamma_do_dma(dev, locked))) { atomic_inc(&dma->total_hit); ++processed; } } else { do { next = drm_select_queue(dev, gamma_dma_schedule_timer_wrapper); if (next >= 0) { q = dev->queuelist[next]; buf = drm_waitlist_get(&q->waitlist); dma->next_buffer = buf; dma->next_queue = q; if (buf && buf->list == DRM_LIST_RECLAIM) { drm_clear_next_buffer(dev); drm_free_buffer(dev, buf); } } } while (next >= 0 && !dma->next_buffer); if (dma->next_buffer) { if (!(retcode = gamma_do_dma(dev, locked))) { ++processed; } } } if (--expire) { if (missed != atomic_read(&dma->total_missed_sched)) { atomic_inc(&dma->total_lost); if (gamma_dma_is_ready(dev)) goto again; } if (processed && gamma_dma_is_ready(dev)) { atomic_inc(&dma->total_lost); processed = 0; goto again; } } clear_bit(0, &dev->interrupt_flag); #if DRM_DMA_HISTOGRAM atomic_inc(&dev->histo.schedule[drm_histogram_slot(get_cycles() - schedule_start)]); #endif return retcode; } static int gamma_dma_priority(drm_device_t *dev, drm_dma_t *d) { unsigned long address; unsigned long length; int must_free = 0; int retcode = 0; int i; int idx; drm_buf_t *buf; drm_buf_t *last_buf = NULL; drm_device_dma_t *dma = dev->dma; DECLARE_WAITQUEUE(entry, current); /* Turn off interrupt handling */ while (test_and_set_bit(0, &dev->interrupt_flag)) { schedule(); if (signal_pending(current)) return -EINTR; } if (!(d->flags & _DRM_DMA_WHILE_LOCKED)) { while (!drm_lock_take(&dev->lock.hw_lock->lock, DRM_KERNEL_CONTEXT)) { schedule(); if (signal_pending(current)) { clear_bit(0, &dev->interrupt_flag); return -EINTR; } } ++must_free; } atomic_inc(&dma->total_prio); for (i = 0; i < d->send_count; i++) { idx = d->send_indices[i]; if (idx < 0 || idx >= dma->buf_count) { DRM_ERROR("Index %d (of %d max)\n", d->send_indices[i], dma->buf_count - 1); continue; } buf = dma->buflist[ idx ]; if (buf->pid != current->pid) { DRM_ERROR("Process %d using buffer owned by %d\n", current->pid, buf->pid); retcode = -EINVAL; goto cleanup; } if (buf->list != DRM_LIST_NONE) { DRM_ERROR("Process %d using %d's buffer on list %d\n", current->pid, buf->pid, buf->list); retcode = -EINVAL; goto cleanup; } /* This isn't a race condition on buf->list, since our concern is the buffer reclaim during the time the process closes the /dev/drm? handle, so it can't also be doing DMA. */ buf->list = DRM_LIST_PRIO; buf->used = d->send_sizes[i]; buf->context = d->context; buf->while_locked = d->flags & _DRM_DMA_WHILE_LOCKED; address = (unsigned long)buf->address; length = buf->used; if (!length) { DRM_ERROR("0 length buffer\n"); } if (buf->pending) { DRM_ERROR("Sending pending buffer:" " buffer %d, offset %d\n", d->send_indices[i], i); retcode = -EINVAL; goto cleanup; } if (buf->waiting) { DRM_ERROR("Sending waiting buffer:" " buffer %d, offset %d\n", d->send_indices[i], i); retcode = -EINVAL; goto cleanup; } buf->pending = 1; if (dev->last_context != buf->context && !(dev->queuelist[buf->context]->flags & _DRM_CONTEXT_PRESERVED)) { add_wait_queue(&dev->context_wait, &entry); current->state = TASK_INTERRUPTIBLE; /* PRE: dev->last_context != buf->context */ drm_context_switch(dev, dev->last_context, buf->context); /* POST: we will wait for the context switch and will dispatch on a later call when dev->last_context == buf->context. NOTE WE HOLD THE LOCK THROUGHOUT THIS TIME! */ schedule(); current->state = TASK_RUNNING; remove_wait_queue(&dev->context_wait, &entry); if (signal_pending(current)) { retcode = -EINTR; goto cleanup; } if (dev->last_context != buf->context) { DRM_ERROR("Context mismatch: %d %d\n", dev->last_context, buf->context); } } #if DRM_DMA_HISTOGRAM buf->time_queued = get_cycles(); buf->time_dispatched = buf->time_queued; #endif gamma_dma_dispatch(dev, address, length); atomic_add(length, &dma->total_bytes); atomic_inc(&dma->total_dmas); if (last_buf) { drm_free_buffer(dev, last_buf); } last_buf = buf; } cleanup: if (last_buf) { gamma_dma_ready(dev); drm_free_buffer(dev, last_buf); } if (must_free && !dev->context_flag) { if (drm_lock_free(dev, &dev->lock.hw_lock->lock, DRM_KERNEL_CONTEXT)) { DRM_ERROR("\n"); } } clear_bit(0, &dev->interrupt_flag); return retcode; } static int gamma_dma_send_buffers(drm_device_t *dev, drm_dma_t *d) { DECLARE_WAITQUEUE(entry, current); drm_buf_t *last_buf = NULL; int retcode = 0; drm_device_dma_t *dma = dev->dma; if (d->flags & _DRM_DMA_BLOCK) { last_buf = dma->buflist[d->send_indices[d->send_count-1]]; add_wait_queue(&last_buf->dma_wait, &entry); } if ((retcode = drm_dma_enqueue(dev, d))) { if (d->flags & _DRM_DMA_BLOCK) remove_wait_queue(&last_buf->dma_wait, &entry); return retcode; } gamma_dma_schedule(dev, 0); if (d->flags & _DRM_DMA_BLOCK) { DRM_DEBUG("%d waiting\n", current->pid); for (;;) { current->state = TASK_INTERRUPTIBLE; if (!last_buf->waiting && !last_buf->pending) break; /* finished */ schedule(); if (signal_pending(current)) { retcode = -EINTR; /* Can't restart */ break; } } current->state = TASK_RUNNING; DRM_DEBUG("%d running\n", current->pid); remove_wait_queue(&last_buf->dma_wait, &entry); if (!retcode || (last_buf->list==DRM_LIST_PEND && !last_buf->pending)) { if (!waitqueue_active(&last_buf->dma_wait)) { drm_free_buffer(dev, last_buf); } } if (retcode) { DRM_ERROR("ctx%d w%d p%d c%d i%d l%d %d/%d\n", d->context, last_buf->waiting, last_buf->pending, DRM_WAITCOUNT(dev, d->context), last_buf->idx, last_buf->list, last_buf->pid, current->pid); } } return retcode; } int gamma_dma(struct inode *inode, struct file *filp, unsigned int cmd, unsigned long arg) { drm_file_t *priv = filp->private_data; drm_device_t *dev = priv->dev; drm_device_dma_t *dma = dev->dma; int retcode = 0; drm_dma_t d; if (copy_from_user(&d, (drm_dma_t *)arg, sizeof(d))) return -EFAULT; DRM_DEBUG("%d %d: %d send, %d req\n", current->pid, d.context, d.send_count, d.request_count); if (d.context == DRM_KERNEL_CONTEXT || d.context >= dev->queue_slots) { DRM_ERROR("Process %d using context %d\n", current->pid, d.context); return -EINVAL; } if (d.send_count < 0 || d.send_count > dma->buf_count) { DRM_ERROR("Process %d trying to send %d buffers (of %d max)\n", current->pid, d.send_count, dma->buf_count); return -EINVAL; } if (d.request_count < 0 || d.request_count > dma->buf_count) { DRM_ERROR("Process %d trying to get %d buffers (of %d max)\n", current->pid, d.request_count, dma->buf_count); return -EINVAL; } if (d.send_count) { if (d.flags & _DRM_DMA_PRIORITY) retcode = gamma_dma_priority(dev, &d); else retcode = gamma_dma_send_buffers(dev, &d); } d.granted_count = 0; if (!retcode && d.request_count) { retcode = drm_dma_get_buffers(dev, &d); } DRM_DEBUG("%d returning, granted = %d\n", current->pid, d.granted_count); if (copy_to_user((drm_dma_t *)arg, &d, sizeof(d))) return -EFAULT; return retcode; } int gamma_irq_install(drm_device_t *dev, int irq) { int retcode; if (!irq) return -EINVAL; down(&dev->struct_sem); if (dev->irq) { up(&dev->struct_sem); return -EBUSY; } dev->irq = irq; up(&dev->struct_sem); DRM_DEBUG("%d\n", irq); dev->context_flag = 0; dev->interrupt_flag = 0; dev->dma_flag = 0; dev->dma->next_buffer = NULL; dev->dma->next_queue = NULL; dev->dma->this_buffer = NULL; INIT_LIST_HEAD(&dev->tq.list); dev->tq.sync = 0; dev->tq.routine = gamma_dma_schedule_tq_wrapper; dev->tq.data = dev; /* Before installing handler */ GAMMA_WRITE(GAMMA_GCOMMANDMODE, 0); GAMMA_WRITE(GAMMA_GDMACONTROL, 0); /* Install handler */ if ((retcode = request_irq(dev->irq, gamma_dma_service, 0, dev->devname, dev))) { down(&dev->struct_sem); dev->irq = 0; up(&dev->struct_sem); return retcode; } /* After installing handler */ GAMMA_WRITE(GAMMA_GINTENABLE, 0x2001); GAMMA_WRITE(GAMMA_COMMANDINTENABLE, 0x0008); GAMMA_WRITE(GAMMA_GDELAYTIMER, 0x39090); return 0; } int gamma_irq_uninstall(drm_device_t *dev) { int irq; down(&dev->struct_sem); irq = dev->irq; dev->irq = 0; up(&dev->struct_sem); if (!irq) return -EINVAL; DRM_DEBUG("%d\n", irq); GAMMA_WRITE(GAMMA_GDELAYTIMER, 0); GAMMA_WRITE(GAMMA_COMMANDINTENABLE, 0); GAMMA_WRITE(GAMMA_GINTENABLE, 0); free_irq(irq, dev); return 0; } int gamma_control(struct inode *inode, struct file *filp, unsigned int cmd, unsigned long arg) { drm_file_t *priv = filp->private_data; drm_device_t *dev = priv->dev; drm_control_t ctl; int retcode; if (copy_from_user(&ctl, (drm_control_t *)arg, sizeof(ctl))) return -EFAULT; switch (ctl.func) { case DRM_INST_HANDLER: if ((retcode = gamma_irq_install(dev, ctl.irq))) return retcode; break; case DRM_UNINST_HANDLER: if ((retcode = gamma_irq_uninstall(dev))) return retcode; break; default: return -EINVAL; } return 0; } int gamma_lock(struct inode *inode, struct file *filp, unsigned int cmd, unsigned long arg) { drm_file_t *priv = filp->private_data; drm_device_t *dev = priv->dev; DECLARE_WAITQUEUE(entry, current); int ret = 0; drm_lock_t lock; drm_queue_t *q; #if DRM_DMA_HISTOGRAM cycles_t start; dev->lck_start = start = get_cycles(); #endif if (copy_from_user(&lock, (drm_lock_t *)arg, sizeof(lock))) return -EFAULT; if (lock.context == DRM_KERNEL_CONTEXT) { DRM_ERROR("Process %d using kernel context %d\n", current->pid, lock.context); return -EINVAL; } DRM_DEBUG("%d (pid %d) requests lock (0x%08x), flags = 0x%08x\n", lock.context, current->pid, dev->lock.hw_lock->lock, lock.flags); if (lock.context < 0 || lock.context >= dev->queue_count) return -EINVAL; q = dev->queuelist[lock.context]; ret = drm_flush_block_and_flush(dev, lock.context, lock.flags); if (!ret) { if (_DRM_LOCKING_CONTEXT(dev->lock.hw_lock->lock) != lock.context) { long j = jiffies - dev->lock.lock_time; if (j > 0 && j <= DRM_LOCK_SLICE) { /* Can't take lock if we just had it and there is contention. */ current->state = TASK_INTERRUPTIBLE; schedule_timeout(j); } } add_wait_queue(&dev->lock.lock_queue, &entry); for (;;) { current->state = TASK_INTERRUPTIBLE; if (!dev->lock.hw_lock) { /* Device has been unregistered */ ret = -EINTR; break; } if (drm_lock_take(&dev->lock.hw_lock->lock, lock.context)) { dev->lock.pid = current->pid; dev->lock.lock_time = jiffies; atomic_inc(&dev->total_locks); atomic_inc(&q->total_locks); break; /* Got lock */ } /* Contention */ atomic_inc(&dev->total_sleeps); schedule(); if (signal_pending(current)) { ret = -ERESTARTSYS; break; } } current->state = TASK_RUNNING; remove_wait_queue(&dev->lock.lock_queue, &entry); } drm_flush_unblock(dev, lock.context, lock.flags); /* cleanup phase */ if (!ret) { sigemptyset(&dev->sigmask); sigaddset(&dev->sigmask, SIGSTOP); sigaddset(&dev->sigmask, SIGTSTP); sigaddset(&dev->sigmask, SIGTTIN); sigaddset(&dev->sigmask, SIGTTOU); dev->sigdata.context = lock.context; dev->sigdata.lock = dev->lock.hw_lock; block_all_signals(drm_notifier, &dev->sigdata, &dev->sigmask); if (lock.flags & _DRM_LOCK_READY) gamma_dma_ready(dev); if (lock.flags & _DRM_LOCK_QUIESCENT) { if (gamma_found() == 1) { gamma_dma_quiescent_single(dev); } else { gamma_dma_quiescent_dual(dev); } } } DRM_DEBUG("%d %s\n", lock.context, ret ? "interrupted" : "has lock"); #if DRM_DMA_HISTOGRAM atomic_inc(&dev->histo.lacq[drm_histogram_slot(get_cycles() - start)]); #endif return ret; }