Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Tomasz Figa | 1748 | 94.79% | 1 | 25.00% |
Yong Zhi | 79 | 4.28% | 1 | 25.00% |
Sakari Ailus | 17 | 0.92% | 2 | 50.00% |
Total | 1844 | 4 |
// SPDX-License-Identifier: GPL-2.0 /* * Copyright (C) 2018 Intel Corporation. * Copyright 2018 Google LLC. * * Author: Tuukka Toivonen <tuukka.toivonen@intel.com> * Author: Sakari Ailus <sakari.ailus@linux.intel.com> * Author: Samu Onkalo <samu.onkalo@intel.com> * Author: Tomasz Figa <tfiga@chromium.org> * */ #include <linux/dma-mapping.h> #include <linux/iopoll.h> #include <linux/pm_runtime.h> #include <linux/slab.h> #include <linux/vmalloc.h> #include <asm/set_memory.h> #include "ipu3-mmu.h" #define IPU3_PT_BITS 10 #define IPU3_PT_PTES (1UL << IPU3_PT_BITS) #define IPU3_PT_SIZE (IPU3_PT_PTES << 2) #define IPU3_PT_ORDER (IPU3_PT_SIZE >> PAGE_SHIFT) #define IPU3_ADDR2PTE(addr) ((addr) >> IPU3_PAGE_SHIFT) #define IPU3_PTE2ADDR(pte) ((phys_addr_t)(pte) << IPU3_PAGE_SHIFT) #define IPU3_L2PT_SHIFT IPU3_PT_BITS #define IPU3_L2PT_MASK ((1UL << IPU3_L2PT_SHIFT) - 1) #define IPU3_L1PT_SHIFT IPU3_PT_BITS #define IPU3_L1PT_MASK ((1UL << IPU3_L1PT_SHIFT) - 1) #define IPU3_MMU_ADDRESS_BITS (IPU3_PAGE_SHIFT + \ IPU3_L2PT_SHIFT + \ IPU3_L1PT_SHIFT) #define IMGU_REG_BASE 0x4000 #define REG_TLB_INVALIDATE (IMGU_REG_BASE + 0x300) #define TLB_INVALIDATE 1 #define REG_L1_PHYS (IMGU_REG_BASE + 0x304) /* 27-bit pfn */ #define REG_GP_HALT (IMGU_REG_BASE + 0x5dc) #define REG_GP_HALTED (IMGU_REG_BASE + 0x5e0) struct imgu_mmu { struct device *dev; void __iomem *base; /* protect access to l2pts, l1pt */ spinlock_t lock; void *dummy_page; u32 dummy_page_pteval; u32 *dummy_l2pt; u32 dummy_l2pt_pteval; u32 **l2pts; u32 *l1pt; struct imgu_mmu_info geometry; }; static inline struct imgu_mmu *to_imgu_mmu(struct imgu_mmu_info *info) { return container_of(info, struct imgu_mmu, geometry); } /** * imgu_mmu_tlb_invalidate - invalidate translation look-aside buffer * @mmu: MMU to perform the invalidate operation on * * This function invalidates the whole TLB. Must be called when the hardware * is powered on. */ static void imgu_mmu_tlb_invalidate(struct imgu_mmu *mmu) { writel(TLB_INVALIDATE, mmu->base + REG_TLB_INVALIDATE); } static void call_if_imgu_is_powered(struct imgu_mmu *mmu, void (*func)(struct imgu_mmu *mmu)) { if (!pm_runtime_get_if_in_use(mmu->dev)) return; func(mmu); pm_runtime_put(mmu->dev); } /** * imgu_mmu_set_halt - set CIO gate halt bit * @mmu: MMU to set the CIO gate bit in. * @halt: Desired state of the gate bit. * * This function sets the CIO gate bit that controls whether external memory * accesses are allowed. Must be called when the hardware is powered on. */ static void imgu_mmu_set_halt(struct imgu_mmu *mmu, bool halt) { int ret; u32 val; writel(halt, mmu->base + REG_GP_HALT); ret = readl_poll_timeout(mmu->base + REG_GP_HALTED, val, (val & 1) == halt, 1000, 100000); if (ret) dev_err(mmu->dev, "failed to %s CIO gate halt\n", halt ? "set" : "clear"); } /** * imgu_mmu_alloc_page_table - allocate a pre-filled page table * @pteval: Value to initialize for page table entries with. * * Return: Pointer to allocated page table or NULL on failure. */ static u32 *imgu_mmu_alloc_page_table(u32 pteval) { u32 *pt; int pte; pt = (u32 *)__get_free_page(GFP_KERNEL); if (!pt) return NULL; for (pte = 0; pte < IPU3_PT_PTES; pte++) pt[pte] = pteval; set_memory_uc((unsigned long int)pt, IPU3_PT_ORDER); return pt; } /** * imgu_mmu_free_page_table - free page table * @pt: Page table to free. */ static void imgu_mmu_free_page_table(u32 *pt) { set_memory_wb((unsigned long int)pt, IPU3_PT_ORDER); free_page((unsigned long)pt); } /** * address_to_pte_idx - split IOVA into L1 and L2 page table indices * @iova: IOVA to split. * @l1pt_idx: Output for the L1 page table index. * @l2pt_idx: Output for the L2 page index. */ static inline void address_to_pte_idx(unsigned long iova, u32 *l1pt_idx, u32 *l2pt_idx) { iova >>= IPU3_PAGE_SHIFT; if (l2pt_idx) *l2pt_idx = iova & IPU3_L2PT_MASK; iova >>= IPU3_L2PT_SHIFT; if (l1pt_idx) *l1pt_idx = iova & IPU3_L1PT_MASK; } static u32 *imgu_mmu_get_l2pt(struct imgu_mmu *mmu, u32 l1pt_idx) { unsigned long flags; u32 *l2pt, *new_l2pt; u32 pteval; spin_lock_irqsave(&mmu->lock, flags); l2pt = mmu->l2pts[l1pt_idx]; if (l2pt) goto done; spin_unlock_irqrestore(&mmu->lock, flags); new_l2pt = imgu_mmu_alloc_page_table(mmu->dummy_page_pteval); if (!new_l2pt) return NULL; spin_lock_irqsave(&mmu->lock, flags); dev_dbg(mmu->dev, "allocated page table %p for l1pt_idx %u\n", new_l2pt, l1pt_idx); l2pt = mmu->l2pts[l1pt_idx]; if (l2pt) { imgu_mmu_free_page_table(new_l2pt); goto done; } l2pt = new_l2pt; mmu->l2pts[l1pt_idx] = new_l2pt; pteval = IPU3_ADDR2PTE(virt_to_phys(new_l2pt)); mmu->l1pt[l1pt_idx] = pteval; done: spin_unlock_irqrestore(&mmu->lock, flags); return l2pt; } static int __imgu_mmu_map(struct imgu_mmu *mmu, unsigned long iova, phys_addr_t paddr) { u32 l1pt_idx, l2pt_idx; unsigned long flags; u32 *l2pt; if (!mmu) return -ENODEV; address_to_pte_idx(iova, &l1pt_idx, &l2pt_idx); l2pt = imgu_mmu_get_l2pt(mmu, l1pt_idx); if (!l2pt) return -ENOMEM; spin_lock_irqsave(&mmu->lock, flags); if (l2pt[l2pt_idx] != mmu->dummy_page_pteval) { spin_unlock_irqrestore(&mmu->lock, flags); return -EBUSY; } l2pt[l2pt_idx] = IPU3_ADDR2PTE(paddr); spin_unlock_irqrestore(&mmu->lock, flags); return 0; } /** * imgu_mmu_map - map a buffer to a physical address * * @info: MMU mappable range * @iova: the virtual address * @paddr: the physical address * @size: length of the mappable area * * The function has been adapted from iommu_map() in * drivers/iommu/iommu.c . */ int imgu_mmu_map(struct imgu_mmu_info *info, unsigned long iova, phys_addr_t paddr, size_t size) { struct imgu_mmu *mmu = to_imgu_mmu(info); int ret = 0; /* * both the virtual address and the physical one, as well as * the size of the mapping, must be aligned (at least) to the * size of the smallest page supported by the hardware */ if (!IS_ALIGNED(iova | paddr | size, IPU3_PAGE_SIZE)) { dev_err(mmu->dev, "unaligned: iova 0x%lx pa %pa size 0x%zx\n", iova, &paddr, size); return -EINVAL; } dev_dbg(mmu->dev, "map: iova 0x%lx pa %pa size 0x%zx\n", iova, &paddr, size); while (size) { dev_dbg(mmu->dev, "mapping: iova 0x%lx pa %pa\n", iova, &paddr); ret = __imgu_mmu_map(mmu, iova, paddr); if (ret) break; iova += IPU3_PAGE_SIZE; paddr += IPU3_PAGE_SIZE; size -= IPU3_PAGE_SIZE; } call_if_imgu_is_powered(mmu, imgu_mmu_tlb_invalidate); return ret; } /** * imgu_mmu_map_sg - Map a scatterlist * * @info: MMU mappable range * @iova: the virtual address * @sg: the scatterlist to map * @nents: number of entries in the scatterlist * * The function has been adapted from default_iommu_map_sg() in * drivers/iommu/iommu.c . */ size_t imgu_mmu_map_sg(struct imgu_mmu_info *info, unsigned long iova, struct scatterlist *sg, unsigned int nents) { struct imgu_mmu *mmu = to_imgu_mmu(info); struct scatterlist *s; size_t s_length, mapped = 0; unsigned int i; int ret; for_each_sg(sg, s, nents, i) { phys_addr_t phys = page_to_phys(sg_page(s)) + s->offset; s_length = s->length; if (!IS_ALIGNED(s->offset, IPU3_PAGE_SIZE)) goto out_err; /* must be IPU3_PAGE_SIZE aligned to be mapped singlely */ if (i == nents - 1 && !IS_ALIGNED(s->length, IPU3_PAGE_SIZE)) s_length = PAGE_ALIGN(s->length); ret = imgu_mmu_map(info, iova + mapped, phys, s_length); if (ret) goto out_err; mapped += s_length; } call_if_imgu_is_powered(mmu, imgu_mmu_tlb_invalidate); return mapped; out_err: /* undo mappings already done */ imgu_mmu_unmap(info, iova, mapped); return 0; } static size_t __imgu_mmu_unmap(struct imgu_mmu *mmu, unsigned long iova, size_t size) { u32 l1pt_idx, l2pt_idx; unsigned long flags; size_t unmap = size; u32 *l2pt; if (!mmu) return 0; address_to_pte_idx(iova, &l1pt_idx, &l2pt_idx); spin_lock_irqsave(&mmu->lock, flags); l2pt = mmu->l2pts[l1pt_idx]; if (!l2pt) { spin_unlock_irqrestore(&mmu->lock, flags); return 0; } if (l2pt[l2pt_idx] == mmu->dummy_page_pteval) unmap = 0; l2pt[l2pt_idx] = mmu->dummy_page_pteval; spin_unlock_irqrestore(&mmu->lock, flags); return unmap; } /** * imgu_mmu_unmap - Unmap a buffer * * @info: MMU mappable range * @iova: the virtual address * @size: the length of the buffer * * The function has been adapted from iommu_unmap() in * drivers/iommu/iommu.c . */ size_t imgu_mmu_unmap(struct imgu_mmu_info *info, unsigned long iova, size_t size) { struct imgu_mmu *mmu = to_imgu_mmu(info); size_t unmapped_page, unmapped = 0; /* * The virtual address, as well as the size of the mapping, must be * aligned (at least) to the size of the smallest page supported * by the hardware */ if (!IS_ALIGNED(iova | size, IPU3_PAGE_SIZE)) { dev_err(mmu->dev, "unaligned: iova 0x%lx size 0x%zx\n", iova, size); return -EINVAL; } dev_dbg(mmu->dev, "unmap this: iova 0x%lx size 0x%zx\n", iova, size); /* * Keep iterating until we either unmap 'size' bytes (or more) * or we hit an area that isn't mapped. */ while (unmapped < size) { unmapped_page = __imgu_mmu_unmap(mmu, iova, IPU3_PAGE_SIZE); if (!unmapped_page) break; dev_dbg(mmu->dev, "unmapped: iova 0x%lx size 0x%zx\n", iova, unmapped_page); iova += unmapped_page; unmapped += unmapped_page; } call_if_imgu_is_powered(mmu, imgu_mmu_tlb_invalidate); return unmapped; } /** * imgu_mmu_init() - initialize IPU3 MMU block * * @parent: struct device parent * @base: IOMEM base of hardware registers. * * Return: Pointer to IPU3 MMU private data pointer or ERR_PTR() on error. */ struct imgu_mmu_info *imgu_mmu_init(struct device *parent, void __iomem *base) { struct imgu_mmu *mmu; u32 pteval; mmu = kzalloc(sizeof(*mmu), GFP_KERNEL); if (!mmu) return ERR_PTR(-ENOMEM); mmu->dev = parent; mmu->base = base; spin_lock_init(&mmu->lock); /* Disallow external memory access when having no valid page tables. */ imgu_mmu_set_halt(mmu, true); /* * The MMU does not have a "valid" bit, so we have to use a dummy * page for invalid entries. */ mmu->dummy_page = (void *)__get_free_page(GFP_KERNEL); if (!mmu->dummy_page) goto fail_group; pteval = IPU3_ADDR2PTE(virt_to_phys(mmu->dummy_page)); mmu->dummy_page_pteval = pteval; /* * Allocate a dummy L2 page table with all entries pointing to * the dummy page. */ mmu->dummy_l2pt = imgu_mmu_alloc_page_table(pteval); if (!mmu->dummy_l2pt) goto fail_dummy_page; pteval = IPU3_ADDR2PTE(virt_to_phys(mmu->dummy_l2pt)); mmu->dummy_l2pt_pteval = pteval; /* * Allocate the array of L2PT CPU pointers, initialized to zero, * which means the dummy L2PT allocated above. */ mmu->l2pts = vzalloc(IPU3_PT_PTES * sizeof(*mmu->l2pts)); if (!mmu->l2pts) goto fail_l2pt; /* Allocate the L1 page table. */ mmu->l1pt = imgu_mmu_alloc_page_table(mmu->dummy_l2pt_pteval); if (!mmu->l1pt) goto fail_l2pts; pteval = IPU3_ADDR2PTE(virt_to_phys(mmu->l1pt)); writel(pteval, mmu->base + REG_L1_PHYS); imgu_mmu_tlb_invalidate(mmu); imgu_mmu_set_halt(mmu, false); mmu->geometry.aperture_start = 0; mmu->geometry.aperture_end = DMA_BIT_MASK(IPU3_MMU_ADDRESS_BITS); return &mmu->geometry; fail_l2pts: vfree(mmu->l2pts); fail_l2pt: imgu_mmu_free_page_table(mmu->dummy_l2pt); fail_dummy_page: free_page((unsigned long)mmu->dummy_page); fail_group: kfree(mmu); return ERR_PTR(-ENOMEM); } /** * imgu_mmu_exit() - clean up IPU3 MMU block * * @info: MMU mappable range */ void imgu_mmu_exit(struct imgu_mmu_info *info) { struct imgu_mmu *mmu = to_imgu_mmu(info); /* We are going to free our page tables, no more memory access. */ imgu_mmu_set_halt(mmu, true); imgu_mmu_tlb_invalidate(mmu); imgu_mmu_free_page_table(mmu->l1pt); vfree(mmu->l2pts); imgu_mmu_free_page_table(mmu->dummy_l2pt); free_page((unsigned long)mmu->dummy_page); kfree(mmu); } void imgu_mmu_suspend(struct imgu_mmu_info *info) { struct imgu_mmu *mmu = to_imgu_mmu(info); imgu_mmu_set_halt(mmu, true); } void imgu_mmu_resume(struct imgu_mmu_info *info) { struct imgu_mmu *mmu = to_imgu_mmu(info); u32 pteval; imgu_mmu_set_halt(mmu, true); pteval = IPU3_ADDR2PTE(virt_to_phys(mmu->l1pt)); writel(pteval, mmu->base + REG_L1_PHYS); imgu_mmu_tlb_invalidate(mmu); imgu_mmu_set_halt(mmu, false); }
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