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nvme-pci: Simplify interrupt allocation
The NVME PCI driver contains a tedious mechanism for interrupt allocation, which is necessary to adjust the number and size of interrupt sets to the maximum available number of interrupts which depends on the underlying PCI capabilities and the available CPU resources. It works around the former short comings of the PCI and core interrupt allocation mechanims in combination with interrupt sets. The PCI interrupt allocation function allows to provide a maximum and a minimum number of interrupts to be allocated and tries to allocate as many as possible. This worked without driver interaction as long as there was only a single set of interrupts to handle. With the addition of support for multiple interrupt sets in the generic affinity spreading logic, which is invoked from the PCI interrupt allocation, the adaptive loop in the PCI interrupt allocation did not work for multiple interrupt sets. The reason is that depending on the total number of interrupts which the PCI allocation adaptive loop tries to allocate in each step, the number and the size of the interrupt sets need to be adapted as well. Due to the way the interrupt sets support was implemented there was no way for the PCI interrupt allocation code or the core affinity spreading mechanism to invoke a driver specific function for adapting the interrupt sets configuration. As a consequence the driver had to implement another adaptive loop around the PCI interrupt allocation function and calling that with maximum and minimum interrupts set to the same value. This ensured that the allocation either succeeded or immediately failed without any attempt to adjust the number of interrupts in the PCI code. The core code now allows drivers to provide a callback to recalculate the number and the size of interrupt sets during PCI interrupt allocation, which in turn allows the PCI interrupt allocation function to be called in the same way as with a single set of interrupts. The PCI code handles the adaptive loop and the interrupt affinity spreading mechanism invokes the driver callback to adapt the interrupt set configuration to the current loop value. This replaces the adaptive loop in the driver completely. Implement the NVME specific callback which adjusts the interrupt sets configuration and remove the adaptive allocation loop. [ tglx: Simplify the callback further and restore the dropped adjustment of number of sets ] Signed-off-by: Ming Lei <ming.lei@redhat.com> Signed-off-by: Thomas Gleixner <tglx@linutronix.de> Acked-by: Marc Zyngier <marc.zyngier@arm.com> Cc: Christoph Hellwig <hch@lst.de> Cc: Bjorn Helgaas <helgaas@kernel.org> Cc: Jens Axboe <axboe@kernel.dk> Cc: linux-block@vger.kernel.org Cc: Sagi Grimberg <sagi@grimberg.me> Cc: linux-nvme@lists.infradead.org Cc: linux-pci@vger.kernel.org Cc: Keith Busch <keith.busch@intel.com> Cc: Sumit Saxena <sumit.saxena@broadcom.com> Cc: Kashyap Desai <kashyap.desai@broadcom.com> Cc: Shivasharan Srikanteshwara <shivasharan.srikanteshwara@broadcom.com> Link: https://lkml.kernel.org/r/20190216172228.602546658@linutronix.de
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@ -2041,41 +2041,42 @@ static int nvme_setup_host_mem(struct nvme_dev *dev)
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return ret;
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}
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/* irq_queues covers admin queue */
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static void nvme_calc_io_queues(struct nvme_dev *dev, unsigned int irq_queues)
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/*
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* nirqs is the number of interrupts available for write and read
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* queues. The core already reserved an interrupt for the admin queue.
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*/
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static void nvme_calc_irq_sets(struct irq_affinity *affd, unsigned int nrirqs)
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{
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unsigned int this_w_queues = write_queues;
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WARN_ON(!irq_queues);
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struct nvme_dev *dev = affd->priv;
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unsigned int nr_read_queues;
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/*
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* Setup read/write queue split, assign admin queue one independent
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* irq vector if irq_queues is > 1.
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* If there is no interupt available for queues, ensure that
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* the default queue is set to 1. The affinity set size is
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* also set to one, but the irq core ignores it for this case.
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*
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* If only one interrupt is available or 'write_queue' == 0, combine
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* write and read queues.
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*
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* If 'write_queues' > 0, ensure it leaves room for at least one read
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* queue.
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*/
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if (irq_queues <= 2) {
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dev->io_queues[HCTX_TYPE_DEFAULT] = 1;
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dev->io_queues[HCTX_TYPE_READ] = 0;
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return;
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}
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/*
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* If 'write_queues' is set, ensure it leaves room for at least
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* one read queue and one admin queue
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*/
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if (this_w_queues >= irq_queues)
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this_w_queues = irq_queues - 2;
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/*
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* If 'write_queues' is set to zero, reads and writes will share
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* a queue set.
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*/
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if (!this_w_queues) {
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dev->io_queues[HCTX_TYPE_DEFAULT] = irq_queues - 1;
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dev->io_queues[HCTX_TYPE_READ] = 0;
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if (!nrirqs) {
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nrirqs = 1;
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nr_read_queues = 0;
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} else if (nrirqs == 1 || !write_queues) {
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nr_read_queues = 0;
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} else if (write_queues >= nrirqs) {
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nr_read_queues = 1;
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} else {
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dev->io_queues[HCTX_TYPE_DEFAULT] = this_w_queues;
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dev->io_queues[HCTX_TYPE_READ] = irq_queues - this_w_queues - 1;
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nr_read_queues = nrirqs - write_queues;
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}
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dev->io_queues[HCTX_TYPE_DEFAULT] = nrirqs - nr_read_queues;
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affd->set_size[HCTX_TYPE_DEFAULT] = nrirqs - nr_read_queues;
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dev->io_queues[HCTX_TYPE_READ] = nr_read_queues;
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affd->set_size[HCTX_TYPE_READ] = nr_read_queues;
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affd->nr_sets = nr_read_queues ? 2 : 1;
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}
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static int nvme_setup_irqs(struct nvme_dev *dev, unsigned int nr_io_queues)
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@ -2083,10 +2084,9 @@ static int nvme_setup_irqs(struct nvme_dev *dev, unsigned int nr_io_queues)
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struct pci_dev *pdev = to_pci_dev(dev->dev);
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struct irq_affinity affd = {
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.pre_vectors = 1,
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.nr_sets = 2,
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.calc_sets = nvme_calc_irq_sets,
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.priv = dev,
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};
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unsigned int *irq_sets = affd.set_size;
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int result = 0;
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unsigned int irq_queues, this_p_queues;
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/*
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@ -2102,51 +2102,12 @@ static int nvme_setup_irqs(struct nvme_dev *dev, unsigned int nr_io_queues)
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}
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dev->io_queues[HCTX_TYPE_POLL] = this_p_queues;
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/*
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* For irq sets, we have to ask for minvec == maxvec. This passes
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* any reduction back to us, so we can adjust our queue counts and
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* IRQ vector needs.
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*/
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do {
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nvme_calc_io_queues(dev, irq_queues);
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irq_sets[0] = dev->io_queues[HCTX_TYPE_DEFAULT];
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irq_sets[1] = dev->io_queues[HCTX_TYPE_READ];
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if (!irq_sets[1])
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affd.nr_sets = 1;
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/* Initialize for the single interrupt case */
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dev->io_queues[HCTX_TYPE_DEFAULT] = 1;
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dev->io_queues[HCTX_TYPE_READ] = 0;
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/*
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* If we got a failure and we're down to asking for just
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* 1 + 1 queues, just ask for a single vector. We'll share
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* that between the single IO queue and the admin queue.
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* Otherwise, we assign one independent vector to admin queue.
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*/
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if (irq_queues > 1)
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irq_queues = irq_sets[0] + irq_sets[1] + 1;
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result = pci_alloc_irq_vectors_affinity(pdev, irq_queues,
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irq_queues,
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PCI_IRQ_ALL_TYPES | PCI_IRQ_AFFINITY, &affd);
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/*
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* Need to reduce our vec counts. If we get ENOSPC, the
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* platform should support mulitple vecs, we just need
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* to decrease our ask. If we get EINVAL, the platform
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* likely does not. Back down to ask for just one vector.
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*/
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if (result == -ENOSPC) {
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irq_queues--;
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if (!irq_queues)
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return result;
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continue;
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} else if (result == -EINVAL) {
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irq_queues = 1;
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continue;
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} else if (result <= 0)
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return -EIO;
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break;
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} while (1);
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return result;
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return pci_alloc_irq_vectors_affinity(pdev, 1, irq_queues,
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PCI_IRQ_ALL_TYPES | PCI_IRQ_AFFINITY, &affd);
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}
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static void nvme_disable_io_queues(struct nvme_dev *dev)
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@ -3019,6 +2980,7 @@ static struct pci_driver nvme_driver = {
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static int __init nvme_init(void)
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{
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BUILD_BUG_ON(IRQ_AFFINITY_MAX_SETS < 2);
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return pci_register_driver(&nvme_driver);
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}
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